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Parathyroidectomy for adults with primary hyperparathyroidism

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Abstract

This is a protocol for a Cochrane Review (Intervention). The objectives are as follows:

To assess the effects of parathyroidectomy for adults with PHPT. We will also compare the effects of different types of parathyroidectomy on people with PHPT.

Background

Description of the condition

Primary hyperparathyroidism

(PHPT) is an endocrine disorder that affects approximately 1% of the adult population, and is the third most common endocrine disorder after diabetes mellitus and hypothyroidism (Best 2017). Incidence of the disease increases in older age groups, with the highest prevalence being about 2% in postmenopausal women in the USA (Ning 2009). The disease is caused by a benign parathyroid adenoma in approximately 80% of cases, as a consequence of multigland disorder (multiple adenomas or multigland hyperplasia) in 15% to 20% of cases, or, in rare cases, a parathyroid carcinoma (Bilezikian 2017). Usually PHPT is associated with hypercalcaemia, elevated or high normal parathyroid hormone (PTH) levels, hypercalciuria, renal stones and bone demineralisation that results in osteopenia or osteoporosis. Although most people with the disease remain asymptomatic prior to the diagnosis with only mild disease, some people may present with symptomatic hypercalcaemia, dehydration leading to acute kidney injury, fragility fractures from osteoporosis, hypertension or chronic kidney disease that prompts clinicians to investigate for PHPT. Elevated PTH levels result in increased bone turnover and skeletal demineralisation. Increased bone turnover leads on to gradual loss of cortical bone mineral density with relative sparing of trabecular bones, and results in predominant osteopenia or osteoporosis of the lumbar spine, neck of femur and forearm bones (Khan 2017; Silverberg 2014). This bone mineral density loss can lead to bone fractures of these sites even with minimal trauma (fragility fractures) which increases morbidity and premature mortality risk, especially in older people with the disease. Alterations in calcium metabolism and bone turnover result in hypercalcaemia, hypercalciuria and nephrolithiasis in a significant proportion of people with PHPT. Recent data suggest a prevalence of renal stone disease in 10% to 20% of individuals with PHPT (Cipriani 2015; Verdelli 2017). Furthermore, hypertension is found in 40% to 65% of people with PHPT, which increases the risk of cardiovascular morbidity and premature mortality (Pepe 2017). PHPT has also been associated with psychoneurological and cognitive dysfunction (Kreidieh 2013; Trombetti 2016). In a proportion of individuals with PHPT serum calcium levels may be consistently in the normal laboratory range and these cases constitute normocalcaemic PHPT. The metabolic and end organ complications in these individuals may be similar to those with classical PHPT (Yener 2016). Overall, PHPT is associated with excess morbidity risk and higher risk of premature mortality.

Description of the intervention

Surgical removal of abnormal parathyroid tissue (parathyroidectomy) is the optimal treatment for people with proven PHPT. Operative removal of the diseased parathyroid gland(s) removes the source of excess PTH production, and thereby cures the disease in most individuals (Kreidieh 2013). International consensus recommends that all people with symptomatic PHPT should be considered for parathyroidectomy, and identifies parathyroidectomy as an effective treatment to improve end organ complications, such as abnormal bone mineral density, renal stone disease and renal functions, and potentially cardiovascular outcomes and neurocognitive functions (Silverberg 2014). This consensus also recommends parathyroidectomy for the following groups with PHPT.

  • People who develop the disease before the age of 50 years.

  • Serum calcium levels greater than 1 mg/dL (0.25 mmol/L) of the upper limit of normal laboratory reference range.

  • Bone mineral density T‐score of −2.5 or more at lumbar spine, femoral neck, total hip or distal 1/3rd of radius for postmenopausal women or males greater than 50 years.

  • Low trauma fragility fracture.

  • A glomerular filtration rate of less than 60 mL/min, renal stones, nephrocalcinosis or high risk for renal stone formation in those with urine calcium of more than 400 mg/day.

Parathyroidectomy is also associated with improvements in functional capacity and health‐related quality of life even in asymptomatic individuals with PHPT (Ambrogini 2007; Morris 2010).

Surgeons employ different techniques for parathyroidectomy depending on the type of involvement of the parathyroid glands. All individuals with the diagnosis of PHPT should be evaluated by parathyroid imaging studies in the attempt to localise the disease pathology in one or more of the parathyroid glands before considering surgical intervention. This approach enables the surgeons to decide the optimal surgical approach for parathyroidectomy. Localisation studies to identify the diseased parathyroid gland(s) include ultrasonography, nuclear medicine‐based parathyroid scintigraphy, and multiphase or four‐dimensional computed tomography (Kuzminski 2018). Minimally invasive parathyroidectomy is the ideal treatment option for patients with a well localised disease identified by preoperative parathyroid imaging (Khan 2017). Open surgery by parathyroid exploration becomes necessary among patients with non‐localisation of adenoma(s) in parathyroid imaging. Although dependent on the surgical expertise, both focused, image‐guided, minimally invasive parathyroidectomy and bilateral neck exploration can achieve high cure rates in people with PHPT (Wilhelm 2016).

Minimally invasive parathyroidectomy

Common approaches for minimally invasive parathyroidectomy involve open focal mini‐incision (70% of cases), video‐assisted approach (˜20% of cases) or total endoscopic approach (˜10% of cases), depending on clinical situation and the surgeons’ ability to perform the technique (Brunaud 2016; Taieb 2013). Gagner 1996 first described total endoscopic parathyroidectomy with subsequent refinements of the technique to the current day surgical practice. Video‐assisted parathyroidectomy, first described in 1997 (Miccoli 1997), is also performed partially with the help of an endoscope but does not use gas to view the surgical field as in the other techniques. An extra‐cervical endoscopic approach that avoids a neck scar, through the chest wall, breast, oral cavity, retro‐auricular region and axilla, is also occasionally used for minimally invasive parathyroidectomy. Robotic parathyroidectomy that places a computer interface between patient and surgeon to optimise the feasibility and quality of surgery is a new approach in minimally invasive parathyroidectomy (Garas 2015). Intraoperative PTH monitoring helps the surgeons to verify successful surgery during minimally invasive parathyroidectomy. Intraoperative PTH monitoring involves measurement of PTH, generally through peripheral veins, pre‐incision, pre‐gland ligation, and at 5, 10 and 20 minutes postgland ligation during the minimally invasive parathyroidectomy. A reduction in PTH level of more than 50 % from the highest baseline value at 10 minutes postgland ligation is generally considered as evidence for adequate gland excision (Barczynski 2009). Intraoperative PTH monitoring has been recently reported to help prediction of successful parathyroidectomy with very high precision, and also to identify multiglandular disease and parathyroid cancer (Dobrinja 2017).

Bilateral neck exploration for parathyroidectomy

Until the late 1970s bilateral neck exploration surgical technique was the standard approach for parathyroidectomy in people with PHPT, which was successful in about 97% of cases and with reported complication rates of 1% to 2% (Brunaud 2016). The surgery involves exploration of all the four parathyroid glands to locate the abnormal gland (the adenoma) usually under general anaesthesia with a large neck incision. Bilateral neck exploration is now utilised only when preoperative localisation of the adenoma is not possible, in case of discordant localisation studies in parathyroid imaging, familial or genetic disorders of PHPT, and concomitant thyroid disease. The procedure may also be performed by a minimal incision or video‐assisted endoscopic approach (Alesina 2013; Kreidieh 2013).

Adverse effects of the intervention

In general, parathyroidectomy is associated with low rates of surgical and postoperative complications. A recent systematic review of 82 observational studies and sic randomised controlled trials (RCTs) at moderate risk of bias concluded that minimally invasive parathyroidectomy and bilateral neck exploration are both effective techniques for parathyroidectomy in the treatment of PHPT, with the safety profile of minimally invasive parathyroidectomy being slightly superior to bilateral neck exploration (Singh 2016a). This publication also revealed a statistically significant increased risk of hypocalcaemia in the bilateral neck exploration group compared with the minimally invasive parathyroidectomy group (14% vs 2.3%, P < 0.001). Statistically significant lower risk of laryngeal nerve injury was also evident with minimally invasive parathyroidectomy compared to bilateral neck exploration (0.3% vs 0.9%). However, the risk of infection (0.5% vs 0.5%) and premature mortality (0.1% vs 0.5%) were comparable in both groups. Another important complication of parathyroidectomy is hematoma formation that may present with neck pain, respiratory distress, dysphagia and increased drainage from the surgical wound (Kreidieh 2013). Open drainage of the hematoma may be necessary in some people. Hungry bone syndrome associated with severe postoperative hypocalcaemia requiring intense medical management can complicate some cases of severe PHPT after parathyroidectomy (Witteveen 2013). Although postoperative hypoparathyroidism with symptomatic hypocalcaemia is usually transient, some cases may warrant long‐term follow‐up and medical management (Fyrsten 2016).

Persistent PHPT with development of postoperative hypercalcaemia within six months of parathyroidectomy occurs in up to 5% of individuals because of incomplete removal of abnormal parathyroid tissue (Silverberg 2014). Recurrent disease, development of new onset PHPT, can also occur in up to 8% of individuals with sporadic parathyroid adenomas after 3 to 11 years. The abnormal glands are often located in eutopic positions (rather than an ectopic gland) that should be identified by localisation studies before reoperations (Khan 2017; Silverberg 2014). The reoperation is best performed as minimally invasive parathyroidectomy if the tumour is localised or as unilateral exploration on the other side that has not been explored previously. Reported success rate of reoperation exceeds 90% especially when preoperative localisation of the abnormal parathyroid tissue is possible and when parathyroidectomy is coupled with intraoperative PTH assay. However, postoperative complications including hypoparathyroidism are higher in people undergoing reoperation (Khan 2017; Silverberg 2014).

How the intervention might work

As PHPT is a consequence of excess production of PTH from one or more of the parathyroid glands, complete surgical removal of the abnormal parathyroid tissue is expected to cure the disease. Biochemical evidence of normalisation of raised PTH level with resolution of hypercalcaemia in people with PHPT after parathyroidectomy usually indicate cure of the disease. In individuals with normocalcaemic PHPT, normalisation of elevated PTH levels usually indicate cure. Regardless of the surgical technique used, high cure rates were observed in patients who underwent successful parathyroidectomy (Khan 2017; Kreidieh 2013; Silverberg 2014; Singh 2016a). Although there is a small risk of recurrence of the disease even in sporadic cases of PHPT, the health benefits of successful parathyroidectomy observed during postoperative follow‐up period form clear rationale for recommending this treatment option for appropriately selected patients.

Why it is important to do this review

The prevalence of PHPT steadily increases with age, and older individuals tend to develop much more complications related to the disease compared to younger individuals (Oltmann 2014). Because of the availability of better healthcare, the proportion of elderly individuals has increased markedly in the global population in recent years. The cumulative risk of adverse hormonal effects from elevated PTH levels on target organs increase with the duration of PHPT, and older age‐groups are more vulnerable to the end‐organ complications related to the disease, such as osteoporosis, kidney disease, cognitive dysfunction and cardiovascular morbidity (Bilezikian 2017). Increased healthcare burden and the related economic loss are the consequences of such complications.

Parathyroidectomy has been shown to improve bone‐related health outcomes in PHPT in multiple observational studies and RCTs (Hansen 2012; Khosla 1999; Koumakis 2013; Lundstam 2015; Nilsson 2017; Vestergaard 2000). Other health benefits, such as prevention of deterioration of renal functions (Tassone 2015), improvement of cardiovascular morbidity (Best 2017; McMahon 2015), and better health‐related quality of life (Aberg 2015), have been demonstrated following parathyroidectomy in patients with PHPT.

Although there are a few recent systematic reviews on this topic (Cheng 2015; McMahon 2015; Singh 2016a; Singh 2016b), and two previous Cochrane protocols suggest moderate health benefits of parathyroidectomy in people with PHPT in terms of improvements in bone mineral density, cognitive functions and health‐related quality of life (Ramakant 2017; Smith 2017), there are still uncertainties on the overall health benefits of parathyroidectomy, the appropriate patient categories that benefit most from surgery, the severity of hyperparathyroidism for which parathyroidectomy should definitely be the choice, and the economic impact of surgery over medical therapy. Therefore, there is a need to compile the latest RCT evidence to examine the benefits of parathyroidectomy as a treatment option for the management of PHPT.

Objectives

To assess the effects of parathyroidectomy for adults with PHPT. We will also compare the effects of different types of parathyroidectomy on people with PHPT.

Methods

Criteria for considering studies for this review

Types of studies

We will include RCTs.

Types of participants

We will limit participants of interest to adults (aged 18 years or more) with PHPT who underwent parathyroidectomy for the first time.

Diagnostic criteria for PHPT

We will define PHPT (Bilezikian 2017), by one or more of the following.

  • Elevated or high normal PTH levels with elevated serum calcium levels above the normal laboratory reference values.

  • Elevated serum PTH with normal calcium levels and exclusion of secondary causes for elevation of PTH (mainly decreased calcium intake, vitamin D deficiency, renal insufficiency and hypercalciuria of renal origin).

  • Exclusion of secondary causes for hyperparathyroidism such as chronic renal insufficiency and vitamin D deficiency.

Types of interventions

We plan to investigate the following comparisons of intervention versus control/comparator.

Intervention

(a) Minimally invasive parathyroidectomy (focal mini‐incision, video‐assisted approach, totally‐endoscopic or robotic approach).

(b) Parathyroidectomy by bilateral surgical neck exploration.

Comparator

Participants compared with (a) or (b) managed by:

  • biochemical, clinical and imaging follow‐up without surgical interventions for any reason, such as personal preference, decision by treating physicians or contraindications for surgery from other serious medical conditions.

  • pharmacotherapy such as bisphosphonates and calcium lowering drugs (calcimimetics) without parathyroidectomy.

We will investigate different parathyroidectomy surgical techniques with each other. Concomitant interventions must be the same in both the intervention and comparator groups to establish fair comparisons. If a trial includes multiple arms, we will include any trial arm that meets the inclusion criteria.

Minimum duration of follow‐up

Minimal duration of follow‐up will be six months after the surgical procedure. We will define any follow‐up period going beyond the original time frame for the primary outcome measure as specified in the power calculation of the trial's protocol as an extended follow‐up period (also called open‐label extension study) (Buch 2011; Megan 2012).

Summary of specific exclusion criteria

We will exclude trials of the following category of participants.

  • Participants with secondary hyperparathyroidism

  • Participants with tertiary hyperparathyroidism

  • Participants with different types of hyperparathyroidism with no separate reporting of results by type

  • Duration of follow‐up less than six months

  • Trials in participants younger than 18 years

Types of outcome measures

We will not exclude a trial if it fails to report one or several of our primary or secondary outcome measures. If a trial does not report any of these primary or secondary outcomes, we will not include the trial but will provide some basic information in an additional table.

We will investigate the following outcomes using the methods and time points specified below.

Primary outcomes

  • Cure of PHPT

  • Morbidity related to PHPT

  • Adverse events of surgery

Secondary outcomes

  • All‐cause mortality

  • Health‐related quality of life

  • Hospitalisation for correction of hypercalcaemia or acute renal impairment

  • Socioeconomic effects

Method of outcome measurement

  • Cure of PHPT: defined by improvement of hypercalcaemia and elevated PTH levels to the normal laboratory reference values.

  • Morbidity related to PHPT such as improvement or lack of progression of osteoporosis osteopenia after parathyroidectomy, lack of progression of kidney dysfunction or renal stone disease, improvement or lack of progression of cognitive function, improvement or lack of worsening of cardiovascular disease.

  • Adverse events of surgery: such as postoperative bleeding, infections, hypocalcaemia and speech problems.

  • All‐cause mortality: defined as death from any cause.

  • Health‐related quality of life: evaluated by a validated instrument such as medical outcomes study Short Form Survey 36 (SF‐36);

  • Hospitalisation for correction of severe hypercalcaemia (calcium level more than 3.0 mmol/L) or acute renal impairment (requiring intravenous hydration or dialysis).

  • Socioeconomic effects: such as direct costs defined as admission or readmission rates, average length of stay, visits to general practitioner, emergency hospital visits, medication consumption, indirect costs defined as resources lost due to illness by the participant or their family member.

Timing of outcome measurement

  • Adverse events, all‐cause mortality: measured at any time after participants were randomised to intervention or comparator groups.

  • Health‐related quality of life, socioeconomic effects: up to six months will be defined as short‐term and longer than six months will be defined as long term.

  • Cure of PHPT: measured by normal calcium and PTH levels at six months or later after participants were randomised to intervention or comparator groups.

  • Morbidity related to PHPT: measured at six months or later after participants were randomised to intervention or comparator groups.

  • Hospitalisation with hypercalcaemia or renal impairment: measured within six months after participants were randomised to intervention or comparator groups.

Search methods for identification of studies

Electronic searches

We will search the following sources from the inception of each database to the specified date and will place no restrictions on the language of publication.

  • Cochrane Central Register of Controlled Trials (CENTRAL) via the Cochrane Register of Studies Online (CRSO).

  • MEDLINE Ovid (Epub Ahead of Print, In‐Process & Other Non‐Indexed Citations, Ovid MEDLINE Daily and Ovid MEDLINE; from 1946 onwards).

  • LILACS (Latin American and Caribbean Health Science Information database).

  • ClinicalTrials.gov (www.clinicaltrials.gov).

  • World Health Organization International Clinical Trials Registry Platform (WHO ICTRP) (www.who.int/trialsearch/).

We will not include Embase in our search, as RCTs indexed in Embase are now prospectively added to CENTRAL via a highly sensitive screening process (CENTRAL 2018).

We will continuously apply a MEDLINE (via Ovid SP) email alert service established by the Cochrane Metabolic and Endocrine Disorders (CMED) Group to identify newly published trials using the same search strategy as described for MEDLINE (Appendix 1). After we submit the review draft for editorial approval, the CMED Group will perform a complete search update on all databases available at the editorial office and will send the results to the review authors. Should we identify new trials for inclusion, we will evaluate these and incorporate the findings into our review (Beller 2013).

Searching other resources

We will try to identify other potentially eligible trials or ancillary publications by searching the reference lists of included trials, systematic reviews, meta‐analyses and health technology assessment reports. In addition we will contact authors of included trials to identify any additional information on the retrieved trials and establish whether we may have missed further trials.

We will not use abstracts or conference proceedings for data extraction unless full data are available from trial authors because this information source does not fulfil the CONSORT requirements which consist of "an evidence‐based, minimum set of recommendations for reporting randomised trials" (CONSORT 2016; Scherer 2007). We will present information on abstracts or conference proceedings in the 'Characteristics of studies awaiting classification' table.

Data collection and analysis

Selection of studies

After removal of duplicates, two review authors (JMP and AKV) will independently screen the abstract and title of every record retrieved by the searches. We will obtain the full‐text of all potentially eligible relevant records, and will screen them for eligibility. We will resolve any disagreements through consensus or by recourse to a third review author (RS). If we cannot resolve a disagreement, we will categorise the trial as a 'study awaiting classification' and will contact the trial authors for clarification. We will present an adapted PRISMA flow diagram to show the process of trial selection (Liberati 2009). We will list all articles excluded after full‐text assessment in a 'Characteristics of excluded studies' table and will provide the reasons for exclusion.

Data extraction and management

Two review authors (JMP and RS) will independently extract the data from trials that fulfil our inclusion criteria to identify key participant and intervention characteristics. We will describe interventions by use of the 'template for intervention description and replication' (TIDieR) checklist (Hoffmann 2014; Hoffmann 2017).

We will report data on efficacy outcomes and adverse events using standardised data extraction sheets from the CMED Group. We will resolve any disagreements by discussion or, if required, we will consult a third review author (AKV).

We will provide information about potentially relevant ongoing trials, including the trial identifiers, in the table 'Characteristics of ongoing trials' and in a joint appendix 'Matrix of trial endpoint (publications and trial documents)'. We will try to find the protocol for each included trial and we will report primary, secondary and other outcomes in comparison with data in publications in a joint appendix.

We will email all authors of included trials to enquire whether they would be willing to answer questions regarding their trials. We will present the results of this survey in an appendix. We will thereafter seek relevant missing information on the trial from the primary trial author(s), if required.

Dealing with duplicate and companion publications

In the event of duplicate publications, companion documents or multiple reports of a primary trial, we will maximise the information yield by collating all available data, and we will use the most complete data set aggregated across all known publications. We will list duplicate publications, companion documents, multiple reports of a primary trial, and trial documents of included trials (such as trial registry information) as secondary references under the study ID of the included trial. Furthermore, we will also list duplicate publications, companion documents, multiple reports of a trial, and trial documents of excluded trials (such as trial registry information) as secondary references under the study ID of the excluded trial.

Data from clinical trials registers

If data from included trials are available as study results in clinical trials registers, such as ClinicalTrials.gov or similar sources, we will make full use of this information and will extract the data. If there is also a full publication of the trial, we will collate and critically appraise all available data. If an included trial is marked as a completed study in a clinical trial register but no additional information (study results, publication or both) is available, we will add this trial to the 'Characteristics of studies awaiting classification' table.

Assessment of risk of bias in included studies

Two review authors (JMP and IML) will independently assess the risk of bias of each included trial. We will resolve any disagreements by consensus or by consulting a third review author (AKV). In the case of disagreement, we will consult the rest of the review author team and we will make a judgement based on consensus. If adequate information is unavailable from the publications, trial protocols or other sources, we will contact the trial authors for more detail to request missing data on 'Risk of bias' items.

We will use the Cochrane 'Risk of bias' assessment tool (Higgins 2017), assigning assessments of low, high or unclear risk of bias (for details see Appendix 2; Appendix 3). We will evaluate individual bias items as described in the Cochrane Handbook for Systematic Reviews of Interventions according to the criteria and associated categorisations contained therein (Higgins 2017).

Summary assessment of risk of bias

We will present a 'Risk of bias' graph and a 'Risk of bias' summary figure.

We will distinguish between self‐reported, investigator‐assessed and adjudicated outcome measures.

We will consider the following self‐reported outcomes.

  • Health‐related quality of life

  • Adverse events of surgery

We will consider the following outcomes to be investigator‐assessed.

  • Cure of PHPT

  • Morbidity related to PHPT

  • All‐cause mortality

  • Adverse events of surgery

  • Hospitalisation with hypercalcaemia or renal impairment

  • Socioeconomic effects

Risk of bias for a trial across outcomes

Some risk of bias domains, such as selection bias (sequence generation and allocation sequence concealment), affect the risk of bias across all outcome measures in a trial. In the case of high risk of selection bias, we will mark all endpoints investigated in the associated trial as being at high risk. Otherwise, we will not perform a summary assessment of the risk of bias across all outcomes for a trial.

Risk of bias for an outcome within a trial and across domains

We will assess the risk of bias for an outcome measure by including all entries relevant to that outcome (i.e. both trial‐level entries and outcome‐specific entries). We consider low risk of bias to denote a low risk of bias for all key domains, unclear risk to denote an unclear risk of bias for one or more key domains and high risk to denote a high risk of bias for one or more key domains.

Risk of bias for an outcome across trials and across domains

These are the main summary assessments that we will incorporate into our judgments about the certainty of evidence in the 'Summary of findings' tables. We will define outcomes as at low risk of bias when most information comes from trials at low risk of bias, unclear risk when most information comes from trials at low or unclear risk of bias, and high risk when a sufficient proportion of information comes from trials at high risk of bias.

Measures of treatment effect

When at least two included trials are available for a comparison and a given outcome, we will try to express dichotomous data as a risk ratio (RR) or odds ratio (OR) with 95% confidence intervals (CIs). For continuous outcomes measured on the same scale (e.g. weight loss in kg), we will estimate the intervention effect using the mean difference (MD) with 95% CIs. For continuous outcomes that measure the same underlying concept (e.g. health‐related quality of life) but use different measurement scales, we will calculate the standardised mean difference (SMD). We will express time‐to‐event data as a hazard ratio (HR) with 95% CIs.

Unit of analysis issues

We will take into account the level at which randomisation occurred, such as for cross‐over trials, cluster‐randomised trials and multiple observations for the same outcome. If more than one comparison from the same trial is eligible for inclusion in the same meta‐analysis, we will either combine groups to create a single pair‐wise comparison or appropriately reduce the sample size so that the same participants do not contribute data to the meta‐analysis more than once (splitting the 'shared' group into two or more groups). While the latter approach offers some solution to adjusting the precision of the comparison, it does not account for correlation arising from the same set of participants being in multiple comparisons (Higgins 2011).

We will attempt to re‐analyse cluster‐RCTs that have not appropriately adjusted for potential clustering of participants within clusters in their analyses. The variance of the intervention effects will be inflated by a design effect. Calculation of a design effect involves estimation of an intracluster correlation coefficient (ICC). We will obtain estimates of ICCs by contacting trial authors or by imputing the ICC values by using either estimates from other included trials that report ICCs or external estimates from empirical research (e.g. Bell 2013). We plan to examine the impact of clustering using sensitivity analyses.

Dealing with missing data

If possible, we will obtain missing data from the authors of the included trials. We will carefully evaluate important numerical data such as screened, randomly assigned participants as well as intention‐to‐treat, and as‐treated and per‐protocol populations. We will investigate attrition rates (e.g. dropouts, losses to follow‐up, withdrawals), and we will critically appraise issues concerning missing data and use of imputation methods (e.g. last observation carried forward).

In trials where the standard deviation (SD) of the outcome is not available at follow‐up or we cannot recreate it, we will standardise by the mean of the pooled baseline SD from those trials that reported this information.

Where included trials do not report means and SDs for outcomes and we do not receive the necessary information from trial authors, we will impute these values by estimating the mean and variance from the median, range and the size of the sample (Hozo 2005).

We will investigate the impact of imputation on meta‐analyses by performing sensitivity analyses, and we will report for every outcome which trials had imputed SDs.

Assessment of heterogeneity

In the event of substantial clinical or methodological heterogeneity, we will not report trial results as the pooled effect estimate in a meta‐analysis.

We will identify heterogeneity (inconsistency) by visually inspecting the forest plots and by using a standard Chi² test with a significance level of α = 0.1 (Deeks 2017). In view of the low power of this test, we will also consider the I² statistic, which quantifies inconsistency across trials to assess the impact of heterogeneity on the meta‐analysis (Higgins 2002; Higgins 2003).

When we find heterogeneity, we will attempt to determine the possible reasons for it by examining individual trial and subgroup characteristics.

Assessment of reporting biases

If we include 10 or more trials that investigate a particular outcome, we will use funnel plots to assess small‐trial effects. Several explanations may account for funnel plot asymmetry, including true heterogeneity of effect with respect to trial size, poor methodological design (and hence bias of small trials) and publication bias (Sterne 2017). Therefore we will interpret the results carefully (Sterne 2011).

Data synthesis

We plan to undertake (or display) a meta‐analysis only if we judge participants, interventions, comparisons and outcomes to be sufficiently similar to ensure an answer that is clinically meaningful. Unless good evidence shows homogeneous effects across trials of different methodological quality, we will primarily summarise low risk of bias data using a random‐effects model (Wood 2008). We will interpret random‐effects meta‐analyses with due consideration to the whole distribution of effects and present a prediction interval (Borenstein 2017a; Borenstein 2017b; Higgins 2009). A prediction interval needs at least four trials to be calculated and specifies a predicted range for the true treatment effect in an individual trial (Riley 2011). For rare events such as event rates below 1%, we will use the Peto's odds ratio method provided that there is no substantial imbalance between intervention and comparator group sizes and intervention effects are not exceptionally large. In addition, we will perform statistical analyses according to the statistical guidelines presented in the Cochrane Handbook for Systematic Reviews of Interventions (Deeks 2017).

Subgroup analysis and investigation of heterogeneity

We expect the following characteristics to introduce clinical heterogeneity, and we plan to carry out the following subgroup analyses including investigation of interactions (Altman 2003).

  • Different surgical techniques

  • Severity of PHPT

  • Difference in the demographics of trial population such as gender, age and ethnic differences

Sensitivity analysis

We plan to perform sensitivity analyses to explore the influence of the following factors (when applicable) on effect sizes by restricting analysis to the following.

  • Published trials.

  • Effect of risk of bias, as specified in the 'Assessment of risk of bias in included studies' section.

  • Very long or large trials to establish the extent to which they dominate the results.

  • Using the following filters: diagnostic criteria, imputation, language of publication, source of funding (industry versus other) or country.

We will also test the robustness of results by repeating the analyses using different measures of effect size (RR, OR, etc.) and different statistical models (fixed‐effect and random‐effects models).

Certainty of the evidence

We will present the overall certainty of evidence for each outcome specified below, according to the GRADE approach, which takes into account issues related not only to internal validity (risk of bias, inconsistency, imprecision, publication bias) but also to external validity, such as directness of results. Two review authors (JMP and IML) will independently assess the certainty of evidence for each outcome. We will resolve any differences in assessment by discussion or consulting a third review author (RS).

We will include an appendix entitled 'Checklist to aid consistency and reproducibility of GRADE assessments', to help with standardisation of the 'Summary of findings' tables (Meader 2014). Alternatively, we will use the GRADEpro Guideline Development Tool (GDT) software and will present evidence profile tables as an appendix (GRADEpro GDT 2015). We will present results for the outcomes as described in the 'Types of outcome measures' section. If meta‐analysis is not possible, we will present the results in a narrative format in the 'Summary of findings' table. We will justify all decisions to downgrade the quality of trials using footnotes, and we will make comments to aid the reader's understanding of the Cochrane Review where necessary.

'Summary of findings' table

We will present a summary of the evidence in a 'Summary of findings' table. This will provide key information about the best estimate of the magnitude of the effect, in relative terms and as absolute differences, for each relevant comparison of alternative management strategies, numbers of participants and trials addressing each important outcome and a rating of overall confidence in effect estimates for each outcome. We will create the 'Summary of findings' table based on the methods described in the Cochrane Handbook for Systematic Reviews of Interventions (Schünemann 2017) using Review Manager 5 (RevMan 5) table editor (RevMan 2014). We will report the following outcomes, listed according to priority.

  • Cure of PHPT

  • Morbidity related to PHPT

  • All‐cause mortality

  • Adverse events of surgery

  • Health‐related quality of life

  • Hospitalisation with hypercalcaemia or renal impairment

  • Socioeconomic effects.