Insulin for the treatment of women with gestational diabetes

Julie Brown; Luke Grzeskowiak; Kathryn Williamson; Michelle R Downie; Caroline A Crowther

doi:10.1002/14651858.CD012037.pub2

نقش انسولین در درمان زنان مبتلا به دیابت بارداری

Declaraciones de intereses de los autores

Versión publicada: 05 noviembre 2017 Historial de versiones

https://doi.org/10.1002/14651858.CD012037.pub2

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چکیده

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پیشینه

دیابت ملیتوس بارداری (gestational diabetes mellitus; GDM) با عوارض کوتاه‌مدت و طولانی‌مدت برای مادر و نوزادش همراه است. زنانی که قادر به حفظ غلظت قند خون خود با اهداف درمانی از پیش تعیین ‌شده با استفاده از مداخلات رژیم غذایی و سبک زندگی نیستند، نیاز به درمان‌های دارویی ضد‐دیابتی خواهند داشت. این مطالعه مروری به بررسی ایمنی و اثربخشی انسولین در مقایسه با درمان‌های دارویی خوراکی ضد‐دیابتی، مداخلات غیر‐دارویی و رژیم‌های انسولین می‌پردازد.

اهداف

بررسی اثرات انسولین در درمان زنان مبتلا به دیابت بارداری.

روش‌های جست‌وجو

ما پایگاه ثبت کارآزمایی‌های گروه بارداری و زایمان در کاکرین (1 می 2017)، ClinicalTrials.gov، پلت‌فرم بین‌المللی ثبت کارآزمایی‌های بالینی سازمان جهانی بهداشت (ICTRP) (1 می 2017) و فهرست منابع مطالعات بازیابی شده را جست‌وجو کردیم.

معیارهای انتخاب

کارآزمایی‌های تصادفی‌سازی و کنترل شده (شامل کارآزمایی‌هایی که به‌صورت خلاصه منتشر شدند) را وارد کردیم که به مقایسه موارد زیر پرداختند:

الف) انسولین با درمان دارویی خوراکی ضد‐دیابتی،

ب) با یک مداخله غیر‐دارویی،

ج) آنالوگ‌های مختلف انسولین؛

د) رژیم‌های مختلف انسولین برای درمان زنان مبتلا به GDM.

ما کارآزمایی‌های شبه‌‐تصادفی‌شده و کارآزمایی‌هایی را که زنان مبتلا به دیابت نوع 1 یا نوع 2 پیش از بارداری را انتخاب کردند، از مطالعه حذف کردیم. کارآزمایی‏‌های متقاطع (cross‐over) برای ورود مناسب نبودند.

گردآوری و تجزیه‌وتحلیل داده‌ها

دو نویسنده مرور به‌طور مستقل از هم به بررسی واجد شرایط بودن مطالعه، خطر سوگیری (bias)، و استخراج داده‌ها پرداختند. دقت داده‌ها کنترل شد.

نتایج اصلی

ما 53 مطالعه مرتبط (103 مقاله) را انتخاب کردیم، که داده‌های مربوط به 7381 زن را گزارش کردند. چهل‌وشش مطالعه از آنها داده‌های مربوط به 6435 نوزاد را گزارش کردند اما تجزیه‌و‌تحلیل‌های ما بر اساس تعداد کمتری از مطالعات/شرکت‌کنندگان انجام شد.

در مجموع، خطر سوگیری نامشخص بود؛ 40 کارآزمایی از 53 مورد انتخاب شده کورسازی نشده بودند. به‌طور کلی، کیفیت شواهد از متوسط تا بسیار پائین رتبه‌بندی شد. دلایل اولیه برای تنزل (downgrading) درجه شواهد عبارت بودند از عدم دقت، خطر سوگیری و ناهمگونی. نتایج را برای پیامدهای سیستم درجه‌‏بندی توصیه‏، ارزیابی، توسعه و ارزشیابی (GRADE) مادری و نوزادی برای مقایسه اصلی گزارش می‌کنیم.

انسولین در مقابل درمان دارویی خوراکی ضد‐دیابت

برای مادر، انسولین در مقایسه با درمان دارویی خوراکی ضد‐دیابتی با افزایش خطر اختلالات ناشی از فشار خون بالا در دوران بارداری (تعریف نشده) مرتبط بود (خطر نسبی (RR): 1.89؛ 95% فاصله اطمینان (CI): 1.14 تا 3.12؛ چهار مطالعه؛ 1214 زن؛ شواهد با کیفیت متوسط). شواهد واضحی در مورد تفاوت بین زنانی که با انسولین درمان شده و زنانی که با درمان دارویی خوراکی ضد‐دیابتی درمان شدند، از نظر خطر ابتلا به پره‌اکلامپسی (pre‐eclampsia) (RR: 1.14؛ 95% CI؛ 0.86 تا 1.52؛ 10 مطالعه؛ 2060 زن؛ شواهد با کیفیت متوسط)؛ خطر زایمان با عمل سزارین (RR: 1.03؛ 95% CI؛ 0.93 تا 1.14؛ 17 مطالعه؛ 1988 زن؛ شواهد با کیفیت متوسط)؛ یا خطر ابتلا به دیابت نوع 2 (فقط متفورمین (metformin)) (RR: 1.39؛ 95% CI؛ 0.80 تا 2.44؛ دو مطالعه؛ 754 زن؛ شواهد با کیفیت متوسط) وجود نداشت. خطر القای زایمان در افرادی که تحت درمان با انسولین قرار گرفتند در مقایسه با درمان دارویی خوراکی ضد‐دیابتی ممکن است افزایش یابد، هر چند شواهد شفاف نیست (میانگین RR: 1.30؛ 95% CI؛ 0.96 تا 1.75؛ سه مطالعه؛ 348 زن؛ I² = 32%؛ شواهد با کیفیت متوسط). هیچ شواهد واضحی درباره تفاوت در احتباس وزن پس از زایمان بین زنان تحت درمان با انسولین و زنانی که درمان دارویی خوراکی ضد‐دیابتی (متفورمین) را در هفته‌های شش تا هشت پس از زایمان (MD؛ 1.60‐ کیلوگرم؛ 95% CI؛ 6.34‐ تا 3.14؛ یک مطالعه؛ 167 زن؛ شواهد با کیفیت پائین) یا یک سال پس از زایمان (MD؛ 3.70‐؛ 95% CI؛ 8.50‐ تا 1.10؛ یک مطالعه؛ 176 زن؛ شواهد با کیفیت پائین) دریافت کردند، وجود نداشت. پیامدهای مربوط به تروما/پارگی پرینه یا افسردگی پس از زایمان در مطالعات وارد شده گزارش نشدند.

برای نوزاد، شواهدی وجود نداشت که تفاوت واضحی را بین مادرانی که با انسولین درمان شدند و مادرانی که با درمان دارویی خوراکی ضد‐دیابتی تحت درمان قرار گرفتند از نظر خطر داشتن نوزاد با اندازه بزرگ برای سن بارداری (میانگین RR: 1.01؛ 95% CI؛ 0.76 تا 1.35؛ 13 مطالعه؛ 2352 نوزاد؛ شواهد با کیفیت متوسط)؛ خطر مرگ‌ومیر پری‌ناتال (مرگ نوزاد یا جنین) (میانگین RR؛ 0.85؛ 95% CI؛ 0.29 تا 2.49؛ 10 مطالعه؛ 1463 نوزاد؛ شواهد با کیفیت پائین)؛ برای خطر ترکیبی از مرگ یا موربیدیتی جدی (میانگین RR؛ 1.03؛ 95% CI؛ 0.84 تا 1.26؛ دو مطالعه؛ 760 نوزاد؛ شواهد با کیفیت متوسط)؛ خطر هیپوگلیسمی نوزادی (neonatal hypoglycaemia) (میانگین RR؛ 1.14؛ 95% CI؛ 0.85 تا 1.52؛ 24 مطالعه؛ 3892 نوزاد؛ شواهد با کیفیت پائین)؛ چاقی نوزاد هنگام زایمان (درصد توده چربی) (MD؛ 1.6%؛ 95% CI؛ 3.77‐ تا 0.57؛ یک مطالعه؛ 82 نوزاد؛ شواهد با کیفیت متوسط)؛ چاقی نوزاد هنگام زایمان (مجموع چین‌های پوستی/میلی‌متر) (MD؛ 0.8 میلی‌متر؛ 95% CI؛ 2.33‐ تا 0.73؛ اثرات تصادفی؛ یک مطالعه؛ 82 نوزاد؛ شواهد با کیفیت بسیار پائین)؛ یا چاقی دوران کودکی (درصد کلی توده چربی)) (MD؛ 0.5%؛ 95% CI؛ 0.49‐ تا 1.49؛ یک مطالعه؛ 318 کودک؛ شواهد با کیفیت پائین) نشان دهد. همچنین شواهدی با کیفیت پائین تفاوت بارزی را بین گروه‌ها از نظر نرخ ناتوانی عصبی‌‐حسی در دوران کودکی نشان نداد: اختلالات شنوایی (RR: 0.31؛ 95% CI؛ 0.01 تا 7.49؛ یک مطالعه؛ 93 کودک)، اختلال بینایی (RR: 0.31؛ 95% CI؛ 0.03 تا 2.90؛ یک مطالعه؛ 93 کودک)، یا هر نوع تأخیر خفیف در تکامل (RR: 1.07؛ 95% CI؛ 0.33 تا 3.44؛ یک مطالعه؛ 93 کودک). مرگ‌ومیر نوزاد در آینده، و دیابت‌های دوران کودکی به‌ عنوان پیامدها در مطالعات وارد شده گزارش نشدند.

ما همچنین مقایسه‌های مربوط به انسولین رگولار انسانی را در مقابل سایر آنالوگ‌های انسولین‌‌، انسولین در مقابل رژیم غذایی/مراقبت استاندارد، انسولین در مقابل ورزش و مقایسه رژیم‌های انسولین را بررسی کردیم، اما شواهد کافی برای تعیین تفاوت‌ها میان بسیاری از پیامدهای کلیدی سلامت وجود نداشت. لطفا برای اطلاعات بیشتر در مورد این مقایسه‌ها به نتایج اصلی مراجعه کنید.

نتیجه‌گیری‌های نویسندگان

مقایسه اصلی در این مطالعه مروری، انسولین در مقابل درمان‌های دارویی خوراکی ضد‐دیابتی است. انسولین و درمان‌های دارویی خوراکی ضد‐دیابتی اثرات مشابهی بر پیامدهای کلیدی سلامت دارند. به دلیل وجود عدم دقت، خطر سوگیری و ناهمگونی، سطح کیفیت شواهد از بسیار پائین تا متوسط رتبه‌بندی شد.

برای مقایسه‌های دیگر این مرور (انسولین در مقایسه با مداخلات غیر‐دارویی، آنالوگ‌های مختلف انسولین یا رژیم‌های مختلف انسولین)، حجم کافی از شواهد با کیفیت بالا برای تعیین تفاوت‌ها در پیامدهای کلیدی سلامت وجود ندارد.

پیامدهای طولانی‌مدت مادر و نوزاد برای همه مقایسه‌ها ضعیف گزارش شد.

شواهد نشان می‌دهد که اثرات درمان با انسولین یا درمان‌های دارویی خوراکی ضد‐دیابتی با حداقل آسیب همراه هستند. انتخاب استفاده از یک درمان یا درمان دیگر ممکن است بر اساس اولویت پزشک یا مادر، قابلیت دسترسی یا شدت GDM باشد. برای بررسی رژیم‌های مناسب انسولین، انجام تحقیقات بیشتری لازم است. هدف تحقیقات بیشتر می‌تواند گزارش داده‌ها برای پیامدهای GDM استاندارد شده باشد.

PICO

Population

Intervention

Comparison

Outcome

El uso y la enseñanza del modelo PICO están muy extendidos en el ámbito de la atención sanitaria basada en la evidencia para formular preguntas y estrategias de búsqueda y para caracterizar estudios o metanálisis clínicos. PICO son las siglas en inglés de cuatro posibles componentes de una pregunta de investigación: paciente, población o problema; intervención; comparación; desenlace (outcome).

Para saber más sobre el uso del modelo PICO, puede consultar el Manual Cochrane.

خلاصه به زبان ساده

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نقش انسولین در درمان زنان مبتلا به دیابت بارداری

موضوع چیست؟

هدف از این مرور کاکرین، بررسی اثربخشی و ایمنی انسولین در مقایسه با مداخلات داروهای خوراکی یا غیر‐دارویی برای درمان دیابت ملیتوس بارداری بود (gestational diabetes mellitus; GDM، دیابت بارداری). زمان‌بندی‌های مختلف برای مصرف انسولین در طول روز نیز مورد بررسی قرار گرفت. ما تمام مطالعات مربوطه را گردآوری (می 2017) و داده‌ها را تجزیه‌و‌تحلیل کردیم.

چرا این موضوع مهم است؟

GDM می‌تواند منجر به عواقب کوتاه‌مدت و بلند‐مدت برای مادر و نوزادش شود.

معمولا، مشاوره در مورد رژیم غذایی و سبک زندگی اولین قدم است، و زنانی که قند خونشان بیش از حد بالا باقی می‌ماند می‌توانند با انسولین درمان شوند، که معمولا هر روز تزریق می‌شود.

پیدا کردن اینکه سایر گزینه‌های درمانی به اندازه انسولین ایمن و موثر هستند یا خیر، مهم است، زیرا درمان‌های دیگر ممکن است توسط زنانی که نمی‌خواهند انسولین به خود تزریق کنند ترجیح داده شود.

ما چه شواهدی را پیدا کردیم؟

ما شواهد را در 1 می 2017 جست‌وجو کرده و 53 مطالعه را یافتیم که داده‌های مربوط به 7381 مادر را گزارش کرده و 46 مطالعه که داده‌های مربوط به 6435 نوزاد را گزارش کردند. به‌طور کلی، کیفیت شواهد از بسیار پائین تا متوسط رتبه‌بندی شد. مطالعات در کشورهای مختلف انجام شد، از جمله کشورهای با درآمد پائین، متوسط و بالا. سه مطالعه حمایت مالی یا دارویی ارائه شده را توسط یک شرکت داروسازی گزارش کردند و 36 مطالعه هیچ‌گونه اظهاراتی را در مورد منبع بودجه خود ارائه نکردند.

برای مادران مبتلا به GDM، انسولین با افزایش احتمال اختلالات هیپرتانسیون در دوران بارداری همراه بود (فشار خون بالا ‐ تعریف نشده) هر چند زمانی که زنان درمان شده با انسولین با زنان درمان شده با داروی خوراکی ضد‐دیابتی مقایسه شدند، شواهدی از تفاوت در پره‌‐اکلامپسی (فشار خون بالا، ورم و وجود پروتئین در ادرار)، زایمان از طریق عمل سزارین، ابتلا به دیابت نوع 2، یا وزن پس از زایمان وجود نداشت.

به نظر می‌رسید که انسولین در مقایسه با داروی خوراکی ضد‐دیابتی احتمال القای زایمان را افزایش می‎‌دهد، اما این نتایج نامشخص هستند. آسیب به پرینه، بازگشت به وزن قبل از بارداری یا افسردگی پس از زایمان در مطالعات وارد شده گزارش نشدند. برای کودک، هیچ شواهدی از تفاوت واضح بین گروه‌ها از نظر خطر داشتن اندازه بزرگ بدن برای سن بارداری، مرگ یا بیماری‌های جدی پس از زایمان، قند خون پائین، داشتن اضافه وزن به عنوان یک نوزاد یا یک کودک، داشتن یک اختلال شنوایی یا بینایی، یا تاخیر اندک در رشد در 18 ماهگی وجود نداشت. هیچ کدام از مطالعات وارد شده سلامت کودک را در دوران کودکی بررسی نکردند.

ما همچنین مقایسه‌های مربوط به انسولین رگولار انسانی را در مقابل سایر انواع انسولین، انسولین در مقابل توصیه‌های رژیم غذایی همراه با مراقبت استاندارد، انسولین در مقابل ورزش، و همچنین مقایسه‌های مربوط به دوزها و تعداد دفعات مختلف انسولین را بررسی کردیم. با این حال، شواهد کافی برای اینکه بتوانیم از تفاوت‌های بسیاری از پیامدهای کلیدی سلامت مطمئن باشیم، وجود نداشت.

این یافته‌ها چه معنایی دارند؟

شواهد موجود نشان می‌دهد که در پیامدهای کوتاه‌مدت برای مادر و نوزاد بین درمان با تزریق انسولین و درمان با داروهای خوراکی تفاوت بسیار کمی وجود دارد. هنوز شواهد کافی برای پیامدهای بلندمدت وجود ندارد. تصمیم‌گیری در مورد اینکه کدام درمان می‌تواند استفاده شود، باید بر اساس بحث و تبادل نظر بین پزشک و مادر صورت گیرد. برای بررسی رژیم‌های مناسب انسولین برای زنان مبتلا به GDM، انجام تحقیقات بیشتری لازم است. مطالعات آینده می‌توانند به منظور ارائه گزارش در مورد پیامدهای بلندمدت و همچنین کوتاه‌مدت مادران و نوزادان آن‌ها انجام گیرند.

Authors' conclusions

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Implications for practice

The data summarised in this systematic review suggests that overall maternal and neonatal outcomes, where reported, are comparable for insulin and oral anti‐diabetic pharmacological therapies. Insulin and metformin have similar outcomes for mother and infant, however insulin does appear to have better outcomes than glibenclamide for reduced risk of being born large‐for‐gestational age (LGA) or macrosomic and reduced risk of neonatal hypoglycaemia. Current data have not yet fully explored the long‐term effects of insulin or oral anti‐diabetic pharmacological therapy for maternal and childhood outcomes and there is therefore insufficient evidence to be able to draw any definite conclusions on long‐term benefits or harms.

The choice of insulin or oral anti‐diabetic pharmacological therapies could be based on informed consultation with the woman and include, preference, compliance, cost, accessibility to medication and control of maternal hyperglycaemia.

There is no clear evidence of a difference between regular human insulin and other insulin analogues for treating women with gestational diabetes. The choice of analogue could be guided by clinician preference, cost and availability.

There is insufficient evidence to determine if insulin improves short‐ and long‐term maternal and neonatal outcomes compared with diet/standard care or exercise.

There is insufficient evidence for different insulin treatment regimens to be able to draw any conclusions as to whether one is superior to another.

Implications for research

A network meta‐analysis may help to identify the superiority of one treatment over another (insulin versus oral anti‐diabetic pharmacological therapy; insulin analogue versus insulin analogue) using indirect rather than direct comparisons. Future studies could aim to report long‐term as well short‐term maternal and infant outcomes using standardised GDM outcomes.

Further trials are needed to identify the optimal treatment regimen/s for women with GDM being treated with insulin.

Summary of findings

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Summary of findings for the main comparison. Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (maternal outcomes)

Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (maternal outcomes)
Patient or population: the treatment of women (maternal outcomes) with gestational diabetes Setting: primary and secondary care (Canada, Egypt, USA, Brazil, Finland, Iran, Australia, New Zealand, India) Intervention: Insulin Comparison: Oral anti‐diabetic pharmacological therapy
Outcomes	*Anticipated absolute effects^ (95% CI)**		Relative effect (95% CI)	№ of participants (studies)	Quality of the evidence (GRADE)	Comments
Outcomes	Risk with oral anti‐diabetic agent	Risk with insulin	Relative effect (95% CI)	№ of participants (studies)	Quality of the evidence (GRADE)	Comments
Hypertensive disorders of pregnancy (pre‐eclampsia)	77 per 1000	88 per 1000 (66 to 117)	RR 1.14 (0.86 to 1.52)	2060 (10 RCTs)	⊕⊕⊕⊝ MODERATE ¹	No data were reported for eclampsia
Hypertensive disorders of pregnancy (not defined)	36 per 1000	69 per 1000 (42 to 114)	RR 1.89 (1.14 to 3.12)	1214 (4 RCTs)	⊕⊕⊕⊝ MODERATE ¹	There were no definitions for hypertensive disorders in pregnancy in the trials reporting this outcome.
Caesarean section	394 per 1000	405 per 1000 (366 to 449)	RR 1.03 (0.93 to 1.14)	1988 (17 RCTs)	⊕⊕⊕⊝ MODERATE ¹
Development of type 2 diabetes	52 per 1000	73 per 1000 (42 to 128)	RR 1.39 (0.80 to 2.44)	754 (2 RCTs)	⊕⊕⊕⊝ MODERATE ²	These 2 trials compared insulin with metformin. No other trials reported this long‐term outcome.
Perineal trauma/tearing ‐ not measured	‐	‐	‐	‐	‐	None of the included trials in this review pre‐specified or reported perineal trauma as an outcome.
Postnatal weight retention or return to pre‐pregnancy weight ‐ Maternal weight six to eight weeks postpartum ‐ Maternal weight one year postpartum	The mean weight at six to eight weeks postpartum was 80.8 kg The mean weight at one year postpartum was 81.8 kg	MD 1.6 kg lower (6.34 lower to 3.14 higher) MD 3.7 kg lower (8.5 lower to 1.1 higher)	MD 1.60 kg (‐6.34 to 3.14) MD 3.70 kg (‐8.50 to 1.10)	167 (1 RCT) 176 (1 RCT)	⊕⊕⊝⊝^2,3 LOW ⊕⊕⊝⊝^2,3 LOW
Postnatal depression ‐ not reported	‐	‐	‐	‐	‐	None of the included trials in this review pre‐specified or reported postnatal depression as an outcome.
Induction of labour	408 per 1000	535 per 1000 (424 to 669)	average RR 1.30, 95%CI 0.96,to 1.75	348 (3 RCTs)	⊕⊕⊕⊝ MODERATE ²	These 3 trials compared insulin with metformin. No other trials reported this outcome.
*The risk in the intervention group (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI). CI: Confidence interval; MD: mean difference; RR: Risk ratio
GRADE Working Group grades of evidence High quality: We are very confident that the true effect lies close to that of the estimate of the effect Moderate quality: We are moderately confident in the effect estimate: The true effect is likely to be close to the estimate of the effect, but there is a possibility that it is substantially different Low quality: Our confidence in the effect estimate is limited: The true effect may be substantially different from the estimate of the effect Very low quality: We have very little confidence in the effect estimate: The true effect is likely to be substantially different from the estimate of effect
¹ Risk of bias: Most of the trials were not blinded ‐ downgraded one level. ² Risk of bias: No blinding. Lacked methodological details to be able to judge randomisation or allocation concealment ‐ downgraded one level. ³ Imprecision: Wide confidence intervals and single study ‐ downgraded one level.

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Summary of findings 2. Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (infant/child/adult outcomes)

Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes
Patient or population: Infants of women with gestational diabetes. Setting: Primary and secondary care (Canada, Egypt, USA, Brazil, Finland, Iran, Australia, New Zealand, India) Intervention: Insulin Comparison: Oral anti‐diabetic pharmacological therapy.
Outcomes	*Anticipated absolute effects^ (95% CI)**		Relative effect (95% CI)	№ of participants (studies)	Quality of the evidence (GRADE)	Comments
Outcomes	Risk with oral anti‐diabetic agent	Risk with insulin	Relative effect (95% CI)	№ of participants (studies)	Quality of the evidence (GRADE)	Comments
Large‐for‐gestational age (birthweight > 90th centile)	159 per 1000	161 per 1000 (121 to 215)	Average RR 1.01 (0.76 to 1.35)	2352 (13 RCTs)	⊕⊕⊕⊝ MODERATE ¹
Perinatal (fetal and neonatal death) and later infant mortality	8 per 1000	7 per 1000 (2 to 20)	RR 0.85 (0.29 to 2.49)	1463 (10 RCTs)	⊕⊕⊝⊝ LOW ^1,2	Event rates are low 5/728 for the group whose mothers were treated with insulin and 6/735 for the group whose mothers were treated with anti‐diabetic pharmacological therapies. No data were reported for later infant mortality.
Death or serious morbidity composite	319 per 1000	329 per 1000 (268 to 402)	RR 1.03 (0.84 to 1.26)	760 (2 RCTs)	⊕⊕⊕⊝ MODERATE ¹	These 2 trials compared insulin with metformin. No other trials reported this outcome. One trial included: resuscitation in the delivery room, preterm birth (< 37 weeks), neonatal intensive care unit admission, birth injury or diagnosis of neonatal complication, glucose infusion, antibiotics or phototherapy. One trial included: hypoglycaemia ‐< 2.6 mmol/L, RDS, phototherapy, birth trauma, Apgar < 7 at 5 minutes, preterm birth (< 37 weeks)
Neonatal hypoglycaemia	111 per 1000	126 per 1000 (94 to 169)	Average RR 1.14 (0.85 to 1.52)	3892 (24 RCTs)	⊕⊕⊝⊝ LOW ^1,5
Adiposity at birth ‐ percentage fat mass	The mean percentage fat mass was 12.8%	MD 1.6% lower (3.77 lower to 0.57 higher)	MD ‐1.60 (‐3.77, 0.57)	82 (1 RCT)	⊕⊕⊕⊝ MODERATE ⁴
Adiposity at birth ‐ skinfold sum (mm)	The mean skinfold sum was 16 mm	MD 0.8 mm lower (0.49 lower to 0.73 higher)	MD ‐0.80 mm (‐2.33, 0.73)	82 (1 RCT)	⊕⊝⊝⊝ VERY LOW ^2,4,7
Adiposity in childhood up to 2 years ‐ total fat mass (%)	The mean childhood Total fat mass (%) ‐ Metformin was 16.4%	MD 0.5% higher (0.49 lower to 1.49 higher)	MD 0.50 % (‐0.49, 1.49)	318 (1 RCT)	⊕⊕⊝⊝ LOW ^1,4
Childhood/adulthood diabetes (type 1, type 2) ‐ not reported	‐	‐	‐	‐	‐	No data were pre‐specified or reported for type 1 or type 2 diabetes in childhood or adulthood in the included trials in this review.
Neurosensory disability in later childhood (18 months) Mild developmental delay Hearing impairment Visual impairment	104 per 1000 0 per 1000 21 per 1000	111 per 1000 (34 to 358) 0 per 1000 (0 to 0) 6 per 1000 (1 to 60)	RR 1.07, (0.33 to 3.44) RR 0.31; (0.01 to 7.49) RR 0.31, (0.03 to 2.90)	93 (1 RCT)	⊕⊕⊝⊝ LOW ^4,6
*The risk in the intervention group (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI). CI: Confidence interval; MD: mean difference; RDS: respiratory distress syndrome; RR: Risk ratio;
GRADE Working Group grades of evidence High quality: We are very confident that the true effect lies close to that of the estimate of the effect Moderate quality: We are moderately confident in the effect estimate: The true effect is likely to be close to the estimate of the effect, but there is a possibility that it is substantially different Low quality: Our confidence in the effect estimate is limited: The true effect may be substantially different from the estimate of the effect Very low quality: We have very little confidence in the effect estimate: The true effect is likely to be substantially different from the estimate of effect
¹ Risk of bias: Most of the trials were not blinded. Downgraded one level. ² Imprecision: Event rates are low and confidence intervals are wide crossing the line of no effect. Downgraded one level. ³ Inconsistency: I² = 78%. Downgraded one level. ⁴ Evidence is based on a single trial. Downgraded one level. ⁵ Inconsistency: I² = 51%. Downgraded one level. ⁶ Imprecision: Wide confidence intervals. Downgraded one level. ⁷ Risk of bias: Selective reporting and other bias detected. Downgraded one level.

Background

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The original review by Alwan 2009 has been split into three new reviews due to the complexity of the included interventions. The new review protocols include the following.

Lifestyle interventions for the treatment of women with gestational diabetes (Brown 2017a)

Oral anti‐diabetic pharmacological therapies for the treatment of women with gestational diabetes (Brown 2017b)

Insulin for the treatment of women with gestational diabetes (this review).

There will be similarities in the background, methods and outcomes between these three systematic reviews. Portions of the methods section of this protocol are based on a standard template used by Cochrane Pregnancy and Childbirth.

Description of the condition

Gestational diabetes mellitus (GDM), often referred to as gestational diabetes can be defined as 'glucose intolerance or hyperglycaemia (high blood glucose concentration) with onset or first recognition during pregnancy' (WHO 1999). GDM occurs when the body is unable to make enough insulin to meet the extra needs in pregnancy. The high blood sugars associated with GDM will usually return to normal after the birth of the baby. However, there is currently no universally accepted diagnostic criteria (ACOG 2013; ADA 2013, Coustan 2010; HAPO 2008; Hoffman 1998; IADPSG 2010; Metzger 1998; NICE 2015) (Table 1). GDM may include previously undetected type 1 diabetes, type 2 diabetes, or diabetes presenting only during pregnancy depending on when the timing of when diagnosis is made (HAPO 2008; IADPSG 2010; Metzger 1998; Nankervis 2014; WHO 2014).

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Table 1. Examples of diagnostic criteria for gestational diabetes mellitus

Organisation/professional body	Screening criteria	Diagnostic criteria
	One‐hour oral glucose challenge test	Oral glucose tolerance test	Fasting	1‐hour	2‐hour	3‐hour
ADA 2015b, IADPSG 2010, ADIPS 2014* (Nankervis 2014); WHO 2014*	‐	75 g	≥ 5.1 mmol/L (≥ 92 mg/dL)	≥ 10 mmol/L (≥ 180 mg/dL)	≥ 8.5 mmol/L (≥ 153 mg/dL)	‐
ADA 2015b	50 g (≥ 7.8 mmol/L; ≥ 140 mg/dL)	75 g	≥ 5.1 mmol/L (≥ 92 mg/dL)	≥ 10 mmol/L (≥ 180 mg/dL)	≥ 8.5 mmol/L (≥ 153 mg/dL)	‐
ACOG 2013 Carpenter and Coustan^ or National Diabetes Data Group^	50 g (> 7.2 mmol/L; > 130 mg/dL)	100 g	≥ 5.3 mmol/L (95 mg/dL)	≥ 10 mmol/L (180 mg/dL)	≥ 8.6 mmol/L (155 mg/dL)	≥ 7.8 mmol/L (140 mg/dL)
	50 g (> 7.8 mmol/L; > 140 mg/dL)	100 g	≥ 5.8 mmol/L (105 mg/dL)	≥ 10.6 mmol/L (190 mg/dL)	≥ 9.2 mmol/L (165 mg/dL)	≥ 8.0 mmol/L (145 mg/dL)
NICE 2008; WHO 1999*; ADIPS 1998 (Hoffman 1998)		75 g	≥ 7.0 mmol/L (≥ 126 mg/dL)	‐	≥ 11.1 mmol/L (≥ 200 mg/dL)	‐
NICE 2015	‐	75 g	≥ 5.6 mmol/L (≥ 101 mg/dL)	‐	≥7.8 mmol/L (140 mg/dL)	‐
New Zealand Ministry of Health 2014*	50 g if HbA1c < 41 mmol/mol (≥ 7.8 mmol/L; ≥ 140 mg/dL)	75 g	≥ 5.5 mmol/L (≥ 99 mg/dL)	‐	≥ 9.0 mmol/L (≥ 162 mg/dL)	‐

ADA: American Diabetes Association (recommends either the one step or two step strategy)

IADPSG: International Association of the Diabetes and Pregnancy Study Groups

ADIPS: Australasian Diabetes in Pregnancy Society

ACOG: American College of Obstetrics and Gynecology

NICE: National Institute for Health and Care Excellence

*1 abnormal result required for diagnosis

^2 or more abnormal results required for diagnosis

mmol/L ‐ millimoles per litre

mg/dL ‐ milligramme per decilitre

GDM is one of the most common pregnancy complications and the prevalence is rising worldwide with 1% to 36% of pregnancies being affected (Bottalico 2007; Cundy 2014; Duran 2014; Ferrara 2007; NICE 2015;Tran 2013). The prevalence of GDM is likely to continue to increase along with the increasing prevalence of maternal obesity and associated type 2 diabetes mellitus (Bottalico 2007; Mulla 2010; Petry 2010).

Screening and diagnosis of GDM

Regardless of whether universal or selective (risk factor) screening with a 50 gram (g) oral glucose challenge test is used, diagnosis of GDM is usually based on either a 75 g two‐hour oral glucose tolerance test (OGTT) or a 100 g three‐hour OGTT performed between 24 and 28 weeks' gestation (ADA 2013; IADPSG 2010; Nankervis 2014; NICE 2015; WHO 1999). Recommendations regarding diagnostic criteria vary nationally and internationally (Table 1), and these diagnostic criteria have changed over time, sometimes due to changing understanding about the effects of hyperglycaemia on pregnancy and infant outcomes (Coustan 2010), but also because of a lack of evidence clearly demonstrating the clinical and cost‐effectiveness of one criterion over another.

The Hyperglycaemia and Adverse Pregnancy Outcomes (HAPO) study (HAPO 2008) was a large, international observational study which reported graded linear associations in the odds of several GDM‐associated adverse outcomes and glucose levels at OGTT, with no clear threshold identified at which risk increased substantially. The International Association of the Diabetes and Pregnancy Study Groups (IADPSG) recommended diagnostic criteria using data from the HAPO study (IADPSG 2010). Applying the IADPSG criteria in most health environments will increase the number of women diagnosed with GDM. A study conducted in Vietnam showed that depending on the criteria used, the diagnosis of GDM varied between 5.9% (American Diabetes Association ‐ ADA), 20.4% (International Association of Diabetes in Pregnancy Study Groups ‐ IADPSG), 20.8% (Australasian Diabetes in Pregnancy Society ‐ ADIPS), and up to 24.3% (World Health Organization ‐ WHO) (Tran 2013). A Bulgarian study also reported differences in prevalence based on the diagnostic criteria ranging from 10.8% (European Association for the Study of Diabetes ‐ EASD), 13.5% (ADA), 16.2% (New Zealand Society for the Study of Diabetes ‐ NZSSD), 17.1% (WHO), 21.2% (ADIPS), 31.6% (IADPSG) (Boyadzhieva 2012).

Pathophysiology of GDM

Normal pregnancy is associated with significant changes in maternal metabolism (Lain 2007). In early pregnancy, oestrogen and progesterone stimulate maternal beta‐cell hyperplasia and insulin secretion, which promotes maternal nutrient storage (adipose and hepatic glycogen) to support later fetal growth. At this stage, insulin sensitivity is maintained or may even increase. However, as pregnancy progresses whole‐body insulin sensitivity steadily decreases, such that by the third trimester it is reduced by almost half (Barbour 2007). Several factors contribute to this, including placental hormones (human placental lactogen and placental growth hormone), cytokines released from adipocytes (IL‐6, TNF‐alpha), increased free fatty acids and lower adiponectin concentrations (Clapp 2006; Devlieger 2008). This results in decreased postprandial peripheral glucose disposal by up to 40% to 60% (Barbour 2007). In normal pregnancy, maternal glycaemia is maintained by a significant increase in insulin secretion of up to 200% to 250% (Barbour 2007; Lain 2007; Suman Rao 2013).

Regulation of fetal glucose metabolism requires (1) the maintenance of maternal glucose concentration through increasing maternal glucose production and at the same time developing maternal glucose intolerance and insulin resistance, (2) transfer of glucose to the fetus across the placenta, and (3) production of fetal insulin and uptake of glucose into adipose tissue and skeletal muscle (Suman Rao 2013).

Women with GDM have further reductions in insulin signalling and glucose uptake is decreased beyond that of normal pregnancy (Barbour 2007). This results in glucose intolerance, though glycaemia in pregnancy represents a continuum. In GDM, the steeper maternal‐fetal glucose gradient, especially postprandial, leads to increased fetal glucose uptake, which stimulates fetal insulin secretion. Insulin is a key fetal anabolic hormone and hyperinsulinaemia promotes fetal overgrowth leading to large‐for‐gestational age (LGA) infants, macrosomia, and possible organ damage (Catalano 2003; Ju 2008; Metzger 2008; Reece 2009).

Women with GDM also have increased circulating inflammatory cytokines and lower adiponectin concentrations leading to increased lipolysis and fatty acid concentrations. Placental transfer of free fatty acids contributes to increased fetal adiposity, independent of glucose uptake (Knopp 1985). Thus, even women with well‐controlled GDM still have increased risk of fetal macrosomia (Langer 2005).

Risk factors associated with GDM

A variety of factors have been associated with an increased risk of developing GDM. Non‐modifiable risk factors include advanced maternal age (Chamberlain 2013; Morisset 2010), high parity, non‐Caucasian race or ethnicity (in particular South Asian, Middle Eastern), family history of diabetes mellitus, maternal high or low birthweight, polycystic ovarian syndrome (Cypryk 2008; Petry 2010; Solomon 1997), a history of having a previous macrosomic infant (birthweight 4000 g or more), and a previous history of GDM (Petry 2010).

Modifiable risk factors include physical inactivity (Chasan‐Taber 2008), having a low‐fibre and high‐glycaemic load diet (Zhang 2006), maternal overweight (body mass index (BMI) equal to or greater than 25 kg/m²) or obesity (equal to or greater than 30 kg/m²) (Kim S 2010), and excessive weight gain during pregnancy, especially for those who are already overweight or obese (Hedderson 2010).

Clinical outcomes for women with pregnancy hyperglycaemia

Adverse outcomes have been consistently reported at higher rates in women diagnosed with GDM and their infants compared to women without GDM (Crowther 2005; Landon 2009; Metzger 2008; Reece 2009).

Women with GDM have an increased risk of developing pre‐eclampsia, are more likely to have their labour induced (Anderberg 2010; Crowther 2005; Ju 2008; Landon 2009; Metzger 2008), and are more likely to give birth by caesarean section (Landon 2009; Metzger 2008). The incidence of uterine rupture, shoulder dystocia and perineal lacerations is increased in women with GDM due to the increased likelihood of having a LGA or macrosomic baby (Jastrow 2010). Women who have experienced GDM are at a greater risk of metabolic dysfunction in later life (Shah 2008; Vohr 2008), with a crude cumulative incidence of type 2 diabetes of 10% to 20% within 10 years (Bellamy 2009; Kim 2002), but up to 50% when adjusted for retention and length of follow‐up (Kim 2002).

Neonatal, infant and later outcomes related to pregnancy hyperglycaemia

A significant adverse health outcome for babies born to mothers with GDM is being born LGA or macrosomic (Catalano 2003; Crowther 2005; Landon 2009; Metzger 2008; Reece 2009). LGA or macrosomic infants are at increased risk of birth injury, such as shoulder dystocia, perinatal asphyxia, bone fractures and nerve palsies (Esakoff 2009; Henriksen 2008; Langer 2005; Metzger 2008).

Babies born to women with GDM, compared with babies born to women without GDM, have significantly greater skinfold measures and fat mass compared with infants of women with normal glucose tolerance (Catalano 2003). The offspring of women with GDM are heavier (adjusted for height) and have greater adiposity than the offspring of women with normal glycaemia during pregnancy (Pettitt 1985; Pettitt 1993) and are more likely to develop early overweight or obesity, type 2 diabetes (Hillier 2007; Pettitt 1993; Whincup 2008) or metabolic syndrome (a cluster of risk factors defined by the occurrence of three of the following: obesity, hypertension, hypertriglyceridaemia and a low concentration of high‐density lipoprotein (HDL) cholesterol) in childhood, adolescence or adulthood (Guerrero‐Romero 2010; Harder 2009).

The development of the metabolic syndrome during childhood is a risk factor for the development of adult type 2 diabetes at 25 to 30 years of age (Morrison 2008). These health problems repeat across generations (Dabelea 2005; Mulla 2010) and are important from a public health perspective, because with each generation the prevalence of diabetes increases. Other adverse outcomes which are increased for babies born to women with GDM include respiratory distress syndrome, hypoglycaemia (which if prolonged can cause brain injury), hyperbilirubinaemia, hypertrophic cardiomyopathy, hypocalcaemia, hypomagnesaemia, polycythaemia and admission to the neonatal nursery (Metzger 2008; Reece 2009).

Description of the intervention

While women with gestational diabetes still make insulin, their bodies are insensitive to it and do not produce enough insulin to maintain glycaemic control. Insulin is often the treatment of choice for women who are unable to maintain glycaemic treatment targets with medical nutrition therapy or other pharmacological therapies (NICE 2015). Insulin may be an alternative for women who are unable to tolerate the side effects (gastrointestinal upset for example) of oral anti‐diabetic pharmacological therapies such as metformin. Glycaemic control is maintained by the replacement of insulin, which facilitates the transport of glucose from the blood stream into the cells of the body for energy. Insulin in itself describes a group of heterogeneous preparations that are clinically differentiated by their course of action over time. Rapid‐acting or short‐acting insulin is used to mimic the response of endogenous insulin to food intake and is useful in correcting postprandial hyperglycaemia, without causing preprandial hypoglycaemia (bolus insulin) (Lambert 2013; Negrato 2012). In contrast, intermediate‐acting and long‐acting insulin is primarily used to provide a continuous supply of small amounts of insulin independent of food intake, over a longer period of time, which regulates lipolysis and the output of hepatic glucose (basal insulin) (Lambert 2013; Negrato 2012). At normal therapeutic doses all types of insulin do not cross the placenta (Lambert 2013; Negrato 2012).

Types of insulin used during pregnancy

Rapid‐acting insulin

Insulin lispro, aspart and glulisine are commonly used rapid‐acting insulin analogues. Their onset of action is within 15 minutes or less following administration. Peak concentrations are reached between 30 to 80 minutes and the maximum duration of action is between three to six hours (Lambert 2013; Negrato 2012).

Short‐acting insulin

Regular human insulin ‐ has an onset of action between 30 to 60 minutes and a time to peak concentration of 90 to 120 minutes with a maximum duration of action of five to 12 hours (Lambert 2013).

Intermediate‐acting insulin

Neutral protamine Hagedorn insulin, also known as isophane insulin is a longer‐acting form of regular human insulin, it has an onset of action of about 60 to 120 minutes and a time to peak action of 240 to 480 minutes. The maximum duration of action is about 16 to 18 hours (Lambert 2013).

Long‐acting insulin

Insulin detemir ‐ this analogue has an onset of action about 60 to 120 minutes after administration and action lasts for 18 to 20 hours. There is no peak of action (Negrato 2012).

Insulin glargine ‐ this analogue has an onset of action about 60 to 120 minutes after administration and action lasts for 24 hours. There is no peak of action (Negrato 2012).

Pre‐mixed insulin ‐ contains a mixture of rapid‐acting or short‐acting insulin with intermediate‐acting insulin. Provides a more rapid onset of action with a subsequent peak and prolonged duration of action.

Other formulations of insulin

Pharmaceutical companies are currently working on other routes of administration of insulin including inhaled and oral. These are still in early trial phases and may be available in the future. Newer analogues of ultra‐long insulin are also being introduced.

Insulin regimens

As a result of the numerous types of insulin available, various regimens for insulin administration may be utilised. This may take the form of multiple injections throughout the day, or continuous administration by subcutaneous insulin infusion. The optimal insulin replacement regimen should be viewed in light of the need to provide appropriate basal insulin requirements across 24 hours, provide sufficient levels to cover food intake, have adequate provision for correction of blood glucose levels when needed, minimise blood glucose fluctuations, and therefore risk of hypoglycaemia and hyperglycaemia, and achieve optimal pregnancy outcomes. Insulin can be administered as:

a once‐daily dose which involves taking a single dose of insulin (intermediate‐ or long‐acting insulin) each day. Individuals may also take oral anti‐diabetic drugs in addition to insulin;
a twice‐daily regimen (basal‐plus) which involves adding in one or two doses of rapid‐acting insulin on to an intermediate or basal dose;
a basal‐bolus regimen which involves taking a long‐acting or intermediate‐acting dose and then separate injections of short‐ or rapid‐acting insulin at each meal. This regimen is more common in those with type 1 diabetes. An advantage of this regimen is that it offers flexibility over timing of meals and variations based on different carbohydrate quantities in meals;
a continuous subcutaneous infusion which involves delivery of a consistent amount of rapid‐acting insulin via an insulin pump. At meal times a bolus of insulin can be delivered to maintain glycaemic control.

How the intervention might work

Insulin is a pancreatic hormone that regulates the movement of glucose from blood into cells. Insulin lowers blood glucose by stimulating peripheral glucose uptake and by inhibiting glucose production and release by the liver. Insulin inhibits lipolysis (breakdown of fat), proteolysis (breakdown of proteins), and gluconeogenesis (manufacture of glucose). It also increases protein synthesis and conversion of excess glucose into fat (Girard 2006).

Why it is important to do this review

With the rising prevalence of gestational diabetes (Bottalico 2007; Mulla 2010), it is likely that more women will require pharmacotherapy to maintain glycaemic control during their pregnancy to reduce the associated maternal and neonatal short‐ and long‐term effects of gestational diabetes. Adherence to medication is an important aspect of treatment for gestational diabetes (NICE 2015). Oral anti‐diabetic agents may be an alternative to insulin. As more insulin analogues emerge on the market, it is important to establish their safety and efficacy for pregnant women with gestational diabetes and to identify the optimal regimen for administering insulin. This review will attempt to answer these important questions.

Objectives

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To evaluate the effects of insulin in treating women with gestational diabetes.

Methods

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Criteria for considering studies for this review

Types of studies

We included published or unpublished randomised in full text or abstract format. We excluded quasi‐randomised studies and cross‐over trials. Cluster‐randomised trials were eligible for inclusion but none were identified.

Types of participants

Participants were pregnant women diagnosed with gestational diabetes (diagnosis as defined by the individual trial). Women with type 1 or type 2 diabetes diagnosed prior to pregnancy were excluded.

Types of interventions

We considered the following interventions and comparisons.

Insulin (any type) versus oral anti‐diabetic agents
Insulin type A versus insulin type B (e.g. rapid‐acting versus short‐acting; intermediate‐acting versus long‐acting insulin)
Insulin (any type) versus diet/standard care
Insulin (any type) versus exercise
Insulin (any type) versus diet plus exercise
Insulin regimen A versus insulin regimen B
Insulin (any type) versus other treatment intervention not previously described

Types of outcome measures

These outcomes were identified from published Cochrane reviews of gestational diabetes, revised and selected by a group of Cochrane authors of systematic reviews related to the treatment of women with gestational diabetes. The outcomes were identified as being important to the mother, the infant and health service provision and included both short‐ and long‐term outcomes.

Primary outcomes

Maternal

Hypertensive disorders of pregnancy (including pre‐eclampsia, pregnancy‐induced hypertension, eclampsia, as defined by trialists)
Caesarean section
Development of type 2 diabetes (as defined by trialists, including results of postnatal testing)

Neonatal

Perinatal (fetal and neonatal death) and later infant mortality
Large‐for‐gestational age (LGA) (as defined by trialists)
Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy)
Neurosensory disability in later childhood (as defined by trialists)

Secondary outcomes

Maternal

Use of additional pharmacotherapy
Maternal hypoglycaemia (as defined by trialists)
Glycaemic control during/end of treatment (as defined by trialists)
Weight gain in pregnancy
Adherence to the intervention
Induction of labour
Placental abruption
Postpartum haemorrhage (as defined by trialists)
Postpartum infection
Perineal trauma/tearing
Breastfeeding at discharge, six weeks postpartum, six months or longer
Maternal mortality
Sense of well‐being and quality of life
Behavioural changes associated with the intervention
Views of the intervention
Relevant biomarker changes associated with the intervention (including adiponectin, free fatty acids, triglycerides, high‐density lipoproteins (HDL), low‐density lipoproteins (LDL), insulin)

Long‐term outcomes for mother

Postnatal depression
Body mass index (BMI)
Postnatal weight retention or return to pre‐pregnancy weight
Type 1 diabetes
Type 2 diabetes
Impaired glucose tolerance
Cardiovascular health (as defined by trialists including blood pressure, hypertension, cardiovascular disease, metabolic syndrome)

Fetal/neonatal outcomes

Stillbirth
Neonatal death
Macrosomia (greater than 4000 g; or as defined by individual study)
Small‐for‐gestational age (SGA) (as defined by trialists)
Birth trauma (shoulder dystocia, bone fracture, nerve palsy)
Gestational age at birth
Preterm birth (less than 37 weeks’ gestation; and less than 32 weeks' gestation)
Five‐minute Apgar less than seven
Birthweight and z score
Head circumference and z score
Length and z score
Ponderal index
Adiposity (including skinfold thickness measurements (mm); fat mass)
Neonatal hypoglycaemia (as defined by trialists)
Respiratory distress syndrome
Neonatal jaundice (hyperbilirubinaemia) (as defined by trialists)
Hypocalcaemia (as defined by trialists)
Polycythaemia (as defined by trialists)
Relevant biomarker changes associated with the intervention (including insulin, cord c‐peptide)

Later infant/childhood outcomes

Weight and z scores
Height and z scores
Head circumference and z scores
Adiposity (including BMI, skinfold thickness, fat mass)
Educational attainment
Blood pressure
Type 1 diabetes
Type 2 diabetes
Impaired glucose tolerance
Dyslipidaemia or metabolic syndrome

Child as an adult outcomes

Weight
Height
Adiposity (including BMI, skinfold thickness, fat mass)
Cardiovascular health (as defined by trialists including blood pressure, hypertension, cardiovascular disease, metabolic syndrome)
Employment, education and social status/achievement
Dyslipidaemia or metabolic syndrome
Type 1 diabetes
Type 2 diabetes
Impaired glucose tolerance

Health service use

Number of antenatal visits or admissions
Number of hospital or health professional visits (including midwife, obstetrician, physician, dietician, diabetic nurse)
Admission to neonatal intensive care unit/nursery
Duration of stay in neonatal intensive care unit or special care baby unit
Length of antenatal stay
Length of postnatal stay (maternal)
Length of postnatal stay (baby)
Cost of maternal care
Cost of offspring care
Costs associated with the intervention
Costs to families associated with the management provided
Cost of dietary monitoring (e.g. diet journals, dietician, nurse visits, etc)
Costs to families ‐ change of diet, extra antenatal visits
Extra use of healthcare services (consultations, blood glucose monitoring, length and number of antenatal visits)
Women’s view of treatment advice

Search methods for identification of studies

The following methods section of this protocol were based on a standard template used by Cochrane Pregnancy and Childbirth.

Electronic searches

We searched Cochrane Pregnancy and Childbirth’s Trials Register by contacting their Information Specialist (1 May 2017).

The Register is a database containing over 23,000 reports of controlled trials in the field of pregnancy and childbirth. For full search methods used to populate Pregnancy and Childbirth’s Trials Register including the detailed search strategies for CENTRAL, MEDLINE, Embase and CINAHL; the list of handsearched journals and conference proceedings, and the list of journals reviewed via the current awareness service, please follow this link to the editorial information about the Cochrane Pregnancy and Childbirth in the Cochrane Library and select the ‘Specialized Register ’ section from the options on the left side of the screen.

Briefly, Cochrane Pregnancy and Childbirth’s Trials Register is maintained by their Information Specialist and contains trials identified from:

monthly searches of the Cochrane Central Register of Controlled Trials (CENTRAL);
weekly searches of MEDLINE (Ovid);
weekly searches of Embase (Ovid);
monthly searches of CINAHL (EBSCO);
handsearches of 30 journals and the proceedings of major conferences;
weekly current awareness alerts for a further 44 journals plus monthly BioMed Central email alerts.

Search results are screened by two people and the full text of all relevant trial reports identified through the searching activities described above is reviewed. Based on the intervention described, each trial report is assigned a number that corresponds to a specific Pregnancy and Childbirth review topic (or topics), and is then added to the Register. The Information Specialist searches the Register for each review using this topic number rather than keywords. This results in a more specific search set which has been fully accounted for in the relevant review sections (Included studies; Excluded studies; Studies awaiting classification; Ongoing studies).

In addition, we searched ClinicalTrials.gov and the WHO International Clinical Trials Registry Platform (ICTRP) for unpublished, planned and ongoing trial reports using search terms detailed in Appendix 1 (1 May 2017).

Searching other resources

We searched the reference lists of retrieved studies.

We did not apply any language or date restrictions.

Data collection and analysis

The following methods section of this protocol was based on a standard template used by Cochrane Pregnancy and Childbirth.

Selection of studies

Two review authors independently assessed for inclusion all the potential studies we identified as a result of the search strategy. We resolved any disagreement through discussion or, if required, we consulted a third person.

We created a study flow diagram to map out the number of records identified, included and excluded (Figure 1).

Figure 1

Study flow diagram.

Data extraction and management

We designed a form to extract data. For eligible studies, two review authors extracted the data using the agreed form. We resolved discrepancies through discussion or, if required, we consulted a third person. We entered data into Review Manager software (RevMan 2014) and checked for accuracy. When information regarding any of the above was unclear, we attempted to contact authors of the original reports to provide further details.

Assessment of risk of bias in included studies

Two review authors independently assessed risk of bias for each study using the criteria outlined in the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011). We resolved any disagreement by discussion or by involving a third assessor.

(1) Random sequence generation (checking for possible selection bias)

We described for each included study the method used to generate the allocation sequence in sufficient detail to allow an assessment of whether it should produce comparable groups.

We assessed the method as:

low risk of bias (any truly random process, e.g. random number table; computer random number generator);
high risk of bias (any non‐random process, e.g. odd or even date of birth; hospital or clinic record number);
unclear risk of bias.

(2) Allocation concealment (checking for possible selection bias)

We described for each included study the method used to conceal allocation to interventions prior to assignment and assessed whether intervention allocation could have been foreseen in advance of, or during recruitment, or changed after assignment.

We assessed the methods as:

low risk of bias (e.g. telephone or central randomisation; consecutively numbered sealed opaque envelopes);
high risk of bias (open random allocation; unsealed or non‐opaque envelopes, alternation; date of birth);
unclear risk of bias.

(3.1) Blinding of participants and personnel (checking for possible performance bias)

We described for each included study the methods used, if any, to blind study participants and personnel from knowledge of which intervention a participant received. We considered that studies were at low risk of bias if they were blinded, or if we judged that the lack of blinding would be unlikely to affect results. We assessed blinding separately for different outcomes or classes of outcomes.

We assessed the methods as:

low, high or unclear risk of bias for participants;
low, high or unclear risk of bias for personnel.

(3.2) Blinding of outcome assessment (checking for possible detection bias)

We described for each included study the methods used, if any, to blind outcome assessors from knowledge of which intervention a participant received. We assessed blinding separately for different outcomes or classes of outcomes.

We assessed methods used to blind outcome assessment as:

low, high or unclear risk of bias.

(4) Incomplete outcome data (checking for possible attrition bias due to the amount, nature and handling of incomplete outcome data)

We described for each included study, and for each outcome or class of outcomes, the completeness of data including attrition and exclusions from the analysis. We stated whether attrition and exclusions were reported and the numbers included in the analysis at each stage (compared with the total randomised participants), reasons for attrition or exclusion where reported, and whether missing data were balanced across groups or were related to outcomes. Where sufficient information was reported, or could be supplied by the trial authors, we re‐included missing data in the analyses which we undertook.

We assessed methods as:

low risk of bias (e.g. no missing outcome data; missing outcome data balanced across groups);
high risk of bias (e.g. numbers or reasons for missing data imbalanced across groups; ‘as treated’ analysis done with substantial departure of intervention received from that assigned at randomisation);
unclear risk of bias.

(5) Selective reporting (checking for reporting bias)

We described for each included study how we investigated the possibility of selective outcome reporting bias and what we found.

We assessed the methods as:

low risk of bias (where it is clear that all of the study’s pre‐specified outcomes and all expected outcomes of interest to the review have been reported);
high risk of bias (where not all the study’s pre‐specified outcomes have been reported; one or more reported primary outcomes were not pre‐specified; outcomes of interest were reported incompletely and so cannot be used; study fails to include results of a key outcome that would have been expected to have been reported);
unclear risk of bias.

(6) Other bias (checking for bias due to problems not covered by (1) to (5) above)

We described for each included study any important concerns we have about other possible sources of bias.

We assessed whether each study was free of other problems that could put it at risk of bias:

low risk of other bias;
high risk of other bias;
unclear whether there is risk of other bias.

(7) Overall risk of bias

We made explicit judgements about whether studies were at high risk of bias, according to the criteria given in the Handbook (Higgins 2011). With reference to (1) to (6) above, we assessed the likely magnitude and direction of the bias and whether we considered it was likely to impact on the findings. We explored the impact of the level of bias through undertaking sensitivity analyses ‐ seeSensitivity analysis.

Assessing the quality of the body of evidence using the GRADE approach

The quality of the evidence was assessed using the GRADE approach as outlined in the GRADE handbook in order to assess the quality of the body of evidence relating to the following outcomes. We selected a maximum of seven outcomes for the mother and seven for the infant/offspring covering both short‐ and long‐term outcomes for the main comparisons.

Maternal outcomes

Hypertensive disorders of pregnancy (including pre‐eclampsia, pregnancy‐induced hypertension, eclampsia as defined by trialists)
Caesarean section
Development of type 2 diabetes
Perineal trauma/tearing
Postnatal weight retention or return to pre‐pregnancy weight
Postnatal depression
Induction of labour

Neonatal/child/adult outcomes

Large‐for‐gestational age (LGA)
Perinatal (fetal and neonatal death) and later infant mortality
Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy)
Neonatal hypoglycaemia
Adiposity (including BMI, skinfold thickness, fat mass)
Diabetes (type 1, type 2 in childhood/adulthood)
Neurosensory disability in later childhood (as defined by trialists)

Where data allowed we graded neonatal, child, and adult data for relevant outcomes.

We used the GRADEpro Guideline Development Tool to import data from Review Manager 5.3 (RevMan 2014) in order to create ’Summary of findings’ tables. The GRADE approach uses five considerations (study limitations, consistency of effect, imprecision, indirectness and publication bias) to assess the quality of the body of evidence for each outcome. The evidence can be downgraded from 'high quality' by one level for serious (or by two levels for very serious) limitations, depending on assessments for risk of bias, indirectness of evidence, serious inconsistency, imprecision of effect estimates or potential publication bias. A summary of the intervention effect and a measure of quality for each of the above outcomes was produced using the GRADE approach for the comparison of insulin versus oral anti‐diabetic pharmacological therapies for the mother and for the infant and for the child/adult.

Measures of treatment effect

Dichotomous data

For dichotomous data, we presented results as summary risk ratio with 95% confidence intervals.

Continuous data

For continuous data, we used the mean difference if outcomes are measured in the same way between trials. We used the standardised mean difference to combine trials that measure the same outcome, but used different methods.

Unit of analysis issues

Cluster‐randomised trials

We did not identify any cluster‐randomised trials. In future updates, if we identify any cluster‐randomised trials we will include them in the analyses along with individually‐randomised trials. We will make adjustments using the methods described in the Handbook [Section 16.3.4 or 16.3.6] using an estimate of the intra‐cluster correlation co‐efficient (ICC) derived from the trial (if possible), from a similar trial or from a study of a similar population. If we use ICCs from other sources, we will report this and conduct sensitivity analyses to investigate the effect of variation in the ICC. We will consider it reasonable to combine the results from both cluster‐randomised trials and individually‐randomised trials if there is little heterogeneity between the study designs and the interaction between the effect of intervention and the choice of randomisation unit is considered to be unlikely. If cluster‐randomised trials are included, we will seek statistical advice on appropriate analysis to enable inclusion of data in the meta‐analyses.

Other unit of analysis issues

Multiple pregnancy

There may be unit of analysis issues that arise when the women randomised have a multiple pregnancy. We presented maternal data as per woman randomised and neonatal data per infant.

Multiple‐arm studies

Where a trial had multiple intervention arms (Bertini 2005), we avoided 'double counting' of participants by splitting the 'shared' group into two groups with smaller sample size and included two comparisons.

Dealing with missing data

For included studies, we noted levels of attrition. We explored the impact of including studies with high levels of missing data (more than 20%) in the overall assessment of treatment effect by using sensitivity analysis.

For all outcomes, we carried out analyses, as far as possible, on an intention‐to‐treat basis, i.e. we attempted to include all participants randomised to each group in the analyses, and all participants were analysed in the group to which they were allocated, regardless of whether or not they received the allocated intervention. The denominator for each outcome in each trial was the number randomised minus any participants whose outcomes were known to be missing.

Assessment of heterogeneity

We assessed statistical heterogeneity in each meta‐analysis using the Tau², I² and Chi² statistics. We regarded heterogeneity as substantial if an I² is greater than 30% and either a Tau² was greater than zero, or there was a low P value (less than 0.10) in the Chi² test for heterogeneity.

Assessment of reporting biases

If there were 10 or more studies in the meta‐analysis, we investigated reporting biases (such as publication bias) using funnel plots Figure 2; Figure 3 . We assessed funnel plot asymmetry visually.

Figure 2

Funnel plot of comparison: 1 Insulin versus anti‐diabetic agent, outcome: 1.3 Caesarean section.

Figure 3

Funnel plot of comparison: 1 Insulin versus anti‐diabetic agent, outcome: 1.6 Large‐for‐gestational age (Birthweight > 90th centile).

Data synthesis

We carried out statistical analysis using the Review Manager software (RevMan 2014). We used fixed‐effect meta‐analysis for combining data where it was reasonable to assume that studies were estimating the same underlying treatment effect: i.e. where trials were examining the same intervention, and the trials’ populations and methods were judged sufficiently similar. If there was clinical heterogeneity sufficient to expect that the underlying treatment effects differed between trials, or if substantial statistical heterogeneity was detected, we used random‐effects meta‐analysis to produce an overall summary, if an average treatment effect across trials was considered clinically meaningful. The random‐effects summary was treated as the average of the range of possible treatment effects and we discussed the clinical implications of treatment effects differing between trials. If the average treatment effect was not clinically meaningful, we did not combine trials.

Where we used random‐effects analyses, the results were presented as the average treatment effect with 95% confidence intervals, and the estimates of Tau² and I².

Subgroup analysis and investigation of heterogeneity

Where we identified substantial heterogeneity, we investigated it using subgroup analyses and sensitivity analyses. We considered whether an overall summary was meaningful, and if it was, used random‐effects analysis to produce it.

Diagnostic test used

ADA 2013, IADPSG 2010, Nankervis 2014 versus ACOG 2013 versus NICE 2008; WHO 1999; WHO 2014; Hoffman 1998 versus New Zealand Ministry of Health 2014 versus other not previously specified.

Timing of diagnosis

Early diagnosis (< 28 weeks' gestation) versus late diagnosis (≥ 28 weeks' gestation).

Comparator intervention

Metformin versus glibenclamide versus acarbose versus diet alone versus exercise alone versus diet plus exercise versus other intervention (not previously specified).

The following outcomes were used in subgroup analysis.

Maternal outcomes

Hypertensive disorders of pregnancy (including pre‐eclampsia, pregnancy‐induced hypertension, eclampsia as defined by trialists)
Caesarean section
Development of type 2 diabetes

Neonatal outcomes

Large‐for‐gestational age (LGA)
Perinatal (fetal and neonatal death) and later infant mortality
Death or serious morbidity composite (variously defined by trials, e.g. infant death, shoulder dystocia, bone fracture or nerve palsy)
Neurosensory disability in later childhood (as defined by trialists)

We assessed subgroup differences by interaction tests available within RevMan (RevMan 2014). We reported the results of subgroup analyses quoting the Chi² statistic and P value, and the interaction test I² value. We were unable to look at timing of diagnosis due to insufficient details to be able to create subgroups. We did not look at differences in diagnostic criteria but have provided this detail, where reported, in Table 2. We did use comparator intervention for subgroup analysis.

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Table 2. Diagnostic criteria

		Screen	Diagnostic test	Diagnostic criteria
Ashoush 2016	Not stated	Not stated	2‐hour, 75 g OGTT	Not stated	ADA 2004
Anjalakshi 2007	Not stated	Not stated	75 g OGTT	2‐hour ≥ 7.7 mmol/L (140 mg/dL)	WHO 1994
Ardilouze 2014	‐	‐	‐	‐	Canadian Diabetes Association (no details)
Balaji 2005	Not stated	Not stated	Not stated	Not stated	Not stated
Balaji 2012	12 to 28 weeks’	Not stated	2‐hour, 75 g OGTT	2‐hour ≥ 7.7 mmol/L (140 mg/dL)	WHO 1994
Behrashi 2016	11 to 33 weeks'	Not stated	3‐hour, 100 g OGTT	2 abnormal values of: Fasting blood glucose ≥ 5.3 mmol/L (95 mg/dL), 1‐hour glucose level 10.0 mmol/L (180 mg/dL), 2‐hour glucose level 8.6 mmol/L (155 mg/dL) 3‐hour glucose level 7.8 mmol/L (140 mg/dL),	Carpenter and Coustan criteria
Bertini 2005	11 to 33 weeks'	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose ≥ 6.1 mmol/L (110 mg/dL) and 2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	WHO 1994
Beyuo 2015	20 to 28 weeks'	Not stated	2‐hour, 75 g OGTT	1 or more abnormal value from: Fasting blood glucose ≥ 5.1 mmol/L (92 mg/dL), 1‐hour glucose level 10.0 mmol/L (180 mg/dL), 2‐hour glucose level 8.5 mmol/L (153 mg/dL).	ADA 2012
Bung 1993	Not stated	Not stated	Not stated	Not stated	Not stated
Castorino 2011	Not stated	Not stated	Not stated	Not stated	Not stated
Coustan 1978	Not stated	Women with risk factors for GDM	3‐hour, 100 g OGTT	2 abnormal values of: Fasting blood glucose ≥ 5.3 mmol/L (95 mg/dL), 1‐hour glucose level 10.0 mmol/L (180 mg/dL), 2‐hour glucose level 8.9 mmol/L (160 mg/dL), 3‐hour glucose level 7.5 mmol/L (135 mg/dL).	Modified O'sullivan and Mahan (1964)
De Veciana 2002	Not stated	Not stated	Not stated	Not stated	Not stated
Di Cianni 2007	No details				Carpenter and Coustan criteria
Hague 2003	‐	‐	‐	‐	ADIPS (old criteria)
Herrera 2015					Carpenter and Coustan 1983 or IADPSG 2010
Hickman 2013	< 20 weeks'	Not stated	3‐hour 100 g OGTT	2 or more abnormal values	National Diabetes Data Group Criteria 1979
Hutchinson 2008	Not stated	Not stated	Not stated	Not stated	Not stated
Ijas 2011	Risk factor	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose 5.3 mmol/L (95 mg/dL), 1‐hour glucose level 11.0 mmol/L, 2‐hour glucose level 9.6 mmol/L. There were to be 1 or more abnormal values.	Not stated
Ismail 2007	Not stated	Not stated	Not stated	Not stated	Not stated
Jovanovic 1999	14 to 32 weeks'				Carpenter and Coustan criteria modification of NDDG criteria
Lain 2009	24 to 34 weeks'	50 g 1‐hour oral glucose challenge test > 7.5 mmol/L (135 mg/dL)	100 g 3‐hour OGTT	2 abnormal values of: Fasting blood glucose 5.3 mmol/L (95 mg/dL), 1‐hour glucose level 10.0 mmol/L (180 mg/dL) 2‐hour glucose level 8.6 mmol/L (155 mg/dL) 3‐hour glucose level 7.8 mmol/L (140 mg/dL), An elevated fasting value of 3‐hour OGTT or 1‐hour OGTT > 11.1 mmol/L or 200 mg/dL diagnostic of diabetes.	Carpenter and Coustan criteria
Langer 2000	11 to 33 weeks'	50 g, 1‐hour oral glucose challenge test > 7.3 mmol/L (130 mg/dL)	100 g OGTT	Fasting blood glucose between 5.3 mmol/L (95 mg/dL) and 7.8 mmol/L (130 mg/dL). 2 or more abnormal values required	Carpenter and Coustan criteria.
Majeed 2015	Not reported	Not reported	Not reported	Not reported	Not reported
Martinez Piccole 2010	Not reported	Not reported	Not reported	Not reported	Not reported
Mecacci 2003	25 to 32 weeks'				Carpenter and Coustan criteria
Mesdaghinia 2013	24 to 34 weeks'	50 g, 1‐hour oral glucose challenge test	100 g 3‐hour OGTT	2 or more abnormal results required from Fasting blood sugar > 5.3 mmol/L or 95 mg/dL; 1‐hour glucose level > 9.99 mmol/L or 180 mg/dL; 2‐hour glucose level > 8.6 mmol/L or 150 mg/dL; 3‐hour glucose level > 7.8 mmol/L or 140 mg/dL.	Carpenter and Coustan criteria
Mirzamoradi 2015	24 to 28 weeks'	Not stated	Not stated	Fasting blood glucose > 5.3 mmol/L or 95 mg/dL, 1‐hour glucose level > 10.0 mmol/L or 180 mg/dL or 2‐hour glucose level > 8.6 mmol/L or 150 mg/dL.	Carpenter and Coustan criteria
Mohamed 2014	‐	‐	‐	Plasma glucose > 7.8 mmol/L (140 mg/dL)	Carpenter and Coustan criteria
Moore 2007	24 to 30 weeks'	1‐hour 50 g glucose challenge test	100 g 3‐hour OGTT	Fasting blood glucose > 105 mg/dL, 1‐hour glucose level > 190 mg/dL, 2‐hour glucose level > 165 mg/dL and 3‐hour glucose level > 145 mg/dL. 2 or more abnormal values required for diagnosis.	ADA criteria (old)
Mukhopadhyay 2012	20 to 28 weeks'	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose ≥ 6.1 mmol/L (110 mg/dL) and 2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	WHO 1994
Nachum 1999	Not stated	Not stated	100 g 3‐hour OGTT	Fasting blood glucose 5.9 mmol/L 1‐hour glucose level 10.6 mmol/L 2‐hour glucose level 9.2 mmol/L 3‐hour glucose level 8.1 mmol/L	NDDG 1979
Niromanesh 2012	20 to 34 weeks'	1‐hour 50 g glucose challenge test	100 g 3‐hour OGTT	‐	Carpenter and Coustan criteria
Notelovitz 1971	Not reported	Not reported	2‐hour, 100 g OGTT	2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	Not reported
Ogunyemi 2007	Not reported	1‐hour 50 g glucose challenge test	3‐hour OGTT	Not reported	Not reported
O'Sullivan 1975a	Not reported	1‐hour 50 g glucose challenge test ‐ ≥ 130 mg/100 mL or presence of risk factors including history of macrosomia, fetal death, neonatal death, congenital anomaly.	3‐hour 100 g OGTT	2 or more abnormal readings from Fasting blood glucose ≥ 110 mg/100 mL 1‐hour blood glucose level ≥ 170 mg/100 mL, 2‐hour blood glucose level ≥ 120 mg/100 mL, 3‐hour blood glucose level ≥ 110 mg/100 mL.	Not reported
O'Sullivan 1975b	Not reported	1‐hour 50 g glucose challenge test ‐ ≥ 130 mg/100 mL	3‐hour 100 g OGTT	2 or more abnormal readings from Fasting blood glucose ≥ 110 mg/100 mL 1‐hour blood glucose level ≥ 170 mg/100 mL, 2‐hour blood glucose level ≥ 120 mg/100 mL, 3‐hour blood glucose level ≥ 110 mg/100 mL.	Not reported
Pavithra 2016	24 to 28 weeks'	1‐hour 50 g glucose challenge test	100 g OGTT	Fasting blood glucose > 5.3 mmol/L or 95 mg/dL, 1‐hour glucose level > 10.0 mmol/L or 180 mg/dL or 2‐hour glucose level > 8.6 mmol/L or 155 mg/dL. 3‐hour glucose level > 7.7 mmol/L or 140 mg/dL	Carpenter and Coustan criteria
Persson 1985	Not stated. Risk based selection	Not stated	3‐hour, 50 g OGTT	Not stated values but note that 2SD above normal	Gillmer 1975
Pettitt 2007	Not stated	Not stated	Not stated	Not stated	Not stated
Poyhonen‐Alho 2002	24 to 28 weeks'	OGTT based on risk factors (BMI > 25 kg/m2, age > 40 years, previous GDM, previous infant with macrosomia > 4500 g, glucosuria, current macrosomia)	2‐hour, 75 g OGTT	2 or more abnormal values from: Fasting ≥ 4.8 mmol/L 1‐hour glucose level ≥ 10.0 mmol/L 2‐hour glucose value ≥ 8.7 mmol/L	Finnish national guidelines (2008)
Prasad 2008	Not stated	Not stated	Not stated	Not stated	Not stated
Riaz 2014	Not stated	Not stated	75 g OGTT	Not stated	Not stated
Rowan 2008	20 to 33 weeks'	Not stated	75 g OGTT	1 or more of the following being abnormal Fasting plasma glucose level ≥ 5.1 mmol/L, 1‐hour venous plasma glucose ≥ 10.0 mmol/L (180 mg/dL), or 2‐hour venous plasma glucose ≥ 8.5 mmol/L.	ADIPS (1998)
Ruholamin 2014	24 to 28 weeks'				ADIPS 1998
Saleh 2016	26 to 34 weeks'	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose ≥ 7.0 mmol/L (126 mg/dL) and 2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	IADPSG 2010
Silva 2007	11 to 33 weeks'	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose ≥ 6.1 mmol/L (110 mg/dL) and 2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	WHO 1994
Spaulonci 2013	Not reported	Not stated	2‐hour 75 g or 3‐hour 100 g OGTT	2 or more abnormal results Fasting blood glucose > 5.3 mmol/L (95 mg/dL) 1‐hour glucose level ≥ 10.0 mmol/L (180 mg/dL) 2‐hour glucose level ≥ 8.6 mmol/L (155 mg/dL) 3‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	ADA 2011
Tertti 2013	22 to 34 weeks'	Screening criteria based on risk changed during the study	2‐hour 75 g OGTT	Diagnostic cut‐off levels up to 2008 were: Fasting blood glucose ≥ 4.8 mmol/L (87 mg/dL) 1‐hour glucose level ≥ 10.0 mmol/L (180 mg/dL) and 2‐hour glucose level ≥ 8.7 mmol/L (157 mg/dL) and thereafter was fasting ≥ 5.3 mmol/L (95 mg/dL), 1‐hour ≥ 10 mmo/L (180 mg/dL) and 2‐hour ≥ 8.6 mmol/L (155 mg/dL).	Finnish national guidelines (2008)
Thompson 1990	28 weeks' or earlier	1‐hour 50 g glucose challenge test	100 g 3‐hour OGTT	Fasting blood glucose > 105 mg/dL, 1‐hour glucose level > 190 mg/dL, 2‐hour glucose level > 165 mg/dL and 3‐hour glucose level > 145 mg/dL. 2 or more abnormal values required for diagnosis.	ADA criteria (old)
Waheed 2013	14 weeks' or more	No details	No details	Fasting blood glucose > 5.5 mmol/L (100 mg/dL), and random blood sugar > 7.7 mmol/L (140 mg/dL).	Not stated
Wali 2015					IADPSG (2010)
Zangeneh 2014	24 weeks'	1‐hour 50 g glucose challenge test	100 g 3‐hour OGTT	Fasting blood glucose between 5.3 mmol/L (95 mg/dL) and 7.8 mmol/L (130 mg/dL). 2 or more abnormal values required	Carpenter and Coustan criteria.
Zawiejska 2016	No details	No details	No details	No details	No details

OGTT: oral glucose tolerance test

Sensitivity analysis

We planned to conduct sensitivity analyses where there was substantive heterogeneity observed for the primary outcomes. We did not observe any substantive heterogeneity for the primary outcomes and therefore no sensitivity analyses were used. In future updates if we observe evidence of significant heterogeneity, we will explore this by using the quality of the included trials for the primary outcomes. We will compare trials with low risk of bias for allocation concealment with those judged to be of unclear or high risk of bias. We will exclude conference abstracts.

Results

Description of studies

Results of the search

A total of 288 potential studies were identified. We assessed 153 full‐text reports of 97 studies. We included 53 studies (103 reports) (Characteristics of included studies). We excluded 21 studies (27 reports) (Characteristics of excluded studies). Eight studies are awaiting classification (Characteristics of studies awaiting classification) (Afshari 2013; Dunne 2001; NCT00160485; Ibrahim 2014; Liang 2009; Shaikh 2013; Todorova 2007; Zhou 2012). There are 15 ongoing studies (Characteristics of ongoing studies).

NCT00414245 trial registration documentation states that the intervention is metformin but the comparison is not stated.

In subsequent updates of this review, we will check if these studies have been published and if they are eligible for inclusion in the review. Figure 1 illustrates the PRISMA flow diagram for this review.

Included studies

Fifty‐three studies associated with 103 publications were included (Characteristics of included studies). The 53 included studies reported data for 7381 women and 46 of these studies reported data for 6435 infants (seven studies reported no neonatal data). Six studies did not contribute any data to this review (Hutchinson 2008; Martinez Piccole 2010; Notelovitz 1971; Riaz 2014; Waheed 2013; Wali 2015).

Design

All of the 53 included studies were parallel randomised controlled trials.

Sample sizes

Sample sizes ranged from a minimum of 10 (Balaji 2005) to a maximum of 733 (Rowan 2008) participants. Thirty‐four studies had a sample size of 100 or less (Anjalakshi 2007; Ardilouze 2014; Ashoush 2016; Balaji 2005; Bertini 2005; Bung 1993; Castorino 2011; Coustan 1978; De Veciana 2002; Di Cianni 2007; Hague 2003; Hickman 2013; Ijas 2011; Ismail 2007; Jovanovic 1999; Lain 2009; Martinez Piccole 2010; Mecacci 2003; Mirzamoradi 2015; Mohamed 2014; Moore 2007; Mukhopadhyay 2012; Ogunyemi 2007; Pavithra 2016; Pettitt 2007; Poyhonen‐Alho 2002; Prasad 2008; Ruholamin 2014; Silva 2007; Spaulonci 2013; Thompson 1990; Waheed 2013; Zangeneh 2014; Zawiejska 2016).

Setting and timing

Sixteen studies were conducted in the USA (Bung 1993; Castorino 2011; Coustan 1978; De Veciana 2002; Herrera 2015; Hickman 2013; Hutchinson 2008; Jovanovic 1999; Lain 2009; Langer 2000; Moore 2007; Ogunyemi 2007; O'Sullivan 1975a; O'Sullivan 1975b; Pettitt 2007; Thompson 1990); seven from India (Anjalakshi 2007; Balaji 2005; Balaji 2012; Majeed 2015; Mukhopadhyay 2012; Pavithra 2016; Prasad 2008); six from Iran (Behrashi 2016; Mesdaghinia 2013; Mirzamoradi 2015; Niromanesh 2012; Ruholamin 2014; Zangeneh 2014) and three each from Egypt (Ashoush 2016; Mohamed 2014; Saleh 2016); Brazil (Bertini 2005; Silva 2007; Spaulonci 2013); Pakistan (Riaz 2014; Waheed 2013; Wali 2015); Finland (Ijas 2011; Poyhonen‐Alho 2002; Tertti 2013); two from Italy (Di Cianni 2007; Mecacci 2003) and one each from Sweden (Persson 1985); Canada (Ardilouze 2014); Ghana (Beyuo 2015); Australia (Hague 2003); New Zealand and Australia (Rowan 2008); Turkey (Martinez Piccole 2010); Israel (Nachum 1999); Malaysia (Ismail 2007); South Africa (Notelovitz 1971); and Poland (Zawiejska 2016).

Thirteen studies were conducted in the 2010s (Ashoush 2016; Beyuo 2015; Herrera 2015; Majeed 2015; Mirzamoradi 2015; Mukhopadhyay 2012; Niromanesh 2012; Riaz 2014; Ruholamin 2014; Saleh 2016; Waheed 2013; Zangeneh 2014; Zawiejska 2016).

Ten studies were conducted in the 2000s (Bertini 2005; Hickman 2013; Ijas 2011; Lain 2009; Moore 2007; Ogunyemi 2007; Rowan 2008; Silva 2007; Spaulonci 2013; Tertti 2013).

Two studies were conducted in the 1990s (Mecacci 2003; Nachum 1999) and one study each in the 1990/80s (Thompson 1990); 1980s (Persson 1985); 1970s (Coustan 1978); 1960s (O'Sullivan 1975b) and 1950s (O'Sullivan 1975a).

The remaining studies provided no details on the timing of the studies (Anjalakshi 2007; Ardilouze 2014; Balaji 2005; Balaji 2012; Behrashi 2016; Bung 1993; Castorino 2011; De Veciana 2002; Di Cianni 2007; Hague 2003; Hutchinson 2008; Ismail 2007; Jovanovic 1999; Langer 2000; Martinez Piccole 2010; Mesdaghinia 2013; Mohamed 2014; Notelovitz 1971; Pavithra 2016; Pettitt 2007; Poyhonen‐Alho 2002; Prasad 2008; Wali 2015).

Participants

Details including maternal age (years); ethnicity/race, maternal body mass index (BMI) at baseline (kg/m²) and gestational age at start of intervention can be referred to in Table 3; Table 4; Table 5 and Table 6, respectively.

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Table 3. Maternal age (Years)

Trial ID
	Insulin	Glibenclamide
Anjalakshi 2007	27.5 ± 5.8 (n = 13)	24.9 ± 3.7 (n = 10)
Behrashi 2016	29.9 ± 7.0 (n = 129)	30.7 ± 7.2 (n = 120)
Bertini 2005	28.7 ± 6.0 (n = 27)	31.2 ± 4.5 (n = 24)
Lain 2009	31.2 ± 5.9 (n = 41)	32.2 ± 5.0 (n = 41)
Langer 2000	30 ± 6 (n = 203)	29 ± 7 (n = 201)
Mirzamoradi 2015	31.2 ± 5.0 (n = 59)	29.5 ± 4.1 (n = 37)
Mukhopadhyay 2012	26 ± 4.3 (n = 30)	26.3 ± 4.6 (n = 30)
Ogunyemi 2007	Not reported	Not reported
Pavithra 2016	27.9 ± 3.6 (n = 50)	28.2 ± 3.1 (n = 50)
Silva 2007	29.9 ± 6.0 (n = 36)	31.6 ± 4.2 (n = 32)
Zangeneh 2014	32.6 ± 6.2 (n = 46)	31.4 ± 5 (n = 44)

	Insulin	Metformin
Ashoush 2016	32.1 ± 3.2 (n = 48)	31.6 ± 2.8 (n = 47)
Beyuo 2015	33.1 ± 4.6 (n = 40)	33.5 ± 4.7 (n = 43)
Hague 2003	34.1 ± 3.7 (n = 14)	33.7 ± 4.44 (n = 16)
Hickman 2013	Median 31 (IQR 26, 33) (n = 14)	Median 36 (IQR 35, 37) (n = 14)
Ijas 2011	31.7 ± 6.1 (n = 50)	32.3 ± 5.6 (n = 47)
Mesdaghinia 2013	30.2 ± 5.9 (n = 100)	29.6 ± 5.3 (n = 100)
Moore 2007	27.7 ± 6.7 (n = 31)	27.1 ± 4.7 (n = 32)
Majeed 2015	Not reported	Not reported
Martinez Piccole 2010	Not reported	Not reported
Niromanesh 2012	31.8 ± 5.1 (n = 80)	30.7 ± 5.5 (n = 80)
Riaz 2014	Not reported	Not reported
Rowan 2008	33 ± 5.1 years (n = 370)	33.5 ± 5.4 (n = 363)
Ruholamin 2014	23.4 ± 2.5 (n = 50)	24.6 ± 6.3 (n = 50)
Saleh 2016	29.8 ± 2.2 (n = 70)	31.0 ± 3.4 (n = 67)
Spaulonci 2013	32.76 ± 4.66 (n = 47)	31.93 ± 6.02 (n = 47)
Tertti 2013	32.1 ± 5.4 (n =107)	31.9 ± 5.0 (n = 110)
Waheed 2013	29.82 ± 4.58 (n = 34)	29.35 ± 4.97 (n = 34)
Wali 2015	Not reported	Not reported
Zawiejska 2016	35 (30 to 38) (n = 43)	22 (29 to 39) (n = 35)

	Insulin	Acarbose
Bertini 2005	28.7 ± 6.0 (n = 27)	31.5 ± 5.8 (n = 19)
De Veciana 2002	Not reported	Not reported

	Insulin	Glyburide/metformin combined
Ardilouze 2014	30.7 ± 4.4 (n = 33)	31.1 ± 4.7 (n = 35)
Hutchinson 2008	Not reported	Not reported
Mohamed 2014	32.1 ± 5.7 (n = 42)	33.2 ± 4.9 (n = 42)

	Human insulin	Insulin aspart
Balaji 2005	31.0 ± 2.7 (n = 5)	30.6 ± 5.0 (n = 5)
Balaji 2012	29.6 ± 4.5 (n = 157)	29.2 ± 4.0 (n = 163)
Di Cianni 2007	Not reported	Not reported
Pettitt 2007	29.7 ± 6.9 (n = 13)	31.6 ± 5.9 (n = 14)
Prasad 2008	Not reported	Not reported


	Human insulin	Insulin lispro
Di Cianni 2007	Not reported	Not reported
Jovanovic 1999	29.8 ± 1.0 (n = 23)	34.2 ± 1.3 (n = 19)
Mecacci 2003	median 35 (range 28 to 41) (n = 24)	Median 34.5 (range 28 to 41) (n = 25)

	Human insulin	Neutral Protamine Hagedorn insulin
Poyhonen‐Alho 2002	Not reported	Not reported
Ismail 2007	Not reported	Not reported
Herrera 2015	Median 35 [ 31‐38] (n = 42)	Median 35 [IQR 32‐38] (n = 45)

	Insulin	Diet
Coustan 1978	Not reported	Not reported
Notelovitz 1971	31.8 (n = 47)	32.7 (n = 56)
Persson 1985	Median 30.5 (range 16 to 42) (n = 97)	Median 29 (range 18 to 46) (n = 105)
Thompson 1990	27 ± 5.4	26 ± 5.7

	Insulin	Exercise
Bung 1993	Not reported	Not reported

	Insulin	Standard care
O'Sullivan 1975a	Not reported	Not reported
O'Sullivan 1975b	Not reported	Not reported

	Insulin regimen A	Insulin regimen B
Castorino 2011	Not reported	Not reported
Nachum 1999	33 ± 5 (n = 136)	33 ± 5 (n = 138)

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Table 4. Ethnicity/Race

Trial ID	Ethnicity
Ashoush 2016	Not reported
Anjalakshi 2007	Not reported but likely to be Indian
Ardilouze 2014	Not reported
Balaji 2005	Not reported but likely to be Indian
Balaji 2012	Not reported but likely to be Indian
Behrashi 2016	Not reported
Bertini 2005	Not reported but likely to be Brazilian
Beyuo 2015	Not reported
Bung 1993	Not reported
Castorino 2011	86% Mexican
Coustan 1978	Not reported
De Veciana 2002	Not reported
Di Cianni 2007	Not reported
Hague 2003	Not reported
Herrera 2015	33% White, 14% Black, 31% Hispanic, 21% Native American/Alaskan
Hickman 2013	79% Hispanic, 14% Black
Hutchinson 2008	Not reported
Ijas 2011	Not reported
Ismail 2007	Not reported
Jovanovic 1999	95% Hispanic
Lain 2009	13% Black (no other details)
Langer 2000	83% were Hispanic and 12% non‐Hispanic Caucasian
Majeed 2015	Not reported but likely to be Indian
Martinez Piccole 2010	Not reported
Mecacci 2003	Caucasian
Mesdaghinia 2013	Not reported but likely to be Iranian
Mirzamoradi 2015	Not reported but likely to be Iranian
Mohamed 2014	Not reported
Moore 2007	50% African American, 44% Native American
Mukhopadhyay 2012	Not reported but likely to be Indian
Nachum 1999	56% were Jewish
Niromanesh 2012	Not stated but likely to be Iranian
Ismail 2007	Not reported
Notelovitz 1971	37% were Bantu (Zulu)
Ogunyemi 2007	80% were Hispanic and 15% African American
O'Sullivan 1975a	Not reported
O'Sullivan 1975b	Not reported
Pavithra 2016	Not reported
Persson 1985	Not reported
Pettitt 2007	75% were Hispanic and 19% were Caucasian
Poyhonen‐Alho 2002	Not reported
Prasad 2008	Not reported
Riaz 2014	Not reported but likely to be Pakistani
Rowan 2008	47% Caucasian, 21% Polynesian, 13% Indian
Ruholamin 2014	Not reported but likely to be Iranian
Saleh 2016	Not reported
Silva 2007	Not reported but likely to be Brazilian
Spaulonci 2013	Not reported
Tertti 2013	Not reported
Thompson 1990	41% 'Black', 49% 'White'
Waheed 2013	Not reported but likely to be Pakistani
Wali 2015	Not reported but likely to be Pakistani
Zangeneh 2014	Not reported but likely to Iranian
Zawiejska 2016	Not reported

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Table 5. Maternal BMI at baseline (kg/m2)

Trial ID
	Insulin	Glibenclamide
Anjalakshi 2007	25.3 ± 5.1 (n = 13)	22.8 ± 3.5 (n = 10)
Behrashi 2016	22.6 ± 3.1 (n = 129)	21.9 ± 2.80 (n = 120)
Bertini 2005	27.0 ± 7.2 (n = 27)	27.5 ± 5.8 (n = 24)
Lain 2009	30.9 ± 5.7 (n = 41)	33.4 ± 12.9 (n = 41)
Langer 2000	Not reported	Not reported
Mirzamoradi 2015	31.8 ± 5.1 (n = 59)	30.8 ± 5.4 (n = 37)
Mukhopadhyay 2012	23.0 ± 2.9 (n = 30)	23.7 ± 2.7 (n = 30)
Ogunyemi 2007	30.8 ± 6.9 (n = 49)	32.0 ± 7.6 (n = 48)
Pavithra 2016	28.3 ± 3.8 (n = 50)	27.8 ± 4.0 (n = 50)
Silva 2007	27.9 ± 6.8 (n = 36)	27.5 ± 5.1 (n = 32)
Zangeneh 2014	27.8 ± 3 (n = 46)	27.5 ± 1.5 (n = 44)

	Insulin	Metformin
Ashoush 2016	31.4 ± 1.5 (n = 48)	31.1 ± 1.3 (n = 47)
Beyuo 2015	32.6 ± 6.2 (n = 40)	33.5 ± 7.0 (n = 43)
Hague 2003	37.9 ± 6.87 (n = 14)	39.5 ± 6.94 (n = 16)
Hickman 2013	Median 33 (IQR 28, 41) (n = 14)	Median 29 (IQR 27,33) (n = 14)
Ijas 2011	30.8 ± 5.4 (n = 50)	31.5 ± 6.5 (n = 47)
Majeed 2015	Not reported	Not reported
Mesdaghinia 2013	28.5* (n = 100)	27.6* (n = 100)
Moore 2007	35.3 ± 6.7 (n = 31)	39.7 ± 9.0 (n = 32)
Niromanesh 2012	27.1 ± 2.1 (n = 80)	28.1 ± 4.0 (n = 80)
Martinez Piccole 2010	Not reported	Not reported
Riaz 2014	Not reported	Not reported
Rowan 2008	34.6 ± 7.2 (n = 370)	35.1 ± 8.3 (n = 363)
Ruholamin 2014	25.1 ± 3.4 (n = 50)	26.4 ± 2.8 (n = 50)
Saleh 2016	31.6 ± 31.1 (n = 70)	30.1 ± 3.2 (n = 67)
Spaulonci 2013	31.39 ± 5.71 (n = 47)	31.96 ± 4.75 (n = 47)
Tertti 2013	28.9 ± 4.7 (n = 107)	29.4 ± 5.9 (n = 110)
Waheed 2013	Not reported	Not reported
Wali 2015	Not reported	Not reported
Zawiejska 2016	32.0 ± 5.8 (n = 43)	32.2 ± 6.4 (n = 35)

	Insulin	Acarbose
Bertini 2005	27.0 ± 7.2 (n = 27)	25.7 ± 4.2 (n = 19)
De Veciana 2002	32.1 ± 5.6 (n = 46)	33.1 ± 6.4 (n = 45)

	Insulin	Glyburide/metformin combined
Ardilouze 2014	32.2 ± 7.2 (n = 33)	32.0 ± 5.4 (n = 35)
Hutchinson 2008	Not reported	Not reported
Mohamed 2014	Not reported	Not reported

	Human insulin	Insulin aspart
Balaji 2005	25.6 ± 2.9 (n = 5)	28.6 ± 3.1 (n = 5)
Balaji 2012	25.8 ± 3.4 (n = 157)	26.0 ± 3.4 (n = 163)
Di Cianni 2007	Not reported	Not reported
Pettitt 2007	33.2 ± 5.7 (n = 13)	29.3 ± 4.7 (n = 14)
Prasad 2008	Not reported	Not reported

	Human insulin	Insulin lispro
Jovanovic 1999	33.3 ± 1.2 (n = 23)	31.5 ± 1.1 (n = 19)
Mecacci 2003	Median 22.3 (range 19.8 to 25.3) (n = 24)	Median 21.5 (range 19.2 to 25.1) (n = 25)

	Human insulin	Neutral Protamine Hagedorn insulin
Di Cianni 2007	Not reported	Not reported
Poyhonen‐Alho 2002	Not reported	Not reported
Ismail 2007	Not reported	Not reported

	Insulin	Diet
Coustan 1978	Not reported	Not reported
Notelovitz 1971	Not reported	Not reported
Persson 1985	Not reported	Not reported
Thompson 1990	Not reported	Not reported

	Insulin detemir	Neutral Protamine Hagedorn insulin
Herrera 2015	28.3 (IQR 24.9‐33.8) (n = 42)	28.6 (IQR 24.4‐31.1) (n = 45)

	Insulin	Exercise
Bung 1993	Not reported	Not reported

	Insulin	Standard care
O'Sullivan 1975a	Not reported	Not reported
O'Sullivan 1975b	Not reported	Not reported

	Insulin regimen A	Insulin regimen B
Castorino 2011	Not reported	Not reported
Nachum 1999	27.8 ± 2.7 (n = 136)	27.9 ± 2.6 (n = 138)

*SD not reported
IQR: interquartile ratio

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Table 6. Gestational age at start of treatment/enrolment (weeks)

Trial ID
	Insulin	Glibenclamide
Anjalakshi 2007	22.6 ± 5.6 (n = 13)	22.5 ± 4.7 (n = 10)
Behrashi 2016	24.5 ± 4.5 (n = 129)	24.9 ±3.9 (n = 120)
Bertini 2005	Not reported	Not reported
Lain 2009	30.6 ± 2.2 (n = 41)	30.8 ± 2.5 (n = 41)
Langer 2000	25.0 ± 7.0 (n = 203)	24.0 ± 7.0 (n = 201)
Mukhopadhyay 2012	27.4 ± 2.7 (n = 30)	28.3 ± 2.2 (n = 30)
Mirzamoradi 2015	30.3 ± 4.0 (n = 59)	29.9 ± 4.1 (n = 37)
Ogunyemi 2007	24.6 ± 8.0 (n = 49)	28.1 ± 7.6 (n = 48)
Pavithra 2016	Not reported	Not reported
Silva 2007	25.6 ± 5.9 (n = 36)	26.6 ± 4.3 (n = 32)
Zangeneh 2014	Not reported	Not reported

	Insulin	Metformin
Ashoush 2016	29.7 ± 1.9 (n = 48)	29.8 ± 1.4 (n = 47)
Beyuo 2015	Median 26 IQ range 23 to 28 (n = 40)	Median 28 IQ range 26 to 29 (n = 43)
Hague 2003	30.4 ± 4.67 (n = 14)	29.8 ± 4.49 (n = 16)
Hickman 2013	Median 14 (IQR 13, 19) (n = 14)	Median 17 (IQR 10, 22) (n = 14)
Ijas 2011	30.0 ± 4.0 (n = 50)	30.0 ± 4.9 (n = 47)
Majeed 2015	Not reported	Not reported
Mesdaghinia 2013	28.9 ± 3.8 (n = 100)	27.9 ± 3.2 (n = 100)
Moore 2007	28.9 ± 5.0 (n = 31)	27.8 ± 6.5 (n = 32)
Niromanesh 2012	28.6 ± 3.6 (n = 80)	28.7 ± 3.7 (n = 80)
Martinez Piccole 2010	Not reported	Not reported
Riaz 2014	Not reported	Not reported
Rowan 2008	30.1 ± 3.2 (n = 370)	30.2 ± 3.3 (n = 363)
Ruholamin 2014	26.7 ± 3.5 (n = 50)	27.6 ± 3.3 (n = 50)
Saleh 2016	Not reported	Not reported
Spaulonci 2013	32.05 ± 3.50 (n = 47)	32.18 ± 3.70 (n = 47)
Tertti 2013	30.4 ± 1.8 (n = 107)	30.3 ± 2.0 (n = 110)
Waheed 2013	Not reported	Not reported
Wali 2015	Not reported	Not reported
Zawiejska 2016	30 (28 to 31) (n = 43)	30 (28 to 32) (n = 35)

	Insulin	Acarbose
Bertini 2005	Not reported	Not reported
De Veciana 2002	30.2 ± 3.7 (n = 46)	30.5 ± 3.5 (n = 45)

	Insulin	Glyburide/metformin combined
Ardilouze 2014	30.1 ± 3.1 (n=33)	29.3 ± 3.8 (n=35)
Hutchinson 2008	Not reported	Not reported
Mohamed 2014	24.5 ± 6.3 (n = 42)	22.1 ± 7.3 (n = 42)

	Human insulin	Insulin aspart
Balaji 2005	Not reported	Not reported
Balaji 2012	22.4 ± 10.1 (n = 157)	21.7 ± 9.3 (n = 163)
Di Cianni 2007	Not reported	Not reported
Pettitt 2007	Not reported	Not reported
Prasad 2008	Not reported	Not reported

	Human insulin	Insulin lispro
Di Cianni 2007	Not reported	Not reported
Jovanovic 1999	25.6 ± 1.3 (n = 23)	27.3 ± 1.4 (n = 19)
Mecacci 2003	Median 29 (range 27 to 32) (n = 24)	Median 29 (range 26 to 32) (n = 25)

	Human insulin	Neutral Protamine Hagedorn insulin
Poyhonen‐Alho 2002	Not reported	Not reported
Ismail 2007	Not reported	Not reported

	Insulin detemir	Neutral Protamine Hagedorn insulin
Herrera 2015	Median 27.3 (IQR 23.3 ‐28.5) (n = 42)	Median 28.1 (25.1 ‐ 29.3) (n = 45)

	Insulin	Diet
Coustan 1978	Not reported	Not reported
Notelovitz 1971	Not reported	Not reported
Persson 1985	Not reported	Not reported
Thompson 1990	Not reported	Not reported

	Insulin	Exercise
Bung 1993	Not reported	Not reported

	Insulin	Standard care
O'Sullivan 1975a	Not reported	Not reported
O'Sullivan 1975b	Not reported	Not reported

	Insulin regimen A	Insulin regimen B
Castorino 2011	Not reported	Not reported
Nachum 1999	28 ± 6.9 (n = 136)	27.4 ± 6.8 (n = 138)

IQR Interquartile range

Diagnostic criteria for GDM

Multiple methods of diagnosing GDM were used in the included studies (Table 2).

The Carpenter and Coustan (1983) criteria were used in 12 studies (Behrashi 2016; Di Cianni 2007; Jovanovic 1999; Lain 2009; Langer 2000; Mecacci 2003; Mesdaghinia 2013; Mirzamoradi 2015; Mohamed 2014; Pavithra 2016; Niromanesh 2012; Zangeneh 2014). In the Herrera 2015 study, either the Carpenter and Coustan (1983) or IADPSG (2010) criteria could be used.

The World Health Organization (WHO) (1994) criteria were used in five studies (Anjalakshi 2007; Balaji 2012; Bertini 2005; Mukhopadhyay 2012; Silva 2007) and the American Diabetes Association (ADA) criteria were used in five studies, ADA (2012) was reported in one study (Beyuo 2015); one study used ADA (2011) (Spaulonci 2013), and three studies used earlier versions of ADA criteria (Ashoush 2016; Moore 2007; Thompson 1990).

Three studies (Hague 2003; Rowan 2008; Ruholamin 2014) used the Australian Diabetes in Pregnancy Society (Hoffman 1998) and two studies used the National Diabetes Data Group (1979) criteria (Hickman 2013; Nachum 1999).

One study reported using the Canadian Diabetes Association (CDA) criteria but no date/version was specified (Ardilouze 2014); IADPSG (2010) criteria was used in two studies (Saleh 2016; Wali 2015); one study reported using a modified O'Sullivan and Mahan criteria (Coustan 1978) and one study (Persson 1985) reported using Gillmer 1975.

Two used the Finnish National Guidelines (2008) (Poyhonen‐Alho 2002; Tertti 2013).

Eighteen studies did not state the diagnostic criteria used for GDM (Balaji 2005; Bung 1993; Castorino 2011; De Veciana 2002; Hutchinson 2008; Ijas 2011; Ismail 2007; Majeed 2015; Martinez Piccole 2010; Notelovitz 1971; Ogunyemi 2007; O'Sullivan 1975a; O'Sullivan 1975b; Pettitt 2007; Prasad 2008; Riaz 2014; Waheed 2013; Zawiejska 2016).

Treatment targets

Treatment targets, where reported, are summarised in Table 7.

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Table 7. Treatment targets

Study ID	Fasting	1‐hour postprandial	2‐hour postprandial
Ashoush 2016	< 5.5 mmol/L (100 mg/dL)		< 7.7 mmol/L (140 mg/dL)
Anjalakshi 2007	‐	‐	< 6.7 mmol/L (120 mg/dL)
Ardilouze 2014	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Balaji 2005	< 5.0 mmol/L (90 mg/dL)		< 6.7 mmol/L (120 mg/dL)
Balaji 2012	> 4.4 mmol/L (> 80 mg/dL) and < 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Behrashi 2016	< 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Bertini 2005	< 5.0 mmol/L (90 mg/dL)	‐	< 5.6 mmol/L (100 mg/dL)
Beyuo 2015	< 5.5 mmol/L (99 mg/dL)		< 7.0 mmol/L (126 mg/dL)
Bung 1993	> 5.8 mmol/L (105 mg/dL) to < 7.2 mmol/L (< 130 mg/dL)	‐	‐
Castorino 2011	< 5.0 mmol/L (90 mg/dL)	< 6.7 mmol/L (120 mg/dL	‐
Coustan 1978	Not reported	Not reported	Not reported
De Veciana 2002	</= 5.3 mmol/L (95 mg/dL)		</= 6.7 mmol/L (120 mg/dL)
Di Cianni 2007	‐	< 7.2 mmol/L (< 130 mg/dL)	‐
Hague 2003	Not reported
Herrera 2015	< 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Hickman 2013	< 5.3 mmol/L (95 mg/dL)	< 7.2 mmol/L (< 130 mg/dL)
Hutchinson 2008	Not reported	Not reported	Not reported
Ijas 2011	< 5.3 mmol/L (95 mg/dL)	‐	1.5 hours postprandial < 6.7 mmol/L (120 mg/dL)
Ismail 2007	< 5.5 mmol/L (100 mg/dL)	‐	‐
Jovanovic 1999	< 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Lain 2009	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Langer 2000	3.4 to 5.0 mmol/L (80 to 95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Majeed 2015	Not reported	‐	Not reported
Martinez Piccole 2010	Not reported	‐	Not reported
Mecacci 2003	< 5.0 mmol/L (90 mg/dL)	< 6.7 mmol/L (120 mg/dL)	‐
Mesdaghinia 2013	< 5.3 mmol/L (95 mg/dL)		< 6.7 mmol/L (120 mg/dL)
Mirzamoradi 2015	3.3 to 5.0 mmol/L (60 to 90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Moore 2007	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Mukhopadhyay 2012	< 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Nachum 1999	3.3 to 5.3 mmol/L	</= 6.7	</= 6.7 mmol/L (120 mg/dL)
Niromanesh 2012	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Ismail 2007	< 5.5 mmol/L
Notelovitz 1971		8.3 mmol/L (150 mg/dL)
Ogunyemi 2007	Not reported	Not reported	Not reported
O'Sullivan 1975a	Not reported	Not reported	Not reported
O'Sullivan 1975b	Not reported	Not reported	Not reported
Pavithra 2016	< 5.0 mmol/L (90 mg/dL)		</= 6.7 mmol/L (120 mg/dL)
Persson 1985	< 5.0 mmol/L	< 6.5 mmol/L	‐
Poyhonen‐Alho 2002	Not reported	Not reported	Not reported
Pettitt 2007	Not reported	Not reported	Not reported
Prasad 2008	Not reported	Not reported	Not reported
Riaz 2014	Not reported	Not reported	Not reported
Rowan 2008	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Ruholamin 2014	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Saleh 2016	≤5.5mmol/L (<100 mg/dL)		< 7.0 mmol/L (126 mg/dL)
Silva 2007	< 5.0 mmol/L (90 mg/dL)	‐	< 5.6 mmol/L (100 mg/dL)
Spaulonci 2013	≤ 5.3 mmol/L (95 mg/dL)	‐	≤ 6.7 mmol/L (120 mg/dL)
Tertti 2013	≤5.5mmol/L (100 mg/dL)	‐	≤ 7.8 mmol/L
Thompson 1990	< 5.8 mmol/L (105mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Waheed 2013	3.5 to 5.5 mmol/L (63 to 100 mg/dL)	‐	‐
Wali 2015	Not reported	‐	Not reported
Zangeneh 2014	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Zawiejska 2016	Not reported	‐	Not reported

Interventions and comparisons

Insulin versus metformin

Nineteen studies compared insulin with metformin (Ashoush 2016; Beyuo 2015; Hague 2003; Hickman 2013; Ijas 2011; Majeed 2015; Martinez Piccole 2010; Mesdaghinia 2013; Moore 2007; Niromanesh 2012; Riaz 2014; Rowan 2008; Ruholamin 2014; Saleh 2016; Spaulonci 2013; Tertti 2013; Waheed 2013; Wali 2015; Zawiejska 2016) though four of these did not contribute data (Martinez Piccole 2010; Riaz 2014; Waheed 2013; Wali 2015).

Comparisons included the following.

Regular insulin (no other details) Majeed 2015
Regular human insulin plus Neutral Protamine Hagedorn insulin versus metformin (Ashoush 2016; Hickman 2013; Mesdaghinia 2013)
Neutral Protamine Hagedorn insulin versus metformin (Niromanesh 2012; Spaulonci 2013)
Insulin lispro plus Neutral Protamine Hagedorn insulin versus metformin (Ijas 2011)
Insulin lispro/aspart plus Neutral Protamine Hagedorn insulin versus metformin (Tertti 2013)
Soluble and premixed insulin (no other details) (Beyuo 2015)
Actrapid and Mixtard versus metformin (Saleh 2016)

Nine studies did not report details on the insulin type used (Hague 2003; Martinez Piccole 2010; Moore 2007; Riaz 2014; Rowan 2008; Ruholamin 2014; Waheed 2013; Wali 2015; Zawiejska 2016).

Hickman 2013 included both women with GDM and pre‐existing diabetes. The data could not be separated however as 50% of the women had GDM these data have been included. Authors have been contacted for further information.

Seven studies are ongoing (NCT01756105; IRCT2014010116025N1; CTRI/2013/10/004055; SLCTR/2011/009; CTRI/2011/08/001956; CTRI/2014/08/004835; NCT00681460). In the next update of this review we will check for publications from these studies and add data if available.

Insulin versus glibenclamide

Eleven studies compared insulin with glibenclamide (Anjalakshi 2007;Behrashi 2016; Bertini 2005; Lain 2009; Langer 2000; Mirzamoradi 2015; Mukhopadhyay 2012; Ogunyemi 2007; Pavithra 2016; Silva 2007; Zangeneh 2014).

Comparisons included the following.

Long‐acting and short‐acting insulin (no details) versus glibenclamide (Lain 2009)
Regular human insulin versus glibenclamide (Langer 2000)
Regular human insulin plus Neutral Protamine Hagedorn insulin versus glibenclamide (Behrashi 2016; Bertini 2005; Mirzamoradi 2015; Silva 2007; Zangeneh 2014).

Four studies did not report any details on the insulin type that was used (Anjalakshi 2007; Mukhopadhyay 2012; Ogunyemi 2007; Pavithra 2016).

There are two ongoing studies (IRCT2013102315045N2; NCT01731431). In the next update of this review we will check for publications from these studies and add data if available.

Insulin versus acarbose

Two studies compared insulin with acarbose (Bertini 2005; De Veciana 2002).

Comparisons included the following.

Regular human insulin plus Neutral Protamine Hagedorn insulin versus acarbose (Bertini 2005)
Insulin lispro plus Neutral Protamine Hagedorn insulin versus acarbose (De Veciana 2002)

Combined metformin and glibenclamide

Three studies compared insulin with a combination of metformin and glibenclamide (Ardilouze 2014; Hutchinson 2008 ; Mohamed 2014). The data for Hutchinson 2008 cannot be separated out for GDM and type 2 diabetes and have not been included. Authors have been contacted.

Comparisons included the following.

Insulin aspart or lispro plus Neutral Protamine Hagedorn insulin versus combined metformin and glibenclamide (Ardilouze 2014)
Intermediate‐ and short‐acting insulin (no details) versus combined metformin and glibenclamide (Mohamed 2014). This study recruited women with both GDM and type 2 diabetes and the data cannot be separated. However, 65 of the women recruited had a diagnosis of GDM and 19 with type 2 diabetes. As the majority of women have GDM (77%) we have included the data in the analyses.

One study is ongoing (NCT02080377). In the next update of this review we will check for publications from these studies and add data if available.

Insulin type A versus insulin type B

Ten studies compared one preparation of insulin with another preparation of insulin (Balaji 2005; Balaji 2012; Di Cianni 2007;Herrera 2015; Jovanovic 1999; Mecacci 2003; Ismail 2007; Pettitt 2007; Poyhonen‐Alho 2002; Prasad 2008).

One ongoing study was identified (NCT01662921) that compares insulin glulisine versus insulin lispro. We will seek data for this study in subsequent updates of this review.

Comparisons included the following.

Regular human insulin versus insulin aspart (Balaji 2005; Balaji 2012; Di Cianni 2007)
Regular human insulin versus insulin lispro (Di Cianni 2007; Jovanovic 1999; Mecacci 2003)
Regular human insulin versus Neutral Protamine Hagedorn insulin (Ismail 2007; Poyhonen‐Alho 2002)
Regular human insulin plus Neutral Protamine Hagedorn insulin versus insulin aspart (Prasad 2008)
Neutral Protamine Hagedorn insulin plus regular human insulin versus Neutral Protamine Hagedorn insulin plus insulin aspart (Pettitt 2007)
Insulin detemir plus and insulin aspart versus Neutral Protamine Hagedorn insulin and insulin aspart (Herrera 2015)

Insulin versus diet

Four studies compared insulin with diet (Coustan 1978; Notelovitz 1971; Persson 1985; Thompson 1990). One study did not provide details of the preparation of insulin that was used (Notelovitz 1971). Two studies compared insulin (plus diet) with standard antenatal care (O'Sullivan 1975a; O'Sullivan 1975b).

Coustan 1978 used regular human insulin plus Neutral Protamine Hagedorn insulin; Persson 1985 compared fast/intermediate‐acting insulin (no details) with diet versus diet alone and Thompson 1990 compared regular human insulin plus Neutral Protamine Hagedorn insulin and diet with diet alone.

Insulin versus exercise

One study compared insulin with exercise (Bung 1993), the type of insulin used was not specified.

Regimens of insulin

Two studies compared different regimens of insulin (Castorino 2011; Nachum 1999).

One ongoing study was identified (NCT01613807) which compares three injections of Humalog® 50/50TM daily with Humalog® plus Humalin N® administered as six injections daily. In subsequent updates of this review we will seek data from this study, where possible.

Comparisons included the following.

50/50 combination of insulin lispro plus Neutral Protamine Hagedorn insulin given as either three pre‐meal doses or as six distinct injections (Castorino 2011)
A twice‐daily regimen of human regular insulin plus human intermediate insulin with a four times daily regimen of regular human insulin (Nachum 1999)

Outcomes

Funding

Academic or governmental funding not related to pharmaceutic industry was reported in 10 studies (Ardilouze 2014; Hickman 2013; Ijas 2011; Lain 2009; Mesdaghinia 2013; Persson 1985; Rowan 2008; Tertti 2013; Wali 2015; Zawiejska 2016). In four studies the manuscript stated that there was no funding received (Behrashi 2016; Beyuo 2015; Mukhopadhyay 2012; Ruholamin 2014).

Jovanovic 1999 declared that drugs were supplied by Eli Lilly and the research was also part funded by this organisation. Notelovitz 1971 reported financial support received from Pfizer laboratories. Pettitt 2007 reported the study was funded in part through a contract with Novo Nordisk Inc.

There was no statement about funding in the manuscript in 36 studies (Anjalakshi 2007; Ashoush 2016; Balaji 2005; Balaji 2012; Bertini 2005; Bung 1993; Castorino 2011; Coustan 1978; De Veciana 2002; Di Cianni 2007; Hague 2003; Herrera 2015; Hutchinson 2008; Ismail 2007; Langer 2000; Majeed 2015; Martinez Piccole 2010; Mecacci 2003; Mirzamoradi 2015; Mohamed 2014; Moore 2007; Nachum 1999; Niromanesh 2012; O'Sullivan 1975a; O'Sullivan 1975b; Ogunyemi 2007; Pavithra 2016; Poyhonen‐Alho 2002; Prasad 2008; Riaz 2014; Saleh 2016; Silva 2007; Spaulonci 2013; Thompson 1990; Waheed 2013; Zangeneh 2014).

Conflicts of interest

Authors make a statement that there were no conflicts of interest in 14 studies (Ashoush 2016; Balaji 2012; Behrashi 2016; Beyuo 2015; Herrera 2015; Ijas 2011; Mesdaghinia 2013; Moore 2007; Mukhopadhyay 2012; Niromanesh 2012; Ruholamin 2014; Saleh 2016; Tertti 2013; Zawiejska 2016).

There were no details of conflicts of interest stated in the manuscript of 36 studies (Anjalakshi 2007; Ardilouze 2014; Balaji 2005; Bertini 2005; Bung 1993; Castorino 2011; Coustan 1978; De Veciana 2002; Di Cianni 2007; Hague 2003; Hickman 2013; Hutchinson 2008; Ismail 2007; Lain 2009; Langer 2000; Majeed 2015; Martinez Piccole 2010; Mecacci 2003; Mirzamoradi 2015; Mohamed 2014; Nachum 1999; Notelovitz 1971; O'Sullivan 1975a; O'Sullivan 1975b; Ogunyemi 2007; Pavithra 2016; Persson 1985; Poyhonen‐Alho 2002; Prasad 2008; Riaz 2014; Silva 2007; Spaulonci 2013; Thompson 1990; Waheed 2013; Wali 2015; Zangeneh 2014).

Jovanovic 1999 reported that two authors received research support from the Sansum Medical Research Institute as being a conflict of interest. Pettitt 2007 reported that one of the authors was an employee of the funding body (Novo Nordisk Inc). In the Rowan 2008 paper, conflicts are reported by Dr Moore for receiving speaking fees from Sanofi‐Aventis. In the 2011 follow‐up paper Dr Hague reports being a speaker at a Merck European Association for the Study of Diabetes symposium.

Excluded studies

Twenty‐one studies associated with 26 full‐text articles were excluded for the following reasons.

Six studies associated with 10 publications were quasi‐randomised (Ainuddin 2015a; Hassan 2012; Maresh 1983; Munshi 2014; O'Sullivan 1971; Tempe 2013). Five studies associated with six publications had the wrong study population for this review (Ainuddin 2015; Fadl 2015; NCT00678080; Schuster 1998; Smith 2015). Seven studies associated with eight publications had the wrong intervention for this review (Coiner 2014; Hopp 1996; Landon 2015; Li 1987; Palatnik 2015; Pettitt 2003; Snyder 1998). One publication had the wrong design (cost‐effectiveness analysis ‐ non RCT) for this review (Brennan 2015) and one publication (Kitzmiller 1990) reported that the study never commenced. One study (Li 1999) was not randomised.

Risk of bias in included studies

Refer to Figure 4 and Figure 5 for graphical representation of risk of bias of the included studies.

Figure 4

'Risk of bias' graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

Figure 5

'Risk of bias' summary: review authors' judgements about each risk of bias item for each included study.

Allocation

Randomisation ‐ Twenty‐three studies were judged to be of low risk of bias for method of randomisation and used random number tables or permuted blocks (Beyuo 2015; Herrera 2015; Hickman 2013; Hutchinson 2008; Ijas 2011; Jovanovic 1999; Lain 2009; Langer 2000; Mesdaghinia 2013; Mirzamoradi 2015; Mohamed 2014; Moore 2007; Mukhopadhyay 2012; Nachum 1999; Niromanesh 2012; Ogunyemi 2007; Riaz 2014; Rowan 2008; Ruholamin 2014; Spaulonci 2013; Thompson 1990; Waheed 2013; Zawiejska 2016).

Twenty‐nine studies were judged to be of unclear risk of bias for method of randomisation due to lack of methodological details (Anjalakshi 2007; Ardilouze 2014; Ashoush 2016; Balaji 2005; Balaji 2012; Behrashi 2016; Bertini 2005; Bung 1993; Castorino 2011; De Veciana 2002; Di Cianni 2007; Hague 2003; Ismail 2007; Majeed 2015; Martinez Piccole 2010; Mecacci 2003; Notelovitz 1971; O'Sullivan 1975a; O'Sullivan 1975b; Pavithra 2016; Persson 1985; Pettitt 2007; Poyhonen‐Alho 2002; Prasad 2008; Saleh 2016; Silva 2007; Tertti 2013; Wali 2015; Zangeneh 2014).

One study was judged to be of high risk of bias for methods of randomisation (Coustan 1978) as the first 20 of 72 women were quasi‐randomised and then the next 52 women were randomised to one of three groups with one new group added.

Allocation concealment ‐ Nineteen studies were judged to be of low risk of bias for allocation concealment and had used serially numbered opaque envelopes (Balaji 2012; Beyuo 2015; Herrera 2015; Hickman 2013; Hutchinson 2008; Ijas 2011; Lain 2009; Langer 2000; Mirzamoradi 2015; Mohamed 2014; Moore 2007; Nachum 1999; Niromanesh 2012; Ogunyemi 2007; Wali 2015; Zawiejska 2016) or a third party (Mesdaghinia 2013; Ruholamin 2014) or centralised allocation (Rowan 2008).

Thirty‐three studies were judged to be of unclear risk of bias for allocation concealment due to lack of methodological details (Anjalakshi 2007; Ardilouze 2014; Ashoush 2016; Balaji 2005; Behrashi 2016; Bertini 2005; Bung 1993; Castorino 2011; De Veciana 2002; Di Cianni 2007; Hague 2003; Ismail 2007; Jovanovic 1999; Majeed 2015; Martinez Piccole 2010; Mecacci 2003; Mukhopadhyay 2012; Notelovitz 1971; O'Sullivan 1975a; O'Sullivan 1975b; Pavithra 2016; Persson 1985; Pettitt 2007; Poyhonen‐Alho 2002; Prasad 2008; Riaz 2014; Saleh 2016; Silva 2007; Spaulonci 2013; Tertti 2013; Thompson 1990; Waheed 2013; Zangeneh 2014).

One study was judged to be of high risk of bias for allocation concealment (Coustan 1978) because the first 20 of 72 women were quasi‐randomised and then the next 52 women were randomised. There were no details for allocation concealment.

Blinding

Performance bias

Only two studies were judged to be low risk of performance bias as the care providers were blinded to treatment allocation (Mesdaghinia 2013) or the care providers and participants were not provided with actual OGTT results (Ruholamin 2014).

Eleven studies were judged to be of unclear risk of performance bias due to insufficient methodological information (Balaji 2005; Ismail 2007; Lain 2009; Mecacci 2003; Mirzamoradi 2015; Mohamed 2014; Nachum 1999; Notelovitz 1971; Persson 1985; Prasad 2008; Spaulonci 2013).

Forty studies were judged to be high risk of performance bias. Fifteen studies stated they were 'open‐label' (Ardilouze 2014; Ashoush 2016; Balaji 2012; Beyuo 2015; Bertini 2005; Herrera 2015; Jovanovic 1999; Langer 2000; Mukhopadhyay 2012; Ogunyemi 2007; Pettitt 2007; Rowan 2008; Silva 2007; Thompson 1990; Wali 2015) and 25 studies were unlikely to have been blinded due to differences in mode of administration of the interventions (Anjalakshi 2007; Behrashi 2016; Bung 1993; Castorino 2011; Coustan 1978; De Veciana 2002; Di Cianni 2007; Hague 2003; Hickman 2013; Hutchinson 2008; Ijas 2011; Majeed 2015; Martinez Piccole 2010; Moore 2007; Niromanesh 2012; O'Sullivan 1975a; O'Sullivan 1975b; Pavithra 2016; Poyhonen‐Alho 2002; Riaz 2014; Saleh 2016; Tertti 2013; Waheed 2013; Zangeneh 2014; Zawiejska 2016).

Detection bias

Five studies were judged to be low risk of detection bias as outcome assessors were blinded for one or more outcomes (Beyuo 2015; Lain 2009; Mesdaghinia 2013; Mohamed 2014; Ruholamin 2014).

Forty‐four studies were judged to be of unclear risk of detection bias due to insufficient methodological details (Anjalakshi 2007; Ardilouze 2014; Ashoush 2016; Balaji 2005; Balaji 2012; Behrashi 2016; Bertini 2005; Bung 1993; Castorino 2011; Coustan 1978; De Veciana 2002; Di Cianni 2007; Hague 2003; Hickman 2013; Hutchinson 2008; Ijas 2011; Ismail 2007; Jovanovic 1999; Majeed 2015; Martinez Piccole 2010; Mecacci 2003; Mirzamoradi 2015; Moore 2007; Nachum 1999; Niromanesh 2012; Notelovitz 1971; Ogunyemi 2007; O'Sullivan 1975a; O'Sullivan 1975b; Pavithra 2016; Persson 1985; Pettitt 2007; Poyhonen‐Alho 2002; Prasad 2008; Riaz 2014; Rowan 2008; Saleh 2016; Spaulonci 2013; Tertti 2013; Thompson 1990; Waheed 2013; Wali 2015; Zangeneh 2014; Zawiejska 2016).

Four studies were judged to be high risk of detection bias as the outcome assessors were aware of the allocation (Herrera 2015; Langer 2000; Mukhopadhyay 2012; Silva 2007).

Incomplete outcome data

Thirty‐one studies were judged to be of low risk of attrition bias as minimal or no losses reported (Ashoush 2016; Balaji 2005; Balaji 2012; Bertini 2005; Castorino 2011; Coustan 1978; Ijas 2011; Jovanovic 1999; Langer 2000; Majeed 2015; Mesdaghinia 2013; Mirzamoradi 2015; Moore 2007; Mukhopadhyay 2012; Nachum 1999; Niromanesh 2012; Notelovitz 1971; Ogunyemi 2007; O'Sullivan 1975a; Pavithra 2016; Poyhonen‐Alho 2002; Riaz 2014; Rowan 2008; Ruholamin 2014; Saleh 2016; Silva 2007; Spaulonci 2013; Tertti 2013; Thompson 1990; Waheed 2013; Zawiejska 2016).

Fourteen studies were judged to be of unclear risk of bias; eight as there was insufficient information to be able to make a judgement (Di Cianni 2007; Hague 2003; Hutchinson 2008; Martinez Piccole 2010; Mohamed 2014; O'Sullivan 1975b; Wali 2015; Zangeneh 2014) and three as there was relatively high attrition (16% loss to follow‐up (87/104) ‐ Beyuo 2015; 17% loss to follow‐up or not completed intervention the reasons for losses are not explained Bung 1993; 18% (87/105) attrition (Herrera 2015). Lain 2009 did not analyse all of the women for all of the outcomes and the number of losses were reported in the Pettitt 2007 study but not the groups they were randomised to. Behrashi 2016 excluded women who had received insulin but these women were not excluded from other trials.

Eight studies were judged to be high risk of bias. Three studies reported preliminary data only in a conference abstract format. It is therefore unclear if these were all the women randomised and if there was any attrition at the end of data collection (Ardilouze 2014; De Veciana 2002; Prasad 2008). One study had high attrition (30%; 3/10) at follow‐up in the glibenclamide group (Anjalakshi 2007). Hickman 2013 reported that only 31 of 230 women were randomised; Ismail 2007 reported that 68 women were randomised but only 61 women analysed; there is no explanation for the difference. One study reported excluding 16 of 65 women post hoc (Mecacci 2003) and one study reported that some data were not available for all women such as HbA1c at delivery and cord C peptide and other outcomes were not reported with total sample denominator. Persson 1985 reported that some data were not available for all women such as HbA1c at delivery and cord C peptide. Other outcomes not reported with total sample denominator.

Selective reporting

Five studies were judged to be of low risk of reporting bias as all outcomes pre‐specified were reported (Ashoush 2016; Bertini 2005; Niromanesh 2012; Tertti 2013; Zangeneh 2014).

Fourteen studies were judged to be of unclear risk of reporting bias. Five studies reported one outcome that had not been pre‐specified (Behrashi 2016; Langer 2000; Mecacci 2003; Mirzamoradi 2015; Mohamed 2014). Three studies reported only a limited number of outcomes that had not been pre‐specified (Ismail 2007; Mesdaghinia 2013; Silva 2007). Moore 2007 did not report data for one of the trials' pre‐specified outcomes and Ijas 2011 reported on data from subgroups that had not been pre‐specified. Ruholamin 2014 did not provide data to support the findings reported in the text of the manuscript. Beyuo 2015 reported on data for women with GDM and with pre‐existing diabetes, the majority of women had GDM 32 of 43 women in the metformin group and 23 of 40 women in the insulin group. Only glycaemic control data are reported although other neonatal outcomes were listed in the methods section of the report. The authors note in the results section that fasting blood glucose, one‐hour postprandial glucose, maternal weight gain, pregnancy and neonatal outcomes were also recorded but were not discussed in this publication. In another study (Waheed 2013), it was unclear if the study includes women with pre‐existing diabetes and what proportion they constituted. The two‐year follow‐up data for the Rowan 2008 study were only reported in two sites in Australia and New Zealand.

Thirty‐four studies were judged to be high risk of reporting bias. Ten studies provided only preliminary data or data only reported in a conference abstract (Ardilouze 2014; Castorino 2011; De Veciana 2002; Hutchinson 2008; Martinez Piccole 2010; Ogunyemi 2007; Prasad 2008; Wali 2015), a brief report (Di Cianni 2007) or letter to the editor (Hague 2003). Five studies did not pre‐specify any maternal or neonatal outcomes (Bung 1993; Notelovitz 1971; Persson 1985; Poyhonen‐Alho 2002; Zawiejska 2016). Coustan 1978 only pre‐specified diabetes postpartum as and outcome. Six studies had limited outcomes (Herrera 2015; Lain 2009; O'Sullivan 1975a; O'Sullivan 1975b; Pavithra 2016; Riaz 2014) and three studies did not report on all of the pre‐specified outcomes (Balaji 2005; Lain 2009; Thompson 1990) or additional outcomes were reported that were not pre‐specified (Majeed 2015). Seven studies reported additional outcomes (Balaji 2012; Hickman 2013; Jovanovic 1999; Mukhopadhyay 2012; Nachum 1999; Pettitt 2007; Spaulonci 2013). In the Anjalakshi 2007 study outcomes were not prespecified and were very limited. The evidence was published as correspondence only and no full publication could be identified.

Other potential sources of bias

Twenty‐six studies were judged to be low risk of other sources of bias (Ardilouze 2014; Ashoush 2016; Balaji 2012; Behrashi 2016; Bertini 2005; Beyuo 2015; Di Cianni 2007; Ijas 2011; Langer 2000; Majeed 2015; Mecacci 2003; Mesdaghinia 2013; Mukhopadhyay 2012; Nachum 1999; Niromanesh 2012; Pavithra 2016; Persson 1985; Pettitt 2007; Ruholamin 2014; Saleh 2016; Spaulonci 2013; Tertti 2013; Thompson 1990; Waheed 2013; Zangeneh 2014; Zawiejska 2016).

Seven studies were judged to be of unclear risk of other sources of bias. In the Mirzamoradi 2015 study more women were allocated to the insulin group (n = 59) compared with the glibenclamide group (n = 37) and the difference was not explained. There was insufficient detail to make a judgement for two studies (Hague 2003; O'Sullivan 1975a). Three studies reported some imbalance between groups at baseline (Castorino 2011; Jovanovic 1999 for age; Rowan 2008 for pregnancy losses (any reason)). One study noted that 33% of participants had type 2 diabetes and 67% had GDM. However, data for blood glucose are reported for GDM alone (Herrera 2015).

Twenty studies were judged to be high risk of other sources of bias. In the Coustan 1978 study data from quasi‐randomised cannot be separated from randomised data. Ten studies only reported preliminary data and/or data in a conference abstract (Balaji 2005; De Veciana 2002; Hutchinson 2008; Martinez Piccole 2010; Prasad 2008; Wali 2015), correspondence (Anjalakshi 2007) or short communication (Ismail 2007; Poyhonen‐Alho 2002; Riaz 2014). One study recruited women with both GDM and type 2 diabetes and did not report data separately, as 77% of the women had GDM we included the data in meta‐analyses but what is not clear is the distribution of women with GDM between the intervention and control groups (Mohamed 2014). Another study recruited women with both GDM and type 2 diabetes and did not report data separately, as 50% of the women had GDM the data have been included (Hickman 2013). The Hickman 2013 study was unable to recruit the expected number of women and was therefore underpowered to detect differences in the outcomes. Notelovitz 1971 included women with both GDM and type 2 diabetes, the groups are not reported separately and the proportion of women with GDM is not reported. The data from this study have therefore not been included in any meta‐analyses. The Lain 2009 study stopped early due to discontinuation of the maintenance equipment for the primary outcome. The O'Sullivan 1975b study stopped early due to lack of funding. Moore 2007 reported only half the sample that had been estimated to be statistically appropriate had been recruited after 32 months and as such an interim report on 63 women was undertaken. There is no evidence of a full report. Two studies reported multiple baseline differences in the relevant blood glucose levels (fasting, one‐hour, two‐hour and HbA1c levels), which were all higher in the insulin group (Ogunyemi 2007) or higher in the glibenclamide group (Silva 2007). Bung 1993 failed to report any baseline demographic data to determine if groups were balanced.

Effects of interventions

See: Summary of findings for the main comparison Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (maternal outcomes); Summary of findings 2 Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (infant/child/adult outcomes)

Comparison 1 ‐ Insulin versus oral anti‐diabetic pharmacological therapy

Twenty‐eight trials involving 4040 women contributed data to this comparison.

Maternal primary outcomes

1.1 and 1.2 Hypertensive disorders of pregnancy (including pre‐eclampsia, pregnancy‐induced hypertension, eclampsia)

Ten studies reported on hypertensive disorders of pregnancy; three compared insulin with glibenclamide (Langer 2000; Mirzamoradi 2015; Zangeneh 2014) and seven studies compared insulin with metformin (Hague 2003; Ijas 2011; Niromanesh 2012; Rowan 2008; Saleh 2016; Spaulonci 2013; Tertti 2013). Hypertensive disorders of pregnancy were reported as pre‐eclampsia or hypertensive disorders of pregnancy (not defined). No studies reported eclampsia as an outcome.

There was no clear evidence of a difference for the risk of pre‐eclampsia between women who had been treated with insulin and those who had been treated with an oral anti‐diabetic pharmacological therapy (risk ratio (RR) 1.14, 95% CI 0.86 to 1.52; 10 studies, 2060 women; moderate‐quality evidence) (Analysis 1.1). The quality of the evidence was downgraded for risk of bias as eight of the 10 studies were not blinded.

Treatment with insulin was associated with an increased risk for hypertensive disorders of pregnancy (not defined) compared with oral anti‐diabetic pharmacological therapy (RR 1.89, 95% CI 1.14 to 3.12; four studies, 1214 women; moderate‐quality evidence,Analysis 1.2). Three studies (Niromanesh 2012; Rowan 2008; Tertti 2013) had used metformin as the anti‐diabetic pharmacological therapy and one study used glibenclamide (Pavithra 2016).

1.3 Caesarean section

Caesarean section was reported in 17 studies; seven compared insulin with glibenclamide (Bertini 2005; Langer 2000; Mirzamoradi 2015; Ogunyemi 2007; Pavithra 2016; Silva 2007; Zangeneh 2014); nine compared insulin with metformin (Ashoush 2016; Hague 2003; Ijas 2011; Moore 2007; Niromanesh 2012; Ruholamin 2014; Saleh 2016; Spaulonci 2013; Tertti 2013), and one study each compared insulin with acarbose (Bertini 2005) and a combination on metformin and glibenclamide (Ardilouze 2014).

There was no clear evidence of a difference for the risk of birth by caesarean section between women who had been treated with insulin and those who had been treated with an oral anti‐diabetic pharmacological therapy (RR 1.03, 95% CI 0.93 to 1.14; 1988 women; 17 studies; moderate‐quality evidence) (Analysis 1.3). The quality of the evidence was downgraded for risk of bias as 15 of the 17 studies were unblinded. Visual inspection of the funnel plot associated with this outcome does not suggest any evidence of publication bias (Figure 2).

1.4 Development of type 2 diabetes

Development of type 2 diabetes was reported in two studies both comparing insulin and metformin (Rowan 2008; Tertti 2013). Rowan 2008 reported the outcome at the six to eight weeks postpartum oral glucose tolerance test and Tertti 2013 at up to one year postpartum. There was no evidence of a difference between groups (RR 1.39, 95% CI 0.80 to 2.44; two studies, 754 women; moderate‐quality evidence) (Analysis 1.4). The quality of the evidence was downgraded for risk of bias as both studies were open‐label.

Neonatal primary outcomes

1.5 Perinatal (fetal and neonatal death) and later infant mortality

Perinatal death was reported in 11 comparisons in 10 studies; five studies compared insulin with glibenclamide (Bertini 2005; Lain 2009; Langer 2000; Mukhopadhyay 2012; Silva 2007); four studies compared insulin with metformin (Ijas 2011; Mesdaghinia 2013; Niromanesh 2012; Tertti 2013), and one study each compared insulin with acarbose (Bertini 2005) and a combination of metformin and glibenclamide (Mohamed 2014).

There was no clear evidence of a difference for the risk of perinatal death between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapies (RR 0.85; 95% CI 0.29 to 2.49; 10 studies, 1463 infants; low‐quality evidence). The quality of evidence was downgraded for risk of bias and imprecision. Six studies reported that there were no events of perinatal group in either the insulin or the oral anti‐diabetic drug groups (Bertini 2005; Ijas 2011; Mesdaghinia 2013; Niromanesh 2012; Silva 2007; Tertti 2013). The studies were not powered to detect differences in perinatal mortality and event rates are very low 3/686 for the insulin‐treated group and 3/693 for the oral anti‐diabetic agent group (Analysis 1.5).

No data were reported for later infant mortality.

1.6 Large‐for‐gestational age (LGA)

LGA was reported in 14 studies of three comparisons; five studies compared insulin with glibenclamide (Bertini 2005; Lain 2009; Langer 2000; Mukhopadhyay 2012; Silva 2007); eight studies compared insulin with metformin (Hickman 2013; Ijas 2011; Mesdaghinia 2013; Niromanesh 2012; Rowan 2008; Saleh 2016; Spaulonci 2013; Tertti 2013) and one study (Bertini 2005) compared insulin with acarbose.

There was no clear evidence of a difference between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapies for the risk of being born LGA (average RR 1.01, 95% CI 0.76 to 1.35; 2352 infants; 13 studies; I² = 35%; moderate‐quality evidence;Analysis 1.6). There was substantial heterogeneity present in this outcome so these result should be interpreted with caution (Heterogeneity: Tau² = 0.08; Chi² = 19.88 (P = 0.10)). Quality of evidence was downgraded for risk of bias and publication bias. The majority of studies were unblinded and visual inspection of the funnel plot (Figure 3) suggests asymmetry and therefore publication bias with those studies with larger effect sizes more likely to be published.

1.7 Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy)

Two studies comparing insulin with metformin reported a composite outcome of serious infant morbidity (Hickman 2013; Rowan 2008). There was no evidence of a clear difference between those whose mothers had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapies (metformin) for the risk of a composite of serious infant morbidity (RR 1.03, 95% CI 0.84 to 1.26; two studies, 760 infants; moderate‐quality evidence;Analysis 1.7). The quality of evidence was downgraded for risk of bias as both studies were not blinded.

1.8 Neurosensory disability in later childhood

At 18 months of age, there was no evidence of a clear difference in the risk of any mild developmental delay between infants whose mothers had been treated with insulin and those who had been treated with oral anti‐diabetic agents (RR 1.07, 95% CI 0.33 to 3.44; one study, 93 children; low‐quality evidence) (Ijas 2011). At 18 months of age, there was no evidence of a difference in the risk of hearing impairment (RR 0.31; 95% CI 0.01 to 7.49; one study, 93 children; low‐quality evidence) or visual impairment (RR 0.31, 95% CI 0.03 to 2.90; one study, 93 children; low‐quality evidence) between infants whose mothers had been treated with insulin and those who had been treated with oral anti‐diabetic agents (Ijas 2011) (Analysis 1.8).

Maternal secondary outcomes

1.9 Use of additional pharmacotherapy

Where reported, for those women who were treated with oral anti‐diabetic pharmacological therapy a total of 22% required supplementary insulin (RR 0.03, 95% CI 0.02 to 0.06; 19 studies; 2761 women). Seven studies reported using glibenclamide as the oral anti‐diabetic (Bertini 2005; Lain 2009; Langer 2000; Mirzamoradi 2015; Ogunyemi 2007;Pavithra 2016; Silva 2007). In these studies 6.7% (29/433) of women required supplementary insulin. Ten studies reported using metformin as the oral anti‐diabetic (Ashoush 2016; Beyuo 2015; Hickman 2013; Ijas 2011; Moore 2007; Niromanesh 2012; Rowan 2008; Ruholamin 2014; Spaulonci 2013; Tertti 2013). For these studies, 30% (250/837) of women required supplementary insulin. These data are skewed by the Rowan 2008 study, which is the largest in this subgroup. In this study almost half of the women (46%, 168/363) received supplementary insulin. Acarbose was used in two studies (Bertini 2005; De Veciana 2002), for which 17% (11/64) women received supplementary insulin. It should be noted that women in the De Veciana 2002 study who were randomised to acarbose commenced insulin because they could not tolerate increasing doses of acarbose rather than an inability to maintain glycaemic control. One study reported comparing insulin with a combination on metformin and glibenclamide (Ardilouze 2014), 37% of the oral anti‐diabetic agent group required additional insulin (Analysis 1.9).

1.10 Maternal hypoglycaemia

There was no evidence of a difference for the risk of maternal hypoglycaemia between women who had been treated with insulin and those who had been treated with an oral anti‐diabetic pharmacological therapy (average RR 3.01, 95% CI 0.74 to 12.27; 10 studies, 998 women; I² = 84%) (Analysis 1.10). Five studies reported no events of maternal hypoglycaemia in either the insulin nor the oral anti‐diabetic pharmacological therapy group (Anjalakshi 2007; Bertini 2005; Moore 2007; Mukhopadhyay 2012; Silva 2007). Heterogeneity may be due to lack of blinding reported in the studies reporting this outcome or to definitions of hypoglycaemia which are poorly report in the individual studies (Heterogeneity: Tau² = 1.91; Chi² = 24.87 (P = < 0.0001)).

1.11 to 1.13 Glycaemic control during/end of treatment

There was no evidence of a clear difference in fasting blood glucose (average standardised mean difference (SMD) 0.05, 95% CI ‐0.09 to 0.19; 19 studies, 2812 women; I² = 66%; Tau² = 0.06; Chi² = 56.67 (P <0.0001)) (Analysis 1.11), postprandial blood glucose (average SMD 0.12, 95% CI ‐0.05 to 0.29; 18 studies 2508 women; I² = 73%; Tau² = 0.09; Chi² = 67.85 (P < 0.00001)) (Analysis 1.12) or HbA1c (average SMD 0.01, 95% CI ‐0.12 to 0.15; nine studies, 1963 women; I² = 45%; Tau² = 0.02; Chi² = 14.42 (P <0.07)) (Analysis 1.13) between women who had been treated with insulin and those treated with oral anti‐diabetic agents. Heterogeneity was substantial for all of these outcomes. Median data for fasting blood glucose concentration, one‐hour postprandial glucose concentration and HbA1c were reported by Hickman 2013 (Table 8). Waheed 2013 and Riaz 2014 report data as the number of women who had values for glycaemic control within the treatment target (Table 8).

Open in table viewer

Table 8. Maternal outcomes

Study ID	Outcome	Insulin (A)	Comparison
Hickman 2013	Fasting blood glucose (mg/dL)	Median 85.2 (IQR 86, 115) (n = 8)	Metformin Median 89.5 (IQR 90, 98) (n = 10)
Coustan 1978	Fasting blood glucose (mg/dL)	86.8 ± 12.7 (n = 33 observations)	Diet 94.7 ± 9.1 (n = 14 observations)
Waheed 2013	Fasting blood glucose	30/34 women within treatment target	Metformin 27/34 women within treatment target
Hickman 2013	1‐hour postprandial blood glucose (mg/dL)	Median 125.3 (IQR 112, 138) (n = 8)	Metformin Median 122.3 (IQR 118, 130) (n = 10)
Coustan 1978	2‐hour postprandial blood glucose (mg/dL)	99.9 ± 27.6 (n = 32 observations)	102.6 ± 12.4 (n = 13 observations)
Hickman 2013	HbA1c (%)	Median 5.6 (IQR 5.3, 6.4) (n = 13)	Metformin Median 5.9 (IQR 5.5, 6.0) (n = 13)
Ismail 2007	HbA1c (%)	Human insulin Median 6.0 (IQR 1.20) (n = 30)	Neutral Protamine Hagedorn insulin Median 5.90 (IQR 0.80) (n = 31)
Waheed 2013	HbA1c (%)	27/34 women within treatment target	Metformin 28/34 women within treatment target
Hickman 2013	Gestational weight gain (kg)	Median 0.30 (IQR 0.18, 0.47) (n = 13)	Metformin Median 0.28 (IQR 0.11, 0.38) (n = 13)
Mecacci 2003	Gestational weight gain (kg)	Regular insulin ‐ Median 11.1 (range 8 to 14) (n = 24)	Insulin lispro ‐ Median 10.9 (range 7 to 17) (n = 25)
Riaz 2014	Glycaemic control	Insulin 56/100	Metformin 72/100

IQR: interquartile range

1.14 Weight gain in pregnancy

Insulin was associated with an increase in gestational weight gain compared with oral anti‐diabetic pharmacological therapy (average mean difference (MD) 1.06 kg, 95% CI 0.63 to 1.48; 10 studies, 2336 women; I² = 65%, Tau² = 0.23) . The subgroup interaction test based on type of oral anti‐diabetic pharmacological therapy was not significant suggesting no differential effect between glibenclamide, metformin, or acarbose (I² = 0%, Chi² = 0.69, P = 0.71) (Analysis 1.14). Median data for gestational weight gain were reported by Hickman 2013 (Table 8). None of the studies detailed wither the gestational weight gain was within, above or below acceptable standards, we suggest caution when interpreting these data.

1.15 Induction of labour

Insulin may possibly increase the risk of induction of labour compared with oral anti‐diabetic pharmacological therapy although the evidence was not clear (average RR 1.30, 95%CI 0.96 to 1.75; three studies, 348 women; I² = 32%; Tau² = 0.02; moderate quality of evidence;Analysis 1.15). Quality of evidence was downgraded for risk of bias as all three studies were not blinded and there was insufficient detail to be able to judge allocation concealment and randomisation. All three studies reporting this outcome (Hague 2003; Ijas 2011; Tertti 2013) used metformin as the oral anti‐diabetic agent.

1.16 Postpartum haemorrhage

There was no evidence of a difference for the risk of postpartum haemorrhage between women who had been treated with insulin and those who had been treated with an oral anti‐diabetic pharmacological therapy (RR 0.34, 95% CI 0.01 to 8.13; two studies, 91 women; Analysis 1.16). One of the two studies reported no events in the insulin nor in the oral anti‐diabetic group (Hickman 2013). There is evidence of imprecision with wide CIs, small sample size and low event rates.

1.17 Breastfeeding

Breastfeeding was poorly reported. There was no evidence of a difference for breastfeeding at six to eight weeks postpartum between women who had been treated with insulin and those who had been treated with an oral anti‐diabetic pharmacological therapy (RR 1.03, 95% CI 0.86 to 1.23; two studies, 411 women) (Analysis 1.17). Both studies (Ijas 2011; Rowan 2008) used metformin as the oral anti‐diabetic.

1.18 Relevant biomarker changes associated with the intervention

There was no clear evidence of a difference between insulin and oral anti‐diabetic pharmacological therapy (metformin) for any of the reported biomarkers associated with the intervention: HOMA‐IR (MD 0.00, 95% CI ‐2.92 to 2.92; one study, 78 women), total cholesterol (MD 0.10, 95% CI ‐0.49 to 0.69; one study, 78 women), high‐density lipoprotein (HDL) cholesterol (MD 0.10, 95% CI ‐0.13 to 0.33; one study, 78 women) or triglycerides (MD ‐0.30, 95% CI ‐0.68 to 0.08; one study, 78 women).

Views of the intervention (data not shown)

Women in the Rowan 2008 trial were asked about the acceptability of the intervention one week postpartum. Of those treated with metformin, 76% said they would choose metformin if needed in a subsequent pregnancy whereas only 27% of women would choose insulin again. Women in the metformin group thought that taking medication was the easiest part of treatment compared with women taking insulin (59% versus 35%).

Adherence to the intervention (data not shown)

Sixty‐nine per cent of women taking metformin in the Rowan 2008 trial reported that they never or rarely forgot to take their medication compared with 81% of women taking insulin.

No data were reported for placental abruption, postpartum infection; perineal trauma/tearing; maternal mortality, sense of well‐being or quality of life or behavioural changes associated with the intervention.

Long‐term outcomes for mother

A limited number of the included studies reported long‐term data for women with GDM (Mirzamoradi 2015; Rowan 2008; Tertti 2013). Rowan 2008 and Tertti 2013 currently report up to two‐years follow‐up.

1.19 Body mass index (BMI)

There was no evidence of a difference between women who had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapy for BMI at six weeks postpartum (MD ‐0.20 kg/m², 95% CI ‐1.29 to 0.89; one study, 733 women) (Analysis 1.19).

1.20 Postnatal weight retention or return to pre‐pregnancy weight

Maternal weight (kg) was reported from the Tertti 2013 study at six to eight weeks' postpartum and at one‐year postpartum. There was no clear evidence of difference in postnatal weight between women treated with insulin and those treated with oral anti‐diabetic pharmacological therapy (metformin) at six to eight weeks postpartum (MD ‐1.60 kg, 95% CI ‐6.34 to 3.14; one study, 167 women; low‐quality evidence) or one year postpartum (MD ‐3.70 kg, 95% CI ‐8.50 to 1.10; one study, 176 women; low‐quality evidence) (Analysis 1.20).

1.21 Impaired glucose tolerance

Three studies reported on impaired glucose tolerance at follow‐up (Mirzamoradi 2015; Rowan 2008; Tertti 2013). At six weeks postpartum there was no clear evidence of a difference for impaired glucose tolerance between women who had been treated with insulin and those with oral anti‐diabetic agents (RR 1.16, 95% CI 0.80 to 1.68; three studies, 841 women). Nor was there evidence of a difference between groups at one‐year postpartum reported in one study (Tertti 2013) (RR 0.84, 95% CI 0.56 to 1.26; one study, 179 women). See Analysis 1.21.

No data were reported for postnatal depression or cardiovascular health.

Fetal/neonatal secondary outcomes

There was no clear difference between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic agents for the following outcomes.

1.22 Stillbirth

There was no evidence of a clear difference between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapy for the risk of stillbirth (RR 0.60, 95% CI 0.08 to 4.52; three studies, 653 infants) (Analysis 1.22).

1.23 Neonatal death

There was no evidence of a clear difference between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapy for the risk of neonatal death (RR 0.99, 95% CI 0.06 to 15.72; two studies, 503 infants) (Analysis 1.23).

1.24 Macrosomia

There was no overall evidence of a clear difference between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapy for the risk of macrosomia (average RR 1.17, 95% CI 0.77 to 1.78; 19 studies, 2305 infants; I² = 42%, Tau² = 0.27; Chi² = 27.47 (P = 0.04)). The subgroup difference was not clear suggesting there was no differential effect between the type of oral anti‐diabetic agent used. The Bertini 2005 study of 33 infants reported no events for macrosomia in either the insulin or the acarbose groups. See Analysis 1.24.

1.25 Small‐for‐gestational age (SGA)

There was no evidence of a clear difference between insulin and oral anti‐diabetics for the risk of being born SGA (RR 1.16, 95% CI 0.79 to 1.69; nine studies, 1812 infants; Analysis 1.25). One study (Mesdaghinia 2013) reported no events in either the insulin or the oral anti‐diabetic group.

1.26 Birth trauma

Birth trauma (not defined) was reported in five studies. There were no events reported in four studies (Bertini 2005; Lain 2009; Saleh 2016; Silva 2007). One study reported no differences for the risk of birth trauma (not specified) for insulin compared with metformin (Rowan 2008) (RR 1.04, 95% CI 0.53 to 2.03; one study, 733 infants) (Analysis 1.26).

There was no evidence of a clear difference for the risk of shoulder dystocia between insulin and oral antidiabetics groups (RR 1.44, 95% CI 0.62 to 3.34; eight studies, 968 infants; Analysis 1.26), the risk of bone fracture (RR 4.71, 95% CI 0.23 to 95.53; two studies, 196 infants) or nerve palsy (RR 5.05, 95% CI 0.24 to 103.90; two studies, 320 infants; Analysis 1.26).

1.27 Gestational age at birth

There was no evidence of a clear difference between insulin and oral anti‐diabetics for gestational age at birth (average MD weeks ‐0.01, 95% CI ‐0.20 to 0.18; 18 studies, 2834 infants; I² = 59%, Tau² = 0.09; Chi² = 43.71 (P = 0.0006); Analysis 1.27). Median data for gestational age at birth were reported by Hickman 2013 (Table 9).

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Table 9. Neonatal outcomes

Study ID	Outcome	Insulin	Comparison
Hague 2003	Cord C‐peptide	Median 0.66 (range 0.45 to 1.71) pmol/mL (n = 14)	Metformin Median 0.53 (range 0.35 to 2.86) pmol/mL (n = 16)
Hague 2003	Duration in special care nursery	Median 24 (range 0 to 102) hours (n = 14)	Metformin Median 48 (range 0 to 360) hours (n = 16)
Niromanesh 2012	Duration of hospitalisation	Mean 2 days (range 1 to 4)	Metformin Mean 2 days (range 1 to 6)
Hickman 2013	Neonatal Cord C‐ peptide	Median 1.5 (IQR 1.1, 3.4) (n = 11)	Metformin Median 1.5 (IQR 0.9, 2.8) (n = 11)

Hickman 2013	Birthweight	Median 2986 (IQR 2822, 3630) (n = 14)	Metformin Median 3202 (IQR 3026, 3608) (n = 14)
Mecacci 2003	Gestational age at birth (weeks)	Regular insulin ‐ Median 40 (range 37 to 41) (n = 24)	Insulin lispro ‐ Median 40 (range 37 to 41) (n = 25)
Hickman 2013	Gestational age at birth (weeks)	Median 38 (IQR 36, 39) (n = 14)	Metformin Median 39 (IQR 37, 39) (n = 14)

		Insulin	Diet
Persson 1985	Gestational age at birth (days)	Median 277 (range 234 to 293) (n = 97)	Median 275 (range 234 to 297) (n = 105)
Persson 1985	Birthweight (g)	Median 3630 (range 1655 to 4830) (n = 97)	Median 3560 (range 2000 to 4700) (n = 105)
Persson 1985	Skinfold thickness triceps (mm) Skinfold thickness subscapular (mm)	Median 4.9 (range 3.3 to 9.4) (n = 97) Median 4.7 (range 3.1 to 7.4) (n = 97)	Median 5.1 (range 2.1 to 9.9) (n = 105) Median 4.9 (range 2.5 to 8.7) (n = 105)

IQR: interquartile range

1.28 Preterm birth (less than 37 weeks’ gestation)

For preterm birth less than 37 weeks' gestation, there was no evidence of a clear difference between insulin and oral anti‐diabetics (average RR 1.10, 95% CI 0.64 to 1.88; 11 studies, 2417 infants; I² = 65%, Tau² = 0.45; Chi² = 28.57 (P = 0.001); Analysis 1.28). No data were presented for preterm birth less than 32 weeks' gestation.

1.29 Congenital abnormality (not pre‐specified)

There was no evidence of a clear difference between insulin and oral anti‐diabetics for the risk of congenital abnormality (RR 1.35, 95% CI 0.88 to 2.08; 15 studies, 2671 infants; Analysis 1.29). Three studies reported no events in either intervention group (De Veciana 2002; Hickman 2013; Zangeneh 2014).

1.30 Five‐minute Apgar less than seven

There was no evidence of a clear difference between insulin and oral anti‐diabetics for a five‐minute Apgar score less than seven (RR 0.49, 95% CI 0.09 to 2.64; four studies, 1170 infants; Analysis 1.30) . There were no events in two of the studies (Mesdaghinia 2013; Ruholamin 2014).

1.31 Birthweight

Birthweight did not differ overall between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic agents (MD ‐20.14 g, 95% CI ‐83.58 to 43.29; 22 studies, 3183 infants; I² = 67%, Tau² = 14034.8; Chi² = 67.47 (P < 0.00001)). The subgroup interaction test including glibenclamide, metformin and acarbose was not clear suggesting there was no differential effect between the oral anti‐diabetic agents used (Analysis 1.31). Data for median birthweight were reported by Hickman 2013 (Table 9).

1.32 Head circumference at birth (cm)

There was no evidence of a difference between insulin and oral anti‐diabetics for head circumference at birth (average MD 0.14 cm, 95% CI ‐0.26 to 0.53; three studies, 975 infants; I² = 65%, Tau² = 0.08; Chi² = 5.71 (P = 0.06); Analysis 1.32).

1.33 Length at birth (cm)

There was no evidence of a difference between insulin and oral anti‐diabetics for length at birth (average MD 0.11 cm, 95% CI ‐0.50 to 0.71; three studies, 975 infants I² = 61%, Tau² = 0.17; Chi² = 5.10 (P = 0.08); Analysis 1.33).

1.34 Ponderal index at birth

Ponderal index did not differ overall between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetics (average MD 0.03 kg/m³, 95% CI ‐0.13 to 0.19; two studies, 815 infants; I² = 78%; Tau² = 0.01; Chi² = 4.46 (P = 0.03); very low‐quality evidence). The subgroup interaction test indicated a differential effect between these studies, one of which compared insulin with glibenclamide (Lain 2009) and showed no difference in ponderal index and one study that compared insulin with metformin (Rowan 2008), which showed a higher ponderal index for infants whose mothers had been treated with insulin (Analysis 1.34). Evidence is based on only two studies and caution should be taken when interpreting the data.

1.35 to 1.38 Adiposity at birth

Skinfold thickness measurements at birth (mm) ‐ There was no clear difference between intervention groups for triceps (MD ‐0.07 mm, 95% CI ‐0.25 to 0.10; two studies, 815 infants; Analysis 1.35), subscapular (average MD ‐0.13 mm, 95% CI ‐0.50 to 0.24; two studies, 815 infants; I² = 52%, Tau² = 0.04; Chi² = 2.09, (P = 0.15); Analysis 1.36) or skinfold sum (MD ‐0.80 mm, 95% CI ‐2.33 to 0.73, one study, 82 infants; very low‐quality evidence).

Percentage (%)fat mass ‐ Percentage fat mass did not clearly differ between intervention groups (MD ‐1.60%, 95% CI ‐3.77 to 0.57; one study, n = 82 infants; moderate‐quality evidence;Analysis 1.38).

1.39 Neonatal hypoglycaemia

Neonatal hypoglycaemia did not differ overall between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic agents (RR 1.14, 95% CI 0.85 to 1.52; 24 studies; 3892 infants; I² = 47%; Tau² = 0.18; Chi² = 43.73 (P = 0.006); low‐quality evidence;Analysis 1.39). The subgroup interaction test suggests a differential effect between the oral anti‐diabetic agents used (Chi² = 11.11, df = 3, P = 0.01, I² = 73%; Analysis 1.39). Insulin was associated with a decreased risk of neonatal hypoglycaemia compared with glibenclamide (RR 0.70, 95% CI 041 to ;1.19; 10 studies, 1283 infants) and an increased risk for neonatal hypoglycaemia when compared with metformin (RR 1.58, 95% CI 1.16 to 2.16; 12 studies, 2424 infants). There was no clear difference between groups for insulin compared with acarbose (RR 0.44, 95% CI 0.02 to 10.16; one study, 33 infants) or insulin compared with combined metformin and glibenclamide (RR 0.76, 95% CI 0.49 to 1.18; two studies, 152 infants; Analysis 1.39) although these latter two comparisons are based on small studies of participants and low event rates.

1.40 Respiratory distress syndrome

There was no evidence of a clear difference between intervention groups for the risk of respiratory distress syndrome (RR 1.29, 95% CI 0.83 to 1.99; 10 studies, 1894 infants; Analysis 1.40).

1.41 Neonatal jaundice (hyperbilirubinaemia)

There was no clear evidence of a difference between intervention groups for the risk of neonatal jaundice (RR 0.99, 95% CI 0.83 to 1.19; 16 studies, 2183 infants; Analysis 1.41) . The subgroup interaction test was not significant suggesting no differential effect between the oral antidiabetic pharmacological therapies.

1.42 Hypocalcaemia

For this outcome there was no evidence of a clear difference between exposure to insulin or oral anti‐diabetic pharmacological therapy (glibenclamide) (RR 1.95, 95% CI 0.49 to 7.78; five studies, 939 infants; Analysis 1.42) . Caution is advised in interpreting the results due to wide CIs and low event rates (5/487 insulin group; 2/452 oral antidiabetic group).

1.43 Polycythaemia

For the outcome of polycythaemia, there was no evidence of a clear difference between exposure to insulin or oral anti‐diabetic pharmacological therapy (glibenclamide) (RR 1.16, 95% CI 0.38 to 3.57; three studies, 590 infants) (Analysis 1.43). Caution is advised in interpreting the results due to wide CIs and low event rates (6/308 insulin group; 5/282 oral antidiabetic group).

1.44 to 1.45 Relevant biomarker changes associated with the intervention

There was no evidence of a clear difference between exposure to insulin or oral anti‐diabetic pharmacological therapy (glibenclamide) for cord blood C‐peptide concentration (MD ‐0.20 ng/mL, 95% CI ‐0.82 to 0.42; one study, 59 infants, Analysis 1.44) or cord blood insulin concentration (SMD 0.03, 95% CI ‐0.15 to 0.21; three studies, 486 infants; Analysis 1.45). Data were reported for median values for cord‐C peptide by Hague 2003, Hickman 2013. The data were not included in the meta‐analysis (Table 9).

No data were reported in the included studies for perinatal death; z scores for birthweight, head circumference or length.

Later infant/childhood outcomes

Two studies reported on follow‐up data into childhood (Ijas 2011; Rowan 2008). Both studies compared insulin with metformin. The offspring of the Ijas 2011 study were followed up at six months, 12 months and 18 months of age. Of the original 100 women randomised 97 (97%) completed the study. At 18 months; 93 children (93% of original cohort) were seen. The offspring from the Rowan 2008 study were followed up at two years of age (median age 29 months, range 22 to 38 months). Of the original 751 women randomised, 733 (98%) completed the study. At two years 577 (78%) were eligible to be seen of which 323 (56%) were seen at follow‐up.

1.46 Childhood weight

At six months of age there was no evidence of a clear difference in weight between infants whose mothers had been treated with insulin and those who had been treated with oral anti‐diabetic agents (MD ‐0.35 kg, 95% CI ‐0.75 to 0.05; one study, 93 children). At 12 months maternal treatment with insulin was associated with reduced weight compared with infants whose mothers had been treated with oral anti‐diabetic pharmacological therapy (MD ‐0.62 kg, 95% CI ‐1.18 to ‐0.06; one study, 93 children). At 18 months to two years there continued to be reduced weight associated with maternal treatment with insulin compared with infants whose mothers had been treated with oral anti‐diabetic agents (MD ‐0.44 kg, 95% CI ‐0.83 to ‐0.05, two studies, 411 children; Analysis 1.46).

1.47 Infant/Childhood height

There was no evidence of a clear difference in height between infants whose mothers had been treated with insulin and those who had been treated with oral anti‐diabetic pharmacological therapy at six months of age (MD ‐0.70 cm, 95% CI ‐2.05 to 0.65, one study, 93 infants), 12 months (MD ‐1.30 cm, 95% CI 2.60 to 0.00; one study, 93 children) or at 18 months to two years (average MD ‐0.65 cm, 95% CI ‐2.61 to 1.31; two studies; 411 children; I² = 80%, Tau² = 1.61; Chi² = 5.10 (P = 0.02); Analysis 1.47).

1.48 to 1.49 Infant/childhood adiposity

There was no evidence of a clear difference in ponderal index between infants whose mothers had been treated with insulin and those who had been treated with oral anti‐diabetic pharmacological therapy at six months (MD ‐1.00 kg/m³, 95% CI ‐3.43 to 1.43; one study, 93 children); 12 months (MD ‐0.20 kg/m³, 95% CI ‐1.12 to 0.72; one study, 93 children) or at 18 months to two years (MD ‐0.10 kg/m³, 95% CI ‐0.88 to 0.68; one study, 93 children) (Analysis 1.48). There was no evidence of a clear difference in childhood total fat mass (%) at up to two years of age between infants whose mothers had been treated with insulin and those who had been treated with oral anti‐diabetic pharmacological therapies (MD 0.50%, 95% CI ‐0.49 to 1.49; one study, 318 children;low‐quality evidence;Analysis 1.49).

1.50 Childhood blood pressure (at two years)

The children of mothers randomised in the Rowan 2008 study were followed up at two years of age (median age 29 months, range 22 to 38 months). Of the original 751 women randomised, 733 (98%) completed the study. At two years 577 (78%) were eligible to be seen of which 323 (56%) were seen at follow‐up. Blood pressure readings were obtained from 83/154 (54%) of children whose mother had been treated in the metformin arm and 87/164 (53%) who had been treated in the insulin arm. There was no evidence of a difference for systolic blood pressure (MD ‐2.24 mmHg, 95% CI ‐5.02 to 0.54; one study, 170 children) or diastolic blood pressure (MD ‐0.50 mmHg, 95% CI ‐16.75 to 15.75; one study, 170 children; Analysis 1.50).

No data were reported for z scores for height or weight, BMI, educational attainment, dyslipidaemia/metabolic syndrome or diabetes (type 1, type 2, or impaired glucose tolerance).

Child as an adult outcomes

None of the outcomes for the infant as an adult have been reported to date (weight, height, adiposity (including BMI, skinfold thickness, fat mass), cardiovascular health (as defined by trialists including blood pressure, hypertension, cardiovascular disease, metabolic syndrome), employment, education and social status/achievement, dyslipidaemia or metabolic syndrome, type 1 diabetes, type 2 diabetes, impaired glucose tolerance).

Health service use

1.51 Number of antenatal visits or admissions

There was no evidence of differences in the number of clinic visits between women treated with insulin and those treated with oral anti‐diabetic pharmacological therapies (RR 1.00, 95% CI ‐0.08 to 2.08; one study, 404 women; Analysis 1.51).

1.52 Admission to neonatal intensive care unit/nursery

Maternal treatment with insulin was associated with an increased risk of the infant being admitted to the neonatal intensive care unit or special care baby unit compared with the infants of women treated with oral anti‐diabetic pharmacological therapy (RR 1.38, 95% CI 1.19 to 1.59; 18 studies, 3441 infants; Analysis 1.52).

1.53 Duration of stay in neonatal intensive care unit or special care baby unit

There was no evidence of a difference in the duration of stay between the groups (average MD ‐0.20 days, 95% CI ‐1.79 to 1.39; three studies, 401 infants; I² = 72%; Tau² = 1.19; Chi² = 7.18 (P = 0.03); Analysis 1.53). Hague 2003 reported data for median duration of stay in the special care nursery and duration of hospital stay for the infant. The data were not in a suitable format to be included in a meta‐analysis (Table 9).

Costs associated with the intervention

Costs of treatment were reported by one study (Ogunyemi 2007). They provide data on the cost of drugs per month which was US$20 for insulin and US$7 for glibenclamide. No other details are provided. Ashoush 2016 reported costs of 174.9 Egyptian pounds for insulin treatment and 89.66 Egyptian pounds for metformin only, or for combined metformin and insulin the cost was 159.48 Egyptian pounds. This did not include the cost of syringes for insulin treatment.

No data were reported for the following health service use outcomes: number of hospital or health professional visits (including midwife, obstetrician, physician, dietician, diabetic nurse); length of antenatal stay, length of postnatal stay (maternal), length of postnatal stay (baby), cost of maternal care, cost of offspring care, costs to families associated with the management provided, cost of dietary monitoring (e.g. diet journals, dietician, nurse visits, etc), costs to families ‐ change of diet, extra antenatal visits, extra use of healthcare services (consultations, blood glucose monitoring, length and number of antenatal visits) or women’s view of treatment advice.

Comparison 2 ‐ Insulin type A versus insulin type B

Nine studies involving 909 women compared one insulin type with another (Balaji 2005; Balaji 2012; Herrera 2015; Ismail 2007; Jovanovic 1999; Mecacci 2003; Pettitt 2007; Poyhonen‐Alho 2002; Prasad 2008).

Maternal primary outcomes

2.1 Hypertensive disorders of pregnancy (including pre‐eclampsia, pregnancy‐induced hypertension, eclampsia

There were no events of pre‐eclampsia reported in one study comparing regular human insulin with insulin aspart in 320 women (Analysis 2.1) (Balaji 2012).

2.2 Caesarean section

There was no evidence of a clear difference in the caesarean section rate between women treated with regular human insulin compared with another insulin preparation (RR 1.00, 95% CI 0.91 to 1.09, three studies, 410 women). There was no evidence of a clear difference between regular human insulin and insulin aspart (RR 1.02, 95% CI 0.94 to 1.10; one study, 320 women) or insulin lispro (RR 0.81, 95% CI 0.42 to 1.56; two studies, 90 women). See Analysis 2.2.

Development of type 2 diabetes

No studies included in this review comparing one preparation of insulin with another reported on development of type 2 diabetes for the woman.

Neonatal primary outcomes

2.3 Large‐for‐gestational age (LGA)

There was no evidence of a cleat difference in the risk of being born LGA between women treated with human insulin compared with another insulin preparation (RR 1.21, 95% CI 0.58 to 2.55; three studies, 411 infants). There was no evidence of a clear difference between regular human insulin and insulin aspart (RR 1.14, 95% CI 0.50 to 2.61; one study, 320 infants) or insulin lispro (RR 1.56, 95% CI 0.29 to 8.55; two studies, 91 infants). See Analysis 2.3.

No studies included in this review comparing one preparation of insulin with another reported on perinatal death (fetal and neonatal death) and later infant mortality, death or serious neonatal morbidity composite or neurosensory disability.

Maternal secondary outcomes

2.4 Use of additional pharmacotherapy

There was no evidence of a clear difference between regular human insulin and other types of insulin for the use of additional pharmacotherapy (average RR 1.11, 95% CI 0.72 to 1.70; three studies, 168 women; I² = 56%; Tau² = 0.08; Chi² = 4.50 (P = 0.11)). There was no evidence of a clear difference for the use of additional pharmacotherapy between regular human insulin and insulin aspart (RR 1.33, 95% CI 0.83 to 2.14; one study, 47 women) insulin lispro (RR 1.38, 95% CI 0.90 to 2.09; two studies, 98 women) or Neutral Protamine Hagedorn insulin (RR 0.65, 95% CI 0.36 to 1.19; one study, 23 women). See Analysis 2.4.

2.5 Maternal hypoglycaemia

There was no evidence of a clear difference between regular human insulin and other types of insulin for the risk of maternal hypoglycaemia (RR 0.96, 95% CI 0.64 to 1.44; four studies, 504 women). There was no evidence of a clear difference for the risk of maternal hypoglycaemia between regular human insulin and insulin aspart (RR 0.90, 95% CI 0.59 to 1.35; three studies, 394 women), or Neutral Protamine Hagedorn insulin (RR 5.16, 95% CI 0.26 to 103.25; one study, 61 women). See Analysis 2.5. There were no events of maternal hypoglycaemia reported in the study by Di Cianni 2007 that compared regular human insulin with insulin lispro and with insulin aspart.

2.6 to 2.8 Glycaemic control during/after treatment

There was no evidence of a clear difference between human insulin and other insulin‐treated women for maternal HbA1c at the end of treatment (average MD 0.04%, 95% CI ‐0.06 to 0.14; three studies, 411 women; I² = 46%; Tau² = 0.00; Chi² = 3.74 (P = 0.15); Analysis 2.6). We explored the heterogeneity by looking at the type of insulin used. The subgroup interaction test suggested there was not a differential effect between regular human insulin compared with either insulin lispro or insulin aspart. The Di Cianni 2007 study reported no differences for HbA1c between regular human insulin compared with insulin aspart or insulin lispro but did not tabulate the data.

There was no evidence of a clear difference between regular human insulin and other insulin‐treated women for fasting plasma glucose (MD 0.15 mg/dL, 95% CI ‐2.02 to 2.32; four studies, 466 women) Analysis 2.7). The subgroup interaction test was not significant, suggesting there was not a differential effect between regular human insulin compared with either insulin lispro or insulin aspart. Herrera 2015 presented data for fasting plasma glucose, but combined GDM and type 2 diabetes which cannot be separated. This is a conference abstract only and we will wait for full publication to see if data are separated and will contact the authors. The Di Cianni 2007 study reported no differences for fasting plasma glucose between regular human insulin compared with insulin aspart or insulin lispro but did not tabulate the data.

There was no evidence of a clear difference between regular human insulin and other insulin preparations for postprandial glucose concentration (average SMD 0.08, 95% CI ‐0.25 to 0.42; five studies, 562 women; I² = 61%, Tau² = 0.10; Chi² = 12.89 (P = 0.02); Analysis 2.8). Subgroup analysis suggested no differential effect between regular human insulin and insulin aspart, insulin lispro or insulin detemir. Herrera 2015 presented data for postprandial plasma glucose but combined GDM and type 2 diabetes which cannot be separated. This is a conference abstract only and we will wait for full publication to see if data are separated and will contact authors.

Median data for HbA1c values were reported by Ismail 2007 (Table 8).

2.9 Weight gain in pregnancy

There was no evidence of a clear difference between regular human insulin and other insulin‐treated (insulin aspart, Neutral Protamine Hagedorn insulin) women for weight gain in pregnancy (MD 0.46 kg, 95% CI ‐0.15 to 1.07; two studies, 407 women; Analysis 2.9). The Di Cianni 2007 study reported no differences for weight gain between regular human insulin compared with insulin aspart or insulin lispro but did not tabulate the data. Median data for gestational weight gain were reported by Mecacci 2003 (Table 8).

2.10 Maternal mortality

There were no events of maternal mortality in the one study, of 61 women, that reported this outcome (Analysis 2.10) (Ismail 2007)

Views of the intervention

Balaji 2005 reported that women were more comfortable with insulin aspart as it was administered just before a meal. No other data were reported.

No data were reported for adherence to the intervention; induction of labour; placental abruption, postpartum haemorrhage; postpartum infection; perineal trauma/tearing; breastfeeding at discharge, six weeks postpartum, six months or longer, quality of life, behavioural changes associated with the intervention or relevant biomarker changes associated with the intervention.

Long‐term outcomes for mother

No data were reported for any of the long‐term maternal outcomes (postnatal depression, BMI; postnatal weight retention or return to pre‐pregnancy weight; type 1 diabetes, type 2 diabetes, impaired glucose tolerance or cardiovascular health).

Fetal/neonatal secondary outcomes

2.11 Stillbirth

Fetal death was reported in four studies including 508 infants (Balaji 2012; Ismail 2007; Pettitt 2007; Prasad 2008). One death due to umbilical cord strangulation was reported by the Pettitt 2007 study (human insulin versus insulin aspart). The other studies reported no deaths in either intervention or control groups (RR 0.36, 95% CI 0.02 to 8.06; four studies, 508 infants; Analysis 2.11).

2.12 Macrosomia

There was no evidence of an overall difference for the risk of being born macrosomic between infants whose mothers had been treated with regular human insulin and those treated with another insulin analogue (average RR 0.99, 95% CI 0.40 to 2.46, six studies, 627 infants; Analysis 2.12). There was evidence of a subgroup difference (Chi² = 5.83, df = 2, P = 0.05, I² = 65.7%). Regular human insulin was associated with reduced risk of macrosomia compared with Neutral Protamine Hagedorn insulin (RR 0.11, 95% CI 0.01 to 0.79; two studies, 84 infants), while there was no evidence of a clear difference between regular human insulin and insulin aspart (RR 1.47, 95% CI 0.71 to 3.05; four studies, 494 infants) or insulin lispro (RR 1.03, 95% CI 0.21 to 5.05; one study, 49 infants).

2.13 Small‐for‐gestational age (SGA)

There was no evidence of a clear difference between regular human insulin and insulin lispro in a single study reporting data for 49 infants (RR 1.04, 95% CI 0.07 to 15.73; one study, 49 infants, Analysis 2.13).

2.14 Birth trauma

There was no evidence of a clear difference between human insulin and Neutral Protamine Hagedorn insulin for the risk of nerve palsy in a single small study reporting data for 23 infants (RR 0.36, 95% CI 0.02 to 8.04; one study, 23 infants, Analysis 2.14). No data were reported for bone fracture or shoulder dystocia or birth trauma (not defined).

2.15 Gestational age at birth

Two studies reported data for gestational age at birth (Balaji 2012; Jovanovic 1999). Balaji 2012 compared regular human insulin with insulin aspart and Jovanovic 1999 compared regular human insulin with insulin lispro. The data were not combined in a meta‐analysis as heterogeneity was I² = 92%, Tau² = 0.21 (data not shown). Balaji 2012 found that regular human insulin was associated with a lower gestational age at birth compared with insulin aspart (MD ‐0.67 weeks, 95% CI ‐1.01 to ‐0.33; one study, 320 infants; Analysis 2.15), there was no evidence of a clear difference reported between regular human insulin and insulin lispro in the Jovanovic 1999 study (MD 0.00 weeks, 95% CI ‐0.16 to 0.16; one study, 41 infants; Analysis 2.15). Median data for gestational age at birth were reported by Mecacci 2003 (Table 9).

2.16 Preterm birth (less than 37 weeks’ gestation)

Three studies reported data for preterm birth (less than 37 weeks' gestation). Two studies compared regular human insulin with insulin aspart (Balaji 2012; Prasad 2008) and one study compared regular human insulin with Neutral Protamine Hagedorn insulin (Poyhonen‐Alho 2002). There was no evidence of a clear difference between regular human insulin and another insulin analogue (RR 2.29, 95% CI 0.52 to 10.05; three studies, 443 infants; Analysis 2.16). Caution is advised in interpreting these data as there are wide CIs and low event rates (5/218 for human insulin; 2/225 for other insulin). No data were reported for preterm birth < 32 weeks' gestation.

2.17 Congenital anomaly (not pre‐specified)

Two studies including 69 infants reported data for congenital anomaly. There was no clear evidence of a difference between regular human insulin and other forms of insulin (RR 3.21, 95% CI 0.14 to 72.55; two studies, 69 infants). Pettitt 2007 compared regular human insulin with insulin aspart and Jovanovic 1999 compared regular human insulin with insulin lispro. Pettitt 2007 reported one event in the regular human insulin group. Jovanovic 1999 reported no events in either the regular human insulin or insulin lispro group (Analysis 2.17).

2.18 Birthweight

Overall, there was no evidence of a clear difference between regular human insulin and other insulin analogues for birthweight (average MD ‐0.04 g, 95% CI ‐0.17 to 0.08; seven studies, 531 infants; I² = 62%, Tau² = 0.01; Chi² = 15.68 (P = 0.02); Analysis 2.18). Three studies compared regular human insulin with insulin aspart (Balaji 2005; Balaji 2012; Pettitt 2007) (MD ‐0.01 g, 95% CI ‐0.11 to 0.09; three studies, 357 infants); two studies compared regular human insulin with insulin lispro (Jovanovic 1999; Mecacci 2003) (MD 0.04 g, 95% CI ‐0.07 to 0.14; two studies, 90 infants) and two studies compared regular human insulin with Neutral Protamine Hagedorn insulin (Ismail 2007; Poyhonen‐Alho 2002) (MD ‐0.44 g; 95% CI ‐1.20 to 0.32; two studies, 84 infants, I² = 86%; Tau² = 0.26; Chi² = 7.28 (P = 0.007)). Di Cianni 2007 reported an increased birthweight in regular human insulin group compared with lispro and aspart groups but provided no data.

2.19 Length (cm) at birth

There was no clear evidence of a difference for length at birth between maternal treatment with regular human insulin compared with other insulin analogues (insulin lispro and aspart) (MD ‐0.11 cm, 95%CI ‐0.57 to 0.34; three studies, 388 infants) (Analysis 2.19).

2.20 Ponderal index

One study compared regular human insulin with insulin aspart (MD ‐0.10 kg/m³, 95% CI ‐1.01 to 0.81; one study, 320 infants; Balaji 2012) and one study compared human insulin with insulin lispro (MD 0.03 kg/m³, 95% CI ‐0.06 to 0.12; one study, 49 infants; Mecacci 2003). There was no evidence of a clear difference overall between regular human insulin and another insulin preparation for ponderal index (MD 0.03 kg/m³, 95% CI ‐0.06 to 0.12; two studies, 369 infants; Analysis 2.20).

2.21 Neonatal hypoglycaemia

There was no clear evidence of an overall difference between regular human insulin and another insulin preparation for the risk of neonatal hypoglycaemia (RR 2.28, 95% CI 0.06 to 82.02; three studies, 165 infants; I² = 65%, Tau² = 4.37; Chi² = 2.89 (P = 0.09); Analysis 2.21). One study found no evidence of a clear difference in the risk for neonatal hypoglycaemia between infants whose mothers had been treated with regular human insulin plus Neutral Protamine Hagedorn insulin or insulin aspart (Prasad 2008) (RR 13.00, 95% CI 0.75 to 224.77; one study, 100 infants). One study that compared regular human insulin and insulin lispro (Jovanovic 1999) reported no events of neonatal hypoglycaemia in either the regular human insulin or the insulin lispro group. There was no evidence of a difference in the risk of neonatal hypoglycaemia between infants whose mothers had been treated with regular human insulin or Neutral Protamine Hagedorn insulin (RR 0.36, 95C% CI 0.02 to 8.04; one study, 23 infants). Data should be interpreted with caution due to low event rates, low sample size and wide CIs.

2.22 Respiratory distress syndrome

There was no evidence of a difference in the risk of respiratory distress syndrome between infants whose mothers had been treated with regular human insulin or insulin aspart (RR 0.52, 95% CI 0.10 to 2.79; one study, 320 infants, Analysis 2.22).

2.23 Neonatal jaundice (Hyperbilirubinaemia)

Overall there was no evidence of a difference in the risk of hyperbilirubinaemia between infants whose mothers had been treated with regular human insulin and those treated with another insulin analogue (average RR 0.48, 95% CI 0.05 to 4.93; two studies, 123 infants; I² = 57%; Tau² = 1.74; Chi² = 2.30, (P = 0.13); Analysis 2.23). There was no clear evidence of a difference between groups for regular human insulin plus Neutral Protamine Hagedorn insulin compared to insulin aspart reported by Prasad 2008 (RR 0.11, 95% CI 0.01 to 2.01; one study, 100 infants) or between regular human insulin compared with Neutral Protamine Hagedorn insulin reported by Poyhonen‐Alho 2002 (RR 1.09, 95% CI 0.28 to 4.32, one study, 23 infants). Data should be interpreted with caution due to low event rates, low sample size and wide CIs.

2.24 Hypocalcaemia

No events of hypocalcaemia were reported in infants whose mothers had been treated with regular human insulin or insulin lispro in a single small study of 42 infants (Jovanovic 1999) (Analysis 2.24) .

No data were reported for neonatal death; perinatal death; five‐ minute Apgar less than seven; head circumference; z scores for birthweight, head circumference, length; measures of adiposity; polycythaemia or relevant biomarker changes associated with the intervention cord blood measures.

Infant/childhood secondary outcomes

No data were reported for any of our pre‐specified infant/childhood secondary outcomes for this review (weight, height, head circumference and z scores; adiposity; educational attainment; blood pressure; type 1 or type 2 diabetes, impaired glucose tolerance; dyslipidaemia or metabolic syndrome).

Child as an adult outcomes

No data were reported for any of our pre‐specified infant as an adult secondary outcomes for this review (weight, height, adiposity, cardiovascular health, employment, education and social status/achievement; dyslipidaemia or metabolic syndrome, type 1 diabetes, type 2 diabetes, impaired glucose tolerance).

Health service use

No data were reported for any health service usage outcomes prespecified for this review (number of antenatal visits or admissions, umber of hospital or health professional visits, admission to neonatal intensive care unit/nursery, duration of stay in neonatal intensive care unit or special care baby unit, length of antenatal stay, length of postnatal stay (maternal), length of postnatal stay (baby), cost of maternal care, cost of offspring care, costs associated with the intervention, costs to families associated with the management provided, cost of dietary monitoring, costs to families, extra use of healthcare services, women’s view of treatment advice).

Comparison 3 ‐ Insulin versus diet

This comparison was reported in six studies involving 1226 women (Coustan 1978; Notelovitz 1971; O'Sullivan 1975a; O'Sullivan 1975b; Persson 1985; Thompson 1990). One study was not included in the meta‐analysis as data for women with gestational diabetes could not be separated from women with pre‐gestational diabetes (Notelovitz 1971).

Maternal primary outcomes

Hypertensive disorders of pregnancy (including pre‐eclampsia, pregnancy‐induced hypertension, eclampsia)

Pre‐eclampsia, pregnancy‐induced hypertension or eclampsia were not reported as outcomes in any of the included studies in this review.

3.1 Caesarean section

There was no evidence of a difference in the risk of birth bycaesarean section between women treated with insulin and those treated with diet (RR 0.85, 95% CI 0.50 to 1.42, two studies, 133 women) (Analysis 3.1).

3.2 Development of type 2 diabetes

There was no evidence of a difference in the risk of developing type 2 diabetes postpartum between women treated with insulin and those treated with diet or standard antenatal care (RR 0.98, 95% CI 0.79 to 1.21; two studies, 653 women; Analysis 3.2). O'Sullivan 1975a reported follow‐up to a maximum of 15 years. Coustan 1978 reported data for follow‐up at five weeks postpartum.

Neonatal primary outcomes

3.3 Perinatal (fetal and neonatal)death and later infant mortality

There was no evidence of a difference in the risk of perinatal death between infants whose mothers had been treated with insulin and those who had been treated with diet/standard antenatal care (RR 0.74, 95% CI 0.41 to 1.33; four studies, 1137 infants; Analysis 3.3). No events of perinatal death were reported in two studies including 297 infants (Persson 1985; Thompson 1990).

3.4 Large‐for‐gestational age (LGA)

There was no difference in the risk of being born LGA between infants whose mothers had been treated with insulin or diet in one study including 202 infants (Persson 1985) (RR 0.85, 95% CI 0.41 to 1.78; one study, 202 infants, Analysis 3.4).

No data were reported for death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy) or neurosensory disability.

Maternal secondary outcomes

3.5 Use of additional pharmacotherapy

Use of additional pharmacotherapy was required by 14% (15/105) of women randomised to the dietary intervention groups reported in a single study including 202 women (Persson 1985). No analysis was conducted as the women in the insulin group all received insulin (data shown, see Analysis 3.5).

3.6 Maternal hypoglycaemia

There were no events of maternal hypoglycaemia reported on one study of 95 women (Thompson 1990) ( Analysis 3.6).

3.7 Glycaemic control during/end of treatment

Insulin was associated with a slight increase in the mean HbA1c at the end of treatment (6.9 mmol/mol ± 0.2; 86 women) compared with diet only treatment (6.8 mmol/mol ± 0.2; 75 women) (MD 0.10 mmol/mol, 95% CI 0.04 to 0.16; one study, 161 women, Analysis 3.7) (Persson 1985). There was no evidence of a difference in the mean fasting blood glucose concentration (MD 1.60 mg/dL, 95% CI ‐2.97 to 6.17, one study, 68 women, Analysis 3.7) or two‐hour postprandial glucose level (MD 0.30 mg/dL, 95% CI ‐5.32 to 5.92, one study, 68 women, Analysis 3.7) during treatment reported in a single study including 68 women (Thompson 1990). Persson 1985 reported maternal blood glucose in the insulin‐treated group and diet‐treated group, however the values are presented in a figure with median and 95% CI values. The data could not be included in a meta‐analysis and authors were unable to provide original data. HbA1c values at birth were estimated from a bar graph (Persson 1985). Coustan 1978 reported data for fasting glucose concentration and two‐hour postprandial glucose concentration at the end of treatment but the data are reported by the number of observations and not the number of women randomised. The data could not be included in a meta‐analysis but indicate a reduced fasting glucose concentration in the insulin groups compared with the diet group (Table 8). O'Sullivan 1975a reported data as the number of samples rather than per woman randomised and the data have therefore not been included in the meta‐analysis. Insulin was associated with reduced fasting blood glucose concentration (blood glucose concentration 80.1 mg/dL (SD 23); 295 samples) compared with routine antenatal care (blood glucose concentration 69.1 mg/dL (SD 16.9); 71 samples). At two to three hours postprandial, the authors report that insulin reduced blood glucose concentration (mean blood glucose concentration 80.1 mg/dL (SD 23); 295 samples) compared with routine antenatal care (mean blood glucose concentration 83.0 mg/dL (SD 21.2); 233 samples).

3.8 Weight gain during pregnancy

There was no evidence of a difference between insulin and dietary intervention groups for weight gain in pregnancy (MD 1.73 kg, 95% CI ‐3.31 to 6.77, one study, 38 women, Analysis 3.8) (Coustan 1978).

No data were reported in the included studies for the other maternal secondary outcomes pre‐specified in this review (use of adherence to the intervention; induction of labour; placental abruption; postpartum haemorrhage; postpartum infection; perineal trauma/tearing; breastfeeding at discharge; six weeks postpartum, six months or longer; maternal mortality; sense of well‐being and quality of life; behavioural changes associated with the intervention; views of the intervention or relevant biomarker changes associated with the intervention).

Long‐term outcomes for mother

No data were reported for postnatal glycaemic level (HbA1c, glucose tolerance test); blood pressure; BMI; weight (kg); return to pre‐pregnancy weight; or insulin sensitivity.

Fetal/neonatal outcomes

3.9 Neonatal death

There was no evidence of a difference for the risk of neonatal death between infants whose mothers had been treated with insulin and those who had been treated with standard antenatal care (RR 0.72, 95% CI 0.23 to 2.23; one study, 611 infants; Analysis 3.9).

3.10 Macrosomia

Maternal treatment with insulin was associated with a reduced risk of macrosomia in the infant compared with diet/standard antenatal care (RR 0.30, 95% CI 0.18 to 0.50; three studies, 717 infants; three studies; I² = 0%; Analysis 3.10). Of interest, these data differ from the single study reporting LGA which found no difference between groups. Two studies were undertaken in the 1970s (Coustan 1978; O'Sullivan 1975a) and one in 1990 (Thompson 1990). The insulin regimens may differ from those administered today and appear to be fixed doses of Neutral Protamine Hagedorn insulin, with or without regular human insulin rather than a weight adjusted dose which is seen in more recent studies. This may in part explain the reduced effectiveness of insulin for this outcome.

3.11 Small‐for‐gestational age (SGA)

There was no evidence of a difference between insulin‐treated and diet‐treated groups for the risk of the infant being born SGA (RR 0.35, 95% CI 0.05 to 2.40; two studies, 240 infants; Analysis 3.11).

3.12 Birth trauma (shoulder dystocia, bone fracture, nerve palsy)

There were no events of shoulder dystocia in the infants of mothers who had been treated with either insulin or the diet alone in two studies including 133 infants (Coustan 1978; Thompson 1990). There were no events of nerve palsy in either group reported from a single study including 38 infants (Coustan 1978). No data were reported for bone fracture in any of the included trials.

3.13 Gestational age at birth

There was no evidence of a difference for gestational age at birth between infants whose mothers had been treated with insulin or with diet (MD ‐0.66 weeks, 95% CI ‐1.37 to 0.06; two studies, 106 infants; Analysis 3.13).

3.14 Preterm birth (less than 37 weeks' gestation; and less than 32 weeks' gestation)

There was no evidence of a difference for the risk of preterm birth (less than 37 weeks' gestation) between infants whose mothers had been treated with insulin and those who had been treated with standard antenatal care (RR 1.09, 95% CI 0.64 to 1.85; one study, 611 infants, Analysis 3.14). No data were reported for preterm birth less than 32 weeks' gestation.

3.15 Birthweight

Maternal treatment with insulin was associated with a reduced birthweight compared with maternal treatment with diet alone (MD ‐342.85 g, 95% CI ‐561.11 to ‐124.60; two studies, 106 infants; Analysis 3.15).

3.16 Ponderal Index

Maternal treatment with insulin was associated with a reduced ponderal index compared with maternal treatment with diet alone (MD ‐0.18 kg/m³, 95% CI ‐0.34 to ‐0.02; one study, 68 infants; Analysis 3.16).

3.17 Neonatal hypoglycaemia

There was no evidence of a difference between infants whose mothers had been treated with insulin and diet‐treated groups for the risk of neonatal hypoglycaemia (RR 0.88, 95% CI 0.34 to 2.24; three studies, 176 infants; I² = 40%, Tau² = 0.24, Analysis 3.17).

3.18 Hyperbilirubinaemia

There were no events of hyperbilirubinaemia in a single study including 68 infants (Thompson 1990) (Analysis 3.18).

3.19 Hypocalcaemia

There were no events of hypocalcaemia in a single study including 68 infants (Thompson 1990) (Analysis 3.19).

3.20 Polycythaemia

There was no evidence of a difference between infants whose mothers had been treated with insulin and diet‐treated groups for the risk of polycythaemia (RR 0.90, 95% CI 0.30 to 2.67; one study, 70 infants; Analysis 3.20).

3.21 Relevant biomarker changes associated with the intervention (including insulin, cord c‐peptide)

Dietary interventions were associated with a reduction in cord blood C‐peptide concentration compared with insulin‐treated groups (MD 0.03 ng/mL, 95% CI 0.02 to 0.04; one study, 202 infants; Analysis 3.21).

No data were reported for other neonatal outcomes pre‐specified in this review (stillbirth; five‐minute Apgar less than seven; head circumference; length; z score for birthweight, head circumference and z score, length and z score; skinfold thickness measurements (mm); fat mass or respiratory distress syndrome).

Infant/childhood outcomes

No data were reported for any of the pre‐specified infant/childhood secondary outcomes for this review (weight and z score; height and z score; head circumference and z score; adiposity; educational attainment; blood pressure; type 1 diabetes; type 2 diabetes; impaired glucose tolerance; dyslipidaemia or metabolic syndrome).

Child as an adult outcomes

No data were reported for any of the pre‐specified infant as an adult secondary outcomes for this review (weight, height; adiposity; cardiovascular health; employment, education and social status/achievement; dyslipidaemia or metabolic syndrome; type 1 diabetes; type 2 diabetes; impaired glucose tolerance).

Health service use

No data were reported for any of the pre‐specified health service usage outcomes for this review (number of antenatal visits or admissions; number of hospital or health professional visits; admission to neonatal intensive care unit/nursery; duration of stay in neonatal intensive care unit or special care baby unit; length of antenatal stay; length of postnatal stay (maternal); length of postnatal stay (baby); cost of maternal care; cost of offspring care; costs associated with the intervention; costs to families associated with the management provided; cost of dietary monitoring; costs to families; extra use of healthcare services or women’s view of treatment advice).

Comparison 4 ‐ Insulin versus exercise

This comparison was reported in a single study including 41 women but data only reported for 34 women (Bung 1993).

Maternal primary outcomes

Caesarean section

There was no evidence of a difference between treatment with insulin and treatment with exercise for the risk of birth by caesarean section (RR 1.50, 95% CI 0.29 to 7.87; one study, 34 women) (Analysis 4.1).

No data were reported for the outcomes of pre‐eclampsia or development of type 2 diabetes.

Neonatal primary outcomes

No data were reported for any of the pre‐specified neonatal primary outcomes for this review (perinatal death; LGA; a composite of serious infant death or morbidity or neurosensory disability).

Maternal secondary outcomes

No data were reported for any of the pre‐specified maternal secondary outcomes for this review (use of additional pharmacotherapy, maternal hypoglycaemia, glycaemic control during/end of treatment, weight gain in pregnancy, adherence to the intervention, induction of labour, placental abruption, postpartum haemorrhage, postpartum infection, perineal trauma/tearing, breastfeeding at discharge, six weeks postpartum, six months or longer, maternal mortality, sense of well‐being and quality of life, behavioural changes associated with the intervention, views of the intervention, relevant biomarker changes associated with the intervention).

Long‐term outcomes for mother

No data were reported for any of the long‐term outcomes for the mother pre‐specified for this review (postnatal depression; BMI; postnatal weight retention or return to pre‐pregnancy weight; type 1 diabetes; type 2 diabetes; impaired glucose tolerance or cardiovascular health).

Fetal/neonatal secondary outcomes

Macrosomia

There was no evidence of a difference for the risk of macrosomia between infants whose mothers had been treated with insulin and those treated with exercise (RR 2.00, 95% CI 0.42 to 9.50; one study, 34 infants) (Analysis 4.2).

Gestational age at birth

There was no evidence of a difference for the timing of gestational age at birth between infants whose mothers had been treated with insulin and those treated with exercise (MD ‐0.80 weeks, 95% CI ‐2.05 to 0.45, one study, 34 infants) (Analysis 4.3).

Birthweight (g)

There was no evidence of a difference in birthweight between infants whose mothers had been treated with insulin and those treated with exercise (MD 103.00 g, 95% CI ‐245.40 to 451.40; one study, 34 infants) (Analysis 4.4).

Length at birth (cm)

There was no evidence of a difference in length at birth (cm) between infants whose mothers had been treated with insulin or those treated with diet (MD 1.60 cm, 95% CI ‐0.01 to 3.21; one study, 34 infants) (Analysis 4.5).

Neonatal hypoglycaemia

There was no evidence of a difference for the risk of neonatal hypoglycaemia between infants whose mothers had been treated with insulin and those treated with exercise (RR 0.50, 95% CI 0.05 to 5.01; one study, 34 infants) (Analysis 4.6).

Respiratory distress syndrome

There were no events of respiratory distress reported in one study of 34 infants (Bung 1993).

Hyperbilirubinaemia

There were no events of hyperbilirubinaemia reported in one study of 34 infants (Bung 1993).

Hypocalcaemia

There were no events of hypocalcaemia reported in one study of 34 infants (Bung 1993).

There were no data reported for stillbirth; neonatal death; SGA, birth trauma, preterm birth, five‐minute Apgar less than seven minutes, birthweight z score, head circumference and z score, length z score, ponderal index, adiposity, polycythaemia, relevant biomarker changes associated with the intervention.

Infant/childhood outcomes

Child as an adult outcomes

Health service use

Comparison 5 ‐ Insulin regimen A versus Insulin regimen B (timing, number of injections)

One study compared twice‐daily insulin with four times daily doses (Nachum 1999). One study compared three injections with six injections (Castorino 2011). In total the two studies involved 314 women.

Maternal primary outcomes

Pregnancy‐induced hypertension

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of pregnancy‐induced hypertension (RR 1.11, 95% CI 0.51 to 2.42; one study, 274 women) (Analysis 5.1).

Caesarean section

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of birth by caesarean section (RR 0.99, 95% CI 0.68 to 1.44; one study, 274 women). There was no evidence of a difference between a maternal regimen using three injections daily or six injections daily for the risk of birth by caesarean section (RR 1.06, 95% CI 0.17 to 6.72; one study, 37 women) (Analysis 5.2).

No data were reported for the development of type 2 diabetes in either of the included studies.

Neonatal primary outcomes

Perinatal (fetal and neonatal death) and later infant mortality

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of perinatal death (RR 3.04, 95% CI 0.13 to 74.07; one study, 274 women) (Analysis 5.3).

Large‐for‐gestational age (LGA)

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of being born LGA (RR 1.16, 95% CI 0.79 to 1.69; one study, 274 women). There was no evidence of a difference between a maternal regimen using three injections daily or six injections daily for the risk of being born LGA (RR 0.35, 95% CI 0.04 to 3.08; one study, 37 infants) (Analysis 5.4).

Composite of serious neonatal morbidity and mortality

A maternal regimen of insulin twice daily was associated with an increased risk of death or serious morbidity composite compared with a four times daily insulin regimen (RR 1.69, 95% CI 1.08 to 2.64; one study, 274 women) (Analysis 5.5).

No data were reported for neurosensory disability.

Maternal secondary outcomes

Maternal hypoglycaemia

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of maternal hypoglycaemia (RR 1.01, 95% CI 0.06 to 16.06; one study, 274 women) (Analysis 5.6).

Glycaemic control (end of treatment)

There was no evidence of a difference for mean fasting blood glucose concentration between women using a regimen of three injections per day compared with six injections per day (MD 4.00 mg/dL, 95% CI ‐0.84 to 8.84; one study, 37 women) (Analysis 5.7). A maternal regimen of insulin four times daily was associated with a decrease in HbA1c at the end of treatment compared with a twice‐daily regimen (MD 0.30%, 95% CI 0.06 to 0.54; one study, 274 women). There was no evidence of a difference for mean HbA1c between women using a regimen of three injections per day compared with six injections per day (MD ‐0.10%, 95% CI ‐0.29 to 0.09; one study, 37 women) (Analysis 5.8).

Weight gain in pregnancy

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for weight gain in pregnancy (MD 0.70 kg, 95% CI ‐0.14 to 1.54; one study, 274 women) (Analysis 5.9). Castorino 2011 reported no evidence of a difference in gestational weight gain per week 0.2 +/‐ 0.3 in the three injection regimen and 0.3 +/‐ 0.2 in the six injection regimen.

No data were reported for other pre‐specified maternal secondary outcomes for this review (use of additional pharmacotherapy, adherence to the intervention, induction of labour, placental abruption, postpartum haemorrhage, postpartum infection, perineal trauma/tearing, breastfeeding at discharge, six weeks postpartum, six months or longer, maternal mortality, sense of well‐being and quality of life, behavioural changes associated with the intervention, views of the intervention, relevant biomarker changes associated with the intervention).

Long‐term outcomes for mother

Fetal/neonatal outcomes

Macrosomia

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of macrosomia (RR 1.20, 95% CI 0.72 to 2.01; one study, 274 women) (Analysis 5.10).

Small‐for‐gestational age (SGA)

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of being born SGA (RR 1.78, 95% CI 0.53 to 5.93; one study, 274 women) (Analysis 5.11).

Birth trauma (not specified)

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of birth trauma (RR 1.52, 95% CI 0.26 to 8.97; one study, 274 women) (Analysis 5.12).

Gestational age at birth

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the timing of gestational age at birth (MD ‐0.30 weeks, 95% CI ‐0.72 to 0.12; one study, 274 women) (Analysis 5.13).

Five‐minute Apgar less than seven

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for a five‐minute Apgar score less than seven (RR 0.34, 95% CI 0.07 to 1.65; one study, 274 women) (Analysis 5.14).

Birthweight

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the outcome of birthweight (MD ‐1.00 g, 95% CI ‐150.49 to 148.49; one study, 274 women). There was no evidence of a difference between a maternal regimen of three injections of insulin daily compared with six injections for the outcome of birthweight (MD ‐197.00 g, 95% CI ‐495.43 to 101.43; one study, 37 infants) (Analysis 5.15).

Neonatal hypoglycaemia

A maternal regimen of insulin twice daily was associated with an increased risk of neonatal hypoglycaemia compared with a regimen of insulin four times daily (RR 8.12, 95% CI 1.03 to 64.03; one study, 274 infants) (Analysis 5.16). Data should be interpreted with caution due to large treatment effect and wide CIs suggesting imprecision.

Respiratory distress syndrome

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of respiratory distress syndrome (RR 0.34, 95% CI 0.01 to 8.23; one study, 274 infants) (Analysis 5.17).

Hyperbilirubinaemia

A maternal regimen of insulin twice‐daily insulin was associated with an increased risk of hyperbilirubinaemia compared with a four times a day regimen (RR 1.96, 95% CI 1.10 to 3.49; one study, 274 infants) (Analysis 5.18).

Polycythaemia

There was no evidence of a difference between a maternal insulin regimen twice daily or four times daily for the risk of polycythaemia (RR 0.43, 95% CI 0.11 to 1.65; one study, 274 infants) (Analysis 5.19).

There were no data reported for other secondary neonatal outcomes pre‐specified for this review (stillbirth; neonatal death; preterm birth, birthweight z score, head circumference and z score, length z score, ponderal index, adiposity, relevant biomarker changes associated with the intervention).

Infant/childhood outcomes

Child as an adult outcomes

Health service use

Discussion

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Summary of main results

Insulin versus oral anti‐diabetic pharmacological therapy

Twenty‐eight studies reported the comparison of insulin with oral anti‐diabetic pharmacological therapy. Insulin was associated with an increased risk of hypertensive disorders of pregnancy (not defined) compared with oral anti‐diabetic pharmacological therapy and may possibly increase the risk for induction of labour although the evidence was not clear for this outcome. There was no evidence of a clear difference between groups for the risk of pre‐eclampsia, caesarean section, or development of type 2 diabetes for the mother (summary of findings Table for the main comparison). No data were reported for eclampsia. For the infant there was no evidence of a difference between groups for the risk of perinatal death, being born large‐for‐gestational age (LGA), a composite of serious neonatal outcomes or neurosensory disability in childhood (summary of findings Table 2). For secondary maternal outcomes, there was no evidence of a difference between women who had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapies for the outcomes of maternal hypoglycaemia, glycaemic control, postpartum haemorrhage or breastfeeding. Insulin was associated with an increase in gestational weight gain compared with oral anti‐diabetic pharmacological therapies. No other pre‐specified maternal outcomes were reported. Long‐term outcomes for the mother were poorly reported. There was no evidence of a difference between groups identified for body mass index (BMI) at six weeks postpartum or impaired glucose tolerance up to one year follow‐up. There was no evidence of a difference for any of the reported neonatal outcomes in this review between infants whose mothers had been treated with insulin and those treated with oral anti‐diabetic pharmacological therapies. Long‐term outcomes were poorly reported with only two of 15 studies reporting data. There was no evidence of a difference between groups for height, adiposity or blood pressure up to 18 months follow‐up. Maternal treatment with insulin was associated with a reduced childhood weight at 12 and 18 months of age compared with children whose mothers had been treated with oral anti‐diabetic pharmacological therapies. Insulin treatment was associated with an increased risk for the infant being admitted to the neonatal intensive care unit although there was no evidence of a difference for the duration of stay in the neonatal intensive care unit.

One insulin versus another insulin

Data were included in meta‐analyses from ten studies comparing regular human insulin with another insulin analogue. There was no evidence of an overall difference between the groups for any of the primary or secondary maternal or infant outcomes where data were reported. No data were reported for long‐term infant outcomes into childhood or adulthood.

Insulin versus diet/standard care

Five of six included studies contributed data to meta‐analyses to the comparison of insulin versus diet. Data for the pre‐specified outcomes for this review were poorly reported. There was no evidence of a difference between women treated with insulin and those treated with diet for the risk of birth by caesarean section or development of type 2 diabetes. Hypertensive disorders of pregnancy (including pre‐eclampsia, pregnancy‐induced hypertension, eclampsia) was not reported as an outcome in any of the included studies of this comparison. There were no differences between groups for perinatal death or being born LGA. A composite of mortality and serious infant morbidity and the outcome of neurosensory disability were not reported in any of the included studies. There was a small, but clinically insignificant increase, in HbA1C at the end of treatment in women who had been treated with insulin compared to diet. Women treated with insulin were less likely to have a macrosomic infant compared to women treated with diet. Only one study reported on the number of women in the diet group who required supplementary insulin (14%). There were no long‐term infant as a child or adult data reported in any of the included studies for this comparison.

Insulin versus exercise

Only one small study of 34 women reported a comparison of insulin with exercise. Data for the pre‐specified outcomes for this review were poorly reported. There was no evidence of a difference between groups for the risk of birth by caesarean section and no data were reported for any of the other maternal or infant primary outcomes for this review. There was no evidence of a difference between groups for the limited number of neonatal outcomes reported in the study. No long‐term data were reported for the mother or for the infant as a child or adult.

Regimen A versus Regimen B

Two studies examined different regimens of providing insulin. One study compared insulin four times a day with twice daily and the second study compared three injections daily with six injections. Data for the pre‐specified outcomes for this review were poorly reported. Women treated with insulin four times daily were more likely to have a lower HbA1c at the end of treatment than women receiving insulin twice daily. No long‐term data were reported for the mother or for the infant as a child or adult.

Overall completeness and applicability of evidence

The studies included in this review were conducted in women diagnosed with gestational diabetes. There were a variety of methods used to diagnose gestational diabetes mellitus although this is unlikely to influence the treatment effectiveness. The majority of the studies were conducted in high‐resource contexts from developed countries.

Not all of the outcomes of interest for this review were addressed in the included studies in particular for the long‐term maternal and infant as a child and adult health outcomes. Only two of 49 studies reported on follow‐up into childhood.

Quality of the evidence

The method of random sequence generation was adequately reported in 23/53 studies (low risk of bias), we judged 29/53 studies to be of unclear risk of bias due to lack of methodological details. The method of allocation concealment was adequately reported in 19/53 studies (low risk of bias). Thirty‐three of 53 studies provided insufficient methodological details to judge method of allocation concealment and were judged to be of unclear risk of bias. One study was judged to be of high risk of selection bias as the first 20 women were randomised using a quasi‐randomised method (Figure 4; Figure 5).

Performance bias was judged to be of high risk in 40/53 studies which were open‐label. Only two studies were judged to be of low risk of performance bias. Detection bias was judged to be of unclear risk of bias in 44/53 studies due to insufficient details being reported. Only five of 53 studies were judged to be of low risk of detection bias (Figure 4; Figure 5).

Attrition bias was judged to be low risk of bias in 31/53 studies, of unclear risk of bias in 14/53 studies and of high risk of bias in 8/53 studies (Figure 4; Figure 5). Reporting bias was judged to be of high risk of bias in 34/53 studies mainly due to lack of reporting of pre‐specified outcomes or reporting of outcomes that had not been pre‐specified. Fourteen of 53 studies were judged to be of unclear risk of reporting bias and only five studies were judged to be of low risk of reporting bias. Other sources of bias were judged to be of high risk of bias in 20/53 studies and of low risk of bias in 26/53 studies. Seven studies were judged to be of unclear risk of other bias due to insufficient information (Figure 4; Figure 5).

We examined the quality of the overall body of the evidence for the comparison of insulin with oral anti‐diabetic pharmacological therapy using GRADE methodology (GRADEpro). The quality of the evidence ranged from low quality to moderate quality. The evidence was downgraded for imprecision (low event rates, wide confidence intervals, evidence based on a single study), risk of bias (lack of blinding, lack of details for method of randomisation/allocation concealment) and inconsistency (I² > 50%) (summary of findings Table for the main comparison; summary of findings Table 2).

Potential biases in the review process

We made every attempt to minimise bias. We searched multiple databases without language or date restrictions to limit bias by identifying all relevant studies. We included published and unpublished studies. Where necessary, we made contact with authors to seek clarification or further information. Two review authors independently appraised studies for inclusion, and extracted data in order to minimise bias.

Agreements and disagreements with other studies or reviews

A systematic review and network meta‐analysis (Jiang 2015) published in 2015 included eight studies comparing insulin with metformin and seven studies that compared insulin with glibenclamide or acabose. We excluded two of the studies (Hassan 2012; Tempe 2013) that had been included in the Jiang review as they were quasi‐randomised and did not meet the inclusion criteria for this review. We identified an additional four studies, three that compared insulin with metformin (Ashoush 2016; Saleh 2016; Zawiejska 2016), and one that compared insulin with glibenclamide (Behrashi 2016).

Our conclusions concur for insulin being associated with an increased maternal weight gain during pregnancy compared with metformin. We found no clear evidence of a difference for birthweight associated with insulin compared with glibenclamide that had been identified in the Jiang 2015 review. Our conclusions differ for macrosomia, preterm birth and neonatal hypoglycaemia and this is likely to be reflective of the additional data we have included in our review with 18 studies comparing insulin and metformin and 10 studies comparing insulin and glibenclamide in addition to our exclusion of quasi‐randomised studies.

Balsells 2015 summarised evidence on short‐term outcomes for randomised trials comparing glibenclamide or metformin versus insulin in women with gestational diabetes. They included seven studies that compared glibenclamide with insulin and six studies that compared metformin with insulin. The Balsells 2015 review also included the quasi‐randomised Tempe 2013 study that was excluded from our review. Results concur with those of our review for the outcomes of birthweight and macrosomia being reduced with insulin compared with glibenclamide; increased gestational weight gain and increased gestational age at birth with insulin compared with metformin. Balsells 2015 reported evidence of a difference between insulin and metformin for neonatal hypoglycaemia in six studies including 1360 infants, whereas our review found no evidence of a difference between groups in 10 studies including 2192 infants.

A review article by Lambert 2013 summarised evidence for the use of insulin analogues in pregnancy that included treating women with gestational diabetes. Six randomised studies were identified and all were also included in our review. There was no meta‐analysis conducted.

Figure 1

Study flow diagram.

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Figure 2

Funnel plot of comparison: 1 Insulin versus anti‐diabetic agent, outcome: 1.3 Caesarean section.

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Figure 3

Funnel plot of comparison: 1 Insulin versus anti‐diabetic agent, outcome: 1.6 Large‐for‐gestational age (Birthweight > 90th centile).

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Figure 4

'Risk of bias' graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.

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Figure 5

'Risk of bias' summary: review authors' judgements about each risk of bias item for each included study.

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Analysis 1.1

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 1 Hypertensive disorders of pregnancy ‐ Pre‐eclampsia.

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Analysis 1.2

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 2 Hypertensive disorders of pregnancy ‐ not defined.

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Analysis 1.3

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 3 Caesarean section.

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Analysis 1.4

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 4 Development of type 2 diabetes.

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Analysis 1.5

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 5 Perinatal (fetal and neonatal death) and later infant mortality.

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Analysis 1.6

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 6 Large‐for‐gestational age.

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$Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 7 Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy).$

Analysis 1.7

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 7 Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy).

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Analysis 1.8

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 8 Neurosensory disability in later childhood (18 to 24 months).

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Analysis 1.9

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 9 Use of additional pharmacotherapy.

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Analysis 1.10

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 10 Maternal hypoglycaemia.

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Analysis 1.11

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 11 Glycaemic control during/end treatment (fasting).

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Analysis 1.12

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 12 Glycaemic control during/end treatment (postprandial).

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Analysis 1.13

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 13 Glycaemic control during/end of treatment (HbA1c).

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Analysis 1.14

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 14 Weight gain in pregnancy.

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Analysis 1.15

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 15 Induction of labour.

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Analysis 1.16

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 16 Postpartum haemorrhage.

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Analysis 1.17

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 17 Breastfeeding at discharge, six weeks postpartum, six months or longer.

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Analysis 1.18

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 18 Relevant biomarker changes associated with the intervention.

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Analysis 1.19

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 19 Body mass index (BMI).

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Analysis 1.20

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 20 Postnatal weight retention.

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Analysis 1.21

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 21 Impaired glucose tolerance.

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Analysis 1.22

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 22 Stillbirth.

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Analysis 1.23

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 23 Neonatal death.

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Analysis 1.24

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 24 Macrosomia (> 4000 g).

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Analysis 1.25

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 25 Small‐for‐gestational age.

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Analysis 1.26

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 26 Birth trauma.

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Analysis 1.27

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 27 Gestational age at birth.

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Analysis 1.28

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 28 Preterm birth (< 37 weeks).

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Analysis 1.29

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 29 Congenital abnormality.

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Analysis 1.30

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 30 Five minute Apgar less than seven.

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Analysis 1.31

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 31 Birthweight (g).

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Analysis 1.32

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 32 Head circumference (cm) at birth.

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Analysis 1.33

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 33 Length (cm) at birth.

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Analysis 1.34

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 34 Ponderal index at birth.

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Analysis 1.35

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 35 Adiposity at birth (Triceps skinfold (mm)).

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Analysis 1.36

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 36 Adiposity at birth (Subscapular skinfold (mm)).

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Analysis 1.37

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 37 Adiposity at birth (Skin fold sum (mm)).

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Analysis 1.38

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 38 Adiposity at birth (Percentage fat mass).

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Analysis 1.39

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 39 Neonatal hypoglycaemia.

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Analysis 1.40

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 40 Respiratory distress syndrome.

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Analysis 1.41

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 41 Neonatal jaundice (hyperbilirubinaemia).

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Analysis 1.42

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 42 Hypocalcaemia.

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Analysis 1.43

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 43 Polycythaemia.

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Analysis 1.44

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 44 Relevant biomarker changes associated with the intervention (Cord blood C‐peptide).

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Analysis 1.45

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 45 Relevant biomarker changes associated with the intervention (Cord blood insulin).

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Analysis 1.46

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 46 Childhood weight (kg).

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Analysis 1.47

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 47 Childhood height (cm).

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Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 48 Childhood adiposity (ponderal index (kg/m3)).

Analysis 1.48

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 48 Childhood adiposity (ponderal index (kg/m³)).

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Analysis 1.49

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 49 Childhood adiposity (Total fat mass (%)).

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Analysis 1.50

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 50 Childhood blood pressure (2 years).

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Analysis 1.51

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 51 Number of antenatal visits or admissions.

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Analysis 1.52

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 52 Admission to neonatal care unit/nursery.

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Analysis 1.53

Comparison 1 Insulin versus oral anti‐diabetic pharmacological therapy, Outcome 53 Duration of stay in neonatal intensive care unit or special care baby unit.

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Analysis 2.1

Comparison 2 One insulin versus another insulin, Outcome 1 Hypertensive disorders of pregnancy ‐ Pre‐eclampsia.

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Analysis 2.2

Comparison 2 One insulin versus another insulin, Outcome 2 Caesarean section.

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Analysis 2.3

Comparison 2 One insulin versus another insulin, Outcome 3 Large‐for‐gestational age.

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Analysis 2.4

Comparison 2 One insulin versus another insulin, Outcome 4 Use of additional pharmacotherapy.

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Analysis 2.5

Comparison 2 One insulin versus another insulin, Outcome 5 Maternal hypoglycaemia.

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Analysis 2.6

Comparison 2 One insulin versus another insulin, Outcome 6 Glycaemic control during/end of treatment (HbA1c) end of treatment.

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Analysis 2.7

Comparison 2 One insulin versus another insulin, Outcome 7 Glycaemic control during/end of treatment (Fasting plasma glucose).

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Analysis 2.8

Comparison 2 One insulin versus another insulin, Outcome 8 Glycaemic control during/end of treatment (Postprandial glucose).

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Analysis 2.9

Comparison 2 One insulin versus another insulin, Outcome 9 Weight gain in pregnancy.

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Analysis 2.10

Comparison 2 One insulin versus another insulin, Outcome 10 Maternal mortality.

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Analysis 2.11

Comparison 2 One insulin versus another insulin, Outcome 11 Fetal death.

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Analysis 2.12

Comparison 2 One insulin versus another insulin, Outcome 12 Macrosomia.

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Analysis 2.13

Comparison 2 One insulin versus another insulin, Outcome 13 Small‐for‐gestational age.

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Analysis 2.14

Comparison 2 One insulin versus another insulin, Outcome 14 Birth trauma (Nerve palsy).

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Analysis 2.15

Comparison 2 One insulin versus another insulin, Outcome 15 Gestational age at birth.

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Analysis 2.16

Comparison 2 One insulin versus another insulin, Outcome 16 Preterm birth (< 37 weeks).

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Analysis 2.17

Comparison 2 One insulin versus another insulin, Outcome 17 Congenital anomaly.

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Analysis 2.18

Comparison 2 One insulin versus another insulin, Outcome 18 Birthweight (kg).

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Analysis 2.19

Comparison 2 One insulin versus another insulin, Outcome 19 Length at birth (cm).

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Analysis 2.20

Comparison 2 One insulin versus another insulin, Outcome 20 Ponderal Index kg/m3.

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Analysis 2.21

Comparison 2 One insulin versus another insulin, Outcome 21 Neonatal hypoglycaemia.

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Analysis 2.22

Comparison 2 One insulin versus another insulin, Outcome 22 Respiratory distress.

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Analysis 2.23

Comparison 2 One insulin versus another insulin, Outcome 23 Neonatal jaundice (hyperbilirubinaemia).

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Analysis 2.24

Comparison 2 One insulin versus another insulin, Outcome 24 Hypocalcaemia.

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Analysis 3.1

Comparison 3 Insulin versus diet/standard care, Outcome 1 Caesarean section.

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Analysis 3.2

Comparison 3 Insulin versus diet/standard care, Outcome 2 Development of type 2 diabetes.

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Analysis 3.3

Comparison 3 Insulin versus diet/standard care, Outcome 3 Perinatal (fetal and neonatal death) and later infant mortality.

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Analysis 3.4

Comparison 3 Insulin versus diet/standard care, Outcome 4 Large‐for‐gestational age.

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Analysis 3.5

Comparison 3 Insulin versus diet/standard care, Outcome 5 Use of additional pharmacotherapy.

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Analysis 3.6

Comparison 3 Insulin versus diet/standard care, Outcome 6 Maternal hypoglycaemia.

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Analysis 3.7

Comparison 3 Insulin versus diet/standard care, Outcome 7 Glycaemic control during/end of treatment.

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Analysis 3.8

Comparison 3 Insulin versus diet/standard care, Outcome 8 Weight gain in pregnancy.

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Analysis 3.9

Comparison 3 Insulin versus diet/standard care, Outcome 9 Neonatal death.

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Analysis 3.10

Comparison 3 Insulin versus diet/standard care, Outcome 10 Macrosomia.

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Analysis 3.11

Comparison 3 Insulin versus diet/standard care, Outcome 11 Small‐for‐gestational age.

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Analysis 3.12

Comparison 3 Insulin versus diet/standard care, Outcome 12 Birth trauma.

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Analysis 3.13

Comparison 3 Insulin versus diet/standard care, Outcome 13 Gestational age at birth.

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Analysis 3.14

Comparison 3 Insulin versus diet/standard care, Outcome 14 Preterm birth (less than 37 weeks' gestation).

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Analysis 3.15

Comparison 3 Insulin versus diet/standard care, Outcome 15 Birthweight.

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Analysis 3.16

Comparison 3 Insulin versus diet/standard care, Outcome 16 Ponderal Index.

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Analysis 3.17

Comparison 3 Insulin versus diet/standard care, Outcome 17 Neonatal hypoglycaemia.

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Analysis 3.18

Comparison 3 Insulin versus diet/standard care, Outcome 18 Neonatal jaundice (Hyperbilirubinaemia).

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Analysis 3.19

Comparison 3 Insulin versus diet/standard care, Outcome 19 Hypocalcaemia.

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Analysis 3.20

Comparison 3 Insulin versus diet/standard care, Outcome 20 Polycythaemia.

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Analysis 3.21

Comparison 3 Insulin versus diet/standard care, Outcome 21 Relevant biomarker changes associated with the intervention (Cord C‐peptide).

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Analysis 4.1

Comparison 4 Insulin versus exercise, Outcome 1 Caesarean section.

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Analysis 4.2

Comparison 4 Insulin versus exercise, Outcome 2 Macrosomia.

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Analysis 4.3

Comparison 4 Insulin versus exercise, Outcome 3 Gestational age at birth.

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Analysis 4.4

Comparison 4 Insulin versus exercise, Outcome 4 Birthweight (g).

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Analysis 4.5

Comparison 4 Insulin versus exercise, Outcome 5 Length at birth (cm).

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Analysis 4.6

Comparison 4 Insulin versus exercise, Outcome 6 Neonatal hypoglycaemia.

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Analysis 4.7

Comparison 4 Insulin versus exercise, Outcome 7 Respiratory distress syndrome.

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Analysis 4.8

Comparison 4 Insulin versus exercise, Outcome 8 Neonatal jaundice (Hyperbilirubinaemia).

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Analysis 4.9

Comparison 4 Insulin versus exercise, Outcome 9 Hypocalcaemia.

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Analysis 5.1

Comparison 5 Regimen A versus regimen B, Outcome 1 Hypertensive disorders of pregnancy ‐ Pregnancy‐induced hypertension.

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Analysis 5.2

Comparison 5 Regimen A versus regimen B, Outcome 2 Caesarean section.

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Analysis 5.3

Comparison 5 Regimen A versus regimen B, Outcome 3 Perinatal (fetal and neonatal death) and later infant mortality.

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Analysis 5.4

Comparison 5 Regimen A versus regimen B, Outcome 4 Large‐for‐gestational age.

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$Comparison 5 Regimen A versus regimen B, Outcome 5 Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy).$

Analysis 5.5

Comparison 5 Regimen A versus regimen B, Outcome 5 Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy).

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Analysis 5.6

Comparison 5 Regimen A versus regimen B, Outcome 6 Maternal hypoglycaemia.

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Analysis 5.7

Comparison 5 Regimen A versus regimen B, Outcome 7 Glycaemic control during/end of treatment (Fasting).

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Analysis 5.8

Comparison 5 Regimen A versus regimen B, Outcome 8 Glycaemic control during/end of treatment (HbA1c).

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Analysis 5.9

Comparison 5 Regimen A versus regimen B, Outcome 9 Weight gain in pregnancy.

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Analysis 5.10

Comparison 5 Regimen A versus regimen B, Outcome 10 Macrosomia.

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Analysis 5.11

Comparison 5 Regimen A versus regimen B, Outcome 11 Small‐for‐gestational age.

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Analysis 5.12

Comparison 5 Regimen A versus regimen B, Outcome 12 Birth trauma.

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Analysis 5.13

Comparison 5 Regimen A versus regimen B, Outcome 13 Gestational age at birth.

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Analysis 5.14

Comparison 5 Regimen A versus regimen B, Outcome 14 Five‐minute Apgar less than 7.

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Analysis 5.15

Comparison 5 Regimen A versus regimen B, Outcome 15 Birthweight (g).

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Analysis 5.16

Comparison 5 Regimen A versus regimen B, Outcome 16 Neonatal hypoglycaemia.

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Analysis 5.17

Comparison 5 Regimen A versus regimen B, Outcome 17 Respiratory distress syndrome.

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Analysis 5.18

Comparison 5 Regimen A versus regimen B, Outcome 18 Neonatal jaundice (Hyperbilirubinaemia).

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Analysis 5.19

Comparison 5 Regimen A versus regimen B, Outcome 19 Polycythaemia.

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Summary of findings for the main comparison. Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (maternal outcomes)

Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (maternal outcomes)
Patient or population: the treatment of women (maternal outcomes) with gestational diabetes Setting: primary and secondary care (Canada, Egypt, USA, Brazil, Finland, Iran, Australia, New Zealand, India) Intervention: Insulin Comparison: Oral anti‐diabetic pharmacological therapy
Outcomes	*Anticipated absolute effects^ (95% CI)**		Relative effect (95% CI)	№ of participants (studies)	Quality of the evidence (GRADE)	Comments
Outcomes	Risk with oral anti‐diabetic agent	Risk with insulin	Relative effect (95% CI)	№ of participants (studies)	Quality of the evidence (GRADE)	Comments
Hypertensive disorders of pregnancy (pre‐eclampsia)	77 per 1000	88 per 1000 (66 to 117)	RR 1.14 (0.86 to 1.52)	2060 (10 RCTs)	⊕⊕⊕⊝ MODERATE ¹	No data were reported for eclampsia
Hypertensive disorders of pregnancy (not defined)	36 per 1000	69 per 1000 (42 to 114)	RR 1.89 (1.14 to 3.12)	1214 (4 RCTs)	⊕⊕⊕⊝ MODERATE ¹	There were no definitions for hypertensive disorders in pregnancy in the trials reporting this outcome.
Caesarean section	394 per 1000	405 per 1000 (366 to 449)	RR 1.03 (0.93 to 1.14)	1988 (17 RCTs)	⊕⊕⊕⊝ MODERATE ¹
Development of type 2 diabetes	52 per 1000	73 per 1000 (42 to 128)	RR 1.39 (0.80 to 2.44)	754 (2 RCTs)	⊕⊕⊕⊝ MODERATE ²	These 2 trials compared insulin with metformin. No other trials reported this long‐term outcome.
Perineal trauma/tearing ‐ not measured	‐	‐	‐	‐	‐	None of the included trials in this review pre‐specified or reported perineal trauma as an outcome.
Postnatal weight retention or return to pre‐pregnancy weight ‐ Maternal weight six to eight weeks postpartum ‐ Maternal weight one year postpartum	The mean weight at six to eight weeks postpartum was 80.8 kg The mean weight at one year postpartum was 81.8 kg	MD 1.6 kg lower (6.34 lower to 3.14 higher) MD 3.7 kg lower (8.5 lower to 1.1 higher)	MD 1.60 kg (‐6.34 to 3.14) MD 3.70 kg (‐8.50 to 1.10)	167 (1 RCT) 176 (1 RCT)	⊕⊕⊝⊝^2,3 LOW ⊕⊕⊝⊝^2,3 LOW
Postnatal depression ‐ not reported	‐	‐	‐	‐	‐	None of the included trials in this review pre‐specified or reported postnatal depression as an outcome.
Induction of labour	408 per 1000	535 per 1000 (424 to 669)	average RR 1.30, 95%CI 0.96,to 1.75	348 (3 RCTs)	⊕⊕⊕⊝ MODERATE ²	These 3 trials compared insulin with metformin. No other trials reported this outcome.
*The risk in the intervention group (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI). CI: Confidence interval; MD: mean difference; RR: Risk ratio
GRADE Working Group grades of evidence High quality: We are very confident that the true effect lies close to that of the estimate of the effect Moderate quality: We are moderately confident in the effect estimate: The true effect is likely to be close to the estimate of the effect, but there is a possibility that it is substantially different Low quality: Our confidence in the effect estimate is limited: The true effect may be substantially different from the estimate of the effect Very low quality: We have very little confidence in the effect estimate: The true effect is likely to be substantially different from the estimate of effect
¹ Risk of bias: Most of the trials were not blinded ‐ downgraded one level. ² Risk of bias: No blinding. Lacked methodological details to be able to judge randomisation or allocation concealment ‐ downgraded one level. ³ Imprecision: Wide confidence intervals and single study ‐ downgraded one level.

Summary of findings for the main comparison. Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (maternal outcomes)

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Summary of findings 2. Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (infant/child/adult outcomes)

Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes
Patient or population: Infants of women with gestational diabetes. Setting: Primary and secondary care (Canada, Egypt, USA, Brazil, Finland, Iran, Australia, New Zealand, India) Intervention: Insulin Comparison: Oral anti‐diabetic pharmacological therapy.
Outcomes	*Anticipated absolute effects^ (95% CI)**		Relative effect (95% CI)	№ of participants (studies)	Quality of the evidence (GRADE)	Comments
Outcomes	Risk with oral anti‐diabetic agent	Risk with insulin	Relative effect (95% CI)	№ of participants (studies)	Quality of the evidence (GRADE)	Comments
Large‐for‐gestational age (birthweight > 90th centile)	159 per 1000	161 per 1000 (121 to 215)	Average RR 1.01 (0.76 to 1.35)	2352 (13 RCTs)	⊕⊕⊕⊝ MODERATE ¹
Perinatal (fetal and neonatal death) and later infant mortality	8 per 1000	7 per 1000 (2 to 20)	RR 0.85 (0.29 to 2.49)	1463 (10 RCTs)	⊕⊕⊝⊝ LOW ^1,2	Event rates are low 5/728 for the group whose mothers were treated with insulin and 6/735 for the group whose mothers were treated with anti‐diabetic pharmacological therapies. No data were reported for later infant mortality.
Death or serious morbidity composite	319 per 1000	329 per 1000 (268 to 402)	RR 1.03 (0.84 to 1.26)	760 (2 RCTs)	⊕⊕⊕⊝ MODERATE ¹	These 2 trials compared insulin with metformin. No other trials reported this outcome. One trial included: resuscitation in the delivery room, preterm birth (< 37 weeks), neonatal intensive care unit admission, birth injury or diagnosis of neonatal complication, glucose infusion, antibiotics or phototherapy. One trial included: hypoglycaemia ‐< 2.6 mmol/L, RDS, phototherapy, birth trauma, Apgar < 7 at 5 minutes, preterm birth (< 37 weeks)
Neonatal hypoglycaemia	111 per 1000	126 per 1000 (94 to 169)	Average RR 1.14 (0.85 to 1.52)	3892 (24 RCTs)	⊕⊕⊝⊝ LOW ^1,5
Adiposity at birth ‐ percentage fat mass	The mean percentage fat mass was 12.8%	MD 1.6% lower (3.77 lower to 0.57 higher)	MD ‐1.60 (‐3.77, 0.57)	82 (1 RCT)	⊕⊕⊕⊝ MODERATE ⁴
Adiposity at birth ‐ skinfold sum (mm)	The mean skinfold sum was 16 mm	MD 0.8 mm lower (0.49 lower to 0.73 higher)	MD ‐0.80 mm (‐2.33, 0.73)	82 (1 RCT)	⊕⊝⊝⊝ VERY LOW ^2,4,7
Adiposity in childhood up to 2 years ‐ total fat mass (%)	The mean childhood Total fat mass (%) ‐ Metformin was 16.4%	MD 0.5% higher (0.49 lower to 1.49 higher)	MD 0.50 % (‐0.49, 1.49)	318 (1 RCT)	⊕⊕⊝⊝ LOW ^1,4
Childhood/adulthood diabetes (type 1, type 2) ‐ not reported	‐	‐	‐	‐	‐	No data were pre‐specified or reported for type 1 or type 2 diabetes in childhood or adulthood in the included trials in this review.
Neurosensory disability in later childhood (18 months) Mild developmental delay Hearing impairment Visual impairment	104 per 1000 0 per 1000 21 per 1000	111 per 1000 (34 to 358) 0 per 1000 (0 to 0) 6 per 1000 (1 to 60)	RR 1.07, (0.33 to 3.44) RR 0.31; (0.01 to 7.49) RR 0.31, (0.03 to 2.90)	93 (1 RCT)	⊕⊕⊝⊝ LOW ^4,6
*The risk in the intervention group (and its 95% confidence interval) is based on the assumed risk in the comparison group and the relative effect of the intervention (and its 95% CI). CI: Confidence interval; MD: mean difference; RDS: respiratory distress syndrome; RR: Risk ratio;
GRADE Working Group grades of evidence High quality: We are very confident that the true effect lies close to that of the estimate of the effect Moderate quality: We are moderately confident in the effect estimate: The true effect is likely to be close to the estimate of the effect, but there is a possibility that it is substantially different Low quality: Our confidence in the effect estimate is limited: The true effect may be substantially different from the estimate of the effect Very low quality: We have very little confidence in the effect estimate: The true effect is likely to be substantially different from the estimate of effect
¹ Risk of bias: Most of the trials were not blinded. Downgraded one level. ² Imprecision: Event rates are low and confidence intervals are wide crossing the line of no effect. Downgraded one level. ³ Inconsistency: I² = 78%. Downgraded one level. ⁴ Evidence is based on a single trial. Downgraded one level. ⁵ Inconsistency: I² = 51%. Downgraded one level. ⁶ Imprecision: Wide confidence intervals. Downgraded one level. ⁷ Risk of bias: Selective reporting and other bias detected. Downgraded one level.

Summary of findings 2. Insulin compared to anti‐diabetic agent for the treatment of women with gestational diabetes (infant/child/adult outcomes)

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Table 1. Examples of diagnostic criteria for gestational diabetes mellitus

Organisation/professional body	Screening criteria	Diagnostic criteria
	One‐hour oral glucose challenge test	Oral glucose tolerance test	Fasting	1‐hour	2‐hour	3‐hour
ADA 2015b, IADPSG 2010, ADIPS 2014* (Nankervis 2014); WHO 2014*	‐	75 g	≥ 5.1 mmol/L (≥ 92 mg/dL)	≥ 10 mmol/L (≥ 180 mg/dL)	≥ 8.5 mmol/L (≥ 153 mg/dL)	‐
ADA 2015b	50 g (≥ 7.8 mmol/L; ≥ 140 mg/dL)	75 g	≥ 5.1 mmol/L (≥ 92 mg/dL)	≥ 10 mmol/L (≥ 180 mg/dL)	≥ 8.5 mmol/L (≥ 153 mg/dL)	‐
ACOG 2013 Carpenter and Coustan^ or National Diabetes Data Group^	50 g (> 7.2 mmol/L; > 130 mg/dL)	100 g	≥ 5.3 mmol/L (95 mg/dL)	≥ 10 mmol/L (180 mg/dL)	≥ 8.6 mmol/L (155 mg/dL)	≥ 7.8 mmol/L (140 mg/dL)
	50 g (> 7.8 mmol/L; > 140 mg/dL)	100 g	≥ 5.8 mmol/L (105 mg/dL)	≥ 10.6 mmol/L (190 mg/dL)	≥ 9.2 mmol/L (165 mg/dL)	≥ 8.0 mmol/L (145 mg/dL)
NICE 2008; WHO 1999*; ADIPS 1998 (Hoffman 1998)		75 g	≥ 7.0 mmol/L (≥ 126 mg/dL)	‐	≥ 11.1 mmol/L (≥ 200 mg/dL)	‐
NICE 2015	‐	75 g	≥ 5.6 mmol/L (≥ 101 mg/dL)	‐	≥7.8 mmol/L (140 mg/dL)	‐
New Zealand Ministry of Health 2014*	50 g if HbA1c < 41 mmol/mol (≥ 7.8 mmol/L; ≥ 140 mg/dL)	75 g	≥ 5.5 mmol/L (≥ 99 mg/dL)	‐	≥ 9.0 mmol/L (≥ 162 mg/dL)	‐
ADA: American Diabetes Association (recommends either the one step or two step strategy) IADPSG: International Association of the Diabetes and Pregnancy Study Groups ADIPS: Australasian Diabetes in Pregnancy Society ACOG: American College of Obstetrics and Gynecology NICE: National Institute for Health and Care Excellence *1 abnormal result required for diagnosis ^2 or more abnormal results required for diagnosis mmol/L ‐ millimoles per litre mg/dL ‐ milligramme per decilitre

Table 1. Examples of diagnostic criteria for gestational diabetes mellitus

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Table 2. Diagnostic criteria

		Screen	Diagnostic test	Diagnostic criteria
Ashoush 2016	Not stated	Not stated	2‐hour, 75 g OGTT	Not stated	ADA 2004
Anjalakshi 2007	Not stated	Not stated	75 g OGTT	2‐hour ≥ 7.7 mmol/L (140 mg/dL)	WHO 1994
Ardilouze 2014	‐	‐	‐	‐	Canadian Diabetes Association (no details)
Balaji 2005	Not stated	Not stated	Not stated	Not stated	Not stated
Balaji 2012	12 to 28 weeks’	Not stated	2‐hour, 75 g OGTT	2‐hour ≥ 7.7 mmol/L (140 mg/dL)	WHO 1994
Behrashi 2016	11 to 33 weeks'	Not stated	3‐hour, 100 g OGTT	2 abnormal values of: Fasting blood glucose ≥ 5.3 mmol/L (95 mg/dL), 1‐hour glucose level 10.0 mmol/L (180 mg/dL), 2‐hour glucose level 8.6 mmol/L (155 mg/dL) 3‐hour glucose level 7.8 mmol/L (140 mg/dL),	Carpenter and Coustan criteria
Bertini 2005	11 to 33 weeks'	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose ≥ 6.1 mmol/L (110 mg/dL) and 2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	WHO 1994
Beyuo 2015	20 to 28 weeks'	Not stated	2‐hour, 75 g OGTT	1 or more abnormal value from: Fasting blood glucose ≥ 5.1 mmol/L (92 mg/dL), 1‐hour glucose level 10.0 mmol/L (180 mg/dL), 2‐hour glucose level 8.5 mmol/L (153 mg/dL).	ADA 2012
Bung 1993	Not stated	Not stated	Not stated	Not stated	Not stated
Castorino 2011	Not stated	Not stated	Not stated	Not stated	Not stated
Coustan 1978	Not stated	Women with risk factors for GDM	3‐hour, 100 g OGTT	2 abnormal values of: Fasting blood glucose ≥ 5.3 mmol/L (95 mg/dL), 1‐hour glucose level 10.0 mmol/L (180 mg/dL), 2‐hour glucose level 8.9 mmol/L (160 mg/dL), 3‐hour glucose level 7.5 mmol/L (135 mg/dL).	Modified O'sullivan and Mahan (1964)
De Veciana 2002	Not stated	Not stated	Not stated	Not stated	Not stated
Di Cianni 2007	No details				Carpenter and Coustan criteria
Hague 2003	‐	‐	‐	‐	ADIPS (old criteria)
Herrera 2015					Carpenter and Coustan 1983 or IADPSG 2010
Hickman 2013	< 20 weeks'	Not stated	3‐hour 100 g OGTT	2 or more abnormal values	National Diabetes Data Group Criteria 1979
Hutchinson 2008	Not stated	Not stated	Not stated	Not stated	Not stated
Ijas 2011	Risk factor	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose 5.3 mmol/L (95 mg/dL), 1‐hour glucose level 11.0 mmol/L, 2‐hour glucose level 9.6 mmol/L. There were to be 1 or more abnormal values.	Not stated
Ismail 2007	Not stated	Not stated	Not stated	Not stated	Not stated
Jovanovic 1999	14 to 32 weeks'				Carpenter and Coustan criteria modification of NDDG criteria
Lain 2009	24 to 34 weeks'	50 g 1‐hour oral glucose challenge test > 7.5 mmol/L (135 mg/dL)	100 g 3‐hour OGTT	2 abnormal values of: Fasting blood glucose 5.3 mmol/L (95 mg/dL), 1‐hour glucose level 10.0 mmol/L (180 mg/dL) 2‐hour glucose level 8.6 mmol/L (155 mg/dL) 3‐hour glucose level 7.8 mmol/L (140 mg/dL), An elevated fasting value of 3‐hour OGTT or 1‐hour OGTT > 11.1 mmol/L or 200 mg/dL diagnostic of diabetes.	Carpenter and Coustan criteria
Langer 2000	11 to 33 weeks'	50 g, 1‐hour oral glucose challenge test > 7.3 mmol/L (130 mg/dL)	100 g OGTT	Fasting blood glucose between 5.3 mmol/L (95 mg/dL) and 7.8 mmol/L (130 mg/dL). 2 or more abnormal values required	Carpenter and Coustan criteria.
Majeed 2015	Not reported	Not reported	Not reported	Not reported	Not reported
Martinez Piccole 2010	Not reported	Not reported	Not reported	Not reported	Not reported
Mecacci 2003	25 to 32 weeks'				Carpenter and Coustan criteria
Mesdaghinia 2013	24 to 34 weeks'	50 g, 1‐hour oral glucose challenge test	100 g 3‐hour OGTT	2 or more abnormal results required from Fasting blood sugar > 5.3 mmol/L or 95 mg/dL; 1‐hour glucose level > 9.99 mmol/L or 180 mg/dL; 2‐hour glucose level > 8.6 mmol/L or 150 mg/dL; 3‐hour glucose level > 7.8 mmol/L or 140 mg/dL.	Carpenter and Coustan criteria
Mirzamoradi 2015	24 to 28 weeks'	Not stated	Not stated	Fasting blood glucose > 5.3 mmol/L or 95 mg/dL, 1‐hour glucose level > 10.0 mmol/L or 180 mg/dL or 2‐hour glucose level > 8.6 mmol/L or 150 mg/dL.	Carpenter and Coustan criteria
Mohamed 2014	‐	‐	‐	Plasma glucose > 7.8 mmol/L (140 mg/dL)	Carpenter and Coustan criteria
Moore 2007	24 to 30 weeks'	1‐hour 50 g glucose challenge test	100 g 3‐hour OGTT	Fasting blood glucose > 105 mg/dL, 1‐hour glucose level > 190 mg/dL, 2‐hour glucose level > 165 mg/dL and 3‐hour glucose level > 145 mg/dL. 2 or more abnormal values required for diagnosis.	ADA criteria (old)
Mukhopadhyay 2012	20 to 28 weeks'	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose ≥ 6.1 mmol/L (110 mg/dL) and 2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	WHO 1994
Nachum 1999	Not stated	Not stated	100 g 3‐hour OGTT	Fasting blood glucose 5.9 mmol/L 1‐hour glucose level 10.6 mmol/L 2‐hour glucose level 9.2 mmol/L 3‐hour glucose level 8.1 mmol/L	NDDG 1979
Niromanesh 2012	20 to 34 weeks'	1‐hour 50 g glucose challenge test	100 g 3‐hour OGTT	‐	Carpenter and Coustan criteria
Notelovitz 1971	Not reported	Not reported	2‐hour, 100 g OGTT	2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	Not reported
Ogunyemi 2007	Not reported	1‐hour 50 g glucose challenge test	3‐hour OGTT	Not reported	Not reported
O'Sullivan 1975a	Not reported	1‐hour 50 g glucose challenge test ‐ ≥ 130 mg/100 mL or presence of risk factors including history of macrosomia, fetal death, neonatal death, congenital anomaly.	3‐hour 100 g OGTT	2 or more abnormal readings from Fasting blood glucose ≥ 110 mg/100 mL 1‐hour blood glucose level ≥ 170 mg/100 mL, 2‐hour blood glucose level ≥ 120 mg/100 mL, 3‐hour blood glucose level ≥ 110 mg/100 mL.	Not reported
O'Sullivan 1975b	Not reported	1‐hour 50 g glucose challenge test ‐ ≥ 130 mg/100 mL	3‐hour 100 g OGTT	2 or more abnormal readings from Fasting blood glucose ≥ 110 mg/100 mL 1‐hour blood glucose level ≥ 170 mg/100 mL, 2‐hour blood glucose level ≥ 120 mg/100 mL, 3‐hour blood glucose level ≥ 110 mg/100 mL.	Not reported
Pavithra 2016	24 to 28 weeks'	1‐hour 50 g glucose challenge test	100 g OGTT	Fasting blood glucose > 5.3 mmol/L or 95 mg/dL, 1‐hour glucose level > 10.0 mmol/L or 180 mg/dL or 2‐hour glucose level > 8.6 mmol/L or 155 mg/dL. 3‐hour glucose level > 7.7 mmol/L or 140 mg/dL	Carpenter and Coustan criteria
Persson 1985	Not stated. Risk based selection	Not stated	3‐hour, 50 g OGTT	Not stated values but note that 2SD above normal	Gillmer 1975
Pettitt 2007	Not stated	Not stated	Not stated	Not stated	Not stated
Poyhonen‐Alho 2002	24 to 28 weeks'	OGTT based on risk factors (BMI > 25 kg/m2, age > 40 years, previous GDM, previous infant with macrosomia > 4500 g, glucosuria, current macrosomia)	2‐hour, 75 g OGTT	2 or more abnormal values from: Fasting ≥ 4.8 mmol/L 1‐hour glucose level ≥ 10.0 mmol/L 2‐hour glucose value ≥ 8.7 mmol/L	Finnish national guidelines (2008)
Prasad 2008	Not stated	Not stated	Not stated	Not stated	Not stated
Riaz 2014	Not stated	Not stated	75 g OGTT	Not stated	Not stated
Rowan 2008	20 to 33 weeks'	Not stated	75 g OGTT	1 or more of the following being abnormal Fasting plasma glucose level ≥ 5.1 mmol/L, 1‐hour venous plasma glucose ≥ 10.0 mmol/L (180 mg/dL), or 2‐hour venous plasma glucose ≥ 8.5 mmol/L.	ADIPS (1998)
Ruholamin 2014	24 to 28 weeks'				ADIPS 1998
Saleh 2016	26 to 34 weeks'	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose ≥ 7.0 mmol/L (126 mg/dL) and 2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	IADPSG 2010
Silva 2007	11 to 33 weeks'	Not stated	2‐hour, 75 g OGTT	Fasting blood glucose ≥ 6.1 mmol/L (110 mg/dL) and 2‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	WHO 1994
Spaulonci 2013	Not reported	Not stated	2‐hour 75 g or 3‐hour 100 g OGTT	2 or more abnormal results Fasting blood glucose > 5.3 mmol/L (95 mg/dL) 1‐hour glucose level ≥ 10.0 mmol/L (180 mg/dL) 2‐hour glucose level ≥ 8.6 mmol/L (155 mg/dL) 3‐hour glucose level ≥ 7.8 mmol/L (140 mg/dL)	ADA 2011
Tertti 2013	22 to 34 weeks'	Screening criteria based on risk changed during the study	2‐hour 75 g OGTT	Diagnostic cut‐off levels up to 2008 were: Fasting blood glucose ≥ 4.8 mmol/L (87 mg/dL) 1‐hour glucose level ≥ 10.0 mmol/L (180 mg/dL) and 2‐hour glucose level ≥ 8.7 mmol/L (157 mg/dL) and thereafter was fasting ≥ 5.3 mmol/L (95 mg/dL), 1‐hour ≥ 10 mmo/L (180 mg/dL) and 2‐hour ≥ 8.6 mmol/L (155 mg/dL).	Finnish national guidelines (2008)
Thompson 1990	28 weeks' or earlier	1‐hour 50 g glucose challenge test	100 g 3‐hour OGTT	Fasting blood glucose > 105 mg/dL, 1‐hour glucose level > 190 mg/dL, 2‐hour glucose level > 165 mg/dL and 3‐hour glucose level > 145 mg/dL. 2 or more abnormal values required for diagnosis.	ADA criteria (old)
Waheed 2013	14 weeks' or more	No details	No details	Fasting blood glucose > 5.5 mmol/L (100 mg/dL), and random blood sugar > 7.7 mmol/L (140 mg/dL).	Not stated
Wali 2015					IADPSG (2010)
Zangeneh 2014	24 weeks'	1‐hour 50 g glucose challenge test	100 g 3‐hour OGTT	Fasting blood glucose between 5.3 mmol/L (95 mg/dL) and 7.8 mmol/L (130 mg/dL). 2 or more abnormal values required	Carpenter and Coustan criteria.
Zawiejska 2016	No details	No details	No details	No details	No details
OGTT: oral glucose tolerance test

Table 2. Diagnostic criteria

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Table 3. Maternal age (Years)

Trial ID
	Insulin	Glibenclamide
Anjalakshi 2007	27.5 ± 5.8 (n = 13)	24.9 ± 3.7 (n = 10)
Behrashi 2016	29.9 ± 7.0 (n = 129)	30.7 ± 7.2 (n = 120)
Bertini 2005	28.7 ± 6.0 (n = 27)	31.2 ± 4.5 (n = 24)
Lain 2009	31.2 ± 5.9 (n = 41)	32.2 ± 5.0 (n = 41)
Langer 2000	30 ± 6 (n = 203)	29 ± 7 (n = 201)
Mirzamoradi 2015	31.2 ± 5.0 (n = 59)	29.5 ± 4.1 (n = 37)
Mukhopadhyay 2012	26 ± 4.3 (n = 30)	26.3 ± 4.6 (n = 30)
Ogunyemi 2007	Not reported	Not reported
Pavithra 2016	27.9 ± 3.6 (n = 50)	28.2 ± 3.1 (n = 50)
Silva 2007	29.9 ± 6.0 (n = 36)	31.6 ± 4.2 (n = 32)
Zangeneh 2014	32.6 ± 6.2 (n = 46)	31.4 ± 5 (n = 44)

	Insulin	Metformin
Ashoush 2016	32.1 ± 3.2 (n = 48)	31.6 ± 2.8 (n = 47)
Beyuo 2015	33.1 ± 4.6 (n = 40)	33.5 ± 4.7 (n = 43)
Hague 2003	34.1 ± 3.7 (n = 14)	33.7 ± 4.44 (n = 16)
Hickman 2013	Median 31 (IQR 26, 33) (n = 14)	Median 36 (IQR 35, 37) (n = 14)
Ijas 2011	31.7 ± 6.1 (n = 50)	32.3 ± 5.6 (n = 47)
Mesdaghinia 2013	30.2 ± 5.9 (n = 100)	29.6 ± 5.3 (n = 100)
Moore 2007	27.7 ± 6.7 (n = 31)	27.1 ± 4.7 (n = 32)
Majeed 2015	Not reported	Not reported
Martinez Piccole 2010	Not reported	Not reported
Niromanesh 2012	31.8 ± 5.1 (n = 80)	30.7 ± 5.5 (n = 80)
Riaz 2014	Not reported	Not reported
Rowan 2008	33 ± 5.1 years (n = 370)	33.5 ± 5.4 (n = 363)
Ruholamin 2014	23.4 ± 2.5 (n = 50)	24.6 ± 6.3 (n = 50)
Saleh 2016	29.8 ± 2.2 (n = 70)	31.0 ± 3.4 (n = 67)
Spaulonci 2013	32.76 ± 4.66 (n = 47)	31.93 ± 6.02 (n = 47)
Tertti 2013	32.1 ± 5.4 (n =107)	31.9 ± 5.0 (n = 110)
Waheed 2013	29.82 ± 4.58 (n = 34)	29.35 ± 4.97 (n = 34)
Wali 2015	Not reported	Not reported
Zawiejska 2016	35 (30 to 38) (n = 43)	22 (29 to 39) (n = 35)

	Insulin	Acarbose
Bertini 2005	28.7 ± 6.0 (n = 27)	31.5 ± 5.8 (n = 19)
De Veciana 2002	Not reported	Not reported

	Insulin	Glyburide/metformin combined
Ardilouze 2014	30.7 ± 4.4 (n = 33)	31.1 ± 4.7 (n = 35)
Hutchinson 2008	Not reported	Not reported
Mohamed 2014	32.1 ± 5.7 (n = 42)	33.2 ± 4.9 (n = 42)

	Human insulin	Insulin aspart
Balaji 2005	31.0 ± 2.7 (n = 5)	30.6 ± 5.0 (n = 5)
Balaji 2012	29.6 ± 4.5 (n = 157)	29.2 ± 4.0 (n = 163)
Di Cianni 2007	Not reported	Not reported
Pettitt 2007	29.7 ± 6.9 (n = 13)	31.6 ± 5.9 (n = 14)
Prasad 2008	Not reported	Not reported


	Human insulin	Insulin lispro
Di Cianni 2007	Not reported	Not reported
Jovanovic 1999	29.8 ± 1.0 (n = 23)	34.2 ± 1.3 (n = 19)
Mecacci 2003	median 35 (range 28 to 41) (n = 24)	Median 34.5 (range 28 to 41) (n = 25)

	Human insulin	Neutral Protamine Hagedorn insulin
Poyhonen‐Alho 2002	Not reported	Not reported
Ismail 2007	Not reported	Not reported
Herrera 2015	Median 35 [ 31‐38] (n = 42)	Median 35 [IQR 32‐38] (n = 45)

	Insulin	Diet
Coustan 1978	Not reported	Not reported
Notelovitz 1971	31.8 (n = 47)	32.7 (n = 56)
Persson 1985	Median 30.5 (range 16 to 42) (n = 97)	Median 29 (range 18 to 46) (n = 105)
Thompson 1990	27 ± 5.4	26 ± 5.7

	Insulin	Exercise
Bung 1993	Not reported	Not reported

	Insulin	Standard care
O'Sullivan 1975a	Not reported	Not reported
O'Sullivan 1975b	Not reported	Not reported

	Insulin regimen A	Insulin regimen B
Castorino 2011	Not reported	Not reported
Nachum 1999	33 ± 5 (n = 136)	33 ± 5 (n = 138)

Table 3. Maternal age (Years)

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Table 4. Ethnicity/Race

Trial ID	Ethnicity
Ashoush 2016	Not reported
Anjalakshi 2007	Not reported but likely to be Indian
Ardilouze 2014	Not reported
Balaji 2005	Not reported but likely to be Indian
Balaji 2012	Not reported but likely to be Indian
Behrashi 2016	Not reported
Bertini 2005	Not reported but likely to be Brazilian
Beyuo 2015	Not reported
Bung 1993	Not reported
Castorino 2011	86% Mexican
Coustan 1978	Not reported
De Veciana 2002	Not reported
Di Cianni 2007	Not reported
Hague 2003	Not reported
Herrera 2015	33% White, 14% Black, 31% Hispanic, 21% Native American/Alaskan
Hickman 2013	79% Hispanic, 14% Black
Hutchinson 2008	Not reported
Ijas 2011	Not reported
Ismail 2007	Not reported
Jovanovic 1999	95% Hispanic
Lain 2009	13% Black (no other details)
Langer 2000	83% were Hispanic and 12% non‐Hispanic Caucasian
Majeed 2015	Not reported but likely to be Indian
Martinez Piccole 2010	Not reported
Mecacci 2003	Caucasian
Mesdaghinia 2013	Not reported but likely to be Iranian
Mirzamoradi 2015	Not reported but likely to be Iranian
Mohamed 2014	Not reported
Moore 2007	50% African American, 44% Native American
Mukhopadhyay 2012	Not reported but likely to be Indian
Nachum 1999	56% were Jewish
Niromanesh 2012	Not stated but likely to be Iranian
Ismail 2007	Not reported
Notelovitz 1971	37% were Bantu (Zulu)
Ogunyemi 2007	80% were Hispanic and 15% African American
O'Sullivan 1975a	Not reported
O'Sullivan 1975b	Not reported
Pavithra 2016	Not reported
Persson 1985	Not reported
Pettitt 2007	75% were Hispanic and 19% were Caucasian
Poyhonen‐Alho 2002	Not reported
Prasad 2008	Not reported
Riaz 2014	Not reported but likely to be Pakistani
Rowan 2008	47% Caucasian, 21% Polynesian, 13% Indian
Ruholamin 2014	Not reported but likely to be Iranian
Saleh 2016	Not reported
Silva 2007	Not reported but likely to be Brazilian
Spaulonci 2013	Not reported
Tertti 2013	Not reported
Thompson 1990	41% 'Black', 49% 'White'
Waheed 2013	Not reported but likely to be Pakistani
Wali 2015	Not reported but likely to be Pakistani
Zangeneh 2014	Not reported but likely to Iranian
Zawiejska 2016	Not reported

Table 4. Ethnicity/Race

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Table 5. Maternal BMI at baseline (kg/m2)

Trial ID
	Insulin	Glibenclamide
Anjalakshi 2007	25.3 ± 5.1 (n = 13)	22.8 ± 3.5 (n = 10)
Behrashi 2016	22.6 ± 3.1 (n = 129)	21.9 ± 2.80 (n = 120)
Bertini 2005	27.0 ± 7.2 (n = 27)	27.5 ± 5.8 (n = 24)
Lain 2009	30.9 ± 5.7 (n = 41)	33.4 ± 12.9 (n = 41)
Langer 2000	Not reported	Not reported
Mirzamoradi 2015	31.8 ± 5.1 (n = 59)	30.8 ± 5.4 (n = 37)
Mukhopadhyay 2012	23.0 ± 2.9 (n = 30)	23.7 ± 2.7 (n = 30)
Ogunyemi 2007	30.8 ± 6.9 (n = 49)	32.0 ± 7.6 (n = 48)
Pavithra 2016	28.3 ± 3.8 (n = 50)	27.8 ± 4.0 (n = 50)
Silva 2007	27.9 ± 6.8 (n = 36)	27.5 ± 5.1 (n = 32)
Zangeneh 2014	27.8 ± 3 (n = 46)	27.5 ± 1.5 (n = 44)

	Insulin	Metformin
Ashoush 2016	31.4 ± 1.5 (n = 48)	31.1 ± 1.3 (n = 47)
Beyuo 2015	32.6 ± 6.2 (n = 40)	33.5 ± 7.0 (n = 43)
Hague 2003	37.9 ± 6.87 (n = 14)	39.5 ± 6.94 (n = 16)
Hickman 2013	Median 33 (IQR 28, 41) (n = 14)	Median 29 (IQR 27,33) (n = 14)
Ijas 2011	30.8 ± 5.4 (n = 50)	31.5 ± 6.5 (n = 47)
Majeed 2015	Not reported	Not reported
Mesdaghinia 2013	28.5* (n = 100)	27.6* (n = 100)
Moore 2007	35.3 ± 6.7 (n = 31)	39.7 ± 9.0 (n = 32)
Niromanesh 2012	27.1 ± 2.1 (n = 80)	28.1 ± 4.0 (n = 80)
Martinez Piccole 2010	Not reported	Not reported
Riaz 2014	Not reported	Not reported
Rowan 2008	34.6 ± 7.2 (n = 370)	35.1 ± 8.3 (n = 363)
Ruholamin 2014	25.1 ± 3.4 (n = 50)	26.4 ± 2.8 (n = 50)
Saleh 2016	31.6 ± 31.1 (n = 70)	30.1 ± 3.2 (n = 67)
Spaulonci 2013	31.39 ± 5.71 (n = 47)	31.96 ± 4.75 (n = 47)
Tertti 2013	28.9 ± 4.7 (n = 107)	29.4 ± 5.9 (n = 110)
Waheed 2013	Not reported	Not reported
Wali 2015	Not reported	Not reported
Zawiejska 2016	32.0 ± 5.8 (n = 43)	32.2 ± 6.4 (n = 35)

	Insulin	Acarbose
Bertini 2005	27.0 ± 7.2 (n = 27)	25.7 ± 4.2 (n = 19)
De Veciana 2002	32.1 ± 5.6 (n = 46)	33.1 ± 6.4 (n = 45)

	Insulin	Glyburide/metformin combined
Ardilouze 2014	32.2 ± 7.2 (n = 33)	32.0 ± 5.4 (n = 35)
Hutchinson 2008	Not reported	Not reported
Mohamed 2014	Not reported	Not reported

	Human insulin	Insulin aspart
Balaji 2005	25.6 ± 2.9 (n = 5)	28.6 ± 3.1 (n = 5)
Balaji 2012	25.8 ± 3.4 (n = 157)	26.0 ± 3.4 (n = 163)
Di Cianni 2007	Not reported	Not reported
Pettitt 2007	33.2 ± 5.7 (n = 13)	29.3 ± 4.7 (n = 14)
Prasad 2008	Not reported	Not reported

	Human insulin	Insulin lispro
Jovanovic 1999	33.3 ± 1.2 (n = 23)	31.5 ± 1.1 (n = 19)
Mecacci 2003	Median 22.3 (range 19.8 to 25.3) (n = 24)	Median 21.5 (range 19.2 to 25.1) (n = 25)

	Human insulin	Neutral Protamine Hagedorn insulin
Di Cianni 2007	Not reported	Not reported
Poyhonen‐Alho 2002	Not reported	Not reported
Ismail 2007	Not reported	Not reported

	Insulin	Diet
Coustan 1978	Not reported	Not reported
Notelovitz 1971	Not reported	Not reported
Persson 1985	Not reported	Not reported
Thompson 1990	Not reported	Not reported

	Insulin detemir	Neutral Protamine Hagedorn insulin
Herrera 2015	28.3 (IQR 24.9‐33.8) (n = 42)	28.6 (IQR 24.4‐31.1) (n = 45)

	Insulin	Exercise
Bung 1993	Not reported	Not reported

	Insulin	Standard care
O'Sullivan 1975a	Not reported	Not reported
O'Sullivan 1975b	Not reported	Not reported

	Insulin regimen A	Insulin regimen B
Castorino 2011	Not reported	Not reported
Nachum 1999	27.8 ± 2.7 (n = 136)	27.9 ± 2.6 (n = 138)
*SD not reported IQR: interquartile ratio

Table 5. Maternal BMI at baseline (kg/m2)

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Table 6. Gestational age at start of treatment/enrolment (weeks)

Trial ID
	Insulin	Glibenclamide
Anjalakshi 2007	22.6 ± 5.6 (n = 13)	22.5 ± 4.7 (n = 10)
Behrashi 2016	24.5 ± 4.5 (n = 129)	24.9 ±3.9 (n = 120)
Bertini 2005	Not reported	Not reported
Lain 2009	30.6 ± 2.2 (n = 41)	30.8 ± 2.5 (n = 41)
Langer 2000	25.0 ± 7.0 (n = 203)	24.0 ± 7.0 (n = 201)
Mukhopadhyay 2012	27.4 ± 2.7 (n = 30)	28.3 ± 2.2 (n = 30)
Mirzamoradi 2015	30.3 ± 4.0 (n = 59)	29.9 ± 4.1 (n = 37)
Ogunyemi 2007	24.6 ± 8.0 (n = 49)	28.1 ± 7.6 (n = 48)
Pavithra 2016	Not reported	Not reported
Silva 2007	25.6 ± 5.9 (n = 36)	26.6 ± 4.3 (n = 32)
Zangeneh 2014	Not reported	Not reported

	Insulin	Metformin
Ashoush 2016	29.7 ± 1.9 (n = 48)	29.8 ± 1.4 (n = 47)
Beyuo 2015	Median 26 IQ range 23 to 28 (n = 40)	Median 28 IQ range 26 to 29 (n = 43)
Hague 2003	30.4 ± 4.67 (n = 14)	29.8 ± 4.49 (n = 16)
Hickman 2013	Median 14 (IQR 13, 19) (n = 14)	Median 17 (IQR 10, 22) (n = 14)
Ijas 2011	30.0 ± 4.0 (n = 50)	30.0 ± 4.9 (n = 47)
Majeed 2015	Not reported	Not reported
Mesdaghinia 2013	28.9 ± 3.8 (n = 100)	27.9 ± 3.2 (n = 100)
Moore 2007	28.9 ± 5.0 (n = 31)	27.8 ± 6.5 (n = 32)
Niromanesh 2012	28.6 ± 3.6 (n = 80)	28.7 ± 3.7 (n = 80)
Martinez Piccole 2010	Not reported	Not reported
Riaz 2014	Not reported	Not reported
Rowan 2008	30.1 ± 3.2 (n = 370)	30.2 ± 3.3 (n = 363)
Ruholamin 2014	26.7 ± 3.5 (n = 50)	27.6 ± 3.3 (n = 50)
Saleh 2016	Not reported	Not reported
Spaulonci 2013	32.05 ± 3.50 (n = 47)	32.18 ± 3.70 (n = 47)
Tertti 2013	30.4 ± 1.8 (n = 107)	30.3 ± 2.0 (n = 110)
Waheed 2013	Not reported	Not reported
Wali 2015	Not reported	Not reported
Zawiejska 2016	30 (28 to 31) (n = 43)	30 (28 to 32) (n = 35)

	Insulin	Acarbose
Bertini 2005	Not reported	Not reported
De Veciana 2002	30.2 ± 3.7 (n = 46)	30.5 ± 3.5 (n = 45)

	Insulin	Glyburide/metformin combined
Ardilouze 2014	30.1 ± 3.1 (n=33)	29.3 ± 3.8 (n=35)
Hutchinson 2008	Not reported	Not reported
Mohamed 2014	24.5 ± 6.3 (n = 42)	22.1 ± 7.3 (n = 42)

	Human insulin	Insulin aspart
Balaji 2005	Not reported	Not reported
Balaji 2012	22.4 ± 10.1 (n = 157)	21.7 ± 9.3 (n = 163)
Di Cianni 2007	Not reported	Not reported
Pettitt 2007	Not reported	Not reported
Prasad 2008	Not reported	Not reported

	Human insulin	Insulin lispro
Di Cianni 2007	Not reported	Not reported
Jovanovic 1999	25.6 ± 1.3 (n = 23)	27.3 ± 1.4 (n = 19)
Mecacci 2003	Median 29 (range 27 to 32) (n = 24)	Median 29 (range 26 to 32) (n = 25)

	Human insulin	Neutral Protamine Hagedorn insulin
Poyhonen‐Alho 2002	Not reported	Not reported
Ismail 2007	Not reported	Not reported

	Insulin detemir	Neutral Protamine Hagedorn insulin
Herrera 2015	Median 27.3 (IQR 23.3 ‐28.5) (n = 42)	Median 28.1 (25.1 ‐ 29.3) (n = 45)

	Insulin	Diet
Coustan 1978	Not reported	Not reported
Notelovitz 1971	Not reported	Not reported
Persson 1985	Not reported	Not reported
Thompson 1990	Not reported	Not reported

	Insulin	Exercise
Bung 1993	Not reported	Not reported

	Insulin	Standard care
O'Sullivan 1975a	Not reported	Not reported
O'Sullivan 1975b	Not reported	Not reported

	Insulin regimen A	Insulin regimen B
Castorino 2011	Not reported	Not reported
Nachum 1999	28 ± 6.9 (n = 136)	27.4 ± 6.8 (n = 138)
IQR Interquartile range

Table 6. Gestational age at start of treatment/enrolment (weeks)

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Table 7. Treatment targets

Study ID	Fasting	1‐hour postprandial	2‐hour postprandial
Ashoush 2016	< 5.5 mmol/L (100 mg/dL)		< 7.7 mmol/L (140 mg/dL)
Anjalakshi 2007	‐	‐	< 6.7 mmol/L (120 mg/dL)
Ardilouze 2014	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Balaji 2005	< 5.0 mmol/L (90 mg/dL)		< 6.7 mmol/L (120 mg/dL)
Balaji 2012	> 4.4 mmol/L (> 80 mg/dL) and < 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Behrashi 2016	< 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Bertini 2005	< 5.0 mmol/L (90 mg/dL)	‐	< 5.6 mmol/L (100 mg/dL)
Beyuo 2015	< 5.5 mmol/L (99 mg/dL)		< 7.0 mmol/L (126 mg/dL)
Bung 1993	> 5.8 mmol/L (105 mg/dL) to < 7.2 mmol/L (< 130 mg/dL)	‐	‐
Castorino 2011	< 5.0 mmol/L (90 mg/dL)	< 6.7 mmol/L (120 mg/dL	‐
Coustan 1978	Not reported	Not reported	Not reported
De Veciana 2002	</= 5.3 mmol/L (95 mg/dL)		</= 6.7 mmol/L (120 mg/dL)
Di Cianni 2007	‐	< 7.2 mmol/L (< 130 mg/dL)	‐
Hague 2003	Not reported
Herrera 2015	< 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Hickman 2013	< 5.3 mmol/L (95 mg/dL)	< 7.2 mmol/L (< 130 mg/dL)
Hutchinson 2008	Not reported	Not reported	Not reported
Ijas 2011	< 5.3 mmol/L (95 mg/dL)	‐	1.5 hours postprandial < 6.7 mmol/L (120 mg/dL)
Ismail 2007	< 5.5 mmol/L (100 mg/dL)	‐	‐
Jovanovic 1999	< 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Lain 2009	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Langer 2000	3.4 to 5.0 mmol/L (80 to 95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Majeed 2015	Not reported	‐	Not reported
Martinez Piccole 2010	Not reported	‐	Not reported
Mecacci 2003	< 5.0 mmol/L (90 mg/dL)	< 6.7 mmol/L (120 mg/dL)	‐
Mesdaghinia 2013	< 5.3 mmol/L (95 mg/dL)		< 6.7 mmol/L (120 mg/dL)
Mirzamoradi 2015	3.3 to 5.0 mmol/L (60 to 90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Moore 2007	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Mukhopadhyay 2012	< 5.0 mmol/L (90 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Nachum 1999	3.3 to 5.3 mmol/L	</= 6.7	</= 6.7 mmol/L (120 mg/dL)
Niromanesh 2012	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Ismail 2007	< 5.5 mmol/L
Notelovitz 1971		8.3 mmol/L (150 mg/dL)
Ogunyemi 2007	Not reported	Not reported	Not reported
O'Sullivan 1975a	Not reported	Not reported	Not reported
O'Sullivan 1975b	Not reported	Not reported	Not reported
Pavithra 2016	< 5.0 mmol/L (90 mg/dL)		</= 6.7 mmol/L (120 mg/dL)
Persson 1985	< 5.0 mmol/L	< 6.5 mmol/L	‐
Poyhonen‐Alho 2002	Not reported	Not reported	Not reported
Pettitt 2007	Not reported	Not reported	Not reported
Prasad 2008	Not reported	Not reported	Not reported
Riaz 2014	Not reported	Not reported	Not reported
Rowan 2008	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Ruholamin 2014	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Saleh 2016	≤5.5mmol/L (<100 mg/dL)		< 7.0 mmol/L (126 mg/dL)
Silva 2007	< 5.0 mmol/L (90 mg/dL)	‐	< 5.6 mmol/L (100 mg/dL)
Spaulonci 2013	≤ 5.3 mmol/L (95 mg/dL)	‐	≤ 6.7 mmol/L (120 mg/dL)
Tertti 2013	≤5.5mmol/L (100 mg/dL)	‐	≤ 7.8 mmol/L
Thompson 1990	< 5.8 mmol/L (105mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Waheed 2013	3.5 to 5.5 mmol/L (63 to 100 mg/dL)	‐	‐
Wali 2015	Not reported	‐	Not reported
Zangeneh 2014	< 5.3 mmol/L (95 mg/dL)	‐	< 6.7 mmol/L (120 mg/dL)
Zawiejska 2016	Not reported	‐	Not reported

Table 7. Treatment targets

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Table 8. Maternal outcomes

Study ID	Outcome	Insulin (A)	Comparison
Hickman 2013	Fasting blood glucose (mg/dL)	Median 85.2 (IQR 86, 115) (n = 8)	Metformin Median 89.5 (IQR 90, 98) (n = 10)
Coustan 1978	Fasting blood glucose (mg/dL)	86.8 ± 12.7 (n = 33 observations)	Diet 94.7 ± 9.1 (n = 14 observations)
Waheed 2013	Fasting blood glucose	30/34 women within treatment target	Metformin 27/34 women within treatment target
Hickman 2013	1‐hour postprandial blood glucose (mg/dL)	Median 125.3 (IQR 112, 138) (n = 8)	Metformin Median 122.3 (IQR 118, 130) (n = 10)
Coustan 1978	2‐hour postprandial blood glucose (mg/dL)	99.9 ± 27.6 (n = 32 observations)	102.6 ± 12.4 (n = 13 observations)
Hickman 2013	HbA1c (%)	Median 5.6 (IQR 5.3, 6.4) (n = 13)	Metformin Median 5.9 (IQR 5.5, 6.0) (n = 13)
Ismail 2007	HbA1c (%)	Human insulin Median 6.0 (IQR 1.20) (n = 30)	Neutral Protamine Hagedorn insulin Median 5.90 (IQR 0.80) (n = 31)
Waheed 2013	HbA1c (%)	27/34 women within treatment target	Metformin 28/34 women within treatment target
Hickman 2013	Gestational weight gain (kg)	Median 0.30 (IQR 0.18, 0.47) (n = 13)	Metformin Median 0.28 (IQR 0.11, 0.38) (n = 13)
Mecacci 2003	Gestational weight gain (kg)	Regular insulin ‐ Median 11.1 (range 8 to 14) (n = 24)	Insulin lispro ‐ Median 10.9 (range 7 to 17) (n = 25)
Riaz 2014	Glycaemic control	Insulin 56/100	Metformin 72/100
IQR: interquartile range

Table 8. Maternal outcomes

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Table 9. Neonatal outcomes

Study ID	Outcome	Insulin	Comparison
Hague 2003	Cord C‐peptide	Median 0.66 (range 0.45 to 1.71) pmol/mL (n = 14)	Metformin Median 0.53 (range 0.35 to 2.86) pmol/mL (n = 16)
Hague 2003	Duration in special care nursery	Median 24 (range 0 to 102) hours (n = 14)	Metformin Median 48 (range 0 to 360) hours (n = 16)
Niromanesh 2012	Duration of hospitalisation	Mean 2 days (range 1 to 4)	Metformin Mean 2 days (range 1 to 6)
Hickman 2013	Neonatal Cord C‐ peptide	Median 1.5 (IQR 1.1, 3.4) (n = 11)	Metformin Median 1.5 (IQR 0.9, 2.8) (n = 11)

Hickman 2013	Birthweight	Median 2986 (IQR 2822, 3630) (n = 14)	Metformin Median 3202 (IQR 3026, 3608) (n = 14)
Mecacci 2003	Gestational age at birth (weeks)	Regular insulin ‐ Median 40 (range 37 to 41) (n = 24)	Insulin lispro ‐ Median 40 (range 37 to 41) (n = 25)
Hickman 2013	Gestational age at birth (weeks)	Median 38 (IQR 36, 39) (n = 14)	Metformin Median 39 (IQR 37, 39) (n = 14)

		Insulin	Diet
Persson 1985	Gestational age at birth (days)	Median 277 (range 234 to 293) (n = 97)	Median 275 (range 234 to 297) (n = 105)
Persson 1985	Birthweight (g)	Median 3630 (range 1655 to 4830) (n = 97)	Median 3560 (range 2000 to 4700) (n = 105)
Persson 1985	Skinfold thickness triceps (mm) Skinfold thickness subscapular (mm)	Median 4.9 (range 3.3 to 9.4) (n = 97) Median 4.7 (range 3.1 to 7.4) (n = 97)	Median 5.1 (range 2.1 to 9.9) (n = 105) Median 4.9 (range 2.5 to 8.7) (n = 105)
IQR: interquartile range

Table 9. Neonatal outcomes

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Comparison 1. Insulin versus oral anti‐diabetic pharmacological therapy

Outcome or subgroup title	No. of studies	No. of participants	Statistical method	Effect size
1 Hypertensive disorders of pregnancy ‐ Pre‐eclampsia Show forest plot	10	2060	Risk Ratio (M‐H, Fixed, 95% CI)	1.14 [0.86, 1.52]

1.1 Glibenclamide	3	590	Risk Ratio (M‐H, Fixed, 95% CI)	1.11 [0.62, 2.00]
1.2 Metformin	7	1470	Risk Ratio (M‐H, Fixed, 95% CI)	1.15 [0.83, 1.60]
2 Hypertensive disorders of pregnancy ‐ not defined Show forest plot	4	1214	Risk Ratio (M‐H, Fixed, 95% CI)	1.89 [1.14, 3.12]

2.1 Glibenclamide	1	100	Risk Ratio (M‐H, Fixed, 95% CI)	2.0 [0.38, 10.43]
2.2 Metformin	3	1114	Risk Ratio (M‐H, Fixed, 95% CI)	1.88 [1.11, 3.18]
3 Caesarean section Show forest plot	17	1988	Risk Ratio (M‐H, Fixed, 95% CI)	1.03 [0.93, 1.14]

3.1 Glibenclamide	7	892	Risk Ratio (M‐H, Fixed, 95% CI)	1.09 [0.93, 1.28]
3.2 Metformin	9	995	Risk Ratio (M‐H, Fixed, 95% CI)	0.99 [0.87, 1.13]
3.3 Acarbose	1	33	Risk Ratio (M‐H, Fixed, 95% CI)	0.81 [0.39, 1.71]
3.4 Combined metformin‐glibenclamide	1	68	Risk Ratio (M‐H, Fixed, 95% CI)	0.94 [0.41, 2.15]
4 Development of type 2 diabetes Show forest plot	2	754	Risk Ratio (M‐H, Fixed, 95% CI)	1.39 [0.80, 2.44]

5 Perinatal (fetal and neonatal death) and later infant mortality Show forest plot	10	1463	Risk Ratio (M‐H, Fixed, 95% CI)	0.85 [0.29, 2.49]

5.1 Glibenclamide	5	668	Risk Ratio (M‐H, Fixed, 95% CI)	0.99 [0.25, 3.91]
5.2 Metformin	4	678	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
5.3 Acarbose	1	33	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
5.4 Combined metformin/glibenclamide	1	84	Risk Ratio (M‐H, Fixed, 95% CI)	0.67 [0.12, 3.79]
6 Large‐for‐gestational age Show forest plot	13	2352	Risk Ratio (M‐H, Random, 95% CI)	1.01 [0.76, 1.35]

6.1 Glibenclamide	5	651	Risk Ratio (M‐H, Random, 95% CI)	0.45 [0.19, 1.07]
6.2 Metformin	8	1668	Risk Ratio (M‐H, Random, 95% CI)	1.17 [0.94, 1.44]
6.3 Acarbose	1	33	Risk Ratio (M‐H, Random, 95% CI)	0.27 [0.01, 5.15]
7 Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy) Show forest plot	2	760	Risk Ratio (M‐H, Fixed, 95% CI)	1.03 [0.84, 1.26]

8 Neurosensory disability in later childhood (18 to 24 months) Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

8.1 Hearing impairment	1	93	Risk Ratio (M‐H, Fixed, 95% CI)	0.31 [0.01, 7.49]
8.2 Visual impairment	1	93	Risk Ratio (M‐H, Fixed, 95% CI)	0.31 [0.03, 2.90]
8.3 Any mild developmental delay	1	93	Risk Ratio (M‐H, Fixed, 95% CI)	1.07 [0.33, 3.44]
9 Use of additional pharmacotherapy Show forest plot	19	2761	Risk Ratio (M‐H, Fixed, 95% CI)	0.03 [0.02, 0.06]

9.1 Glibenclamide	7	893	Risk Ratio (M‐H, Fixed, 95% CI)	0.10 [0.03, 0.31]
9.2 Metformin	10	1676	Risk Ratio (M‐H, Fixed, 95% CI)	0.02 [0.01, 0.04]
9.3 Acarbose	2	124	Risk Ratio (M‐H, Fixed, 95% CI)	0.10 [0.01, 0.74]
9.4 Metformin/glibenclamide	1	68	Risk Ratio (M‐H, Fixed, 95% CI)	0.04 [0.00, 0.63]
10 Maternal hypoglycaemia Show forest plot	10	998	Risk Ratio (M‐H, Random, 95% CI)	3.01 [0.74, 12.27]

10.1 Glibenclamide	7	779	Risk Ratio (M‐H, Random, 95% CI)	2.80 [0.29, 26.99]
10.2 Metformin	3	186	Risk Ratio (M‐H, Random, 95% CI)	3.01 [0.91, 9.94]
10.3 Acarbose	1	33	Risk Ratio (M‐H, Random, 95% CI)	0.0 [0.0, 0.0]
11 Glycaemic control during/end treatment (fasting) Show forest plot	19	2812	Std. Mean Difference (IV, Random, 95% CI)	0.05 [‐0.09, 0.19]

11.1 Glibenclamide	9	1185	Std. Mean Difference (IV, Random, 95% CI)	0.03 [‐0.21, 0.27]
11.2 Metformin	8	1441	Std. Mean Difference (IV, Random, 95% CI)	0.03 [‐0.18, 0.24]
11.3 Combined metformin‐glyburide	1	68	Std. Mean Difference (IV, Random, 95% CI)	0.33 [‐0.15, 0.81]
11.4 Acarbose	2	118	Std. Mean Difference (IV, Random, 95% CI)	0.10 [‐0.60, 0.79]
12 Glycaemic control during/end treatment (postprandial) Show forest plot	18	2508	Std. Mean Difference (IV, Random, 95% CI)	0.12 [‐0.05, 0.29]

12.1 Glibenclamide	9	959	Std. Mean Difference (IV, Random, 95% CI)	0.00 [‐0.25, 0.26]
12.2 Metformin	7	1363	Std. Mean Difference (IV, Random, 95% CI)	0.33 [0.07, 0.59]
12.3 Combined metformin‐glyburide	1	68	Std. Mean Difference (IV, Random, 95% CI)	0.20 [‐0.28, 0.67]
12.4 Acarbose	2	118	Std. Mean Difference (IV, Random, 95% CI)	‐0.30 [‐0.67, 0.07]
13 Glycaemic control during/end of treatment (HbA1c) Show forest plot	9	1963	Std. Mean Difference (IV, Random, 95% CI)	0.01 [‐0.12, 0.15]

13.1 Glibenclamide	3	487	Std. Mean Difference (IV, Random, 95% CI)	0.04 [‐0.31, 0.39]
13.2 Metformin	5	1392	Std. Mean Difference (IV, Random, 95% CI)	0.05 [‐0.14, 0.24]
13.3 Combined metformin/glibenclamide	1	84	Std. Mean Difference (IV, Random, 95% CI)	‐0.13 [‐0.55, 0.30]
14 Weight gain in pregnancy Show forest plot	10	2336	Mean Difference (IV, Random, 95% CI)	1.06 [0.63, 1.48]

14.1 Glibenclamide	3	509	Mean Difference (IV, Random, 95% CI)	0.63 [‐0.42, 1.67]
14.2 Metformin	7	1794	Mean Difference (IV, Random, 95% CI)	1.11 [0.62, 1.61]
14.3 Acarbose	1	33	Mean Difference (IV, Random, 95% CI)	0.90 [‐1.56, 3.36]
15 Induction of labour Show forest plot	3		Risk Ratio (M‐H, Random, 95% CI)	Subtotals only

15.1 Metformin	3	348	Risk Ratio (M‐H, Random, 95% CI)	1.30 [0.96, 1.75]
16 Postpartum haemorrhage Show forest plot	2		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

16.1 Metformin	2	91	Risk Ratio (M‐H, Fixed, 95% CI)	0.34 [0.01, 8.13]
17 Breastfeeding at discharge, six weeks postpartum, six months or longer Show forest plot	2		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

17.1 Metformin	2	411	Risk Ratio (M‐H, Fixed, 95% CI)	1.03 [0.86, 1.23]
18 Relevant biomarker changes associated with the intervention Show forest plot	1		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

18.1 HOMA‐IR	1	78	Mean Difference (IV, Fixed, 95% CI)	0.0 [‐2.92, 2.92]
18.2 Total Cholesterol	1	78	Mean Difference (IV, Fixed, 95% CI)	0.10 [‐0.49, 0.69]
18.3 HDL Cholesterol	1	78	Mean Difference (IV, Fixed, 95% CI)	0.10 [‐0.13, 0.33]
18.4 Triglycerides	1	78	Mean Difference (IV, Fixed, 95% CI)	‐0.30 [‐0.68, 0.08]
19 Body mass index (BMI) Show forest plot	1	733	Mean Difference (IV, Fixed, 95% CI)	‐0.20 [‐1.29, 0.89]

19.1 Metformin	1	733	Mean Difference (IV, Fixed, 95% CI)	‐0.20 [‐1.29, 0.89]
20 Postnatal weight retention Show forest plot	1		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

20.1 Six to eight weeks postpartum	1	167	Mean Difference (IV, Fixed, 95% CI)	‐1.60 [‐6.34, 3.14]
20.2 One year postpartum	1	176	Mean Difference (IV, Fixed, 95% CI)	‐3.70 [‐8.50, 1.10]
21 Impaired glucose tolerance Show forest plot	3		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

21.1 six weeks postpartum	3	841	Risk Ratio (M‐H, Fixed, 95% CI)	1.16 [0.80, 1.68]
21.2 one year postpartum	1	179	Risk Ratio (M‐H, Fixed, 95% CI)	0.84 [0.56, 1.26]
22 Stillbirth Show forest plot	3	653	Risk Ratio (M‐H, Fixed, 95% CI)	0.60 [0.08, 4.52]

22.1 Glibenclamide	1	404	Risk Ratio (M‐H, Fixed, 95% CI)	0.99 [0.06, 15.72]
22.2 Metformin	2	249	Risk Ratio (M‐H, Fixed, 95% CI)	0.34 [0.01, 8.17]
23 Neonatal death Show forest plot	2		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

23.1 Glibenclamide	2	503	Risk Ratio (M‐H, Fixed, 95% CI)	0.99 [0.06, 15.72]
24 Macrosomia (> 4000 g) Show forest plot	19	2305	Risk Ratio (M‐H, Random, 95% CI)	1.17 [0.77, 1.78]

24.1 Glibenclamide	9	1186	Risk Ratio (M‐H, Random, 95% CI)	0.77 [0.31, 1.94]
24.2 Metformin	10	1086	Risk Ratio (M‐H, Random, 95% CI)	1.26 [0.88, 1.81]
24.3 Acarbose	1	33	Risk Ratio (M‐H, Random, 95% CI)	0.0 [0.0, 0.0]
25 Small‐for‐gestational age Show forest plot	9	1812	Risk Ratio (M‐H, Fixed, 95% CI)	1.16 [0.79, 1.69]

25.1 Glibenclamide	2	136	Risk Ratio (M‐H, Fixed, 95% CI)	0.84 [0.17, 4.20]
25.2 Metformin	7	1643	Risk Ratio (M‐H, Fixed, 95% CI)	1.15 [0.77, 1.71]
25.3 Acarbose	1	33	Risk Ratio (M‐H, Fixed, 95% CI)	4.0 [0.17, 91.48]
26 Birth trauma Show forest plot	12		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

26.1 Birth trauma not defined	5	1107	Risk Ratio (M‐H, Fixed, 95% CI)	1.04 [0.53, 2.03]
26.2 Shoulder dystocia	8	968	Risk Ratio (M‐H, Fixed, 95% CI)	1.44 [0.62, 3.34]
26.3 Clavicular fracture	2	196	Risk Ratio (M‐H, Fixed, 95% CI)	4.71 [0.23, 95.53]
26.4 Brachial nerve injury	2	320	Risk Ratio (M‐H, Fixed, 95% CI)	5.05 [0.24, 103.90]
27 Gestational age at birth Show forest plot	18	2834	Mean Difference (IV, Random, 95% CI)	‐0.01 [‐0.20, 0.18]

27.1 Glibenclamide	7	1025	Mean Difference (IV, Random, 95% CI)	‐0.21 [‐0.67, 0.26]
27.2 Metformin	8	1533	Mean Difference (IV, Random, 95% CI)	0.17 [0.04, 0.30]
27.3 Acarbose	2	124	Mean Difference (IV, Random, 95% CI)	‐0.01 [‐0.52, 0.49]
27.4 Combined metformin/glibenclamide	2	152	Mean Difference (IV, Random, 95% CI)	‐0.07 [‐0.56, 0.42]
28 Preterm birth (< 37 weeks) Show forest plot	11	2417	Risk Ratio (M‐H, Random, 95% CI)	1.10 [0.64, 1.88]

28.1 Glibenclamide	2	182	Risk Ratio (M‐H, Random, 95% CI)	0.94 [0.51, 1.74]
28.2 Metformin	9	2235	Risk Ratio (M‐H, Random, 95% CI)	1.18 [0.58, 2.39]
29 Congenital abnormality Show forest plot	15	2671	Risk Ratio (M‐H, Fixed, 95% CI)	1.35 [0.88, 2.08]

29.1 Glibenclamide	6	922	Risk Ratio (M‐H, Fixed, 95% CI)	1.13 [0.50, 2.54]
29.2 Metformin	7	1574	Risk Ratio (M‐H, Fixed, 95% CI)	1.40 [0.81, 2.41]
29.3 Acarbose	1	91	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
29.4 Combined metformin/glibenclamide	1	84	Risk Ratio (M‐H, Fixed, 95% CI)	2.0 [0.39, 10.34]
30 Five minute Apgar less than seven Show forest plot	4		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

30.1 Metformin	4	1170	Risk Ratio (M‐H, Fixed, 95% CI)	0.49 [0.09, 2.64]
31 Birthweight (g) Show forest plot	22	3183	Mean Difference (IV, Random, 95% CI)	‐20.14 [‐83.58, 43.29]

31.1 Glibenclamide	9	1116	Mean Difference (IV, Random, 95% CI)	‐75.73 [‐230.46, 78.99]
31.2 Metformin	10	1791	Mean Difference (IV, Random, 95% CI)	22.00 [‐33.67, 77.67]
31.3 Acarbose	2	124	Mean Difference (IV, Random, 95% CI)	22.17 [‐154.08, 198.42]
31.4 Combined metformin‐glyburide	2	152	Mean Difference (IV, Random, 95% CI)	‐46.17 [‐199.60, 107.26]
32 Head circumference (cm) at birth Show forest plot	3	975	Mean Difference (IV, Random, 95% CI)	0.14 [‐0.26, 0.53]

32.1 Glibenclamide	1	82	Mean Difference (IV, Random, 95% CI)	‐0.40 [‐1.08, 0.28]
32.2 Metformin	2	893	Mean Difference (IV, Random, 95% CI)	0.27 [‐0.12, 0.65]
33 Length (cm) at birth Show forest plot	3	975	Mean Difference (IV, Random, 95% CI)	0.11 [‐0.50, 0.71]

33.1 Glibenclamide	1	82	Mean Difference (IV, Random, 95% CI)	‐0.60 [‐1.64, 0.44]
33.2 Metformin	2	893	Mean Difference (IV, Random, 95% CI)	0.29 [‐0.38, 0.97]
34 Ponderal index at birth Show forest plot	2	815	Mean Difference (IV, Random, 95% CI)	0.03 [‐0.13, 0.19]

34.1 Glibenclamide	1	82	Mean Difference (IV, Random, 95% CI)	‐0.07 [‐0.22, 0.08]
34.2 Metformin	1	733	Mean Difference (IV, Random, 95% CI)	0.10 [0.06, 0.14]
35 Adiposity at birth (Triceps skinfold (mm)) Show forest plot	2	815	Mean Difference (IV, Fixed, 95% CI)	‐0.07 [‐0.25, 0.10]

35.1 Glibenclamide	1	82	Mean Difference (IV, Fixed, 95% CI)	0.0 [‐0.35, 0.35]
35.2 Metformin	1	733	Mean Difference (IV, Fixed, 95% CI)	‐0.10 [‐0.31, 0.11]
36 Adiposity at birth (Subscapular skinfold (mm)) Show forest plot	2	815	Mean Difference (IV, Random, 95% CI)	‐0.13 [‐0.50, 0.24]

36.1 Glibenclamide	1	82	Mean Difference (IV, Random, 95% CI)	‐0.40 [‐0.90, 0.10]
36.2 Metformin	1	733	Mean Difference (IV, Random, 95% CI)	0.0 [‐0.20, 0.20]
37 Adiposity at birth (Skin fold sum (mm)) Show forest plot	1	82	Mean Difference (IV, Fixed, 95% CI)	‐0.80 [‐2.33, 0.73]

38 Adiposity at birth (Percentage fat mass) Show forest plot	1	82	Mean Difference (IV, Fixed, 95% CI)	‐1.60 [‐3.77, 0.57]

39 Neonatal hypoglycaemia Show forest plot	24	3892	Risk Ratio (M‐H, Random, 95% CI)	1.14 [0.85, 1.52]

39.1 Glibenclamide	10	1283	Risk Ratio (M‐H, Random, 95% CI)	0.70 [0.41, 1.19]
39.2 Metformin	12	2424	Risk Ratio (M‐H, Random, 95% CI)	1.58 [1.16, 2.16]
39.3 Acarbose	1	33	Risk Ratio (M‐H, Random, 95% CI)	0.44 [0.02, 10.16]
39.4 Combined hypoglycaemia	2	152	Risk Ratio (M‐H, Random, 95% CI)	0.76 [0.49, 1.18]
40 Respiratory distress syndrome Show forest plot	10	1894	Risk Ratio (M‐H, Fixed, 95% CI)	1.29 [0.83, 1.99]

40.1 Glibenclamide	3	409	Risk Ratio (M‐H, Fixed, 95% CI)	1.32 [0.45, 3.91]
40.2 Metformin	7	1485	Risk Ratio (M‐H, Fixed, 95% CI)	1.28 [0.80, 2.06]
41 Neonatal jaundice (hyperbilirubinaemia) Show forest plot	16	2183	Risk Ratio (M‐H, Fixed, 95% CI)	0.99 [0.83, 1.19]

41.1 Glibenclamide	6	999	Risk Ratio (M‐H, Fixed, 95% CI)	0.79 [0.61, 1.02]
41.2 Metformin	9	1100	Risk Ratio (M‐H, Fixed, 95% CI)	1.18 [0.89, 1.56]
41.3 Combined metformin/glibenclamide	1	84	Risk Ratio (M‐H, Fixed, 95% CI)	1.11 [0.69, 1.78]
42 Hypocalcaemia Show forest plot	5		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

42.1 Glibenclamide	5	939	Risk Ratio (M‐H, Fixed, 95% CI)	1.95 [0.49, 7.78]
43 Polycythaemia Show forest plot	3		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

43.1 Glibenclamide	3	590	Risk Ratio (M‐H, Fixed, 95% CI)	1.16 [0.38, 3.57]
44 Relevant biomarker changes associated with the intervention (Cord blood C‐peptide) Show forest plot	1	59	Mean Difference (IV, Fixed, 95% CI)	‐0.20 [‐0.82, 0.42]

44.1 Glibenclamide	1	59	Mean Difference (IV, Fixed, 95% CI)	‐0.20 [‐0.82, 0.42]
45 Relevant biomarker changes associated with the intervention (Cord blood insulin) Show forest plot	3		Std. Mean Difference (IV, Fixed, 95% CI)	Subtotals only

45.1 Glibenclamide	3	486	Std. Mean Difference (IV, Fixed, 95% CI)	0.03 [‐0.15, 0.21]
46 Childhood weight (kg) Show forest plot	2		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

46.1 6 months	1	93	Mean Difference (IV, Fixed, 95% CI)	‐0.35 [‐0.75, 0.05]
46.2 12 months	1	93	Mean Difference (IV, Fixed, 95% CI)	‐0.62 [‐1.18, ‐0.06]
46.3 18 months to 2 years	2	411	Mean Difference (IV, Fixed, 95% CI)	‐0.44 [‐0.83, ‐0.05]
47 Childhood height (cm) Show forest plot	2		Mean Difference (IV, Random, 95% CI)	Subtotals only

47.1 6 months	1	93	Mean Difference (IV, Random, 95% CI)	‐0.70 [‐2.05, 0.65]
47.2 12 months	1	93	Mean Difference (IV, Random, 95% CI)	‐1.30 [‐2.60, 0.00]
47.3 18 to 24 months	2	411	Mean Difference (IV, Random, 95% CI)	‐0.65 [‐2.61, 1.31]
48 Childhood adiposity (ponderal index (kg/m³)) Show forest plot	1		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

48.1 6 months	1	93	Mean Difference (IV, Fixed, 95% CI)	‐1.0 [‐3.43, 1.43]
48.2 12 months	1	93	Mean Difference (IV, Fixed, 95% CI)	‐0.20 [‐1.12, 0.72]
48.3 18 months to 2 years	1	93	Mean Difference (IV, Fixed, 95% CI)	‐0.10 [‐0.88, 0.68]
49 Childhood adiposity (Total fat mass (%)) Show forest plot	1		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

49.1 Metformin	1	318	Mean Difference (IV, Fixed, 95% CI)	0.5 [‐0.49, 1.49]
50 Childhood blood pressure (2 years) Show forest plot	1		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

50.1 Systolic BP	1	170	Mean Difference (IV, Fixed, 95% CI)	‐2.24 [‐5.02, 0.54]
50.2 Diastolic BP	1	170	Mean Difference (IV, Fixed, 95% CI)	‐0.5 [‐16.75, 15.75]
51 Number of antenatal visits or admissions Show forest plot	1		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

51.1 Glibenclamide	1	404	Mean Difference (IV, Fixed, 95% CI)	1.0 [‐0.08, 2.08]
52 Admission to neonatal care unit/nursery Show forest plot	18	3441	Risk Ratio (M‐H, Fixed, 95% CI)	1.38 [1.19, 1.59]

52.1 Glibenclamide	7	1018	Risk Ratio (M‐H, Fixed, 95% CI)	1.19 [0.74, 1.92]
52.2 Metformin	10	2306	Risk Ratio (M‐H, Fixed, 95% CI)	1.44 [1.22, 1.71]
52.3 Acarbose	1	33	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
52.4 Combined metformin/glibenclamide	1	84	Risk Ratio (M‐H, Fixed, 95% CI)	1.12 [0.82, 1.52]
53 Duration of stay in neonatal intensive care unit or special care baby unit Show forest plot	3	401	Mean Difference (IV, Random, 95% CI)	‐0.20 [‐1.79, 1.39]

Comparison 1. Insulin versus oral anti‐diabetic pharmacological therapy

Ir a la tabla de la revisión

Comparison 2. One insulin versus another insulin

Outcome or subgroup title	No. of studies	No. of participants	Statistical method	Effect size
1 Hypertensive disorders of pregnancy ‐ Pre‐eclampsia Show forest plot	1	320	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

1.1 Insulin aspart	1	320	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
2 Caesarean section Show forest plot	3	410	Risk Ratio (M‐H, Fixed, 95% CI)	1.00 [0.91, 1.09]

2.1 Insulin aspart	1	320	Risk Ratio (M‐H, Fixed, 95% CI)	1.02 [0.94, 1.10]
2.2 Insulin lispro	2	90	Risk Ratio (M‐H, Fixed, 95% CI)	0.81 [0.42, 1.56]
3 Large‐for‐gestational age Show forest plot	3	411	Risk Ratio (M‐H, Fixed, 95% CI)	1.21 [0.58, 2.55]

3.1 Insulin aspart	1	320	Risk Ratio (M‐H, Fixed, 95% CI)	1.14 [0.50, 2.61]
3.2 Insulin lispro	2	91	Risk Ratio (M‐H, Fixed, 95% CI)	1.56 [0.29, 8.55]
4 Use of additional pharmacotherapy Show forest plot	3	168	Risk Ratio (M‐H, Random, 95% CI)	1.11 [0.72, 1.70]

4.1 Insulin aspart	1	47	Risk Ratio (M‐H, Random, 95% CI)	1.33 [0.83, 2.14]
4.2 Insulin lispro	2	98	Risk Ratio (M‐H, Random, 95% CI)	1.38 [0.90, 2.09]
4.3 NPH	1	23	Risk Ratio (M‐H, Random, 95% CI)	0.65 [0.36, 1.19]
5 Maternal hypoglycaemia Show forest plot	4	504	Risk Ratio (M‐H, Fixed, 95% CI)	0.96 [0.64, 1.44]

5.1 Insulin aspart	3	394	Risk Ratio (M‐H, Fixed, 95% CI)	0.90 [0.59, 1.35]
5.2 Insulin lispro	1	49	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
5.3 NPH	1	61	Risk Ratio (M‐H, Fixed, 95% CI)	5.16 [0.26, 103.25]
6 Glycaemic control during/end of treatment (HbA1c) end of treatment Show forest plot	3	411	Mean Difference (IV, Random, 95% CI)	0.04 [‐0.06, 0.14]

6.1 Insulin aspart	1	320	Mean Difference (IV, Random, 95% CI)	0.14 [‐0.01, 0.29]
6.2 Insulin lispro	2	91	Mean Difference (IV, Random, 95% CI)	0.00 [‐0.12, 0.12]
7 Glycaemic control during/end of treatment (Fasting plasma glucose) Show forest plot	4	466	Mean Difference (IV, Fixed, 95% CI)	0.15 [‐2.02, 2.32]

7.1 Insulin aspart	2	330	Mean Difference (IV, Fixed, 95% CI)	2.05 [‐1.53, 5.63]
7.2 insulin lispro	1	49	Mean Difference (IV, Fixed, 95% CI)	‐1.80 [‐6.84, 3.24]
7.3 Insulin detemir	1	87	Mean Difference (IV, Fixed, 95% CI)	‐0.60 [‐3.85, 2.65]
8 Glycaemic control during/end of treatment (Postprandial glucose) Show forest plot	5	562	Std. Mean Difference (IV, Random, 95% CI)	0.08 [‐0.25, 0.42]

8.1 Insulin aspart	3	377	Std. Mean Difference (IV, Random, 95% CI)	0.10 [‐0.46, 0.65]
8.2 Insulin lispro	2	98	Std. Mean Difference (IV, Random, 95% CI)	0.22 [‐0.87, 1.30]
8.3 Insulin detemir	1	87	Std. Mean Difference (IV, Random, 95% CI)	‐0.14 [‐0.56, 0.29]
9 Weight gain in pregnancy Show forest plot	2	407	Mean Difference (IV, Fixed, 95% CI)	0.46 [‐0.15, 1.07]

9.1 Insulin aspart	1	320	Mean Difference (IV, Fixed, 95% CI)	0.47 [‐0.15, 1.09]
9.2 NPH	1	87	Mean Difference (IV, Fixed, 95% CI)	0.10 [‐3.48, 3.68]
10 Maternal mortality Show forest plot	1	61	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

10.1 NPH	1	61	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
11 Fetal death Show forest plot	4	508	Risk Ratio (M‐H, Fixed, 95% CI)	0.36 [0.02, 8.06]

11.1 Insulin aspart	3	447	Risk Ratio (M‐H, Fixed, 95% CI)	0.36 [0.02, 8.06]
11.2 NPH	1	61	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
12 Macrosomia Show forest plot	6	627	Risk Ratio (M‐H, Random, 95% CI)	0.99 [0.40, 2.46]

12.1 Insulin aspart	4	494	Risk Ratio (M‐H, Random, 95% CI)	1.47 [0.71, 3.05]
12.2 Insulin lispro	1	49	Risk Ratio (M‐H, Random, 95% CI)	1.03 [0.21, 5.05]
12.3 NPH	2	84	Risk Ratio (M‐H, Random, 95% CI)	0.11 [0.01, 0.79]
13 Small‐for‐gestational age Show forest plot	1	49	Risk Ratio (M‐H, Fixed, 95% CI)	1.04 [0.07, 15.73]

13.1 Insulin lispro	1	49	Risk Ratio (M‐H, Fixed, 95% CI)	1.04 [0.07, 15.73]
14 Birth trauma (Nerve palsy) Show forest plot	1	23	Risk Ratio (M‐H, Fixed, 95% CI)	0.36 [0.02, 8.04]

14.1 NPH	1	23	Risk Ratio (M‐H, Fixed, 95% CI)	0.36 [0.02, 8.04]
15 Gestational age at birth Show forest plot	2		Mean Difference (IV, Random, 95% CI)	Subtotals only

15.1 Insulin aspart	1	320	Mean Difference (IV, Random, 95% CI)	‐0.67 [‐1.01, ‐0.33]
15.2 Insulin lispro	1	41	Mean Difference (IV, Random, 95% CI)	0.0 [‐0.16, 0.16]
16 Preterm birth (< 37 weeks) Show forest plot	3	443	Risk Ratio (M‐H, Fixed, 95% CI)	2.29 [0.52, 10.05]

16.1 Insulin aspart	2	420	Risk Ratio (M‐H, Fixed, 95% CI)	3.06 [0.49, 19.29]
16.2 NPH	1	23	Risk Ratio (M‐H, Fixed, 95% CI)	1.09 [0.08, 15.41]
17 Congenital anomaly Show forest plot	2	69	Risk Ratio (M‐H, Fixed, 95% CI)	3.21 [0.14, 72.55]

17.1 Insulin aspart	1	27	Risk Ratio (M‐H, Fixed, 95% CI)	3.21 [0.14, 72.55]
17.2 Insulin lispro	1	42	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
18 Birthweight (kg) Show forest plot	7	531	Mean Difference (IV, Random, 95% CI)	‐0.04 [‐0.17, 0.08]

18.1 Insulin aspart	3	357	Mean Difference (IV, Random, 95% CI)	‐0.01 [‐0.11, 0.09]
18.2 Insulin lispro	2	90	Mean Difference (IV, Random, 95% CI)	0.04 [‐0.07, 0.14]
18.3 NPH	2	84	Mean Difference (IV, Random, 95% CI)	‐0.44 [‐1.20, 0.32]
19 Length at birth (cm) Show forest plot	3	388	Mean Difference (IV, Fixed, 95% CI)	‐0.11 [‐0.57, 0.34]

19.1 Insulin aspart	2	347	Mean Difference (IV, Fixed, 95% CI)	‐0.08 [‐0.58, 0.42]
19.2 Insulin lispro	1	41	Mean Difference (IV, Fixed, 95% CI)	‐0.30 [‐1.45, 0.85]
20 Ponderal Index kg/m3 Show forest plot	2	369	Mean Difference (IV, Fixed, 95% CI)	0.03 [‐0.06, 0.12]

20.1 Insulin aspart	1	320	Mean Difference (IV, Fixed, 95% CI)	‐0.10 [‐1.01, 0.81]
20.2 Insulin lispro	1	49	Mean Difference (IV, Fixed, 95% CI)	0.03 [‐0.06, 0.12]
21 Neonatal hypoglycaemia Show forest plot	3	165	Risk Ratio (M‐H, Random, 95% CI)	2.28 [0.06, 82.02]

21.1 Insulin aspart	1	100	Risk Ratio (M‐H, Random, 95% CI)	13.0 [0.75, 224.77]
21.2 Insulin lispro	1	42	Risk Ratio (M‐H, Random, 95% CI)	0.0 [0.0, 0.0]
21.3 NPH	1	23	Risk Ratio (M‐H, Random, 95% CI)	0.36 [0.02, 8.04]
22 Respiratory distress Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

22.1 Insulin aspart	1	320	Risk Ratio (M‐H, Fixed, 95% CI)	0.52 [0.10, 2.79]
23 Neonatal jaundice (hyperbilirubinaemia) Show forest plot	2	123	Risk Ratio (M‐H, Random, 95% CI)	0.48 [0.05, 4.93]

23.1 Insulin aspart	1	100	Risk Ratio (M‐H, Random, 95% CI)	0.11 [0.01, 2.01]
23.2 NPH	1	23	Risk Ratio (M‐H, Random, 95% CI)	1.09 [0.28, 4.32]
24 Hypocalcaemia Show forest plot	1	42	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

24.1 Insulin lispro	1	42	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

Comparison 2. One insulin versus another insulin

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Comparison 3. Insulin versus diet/standard care

Outcome or subgroup title	No. of studies	No. of participants	Statistical method	Effect size
1 Caesarean section Show forest plot	2	133	Risk Ratio (M‐H, Fixed, 95% CI)	0.85 [0.50, 1.42]

2 Development of type 2 diabetes Show forest plot	2	653	Risk Ratio (M‐H, Fixed, 95% CI)	0.98 [0.79, 1.21]

3 Perinatal (fetal and neonatal death) and later infant mortality Show forest plot	4	1137	Risk Ratio (M‐H, Fixed, 95% CI)	0.74 [0.41, 1.33]

4 Large‐for‐gestational age Show forest plot	1	202	Risk Ratio (M‐H, Fixed, 95% CI)	0.85 [0.41, 1.78]

5 Use of additional pharmacotherapy Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Totals not selected

6 Maternal hypoglycaemia Show forest plot	1	95	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

7 Glycaemic control during/end of treatment Show forest plot	2		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

7.1 HbA1c	1	161	Mean Difference (IV, Fixed, 95% CI)	0.10 [0.04, 0.16]
7.2 Fasting blood glucose	1	68	Mean Difference (IV, Fixed, 95% CI)	1.60 [‐2.97, 6.17]
7.3 Postprandial blood glucose	1	68	Mean Difference (IV, Fixed, 95% CI)	0.30 [‐5.32, 5.92]
8 Weight gain in pregnancy Show forest plot	1	38	Mean Difference (IV, Fixed, 95% CI)	1.73 [‐3.31, 6.77]

9 Neonatal death Show forest plot	1	611	Risk Ratio (M‐H, Fixed, 95% CI)	0.72 [0.23, 2.23]

10 Macrosomia Show forest plot	3	717	Risk Ratio (M‐H, Fixed, 95% CI)	0.30 [0.18, 0.50]

11 Small‐for‐gestational age Show forest plot	2	240	Risk Ratio (M‐H, Fixed, 95% CI)	0.35 [0.05, 2.40]

12 Birth trauma Show forest plot	2		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

12.1 Shoulder dystocia	2	133	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
12.2 Nerve palsy	1	38	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]
13 Gestational age at birth Show forest plot	2	106	Mean Difference (IV, Fixed, 95% CI)	‐0.66 [‐1.37, 0.06]

14 Preterm birth (less than 37 weeks' gestation) Show forest plot	1	611	Risk Ratio (M‐H, Fixed, 95% CI)	1.09 [0.64, 1.85]

15 Birthweight Show forest plot	2	106	Mean Difference (IV, Fixed, 95% CI)	‐342.85 [‐561.11, ‐124.60]

16 Ponderal Index Show forest plot	1	68	Mean Difference (IV, Fixed, 95% CI)	‐0.18 [‐0.34, ‐0.02]

17 Neonatal hypoglycaemia Show forest plot	3	176	Risk Ratio (M‐H, Random, 95% CI)	0.88 [0.34, 2.24]

18 Neonatal jaundice (Hyperbilirubinaemia) Show forest plot	1	68	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

19 Hypocalcaemia Show forest plot	1	68	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

20 Polycythaemia Show forest plot	1	70	Risk Ratio (M‐H, Fixed, 95% CI)	0.9 [0.30, 2.67]

21 Relevant biomarker changes associated with the intervention (Cord C‐peptide) Show forest plot	1	202	Mean Difference (IV, Fixed, 95% CI)	0.03 [0.02, 0.04]

Comparison 3. Insulin versus diet/standard care

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Comparison 4. Insulin versus exercise

Outcome or subgroup title	No. of studies	No. of participants	Statistical method	Effect size
1 Caesarean section Show forest plot	1	34	Risk Ratio (M‐H, Fixed, 95% CI)	1.5 [0.29, 7.87]

2 Macrosomia Show forest plot	1	34	Risk Ratio (M‐H, Fixed, 95% CI)	2.0 [0.42, 9.50]

3 Gestational age at birth Show forest plot	1	34	Mean Difference (IV, Fixed, 95% CI)	‐0.80 [‐2.05, 0.45]

4 Birthweight (g) Show forest plot	1	34	Mean Difference (IV, Fixed, 95% CI)	103.0 [‐245.40, 451.40]

5 Length at birth (cm) Show forest plot	1	34	Mean Difference (IV, Fixed, 95% CI)	1.60 [‐0.01, 3.21]

6 Neonatal hypoglycaemia Show forest plot	1	34	Risk Ratio (M‐H, Fixed, 95% CI)	0.5 [0.05, 5.01]

7 Respiratory distress syndrome Show forest plot	1	34	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

8 Neonatal jaundice (Hyperbilirubinaemia) Show forest plot	1	34	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

9 Hypocalcaemia Show forest plot	1	34	Risk Ratio (M‐H, Fixed, 95% CI)	0.0 [0.0, 0.0]

Comparison 4. Insulin versus exercise

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Comparison 5. Regimen A versus regimen B

Outcome or subgroup title	No. of studies	No. of participants	Statistical method	Effect size
1 Hypertensive disorders of pregnancy ‐ Pregnancy‐induced hypertension Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

1.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	1.11 [0.51, 2.42]
2 Caesarean section Show forest plot	2		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

2.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	0.99 [0.68, 1.44]
2.2 Three injections versus six injections	1	37	Risk Ratio (M‐H, Fixed, 95% CI)	1.06 [0.17, 6.72]
3 Perinatal (fetal and neonatal death) and later infant mortality Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

3.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	3.04 [0.13, 74.07]
4 Large‐for‐gestational age Show forest plot	2		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

4.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	1.16 [0.79, 1.69]
4.2 Three injections versus six injections	1	37	Risk Ratio (M‐H, Fixed, 95% CI)	0.35 [0.04, 3.08]
5 Death or serious morbidity composite (variously defined by trials, e.g. perinatal or infant death, shoulder dystocia, bone fracture or nerve palsy) Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

5.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	1.69 [1.08, 2.64]
6 Maternal hypoglycaemia Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

6.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	1.01 [0.06, 16.06]
7 Glycaemic control during/end of treatment (Fasting) Show forest plot	1	37	Mean Difference (IV, Fixed, 95% CI)	4.0 [‐0.84, 8.84]

7.1 Three injections versus six injections	1	37	Mean Difference (IV, Fixed, 95% CI)	4.0 [‐0.84, 8.84]
8 Glycaemic control during/end of treatment (HbA1c) Show forest plot	2		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

8.1 Twice v four times daily	1	274	Mean Difference (IV, Fixed, 95% CI)	0.30 [0.06, 0.54]
8.2 Three injections versus six injections	1	37	Mean Difference (IV, Fixed, 95% CI)	‐0.10 [‐0.29, 0.09]
9 Weight gain in pregnancy Show forest plot	1		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

9.1 Twice v four times daily	1	274	Mean Difference (IV, Fixed, 95% CI)	0.70 [‐0.14, 1.54]
10 Macrosomia Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

10.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	1.20 [0.72, 2.01]
11 Small‐for‐gestational age Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

11.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	1.78 [0.53, 5.93]
12 Birth trauma Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

12.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	1.52 [0.26, 8.97]
13 Gestational age at birth Show forest plot	1	274	Mean Difference (IV, Fixed, 95% CI)	‐0.30 [‐0.72, 0.12]

13.1 Twice v four times daily	1	274	Mean Difference (IV, Fixed, 95% CI)	‐0.30 [‐0.72, 0.12]
14 Five‐minute Apgar less than 7 Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

14.1 twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	0.34 [0.07, 1.65]
15 Birthweight (g) Show forest plot	2		Mean Difference (IV, Fixed, 95% CI)	Subtotals only

15.1 Twice v four times daily	1	274	Mean Difference (IV, Fixed, 95% CI)	‐1.0 [‐150.49, 148.49]
15.2 Three injections versus six injections	1	37	Mean Difference (IV, Fixed, 95% CI)	‐197.0 [‐495.43, 101.43]
16 Neonatal hypoglycaemia Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

16.1 Twice daily v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	8.12 [1.03, 64.03]
17 Respiratory distress syndrome Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

17.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	0.34 [0.01, 8.23]
18 Neonatal jaundice (Hyperbilirubinaemia) Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

18.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	1.96 [1.10, 3.49]
19 Polycythaemia Show forest plot	1		Risk Ratio (M‐H, Fixed, 95% CI)	Subtotals only

19.1 Twice v four times daily	1	274	Risk Ratio (M‐H, Fixed, 95% CI)	0.43 [0.11, 1.65]

Comparison 5. Regimen A versus regimen B

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چکیده

پیشینه

اهداف

روش‌های جست‌وجو

معیارهای انتخاب

گردآوری و تجزیه‌وتحلیل داده‌ها

نتایج اصلی

نتیجه‌گیری‌های نویسندگان

PICO

PICO

Population

Intervention

Comparison

Outcome

خلاصه به زبان ساده

نقش انسولین در درمان زنان مبتلا به دیابت بارداری

Resumen visual

Authors' conclusions

Implications for practice

Implications for research

Summary of findings

Background

Description of the condition

Screening and diagnosis of GDM

Pathophysiology of GDM

Risk factors associated with GDM

Clinical outcomes for women with pregnancy hyperglycaemia

Neonatal, infant and later outcomes related to pregnancy hyperglycaemia

Description of the intervention

Types of insulin used during pregnancy

Rapid‐acting insulin

Short‐acting insulin

Intermediate‐acting insulin

Long‐acting insulin

Other formulations of insulin

Insulin regimens

How the intervention might work

Why it is important to do this review

Objectives

Methods

Criteria for considering studies for this review

Types of studies

Types of participants

Types of interventions

Types of outcome measures

Primary outcomes

Maternal

Neonatal

Secondary outcomes

Maternal

Long‐term outcomes for mother

Fetal/neonatal outcomes

Later infant/childhood outcomes

Child as an adult outcomes

Health service use

Search methods for identification of studies

Electronic searches

Searching other resources

Data collection and analysis

Selection of studies

Data extraction and management

Assessment of risk of bias in included studies

(1) Random sequence generation (checking for possible selection bias)

(2) Allocation concealment (checking for possible selection bias)

(3.1) Blinding of participants and personnel (checking for possible performance bias)

(3.2) Blinding of outcome assessment (checking for possible detection bias)

(4) Incomplete outcome data (checking for possible attrition bias due to the amount, nature and handling of incomplete outcome data)

(5) Selective reporting (checking for reporting bias)

(6) Other bias (checking for bias due to problems not covered by (1) to (5) above)

(7) Overall risk of bias

Assessing the quality of the body of evidence using the GRADE approach

Measures of treatment effect

Dichotomous data

Continuous data

Unit of analysis issues

Cluster‐randomised trials

Other unit of analysis issues

Multiple pregnancy