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Oralni aspirin za liječenje venskih ulkusa nogu

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Abstract

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Background

Venous leg ulcers (VLUs) or varicose ulcers are the final stage of chronic venous insufficiency (CVI), and are the most common type of leg ulcer. The development of VLUs on ankles and lower legs can occur spontaneously or after minor trauma. The ulcers are often painful and exudative, healing is often protracted and recurrence is common. This cycle of healing and recurrence has a considerable impact on the health and quality of life of individuals, and healthcare and socioeconomic costs. VLUs are a common and costly problem worldwide; prevalence is estimated to be between 1.65% to 1.74% in the western world and is more common in adults aged 65 years and older. The main treatment for a VLU is a firm compression bandage. Compression assists by reducing venous hypertension, enhancing venous return and reducing peripheral oedema. However, studies show that it only has moderate effects on healing, with up to 50% of VLUs unhealed after two years of compression. Non‐adherence may be the principal cause of these poor results, but presence of inflammation in people with CVI may be another factor, so a treatment that suppresses inflammation (healing ulcers more quickly) and reduces the frequency of ulcer recurrence (thereby prolonging time between recurrent episodes) would be an invaluable intervention to complement compression treatments. Oral aspirin may have a significant impact on VLU clinical practice worldwide. Evidence for the effectiveness of aspirin on ulcer healing and recurrence in high quality RCTs is currently lacking.

Objectives

To assess the benefits and harms of oral aspirin on the healing and recurrence of venous leg ulcers.

Search methods

In May 2015 we searched: The Cochrane Wounds Specialised Register; The Cochrane Central Register of Controlled Trials (CENTRAL) (The Cochrane Library); Ovid MEDLINE; Ovid MEDLINE (In‐Process & Other Non‐Indexed Citations); Ovid EMBASE and EBSCO CINAHL. Additional searches were made in trial registers and reference lists of relevant publications for published or ongoing trials. There were no language or publication date restrictions.

Selection criteria

We included randomised controlled trials (RCTs) that compared oral aspirin with placebo or no drug intervention (in the presence or absence of compression therapy) for treating people with venous leg ulcers. Our main outcomes were time to complete ulcer healing, rate of change in the area of the ulcer, proportion of ulcers healed in the trial period, major bleeding, pain, mortality, adverse events and ulcer recurrence (time for recurrence and proportion of recurrence).

Data collection and analysis

Two review authors independently selected studies for inclusion, extracted data, assessed the risk of bias of each included trial and assessed overall quality of evidence for the main outcomes in the 'Summary of findings' table.

Main results

The electronic search located 62 studies. We included two RCTs of oral aspirin (300 mg/daily) given in addition to compression compared with compression and placebo, or compression alone. To date, the impact of aspirin on VLUs has been examined by only two randomised clinical trials, both with a small number of participants. The first RCT was conducted in the United Kingdom (n=20) and reported that daily administration of aspirin (300mg) in addition to compression bandages increased both the rate of healing, and the number of participants healed when compared to placebo in addition to compression bandaging over a four month period. Thirty‐eight per cent of the participants given aspirin reported complete healing compared with 0% in the placebo group . Improvement (assessed by reduction in wound size) occurred in 52% of the participants taking aspirin compared with 26% in those taking placebo). The study identified potential benefits of taking aspirin as an adjunct to compression but the sample size was small, and neither the mechanism by which aspirin improved healing nor its effects on recurrence were investigated.

In 2012 an RCT in Spain (n=51) compared daily administration of aspirin (300mg) in addition to compression bandages with compression alone over a five month period. There was little difference in complete healing rates between groups (21/28 aspirin and 17/23 compression bandages alone) but the average time to healing was shorter (12 weeks in the treated group vs 22 weeks in the compression only group) and the average time for recurrence was longer in the aspirin group (39 days: [SD 6.0] compared with 16.3 days [SD 7.5] in the compression only group). Although this trial provides some limited data about the potential use of aspirin therapy, the sample size (only 20 patients) was too small for us to draw meaningful conclusions. In addition, patients were only followed up for 4 months and no information on placebo was reported.

Authors' conclusions

Low quality evidence from two trials indicate that there is currently insufficient evidence for us to draw definitive conclusions about the benefits and harms of oral aspirin on the healing and recurrence of venous leg ulcers. We downgraded the evidence to low quality due to potential selection bias and imprecision due to the small sample size. The small number of participants may have a hidden real benefit, or an increase in harm. Due to the lack of reliable evidence, we are unable to draw conclusions about the benefits and harms of oral daily aspirin as an adjunct to compression in VLU healing or recurrence. Further high quality studies are needed in this area.

PICOs

Population
Intervention
Comparison
Outcome

The PICO model is widely used and taught in evidence-based health care as a strategy for formulating questions and search strategies and for characterizing clinical studies or meta-analyses. PICO stands for four different potential components of a clinical question: Patient, Population or Problem; Intervention; Comparison; Outcome.

See more on using PICO in the Cochrane Handbook.

Laički sažetak

Aspirin za liječenje venskih ulkusa nogu

Dosadašnje spoznaje
Venski su ulkusi nogu najčešći tip ulkusa (rana) na nozi, a uzrokuje ih slab protok krvi kroz vene nogu (kronična venska insuficijencija). Kronična venska insuficijencija dovodi do visokog krvnog tlaka u venama (venska hipertenzija) što uzrokuje različite promjene na koži noge. Ulkusi na nogama završna su faza tih promjena. Venski ulkusi noge mogu se javiti spontano ili nakon manje traume, često su bolni i iz njih curi obilna količina tekućine (eksudat). Ti ulkusi predstavljaju veliki problem zato što su vrlo česti, sklon su dugom trajanju, a također imaju visoku sklonost ponavljanja. Češće obolijevaju stariji ljudi, imaju visoke troškove liječenja, što predstavlja visok individualni i društveni teret za oboljele.

Kompresijska je terapija, u obliku čvrstog zavoja preko noge što pomaže protoku krvi kroz vene, dobro uspostavljena terapija za venske ulkuse noge. Međutim, istraživanja su pokazala da kompresija ima samo umjerene učinke na ozdravljenje, pri čemu oko 50% venskih ulkusa na nogama ostaju neizliječeni nakon dvije godine kompresije, vjerojatno zbog produljenog upalnog procesa. Bolje razumijevanje degenerativnih promjena na koži noge u ljudi s venskim ulkusima nogu i kronični upalni proces uključen u navedeno, navelo je znanstvenike na testiranje različitih lijekova koji bi mogli poboljšati liječenje tog stanja. Aspirin ima neke vrlo poznate osobine kao što su: ublažavanje boli (analgetsko djelovanje), smanjenje upale i vrućice te sprječavanje krvnih stanica od međusobnog nagomilavanja što sprječava stvaranje krvnih ugrušaka. Terapija aspirinom može poboljšati vrijeme ozdravljenja i smanjiti broj ponavljajućih epizoda venskih ulkusa nogu. Ako se dokaže djelotvornim, niski bi troškovi značili da je aspirin uz dodatak kompresijske terapije povoljno preventivno sredstvo za ljude koji pate od venskih ulkusa noge u svim zemljama.

Istraživačko pitanje

Koje su prednosti i mane aspirina uzetog na usta na ozdravljenje i ponovno javljanje venskih ulkusa na nogama?

Ključni rezultati

Pronađena su samo dva randomizirana (nasumična) kontrolirana ispitivanja koja su usporedila oralni aspirin (300 mg dnevno) i kompresiju s kompresijom i placebom ili samo kompresijom. Jedna je studija provedena u Velikoj Britaniji i uključila je 20 ispitanika (10 u aspirinskoj grupi i 10 u kontrolnoj grupi) te je pratila ispitanike tijekom 4 mjeseca. Ovo je ispitivanje prikazalo rezultate da se ulcerozno područje smanjilo (do 6,5 m2 odnosno 39,4%) u aspirinskoj grupi u usporedbi s kontrolnom grupom gdje nije došlo do smanjenja, a veći je dio ulkusa (38%) u aspirinskoj grupi u potpunosti izliječen u usporedbi s niti jednim u kontrolnoj grupi. Ponovno javljanje ulkusa nije istraživano ovom studijom. Druga je studija provedena u Španjolskoj; uključila je 51 sudionika (23 u aspirinskoj grupi i 28 u kontrolnoj grupi) te pratila ispitanike dok nije došlo do izlječenja ulceracija. Studija je prikazala podatke da je prosječno vrijeme za ozdravljenje bilo 12 tjedana u aspirinskoj grupi i 22 tjedna u kontrolnoj grupi. Nije uočena stvarna razlika između udjela osoba s izliječenim ulkusima (17 (74%) od 23 osobe u aspirinskoj grupi i 21 (75%) od 28 osoba u kontrolnoj grupi). Prosječno je vrijeme do ponovnog javljanja bilo duže u aspirinskoj grupi (39 dana) u usporedbi s (16,3 dana) u grupi na kompresijskoj terapiji. Nuspojave nisu prikazane ni u jednom istraživanju.

Te dvije studije smatraju se premalenima i niske kvalitete kako bismo donijeli konačan zaključak o prednostima i manama oralnog aspirina na izlječenje i ponavljanje venskih ulkusa nogu. Britanska studija pruža samo ograničene podatke o potencijalnim prednostima dnevne terapije oralnim aspirinom uz kompresiju zbog male veličine uzorka od samo 20 sudionika i kratkog vremena praćenja. Španjolska studija pruža ograničene podatke na 51 sudionika uspoređujući aspirin i kompresiju s kontrolnom grupom. Činjenica da nisu prikazane nikakve informacije o placebu u kontrolnoj grupi znači da je procijenjeni učinak neizvjestan. Daljnje su studije visoke kvalitete potrebne u ovom području.

Dokazi se temelje na literaturi objavljenoj do 27. svibnja 2015. godine.

Authors' conclusions

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Implications for practice

Two small studies showed that aspirin may improve the healing of venous leg ulcers (VLUs). Given that these studies were at moderate (to high) risk of bias and did not report on other important adverse events, such as bleeding, it may be prudent to limit the use of aspirin to aid healing in this population until evidence of benefit, and of no harm, is available. The conclusions we can draw in our systematic review are limited by the quality and number of trials that met our inclusion criteria, and lack of reporting of important outcomes. The trials we identified were susceptible to bias, and hampered by inadequate reporting and small sample sizes, which may have hidden real benefits.

Implications for research

Although the role of inflammation in the development of VLUs is well documented, this review has shown that there is very little research on the benefits and harms of aspirin in their treatment. Consequently, we still have insufficient high‐quality evidence to make definitive conclusions about the effectiveness and safety of aspirin for people with this condition. Further high quality research is required before definitive conclusions can be made about the benefits of aspirin as an adjunct to compression in people with VLUs. Future trials should clearly report baseline participant characteristics and conform to the CONSORT 2010 recommendations with sufficient power to detect a true treatment effect.

Summary of findings

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Summary of findings for the main comparison. Oral aspirin for venous leg ulcers

Oral aspirin for venous leg ulcers

Patient or population: patients with venous leg ulcers
Settings: hospital outpatients in UK and Spain
Intervention: oral aspirin

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

No of participants
(studies)

Quality of the evidence
(GRADE)

Comments

Assumed risk

Corresponding risk

Control

Oral aspirin

Average time for ulcer healing

22 weeks

12 weeks

Not estimable

51 (1 study)

⊕⊕⊝⊝
low1,2

P values and confidence intervals were not reported

Reduction of ulcer area (median)

0 cm²

6.5cm²

Not estimable

20
(1 study)

⊕⊕⊝⊝
low2,3

P value < 0.002

Follow‐up: 4 months

Proportion of healed ulcers in the trial period

No healed ulcers

38% of healed ulcers

Not estimable

20
(1 study)

⊕⊕⊝⊝
low2,3

P value < 0.007

Follow‐up: 4 months

Major bleeding

See comment

See comment

Not estimable

20
(1 study)

⊕⊕⊝⊝
low2,3

No events were observed in either group, follow‐up: 4 months

Another study reported 2 hospitalisations for unknown reasons, intervention group not specified

Average time of ulcer recurrence

16.33 days

SD: 7.5

39 days

SD: 6.0

Not estimable

51
(1 study)

⊕⊕⊝⊝
low1,2

P value = 0.007

Post hoc assessment not pre‐specified in protocol

Mortality

See comment

See comment

Not estimable

See comment

See comment

Mortality not reported

Other adverse events

See comment

See comment

Not estimable

71
(2 study)

See comment

No events were observed in either group. del Río Solá reported 2 hospitalisations for unknown reasons, the group of these patients were not specified and they were removed from the study

*The basis for the assumed risk (for example, the median control group risk across studies) is provided in footnotes. The corresponding risk (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; RR: risk ratio; SD: standard deviation

GRADE Working Group grades of evidence
High quality: Further research is very unlikely to change our confidence in the estimate of effect
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate
Very low quality: We are very uncertain about the estimate

1 Allocation concealment and blinding of outcome assessment were not described. Participants and personnel were not blinded. There was a high risk of bias from incomplete outcome data.There were some inconsistencies in the reporting of the data
2 The study results are based on one small study with insufficient data to estimate the effect precisely
3 Selection, performance and reporting biases were unclear

Background

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Description of the condition

Venous leg ulcers (VLUs; also known as varicose ulcers or stasis ulcers) occur as results of the chronic venous insufficiency (CVI), which is a functional disorder of the venous system of the leg. The venous leg system is a compound of superficial, deep and perforating veins (perforating veins connect the superficial and deep veins). Damage in any of these veins causes an impairment of venous return, this impairment causes increased venous pressure also known as venous hypertension Ballard 2000). Chronic venous hypertension (CVH) leads to an inflammatory response by leukocytes (white blood cells involved in the inflammation process) that causes cellular and tissue dysfunction which in turn results in varicose veins (veins unnaturally and permanently distended) and dermal changes called lipodermatosclerois characterised by the presence of oedema, hyperpigmentation, induration and eczema of the skin. Ulceration is the final stage of these alterations. (Appendix 1; Thomas 1988; De Araujo 2003; Barron 2007; Rafetto 2009).

Clinically, a VLU is characterised by erosion of the skin usually in the gaiter area of the lower leg (between the knee and the ankle; Dorland 2007). Ulcers vary in size and number. Usually, they have a shallow base, flat margin with the surrounding skin showing features of CVH (Gilliland 1991; Valencia 2001; Raju 2009). Pain that impairs quality of life is present in 75% of people with this condition (Friedman 1990; Philips 1994); in some cases the ulcer has an associated odour that can result in social isolation and depression (Gilliland 1991;Jones 2008).

Venous leg ulceration has a tendency to become chronic and recurrent; one estimate suggests that 30% of healed ulcers recur in the first year, rising to 78% after two years (Mayer 1994). Around 80% of lower extremity leg ulcers presenting in general practice are VLUs; the remaining 20% are as a result of arterial insufficiency, neuropathy, trauma, inflammatory or metabolic conditions, malignancy and infections (Falabella 1998; Sibbald 1998; Valencia 2001; Moloney 2004; Dealey 2005). Diagnosis of a VLU is based on a clinical assessment and the presence of symptoms that are consistent with venous hypertension (i.e. an ulcer located in the medial gaiter area; presence of varicose veins, eczema, pigmentation, induration and oedema, in any combination). In a few cases the diagnosis can be complemented by non‐invasive methods such as ultrasonography.

VLUs are a major health problem because of their frequent occurrence and associated high cost of care. The disease mainly affects people between 60 and 80 years of age, women are affected three times more frequently than men. The rate of occurrence of VLUs is likely to increase as the average age of the population increases (Callam 1987; Margolis 2002). Estimates of its occurrence rate vary by country. For example, in Europe, including countries such as Denmark, Czechoslovakia and Switzerland, the rates of occurrence have been reported at 1% to 5.5% in women and 0.9% to 1.9% in men (Bobek 1966; Arnoldi 1968; Kamber 1978); in the USA the rates were reported as 0.2% in women and 0.1% in men (Coon 1973); and in Brazil as approximately 1.5% for open or healed VLU (Maffei 1986). The cost of treating VLUs is estimated to be one billion USD per year in the USA, and the average cost for one person over a lifetime has been estimated to exceed USD 40,000 (Valencia 2001). Another study of people with VLUs estimated that the average duration of follow‐up was 119 days and the average total medical cost per person was USD 9685 (Olin 1999).

Description of the intervention

The goals of treatment for people with venous leg ulcers include: reduction of oedema, relief of pain and lipodermatosclerosis, ulcer healing, and prevention of recurrence (De Araujo 2003). Different modalities of treatment are used for treating VLUs and these are sometimes used in combination (Blankensteijn 2009). The most common form of treatment is compression therapy (covering the leg with a firm bandage or socks, to apply an external force which aids the flow of blood in the veins). Whilst compression has the potential to heal approximately 50% of VLUs (Weller 2012), rest with elevation of the affected leg, venous surgery, and oral medication with drugs (such as pentoxifylline that aim to improve blood flow and reduce clotting (Jull 2007)) are also used to treat this condition. A treatment that can suppress inflammation would be useful. Oral aspirin is a widely used drug that may have the potential to exert a beneficial influence in the treatment of VLUs. However, until now, no comprehensive summary of the available evidence has been conducted.

How the intervention might work

Classical signs of inflammation have been observed in biopsies and plasma samples in experimental models of venous disease. The cascade starts with increased vascular permeability (increased leakage of plasma and cells through the vein wall) and progression to adhesion of leukocytes (white blood cell involved in the inflammation process) and platelets (very small structures shaped like a discus, present in the blood with important role in the coagulation) to endothelium (the cells lining the lumen of the veins). Over time the disease progresses to vascular restructuring of venous varicosities (veins which are unnaturally and permanently distended). Unlike acute wound healing, chronic VLUs remain at an prolonged inflammatory stage with formation of granulation tissue (newly formed tissue which repairs damaged areas) (Bergan 2007).

Aspirin or acetylsalicylic acid was introduced as a medication in 1899 by Dreser (Burke 2006). Aspirin has analgesic, anti‐inflammatory and antipyretic (fever‐reducing) properties (Winter 1966). It inhibits platelet aggregation, and acts as an inhibitor of cyclooxygenase (substance involved in the synthesis prostaglandins), resulting in the inhibition of the biosynthesis (physiologic production of a substance into the body) of prostaglandins (substances involved in the inflammatory process causing venous dilatation and inhibition the platelet aggregation) (Salzman 1971; Vane 1971). Prostaglandins are released during the inflammatory phase, and are thought to increase blood vessel permeability, manifested by venous oedema and capillary leakage. Aspirin stimulates the biosynthesis of other anti‐inflammatory compounds by inhibiting the cyclooxygenase pathway. The precise mechanism by which aspirin is thought to mediate effects on VLU healing is unclear, although inhibition of platelet activation and reduction of inflammation and pain have been suggested (Ibbotson 1995; De Araujo 2003). However, aspirin is known to have adverse effects, most commonly gastric ulceration and other gastrointestinal effects, as well as hepatotoxicity (liver damage), exacerbation of asthma, skin rashes and renal toxicity (Cappelleri 1995; Burke 2006).  

Why it is important to do this review

Chronic VLU healing remains a complex clinical problem and requires the intervention of skilled, but costly, multidisciplinary wound care teams. Recurrence is often an ongoing issue for people who experience venous ulcers. Aspirin is an inexpensive and widely available treatment currently used in several other clinical situations. Oral aspirin is potentially one of the most effective preventive agents for use in people with VLUs. It has the potential to improve healing rates, shorten time to healing and decrease the number of recurrent episodes after healing. If proved effective, the low cost of aspirin therapy as an adjunct to compression would make it an affordable preventive agent for people with VLUs in all countries. Despite its potential benefits, there are limited data available about the effectiveness of aspirin in people with VLUs. Additionally, with the number of people with VLUs expected to rise significantly in the coming decades, development of new safe ways of healing and reducing recurrence are high priorities in health research.

Objectives

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To assess the benefits and harms of oral aspirin on the healing and recurrence of venous leg ulcers.

Methods

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Criteria for considering studies for this review

Types of studies

Randomised controlled trials (RCTs) of oral aspirin to treat people with venous leg ulcers.

Types of participants

Adults (as defined in trials) undergoing treatment for venous leg ulceration or prevention of recurrence of venous leg ulcers.

Types of interventions

Oral aspirin compared with placebo or any other therapy in the presence or absence of compression therapy.

To be eligible for inclusion, treatment with oral aspirin must be the only systematic difference between treatment arms, therefore a study in which one group received compression and one did not would not be eligible for inclusion unless within a factorial design.

Types of outcome measures

Primary outcomes

  • Time to complete ulcer healing.

  • Rate of changes in the area of the ulcer in the trial period.

  • Proportion of ulcers healed in the trial period.

  • Proportions of people with ulcers completely healed in the trial period.

  • Major bleeding (haemorrhagic stroke, gastric bleeding, any bleeding requiring blood transfusion, any bleeding causing hospitalisation).

Secondary outcomes

  • Pain relief (as measured by a valid pain scale).

  • Mortality from any cause.

  • Any adverse events (e.g. renal failure, neutropenia, low platelets level, gastric complaints, diarrhoea, skin rash, minor bleeding).

  • Ulcer recurrence (time to recurrence and proportion of people with recurrence).

Search methods for identification of studies

Electronic searches

We searched the following electronic databases to identify reports of randomised controlled trials:

  • The Cochrane Wounds Specialised Register (searched 27 May 2015);

  • The Cochrane Central Register of Controlled Trials (CENTRAL) (The Cochrane Library 2015, Issue 4);

  • Ovid MEDLINE (1946 to 26 May 2015);

  • Ovid MEDLINE (In‐Process & Other Non‐Indexed Citations) (searched 26 May 2015);

  • Ovid EMBASE (1974 to 26 May 2015);

  • EBSCO CINAHL (1982 to 27 May 2015).

The search strategies we used can be found in Appendix 2. The Ovid MEDLINE searches were combined with the Cochrane Highly Sensitive Search Strategy for identifying randomised trials in MEDLINE: sensitivity‐ and precision‐maximizing version (2008 revision) (Lefebvre 2011). We combined the EMBASE search with the Ovid EMBASE trial filter terms developed by the UK Cochrane Centre (Lefebvre 2011). We combined the CINAHL search with the trial filter developed by the Scottish Intercollegiate Guidelines Network (SIGN 2011). There was no restriction on the basis of date, or language of publication.

We also searched the following clinical trials registries:

ClinicalTrials.gov (https://clinicaltrials.gov/);
WHO International Clinical Trials Registry Platform (ICTRP) (http://apps.who.int/trialsearch/default.aspx).

Searching other resources

We searched the references of all identified studies in order to find any further relevant trials. We also contacted experts in the field.

Data collection and analysis

Selection of studies

Two reviews authors (NGM and RFA) selected studies as described in Chapter 7 of theCochrane Handbook for Systematic Reviews of Interventions as follows (Higgins 2011a):

  • We merged search results using reference management software, and removed duplicate records of the same report.

  • We examined titles and abstracts to remove obviously irrelevant reports.

  • We retrieved full text of the potentially relevant reports.

  • We linked multiple reports of the same study.

  • We examined full‐text reports for compliance of studies with eligibility criteria.

  • We clarified study eligibility (where appropriate) by corresponding with investigators.

  • We made final decisions on study inclusion to allow data collection to proceed.

Any disagreements were solved by discussion. If this did not result in agreement, the opinion of the third review author (PEdOC) was decisive. We documented the reasons for exclusion of any article.

Data extraction and management

Two reviews authors (NGM and RFA) independently extracted details of eligible studies and summarised them using a data extraction sheet specific to this review that was constructed according Chapter 7 of the Cochrane Handbook for Systematic Reviews of Interventions (Higgins 2011a). The data extracted included the baseline characteristics of the intervention and control group participants, and included (where available): participant numbers, age, gender, ethnicity, the main outcome measures, length of follow‐up, and numbers of drop‐outs (Table 1).

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Table 1. Data extracted from included studies

Study identification

 Layton

 del Río Solá

Country        

United Kingdom

Spain

Period

Not reported

2001 to 2005

Centres

Academic Unit of Dermatology, General Infirmary at Leeds, West Yorkshire

University Hospital of Valladolid

Source of funding

 Not specified

 Not specified

Method

Study design

Prospective randomized, double‐blind

Prospective randomized trial

Power calculation

Not described

Yes

Method of randomisation

Not described

Generated by computer program

Concealment of allocation

Not described

Not described

Number of participants randomized

20

51

Number of participants analyzed

20

47

Number of participants excluded after randomizations

0

0

Number of participant withdrawals and reasons

0

4 people; 2 people needed hospitalisation and left the study and 2 people opted for treatment in another service

Intention‐to‐treat analysis

Yes

Yes

Participants

Inclusion criteria

People with chronic venous leg ulcer

Venous leg ulcer ≥ 2 cm

Ankle‐brachial rate < 0.9

No contraindication to taking aspirin

Exclusion criteria

Ulcer diameter < 2 cm

Already taking aspirin, anticoagulants or non‐steroidal anti‐inflammatory

Doppler flowmetry ankle‐brachial rate < 0.9

People with diabetes mellitus, rheumatoid arthritis, peripheral arterial disease and neurologic disease

Previous or concomitant therapy with aspirin

Aspirin

Control

P value

Aspirin

Control

P value

Number of participants

10

10

 

23

 28

 

Age (years)

62.2 years (mean)

(48‐81)

66 years (mean)

(46 ‐ 85)

 

60.50 years (SD:12.07)

58.59 years (SD:16.55)

reported as non significant

Sex

3 female, 7 male

5 female, 5 male

 

10 female, 13 male

19 female, 9 male

reported as non significant

Ulcer duration before the study

11.4 years (mean)

(1‐24)

10.5 years (mean)

(2‐22)

 

6‐12 months

> 12 months

 

1 Number of ulcers

Not reported

Not reported

Not reported

Not reported

reported as non significant

Initial ulcer surface area (cm²)

16.5 cm² (mean)

(2.5‐39.5)

14.25 cm² (mean)

(1.5‐48.5)

25.15 cm²

24.87 cm²

P=0.944

Signs of ulcer infection

Not reported

Not reported

Yes, 20 patients

Yes, 22 patients

P=0.094

Any comorbidity

Not reported

Not reported

9 patients

10 patients

Previously treated

\not reported

Not reported

10 patients

20 patients

Interventions

Aspirin 300 mg/day

Placebo

Aspirin 300 mg/day

No drug treatment

Outcomes

Follow‐up (months)

4 months

4 months

42 months mean (24‐61)

42 months mean (24‐61)

2 Withdrawals

0

0

2 people

2 people

Duration of the study to complete ulcer healing

Not reported

Not reported

Not reported

12.4 weeks

16.5 weeks

P=0.07 Mann‐Whitney

Healing period

Not reported

Not reported

Not reported

Reported as short in the aspirin group

Reported as short in the aspirin group

P=0.04

log‐rank test = 3.90

OR = 0.93 95% CI 0.25‐3.5

Average time to complete ulcer healing (weeks)

Not reported

Not reported

Not reported

12

22

Not reported

Number of participants with complete ulcer healing in the trial period

Not reported

Not reported

Not reported

17 (74%)

21 (75%)

reported as non significant

Proportion of ulcers healed in the trial period

38% of the ulcers

0% of the ulcers

< 0.007

(x² test)

Not reported

Not reported

Not reported

Change in ulcer areas in the trial period (second month; ulcer area cm²)

15.5 cm² (median)

1 cm² of reduction

(6.07% of reduction)

No reduction

< 0.01 (x² test)

 Not reported

 Not reported

Not reported

Reduction in ulcer size in the trial period (fourth month; ulcer area cm²)

10.0 cm² (median)

6.5 cm² of reduction (39.4% of reduction)

No reduction

< 0.002 (x² test)

Not reported

Not reported

Not reported

Improvement assessed by reduction in ulcer size

52% of the ulcers

26% of the ulcers

< 0.007

(x² test)

Not reported

Not reported

Not reported

Increase in ulcer size in the trial period

10% of the ulcers

26% of the ulcers

< 0.004

(x² test)

Not reported

Not reported

Not reported

Ulcers size unchanged in the trial period

0% of the ulcers

48% of the ulcers

< 0.001

(x2 test)

Not reported

Not reported

Not reported

Proportion of participants with ulcers healed in the trial period

Not reported

Not reported

Not reported

17 (74%)

21 (75%)

reported as non significant

Proportion of participants with ulcer recurrence

Not reported

Not reported

Not reported

25%

33.33%

0.74

Average time for ulcer recurrence (days)

Not reported

Not reported

Not reported

39 (SD 6)

16.33 (SD 7.5)

P=0.007 Kaplan‐Meier

adverse effects

0

0

0

0

Not reported

  1. Layton reported 12 people (60%) and del Rio 28 people (54%) with multiples ulcers but they did not specified the number in each group

  2. del Rio Solá reported that two people were hospitalised and were withdrawn from the study, but did not specify the cause of hospitalisation or their trial group

Assessment of risk of bias in included studies

We used the Cochrane tool for assessing risk of bias to present a summary of the risk of bias for each included study . This tool addresses seven specific domains Higgins 2011b:

  • Was the allocation sequence adequately generated?

  • Was the allocation adequately concealed?

  • Was the blinding of participants and personnel adequately provided?

  • Was the blinding of outcome assessors adequately provided?

  • Were incomplete outcome data adequately addressed?

  • Were reports of the study free of suggestion of selective outcome reporting?

  • Was the study apparently free of other problems that could put it at a high risk of bias?

Two authors (NGM and RFA) assessed each study independently; disagreements were solved by consultation with the third review author (PEdOC). Additionally, we presented a 'Risk of bias' summary figure, reporting all our judgements in a cross‐tabulation of study by entry (Figure 1). This display of internal validity shows the weight given to the results of the particular studies.


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

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

Measures of treatment effect

For binary outcomes (e.g. recurrence, improvement), we planned to present risk ratios (RR); risk differences (RD), the number needed to treat for an additional beneficial outcome (NNTB), and the number needed to treat for an additional harmful outcome (NNTH), all with corresponding 95% confidence intervals (CI).

For continuous data (e.g. ulcer area), we planned to present differences as mean differences (MD) with corresponding 95% CIs, or standardised mean differences (SMD) when the studies assessed the same outcome but measured it in a variety of ways (e.g. different questionnaires for pain assessment).

For time to complete ulcer healing, that is time‐to‐event data, we planned to use the most appropriate way of summarising this type of data using survival analysis methods and to express the intervention effect as a hazard ratio (HR).

Unit of analysis issues

We only considered simple parallel‐group designs for clinical trials (Deeks 2011). If healing outcomes were reported at several time points, we planned to perform the analysis using the time‐points reported (for example, 30 or 60 days or the time for ulcer healing). We planned to consider the number of ulcers per patient and the ulcer area per patient, which means, for patients with more than one ulcer, calculating the total area of the ulcers.

Dealing with missing data

We contacted the trial authors to obtain relevant missing data and investigated attrition rates (for example, drop‐outs, losses to follow‐up and withdrawals). Authors did not respond to our requests. We address the potential impact of missing data on the findings of the review in the discussion section (Higgins 2011c).

Assessment of heterogeneity

We planned to assess statistical heterogeneity using the I² statistic to examine the percentage of total variation across studies due to heterogeneity rather than to chance (Higgins 2003). Values of I² under 40% indicate a low level of heterogeneity and justify the use of a fixed‐effect model for meta‐analysis. Values of I² between 30% and 60% are considered to indicate moderate heterogeneity and a random‐effects model would have been used. Values of I² higher than 60% indicate a high level of heterogeneity; in which case meta‐analysis would not be appropriate. We planned to report whether statistical, methodological and clinical heterogeneity were present (Deeks 2011).

Assessment of reporting biases

If a sufficient number of studies had been eligible for inclusion (more than 10), we planned to use funnel plots to assess for the potential existence of small study bias. There are a number of explanations for the asymmetry of a funnel plot and we planned to interpret the results (Egger 1997).

Data synthesis

In the absence of heterogeneity, we planned to use a fixed‐effect model for meta‐analysis. If statistical heterogeneity was moderate (I² between 30% and 60%), we planned to use a random‐effects model. In the presence of substantial statistical heterogeneity between studies, we planned to present a narrative summary (O'Rourke 1989).

'Summary of findings' tables

We planned to present the main results of the review in 'Summary of findings' tables. These tables present key information concerning the quality of the evidence, the magnitude of the effects of the interventions examined and the sum of available data for the main outcomes (Schunemann 2011a). The 'Summary of findings' tables also include an overall grading of the evidence related to each of the main outcomes using the GRADE (Grades of Recommendation, Assessment, Development and Evaluation) approach. The GRADE approach defines the quality of a body of evidence as the extent to which one can be confident that an estimate of effect or association is close to the true quantity of specific interest. The quality of a body of evidence involves consideration of within trial risk of bias (methodological quality), directness of evidence, heterogeneity, precision of effect estimates and risk of publication bias (Schunemann 2011b). We planned to present the following outcomes in the 'Summary of findings' tables.

  • Time to complete ulcer healing.

  • Rate of changes in the area of the ulcer in the trial period.

  • Proportion of ulcers healed in the trial period.

  • Major bleeding (haemorrhagic stroke, gastric bleeding, any bleeding requiring blood transfusion, any bleeding causing hospitalisation).

  • Mortality from any cause.

  • Any adverse events (e.g. renal failure, neutropenia, low platelets level, gastric complaints, diarrhoea, skin rash, minor bleeding).

  • Ulcer recurrence (time to recurrence and proportion of people with recurrence).

Sensitivity analysis

We planned to perform sensitivity analyses to explore the influence of the following factors on the effect of aspirin:

  • repeating the analysis excluding unpublished studies;

  • repeating the analysis taking into account risk of bias: we planned to exclude those studies at high risk of bias (i.e. those lacking adequate sequence generation, unclear allocation concealment and no blinding of outcome assessment).

We also planned to test the robustness of the results by repeating the analysis using different measures of effect size (risk ratio, odds ratio, etc.) and different statistical models (fixed‐effect and random‐effects models; (Deeks 2011).

Results

Description of studies

Results of the search

The electronic search identified 62 studies; no studies were found through additional searching strategies (such as contact with experts and checking the references of studies​​). After the analysis of title and abstracts, we excluded 59 studies as they did not meet the inclusion criteria.Three RCTs were selected for full‐text analysis: Layton 1994; Ibbotson 1995 and del Río Solá 2012. After the full‐text analysis, two RCTs were included in the review (Layton 1994; del Río Solá 2012). Ibbotson 1995 used the same people and data as the Layton RCT but compared them with a control group of healthy people, so we excluded this trial (Figure 2).


Flow diagram of included and excluded studies

Flow diagram of included and excluded studies

Included studies

Details of the included studies are summarised in Characteristics of included studiesTable 1.

Layton 1994 reported a single‐centre parallel RCT (20 participants) that evaluated daily administration of oral aspirin (300 mg) in addition to compression, compared to placebo and compression. Participants were recruited from the Academic Unit of Dermatology, General Infirmary at Leeds, West Yorkshire, UK. del Río Solá 2012 reported a single‐centre parallel RCT (51 participants) that evaluated daily administration of oral aspirin (300 mg) in addition to compression compared to compression only and recruited from the Department of Angiology and Vascular Surgery, University Hospital of Valladolid, Spain, from December 2001 to September 2005.

Layton 1994 was a prospective trial that included 20 people with venous leg ulcers 2 cm or larger, divided into two parallel groups: 10 participants received oral aspirin (300 mg/day) plus compression therapy compared with 10 who received placebo plus compression therapy.

The del Río Solá 2012 study was a prospective trial that included 51 people with venous leg ulcers 2 cm or larger, divided into two parallel groups: 23 participants received oral aspirin (300 mg/day) plus compression therapy compared with 28 who received compression therapy alone.

The source of funding was not reported for either trial.

Both RCTs used the same intervention (oral aspirin 300 mg/day). The Layton 1994 study randomized participants to a placebo as an adjunct to compression therapy in the control group, while the del Río Solá 2012 study randomized those in the control group to compression therapy alone (no placebo). Compression therapy consisted of high compression (Setopress) in the Layton 1994 RCT. The del Río Solá 2012 RCT did not specify what type of compression was used, although the trialists reported the application of a two‐layer system consisting of one layer of padding and one layer of compression bandage.

The Layton 1994 trial followed participants for four months and then stopped the trial. The results were expressed in terms of reduction of the ulcers' size (surface area cm²) and proportions of ulcers completely healed in the trial period.

The del Río Solá 2012 trial followed participants until their ulcers had healed completely. The results were expressed in terms of proportion of healed ulcers in each group and average time for ulcer healing. . After healing, they continued to follow participants to analyse the proportion of ulcer recurrence and time until ulcer recurrence.

Excluded studies

We excluded the Ibbotson 1995 trial. This trial used the same participants reported in Layton 1994 and compared them with a control group of healthy people without venous leg ulcers. The objective was to evaluate some haemostatic parameters in people with venous leg ulcers taking oral aspirin (see Characteristics of excluded studies).

Ongoing studies

We identified three ongoing studies which evaluate the benefits and harms of aspirin in people with VLUs. (Characteristics of ongoing studies).

Low dose aspirin for venous leg ulcers in NZ (Aspirin4VLU) (NCT02158806) is a prospective, randomised, double blinded, 2 groups in parallel study that will evaluate whether aspirin (150 mg) once daily for up to 24 weeks improves time to healing when compared to placebo once daily for up to 24 weeks as an adjunct to compression. NCT02333123 is leading a phase II randomised, double blind, parallel group, placebo‐controlled efficacy trial taking place in the UK. The Aspirin for Venous Ulcer Randomised Trial (AVURT) will evaluate if aspirin 300 mg once daily for up to 27 weeks added to compression improves time to healing when compared to placebo once daily for up to 27 weeks. ACTRN12614000293662 is investigating the clinical effectiveness of aspirin as an adjunct to compression therapy in healing chronic venous leg ulcers: a randomised double‐blinded placebo‐controlled trial in Australia. The ASPiVLU study will compare if a daily dose of 300 mg enteric coated aspirin as an adjunct to compression for 24 weeks improves time to healing when compared to a placebo. Recruitment has commenced for all three trials.

Risk of bias in included studies

See Figure 1 and summary of findings Table for the main comparison.

Allocation

The Layton 1994 trial was described as 'randomized' but did not report the method of randomizations or the concealment of allocation. In del Río Solá 2012, randomization was undertaken by an independent researcher using a computer program, but allocation concealment was not described.

Blinding

The Layton 1994 trial compared oral aspirin with placebo, and the trial was described as 'double‐blinded', but the trialists did not describe their methods. The evaluation of ulcer size was conducted by planimetry of photographs taken in standardized conditions, so we judged this as low risk of bias.

The del Río Solá 2012 trial did not use a placebo but compared intervention (aspirin) with no intervention. In this scenario, blinding of participants and personnel was not possible. The study reported information about ulcer development (size, epithelization) weekly in a specific data sheet, but they did not describe who did what and how this work was done, so we judged this study as high risk of bias.

Incomplete outcome data

The Layton 1994 trial did not have any withdrawals. The del Río Solá 2012 trial reported four withdrawals, two from each group. Two of these four participants were withdrawn because they needed to be in hospital, but the cause and group assignments were not reported.

Selective reporting

As there were several inconsistencies in the del Río Solá 2012 report, we assigned the study a low risk of reporting bias. Time for complete ulcer healing in the control group, which was stated as 22 weeks in the text but as 16.5 weeks in the table (Table I of the study); errors with the numbers of people in each group, which were reported as 23 for the aspirin group and 28 for the control group in the main text, but appeared as 20 and 31 in the table; and the proportion of people completely healed was reported as 0.73% rather than 75% (21 out of 28 people) for the control group and 0.75% rather than 74% (17 out of 23 people) for the treatment group.

As the results of both prespecified primary outcomes were reported in Layton 1994, we judged it to be free of selective reporting.

Other potential sources of bias

The Layton 1994 trial was stopped in the fourth month. In that time, 38% of ulcers had healed in the aspirin group, but no ulcers had healed in the placebo group. However, the time period could be considered too short, as the assumption that all ulcers could heal in this period may lead to misinterpretation (i.e. some ulcers may have healed in the control group given more time).

In the del Río Solá 2012 trial, despite an appropriate method of randomizations (an independent researcher and computer program), the generated groups were different in relation to the length of time that people had ulcers before treatment. 'Young' ulcers predominated in the aspirin group, and may have had a tendency to heal faster than chronic or 'older' ulcers. Also, the trial authors did not determine a specific trial period. To calculate the size of the study, they used an expected difference of 45% between groups, but did not specify whether the difference was in the proportion of people with healed ulcers, the area of the ulcers or the time for healing.

Effects of interventions

See: Summary of findings for the main comparison Oral aspirin for venous leg ulcers

Both included RCTs analysed the ulcer healing time, but reported it using different outcome measures. The interventions that were studied in the two trials that reported relevant outcomes for this review were too heterogenous to allow pooling of outcomes data. We therefore reported the trial results for each trial separately.

Primary outcomes

Time to complete ulcer healing

The del Río Solá 2012 trial followed the people until the healing of their ulcers and reported the average time for healing was 12 weeks in the aspirin group and 22 weeks in the control group, P values and confidence intervals were not reported Table 1.

Rate of changes in the area of the ulcer in the trial period

The Layton 1994 stopped the trial in the fourth month and reported this outcome: by four months, ulcer area had reduced (by 6.5 cm², a 39.4% reduction) in the aspirin group compared with no reduction in ulcer area in the control group (P value < 0.002; summary of findings Table for the main comparison).

Proportion of ulcers healed in the trial period

The Layton 1994 trial reported this outcome: a higher proportion of the ulcers (38%) in the aspirin group had completely healed in the trial period compared with none in the control group (P value < 0.007; summary of findings Table for the main comparison).

Proportion of people with ulcers healed in the trial period

The del Río Solá 2012 trial reported that there was no real difference between the proportion of people with ulcers healed in the aspirin group (74%, 17 out of 23 people) and in the control group (75%, 21 out of 28 people; Table 1), (RR 0.99, 95% CI 0.71 to 1.36; Analysis 1.1).

Major bleeding (haemorrhagic stroke, gastric bleeding, any bleeding requiring blood transfusion, any bleeding causing hospitalisation)

The del Río Solá 2012 trial reported two hospitalisations, in addition to two other withdrawals, but did not specify the cause or the group assignment of the participants who withdrew (Table 1).

The Layton 1994 trial reported that no side effects were experienced (Table 1).

Secondary outcomes

Pain relief

Neither study reported pain relief.

Mortality

The Layton 1994 trial reported that no side effects were experienced.

The del Río Solá 2012 trial reported that two people needed hospitalisation and had to be withdrawn from the trial (in addition to two other withdrawals), but they didn't report the reason for hospitalisation or their group assignment. The authors did not report other adverse events.

Adverse events

The Layton 1994 trial reported that participants had no adverse effects, but did not explain how this was established. The del Río Solá 2012 trial did not report adverse events.

Ulcer recurrence

The del Río Solá 2012 trial reported the average time of ulcer recurrence was 16.33 days (SD: 7.5) in the control group and 39 days (SD: 6.0) in the aspirin group (P = 0.007).

Layton 1994 did not report recurrence.

Discussion

available in

Summary of main results

Aspirin has been used as medication since 1899 and its pharmacodynamic properties as an anti‐inflammatory, analgesic, antipyretic, and inhibitor of both platelet aggregation and biosynthesis of prostaglandins, have been well studied. VLUs are associated with venous stasis, inflammation and necrosis; so some of the properties of aspirin may be useful for patients with VLUs. We searched extensively in seven different databases, using an appropriate search strategy for each one, to identify studies that had analysed the effect of aspirin on healing of VLUs. This review intended to summarize the effect of oral aspirin in treatment of VLUs; our searches identified no previous reviews and only two clinical trials that could be included, del Río Solá 2012 with 51 participants, and Layton 1994 with 20 participants. Both studies used the same intervention (oral aspirin 300 mg/day) and had the objective of evaluating the effects of oral aspirin on the healing of VLUs, however they used different outcome measurements. The Layton 1994 trial compared the average reduction in ulcer area in the second and fourth months, while the del Río Solá 2012 trial compared the average time for complete healing of the ulcer. The conclusions of both studies favoured the aspirin group: Layton 1994 showed a significant reduction in ulcer area in the fourth month of treatment and del Río Solá 2012 showed a significant reduction in the time required for complete healing of ulcers. However the two studies included very few participants, a total of 71, and the differences in the outcomes measurements prevented meta‐analysis. The evidence was downgraded to low quality due to the potential for selection bias and imprecision in the results, thus there is uncertainty around the effect estimates.

Overall completeness and applicability of evidence

There was scant evidence available to assess the benefits of 300,mg aspirin to heal people with venous leg ulcers.The small number, small size and differing outcome measurements of the two included trials meant that there was insufficient evidence for us to draw meaningful conclusions about the use of oral aspirin in the treatment of VLUs.

The benefits and harms of aspirin varies with its plasmatic level. Aspirin blood concentration from 50 to 300 mcg/ml are sufficient for most of its therapeutic effects and doses greater than 200 mcg/ml increase the risks for adverse events. Nowadays aspirin is used to treat many vascular conditions such as, ischemic stroke, angina pectoris, myocardial infarction, revascularization procedures, etc, with doses that vary from 50 to 325 mg/day. Both studies included in this review used 300 mg aspirin daily, however, the ideal dose for each clinical condition remains in debate (Cappelleri 1995; Dalen 2006).

Layton 1994, did not report any characteristics of the population included in his study; del Río Solá 2012 included 51 patients, 29 women and 22 men with mean age of 60 years ranging from 36‐86 years old. The study excluded patients with co morbidities such as diabetes mellitus, rheumatoid arthritis, peripheral arterial disease and neurologic disease. The characteristics of this population is in concordance with the populations described in the epidemiologic studies of chronic venous insufficiency (Beebe‐Dimmer 2005).

Quality of the evidence

Only low quality evidence was available from two trials and both the RCTs that were eligible for inclusion in the review had an unclear or high risk of bias for most domains (allocation concealment, blinding of participants and personnel, incomplete outcome data and other biases). Due to the lack of reliable evidence, we are unable to draw conclusions about the benefits and harms of oral daily aspirin as an adjunct to compression in VLU healing or recurrence. We graded the overall quality of the evidence as low, indicating that future research is likely to have an important influence on the effect estimates.

Potential biases in the review process

We are confident that the broad literature search used in this review has captured most of the relevant literature, and minimised the likelihood that we have missed any relevant trials. Two review authors independently selected trials, extracted data, and assessed risk of bias, in order to minimise bias. Due to the differences in reporting of outcome measures between the trials, we could not conduct the planned meta‐analysis.

Agreements and disagreements with other studies or reviews

This is the first review of randomised studies that address this question, as far as we are aware. The treatment of VLUs can be frustrating for physicians and people with ulcers because these kinds of ulcers have a tendency to recur and become chronic. Some therapies are already well established, such as compression and rest with elevated legs (O'Meara 2012). On the basis of recent research that showed the importance of inflammation in the development of ulcers, new therapies using anti‐inflammatory drugs have been evaluated, including pentoxifylline (Jull 2007), prostaglandins (Rudofsky 1989), and prostacyclin analogues (Werner‐Schlenzka 1994). These studies often describe benefits, but like the studies included in this review, they have only included small numbers of participants.

Risk of bias graph: review authors' judgements about each risk of bias item presented as percentages across all included studies.
Figures and Tables -
Figure 1

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

Flow diagram of included and excluded studies
Figures and Tables -
Figure 2

Flow diagram of included and excluded studies

Comparison 1 Oral aspirin versus control, Outcome 1 Number of people with healed ulcer.
Figures and Tables -
Analysis 1.1

Comparison 1 Oral aspirin versus control, Outcome 1 Number of people with healed ulcer.

Comparison 1 Oral aspirin versus control, Outcome 2 Time to recurrence (days).
Figures and Tables -
Analysis 1.2

Comparison 1 Oral aspirin versus control, Outcome 2 Time to recurrence (days).

Summary of findings for the main comparison. Oral aspirin for venous leg ulcers

Oral aspirin for venous leg ulcers

Patient or population: patients with venous leg ulcers
Settings: hospital outpatients in UK and Spain
Intervention: oral aspirin

Outcomes

Illustrative comparative risks* (95% CI)

Relative effect
(95% CI)

No of participants
(studies)

Quality of the evidence
(GRADE)

Comments

Assumed risk

Corresponding risk

Control

Oral aspirin

Average time for ulcer healing

22 weeks

12 weeks

Not estimable

51 (1 study)

⊕⊕⊝⊝
low1,2

P values and confidence intervals were not reported

Reduction of ulcer area (median)

0 cm²

6.5cm²

Not estimable

20
(1 study)

⊕⊕⊝⊝
low2,3

P value < 0.002

Follow‐up: 4 months

Proportion of healed ulcers in the trial period

No healed ulcers

38% of healed ulcers

Not estimable

20
(1 study)

⊕⊕⊝⊝
low2,3

P value < 0.007

Follow‐up: 4 months

Major bleeding

See comment

See comment

Not estimable

20
(1 study)

⊕⊕⊝⊝
low2,3

No events were observed in either group, follow‐up: 4 months

Another study reported 2 hospitalisations for unknown reasons, intervention group not specified

Average time of ulcer recurrence

16.33 days

SD: 7.5

39 days

SD: 6.0

Not estimable

51
(1 study)

⊕⊕⊝⊝
low1,2

P value = 0.007

Post hoc assessment not pre‐specified in protocol

Mortality

See comment

See comment

Not estimable

See comment

See comment

Mortality not reported

Other adverse events

See comment

See comment

Not estimable

71
(2 study)

See comment

No events were observed in either group. del Río Solá reported 2 hospitalisations for unknown reasons, the group of these patients were not specified and they were removed from the study

*The basis for the assumed risk (for example, the median control group risk across studies) is provided in footnotes. The corresponding risk (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; RR: risk ratio; SD: standard deviation

GRADE Working Group grades of evidence
High quality: Further research is very unlikely to change our confidence in the estimate of effect
Moderate quality: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate
Low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and is likely to change the estimate
Very low quality: We are very uncertain about the estimate

1 Allocation concealment and blinding of outcome assessment were not described. Participants and personnel were not blinded. There was a high risk of bias from incomplete outcome data.There were some inconsistencies in the reporting of the data
2 The study results are based on one small study with insufficient data to estimate the effect precisely
3 Selection, performance and reporting biases were unclear

Figures and Tables -
Summary of findings for the main comparison. Oral aspirin for venous leg ulcers
Table 1. Data extracted from included studies

Study identification

 Layton

 del Río Solá

Country        

United Kingdom

Spain

Period

Not reported

2001 to 2005

Centres

Academic Unit of Dermatology, General Infirmary at Leeds, West Yorkshire

University Hospital of Valladolid

Source of funding

 Not specified

 Not specified

Method

Study design

Prospective randomized, double‐blind

Prospective randomized trial

Power calculation

Not described

Yes

Method of randomisation

Not described

Generated by computer program

Concealment of allocation

Not described

Not described

Number of participants randomized

20

51

Number of participants analyzed

20

47

Number of participants excluded after randomizations

0

0

Number of participant withdrawals and reasons

0

4 people; 2 people needed hospitalisation and left the study and 2 people opted for treatment in another service

Intention‐to‐treat analysis

Yes

Yes

Participants

Inclusion criteria

People with chronic venous leg ulcer

Venous leg ulcer ≥ 2 cm

Ankle‐brachial rate < 0.9

No contraindication to taking aspirin

Exclusion criteria

Ulcer diameter < 2 cm

Already taking aspirin, anticoagulants or non‐steroidal anti‐inflammatory

Doppler flowmetry ankle‐brachial rate < 0.9

People with diabetes mellitus, rheumatoid arthritis, peripheral arterial disease and neurologic disease

Previous or concomitant therapy with aspirin

Aspirin

Control

P value

Aspirin

Control

P value

Number of participants

10

10

 

23

 28

 

Age (years)

62.2 years (mean)

(48‐81)

66 years (mean)

(46 ‐ 85)

 

60.50 years (SD:12.07)

58.59 years (SD:16.55)

reported as non significant

Sex

3 female, 7 male

5 female, 5 male

 

10 female, 13 male

19 female, 9 male

reported as non significant

Ulcer duration before the study

11.4 years (mean)

(1‐24)

10.5 years (mean)

(2‐22)

 

6‐12 months

> 12 months

 

1 Number of ulcers

Not reported

Not reported

Not reported

Not reported

reported as non significant

Initial ulcer surface area (cm²)

16.5 cm² (mean)

(2.5‐39.5)

14.25 cm² (mean)

(1.5‐48.5)

25.15 cm²

24.87 cm²

P=0.944

Signs of ulcer infection

Not reported

Not reported

Yes, 20 patients

Yes, 22 patients

P=0.094

Any comorbidity

Not reported

Not reported

9 patients

10 patients

Previously treated

\not reported

Not reported

10 patients

20 patients

Interventions

Aspirin 300 mg/day

Placebo

Aspirin 300 mg/day

No drug treatment

Outcomes

Follow‐up (months)

4 months

4 months

42 months mean (24‐61)

42 months mean (24‐61)

2 Withdrawals

0

0

2 people

2 people

Duration of the study to complete ulcer healing

Not reported

Not reported

Not reported

12.4 weeks

16.5 weeks

P=0.07 Mann‐Whitney

Healing period

Not reported

Not reported

Not reported

Reported as short in the aspirin group

Reported as short in the aspirin group

P=0.04

log‐rank test = 3.90

OR = 0.93 95% CI 0.25‐3.5

Average time to complete ulcer healing (weeks)

Not reported

Not reported

Not reported

12

22

Not reported

Number of participants with complete ulcer healing in the trial period

Not reported

Not reported

Not reported

17 (74%)

21 (75%)

reported as non significant

Proportion of ulcers healed in the trial period

38% of the ulcers

0% of the ulcers

< 0.007

(x² test)

Not reported

Not reported

Not reported

Change in ulcer areas in the trial period (second month; ulcer area cm²)

15.5 cm² (median)

1 cm² of reduction

(6.07% of reduction)

No reduction

< 0.01 (x² test)

 Not reported

 Not reported

Not reported

Reduction in ulcer size in the trial period (fourth month; ulcer area cm²)

10.0 cm² (median)

6.5 cm² of reduction (39.4% of reduction)

No reduction

< 0.002 (x² test)

Not reported

Not reported

Not reported

Improvement assessed by reduction in ulcer size

52% of the ulcers

26% of the ulcers

< 0.007

(x² test)

Not reported

Not reported

Not reported

Increase in ulcer size in the trial period

10% of the ulcers

26% of the ulcers

< 0.004

(x² test)

Not reported

Not reported

Not reported

Ulcers size unchanged in the trial period

0% of the ulcers

48% of the ulcers

< 0.001

(x2 test)

Not reported

Not reported

Not reported

Proportion of participants with ulcers healed in the trial period

Not reported

Not reported

Not reported

17 (74%)

21 (75%)

reported as non significant

Proportion of participants with ulcer recurrence

Not reported

Not reported

Not reported

25%

33.33%

0.74

Average time for ulcer recurrence (days)

Not reported

Not reported

Not reported

39 (SD 6)

16.33 (SD 7.5)

P=0.007 Kaplan‐Meier

adverse effects

0

0

0

0

Not reported

  1. Layton reported 12 people (60%) and del Rio 28 people (54%) with multiples ulcers but they did not specified the number in each group

  2. del Rio Solá reported that two people were hospitalised and were withdrawn from the study, but did not specify the cause of hospitalisation or their trial group

Figures and Tables -
Table 1. Data extracted from included studies
Comparison 1. Oral aspirin versus control

Outcome or subgroup title

No. of studies

No. of participants

Statistical method

Effect size

1 Number of people with healed ulcer Show forest plot

1

51

Risk Ratio (M‐H, Fixed, 95% CI)

0.99 [0.71, 1.36]

2 Time to recurrence (days) Show forest plot

1

51

Mean Difference (IV, Fixed, 95% CI)

22.67 [18.96, 26.38]

Figures and Tables -
Comparison 1. Oral aspirin versus control