Safety and efficacy of tranexamic acid in minimizing perioperative bleeding in extrahepatic abdominal surgery: meta-analysis.

BACKGROUND: Perioperative bleeding is associated with increased morbidity and mortality in patients undergoing elective abdominal surgery. The antifibrinolytic agent tranexamic acid (TXA) has been shown to reduce perioperative bleeding and mortality risk in patients with traumatic injuries, but there is a lack of evidence for its use in elective abdominal and pelvic surgery. This meta-analysis of RCTs evaluated the effectiveness and safety of TXA in elective extrahepatic abdominopelvic surgery.
METHODS: PubMed, Embase, and ClinicalTrial.gov databases were searched to identify relevant RCTs from January 1947 to May 2020. The primary outcome, intraoperative blood loss, and secondary outcomes, need for perioperative blood transfusion, units of blood transfused, thromboembolic events, and mortality, were extracted from included studies. Quantitative pooling of data was based on a random-effects model.
RESULTS: Some 19 studies reporting on 2205 patients who underwent abdominal, pelvic, gynaecological or urological surgery were included. TXA reduced intraoperative blood loss (mean difference -188.35 (95 per cent c.i. -254.98 to -121.72) ml) and the need for perioperative blood transfusion (odds ratio (OR) 0.43, 95 per cent c.i. 0.28 to 0.65). TXA had no impact on the incidence of thromboembolic events (OR 0.49, 0.18 to 1.35). No adverse drug reactions or in-hospital deaths were reported.
CONCLUSION: TXA reduces intraoperative blood loss during elective extrahepatic abdominal and pelvic surgery without an increase in complications.

Introduction

Perioperative bleeding is a major risk during and after surgery, and is associated with increases in transfusion requirements, treatment costs, morbidity and mortality,. The cause of bleeding in the surgical patient is multifactorial, and can include several contributing factors such as undiagnosed and acquired coagulopathies, haemodilution, activation of fibrinolytic and inflammatory factors, and hypothermia,. Perioperative bleeding is the most common indication for blood transfusion in the inpatient setting. Blood transfusion carries significant risks, including transfusion-related adverse reactions, infections, renal impairment, immunological incompatibility, and even death,.

Tranexamic acid (TXA) is a synthetic lysine analogue that reduces the risk of haemorrhage by inhibition of plasmin activity and therefore fibrinolysis. Its antifibrinolytic properties were first described in 1966. Its effectiveness in reducing perioperative blood loss and improving outcomes have been described in trauma, and orthopaedic surgery,, resulting in its incorporation into the standard of care. It is a safe drug with minimal serious side-effects even at high doses and with long-term use. TXA is inexpensive, costing €20 for a single dose, whereas a single blood transfusion can cost up to €170.

Although evidence exists for its use in trauma,, there is a lack of data showing benefit in elective abdominal and pelvic procedures, which are often associated with high risks of surgical bleeding,. A Cochrane review in 2011 evaluated three antifibrinolytic agents, including aprotinin, TXA, and ε-aminocaproic acid, in elective surgery. Of the 53 trials included in that review reporting on TXA use, only three involved elective abdominal or pelvic surgery. Current National Institute for Health and Care Excellence guidelines recommend the administration of perioperative TXA in procedures with a reasonable likelihood of moderate blood loss (quantified as 500 ml), but of the 25 trials reviewed only four were in abdominal or pelvic surgery; the majority were studies in orthopaedic, cardiac, and head and neck surgery. In these trials, TXA was given topically, orally or intravenously, and at a variety of doses. Whether these results can be extrapolated to cover all of elective abdominal surgery is debatable. The recently published HALT-IT trial concluded that TXA was not beneficial for gastrointestinal bleeding, suggesting that the pathophysiology of bleeding may well be specific to the patient population and setting.

The aim of this systematic review was to evaluate the efficacy and safety of TXA in elective extrahepatic abdominal and pelvic surgery based on the results from RCTs.

Methods

This systematic review was conducted according to the PRISMA statement.

Search strategy

A systematic search of MEDLINE, Embase, PubMed, and ClinicalTrials.gov databases was undertaken to identify relevant studies from January 1947 to May 2020. Medical Subject Heading (MeSH) terms and keywords relating to TXA in perioperative bleeding were combined with terms relating to gastrointestinal, urological, and gynaecological surgery, [‘tranexamic acid’] AND [‘perioperative’ OR ‘intraoperative’ OR ‘postoperative’ AND ‘haemorrhage’] AND [‘abdominal surgery’ or ‘pelvic surgery’] (). Cochrane Handbook search filters were used to identify RCTs using the sensitivity-maximizing filter. The bibliographies of all studies that met the inclusion criteria were hand‐searched for additional articles to ensure comprehensive study inclusion.

Inclusion criteria

The review included RCTs evaluating the use of perioperative systemic TXA (oral or intravenous) administered to any patients undergoing elective abdominal extrahepatic surgery. This included extrahepatic gastrointestinal, vascular, urological, and gynaecological procedures. Comparator groups of interest included standard of care, placebo or no intervention. Studies had to include human subjects aged 18 years or older; only those published in English were considered.

Exclusion criteria

Case reports, observational studies, letters, systematic reviews, and meta-analyses were excluded. RCTs evaluating antifibrinolytics other than TXA were excluded from analysis. Studies in which TXA was not the sole agent and those that lacked a comparator group were excluded. RCTs evaluating TXA in hepatic, skeletal, non-abdominal, non-surgical, and emergency or trauma procedures were not examined.

Study selection and data extraction

Studies were screened based on title and abstract. Those meeting the eligibility criteria were read in full. Two reviewers independently assessed the full texts of the retrieved studies to ensure they met the inclusion criteria, with discordance resolved by consensus.

Study characteristics and outcomes were documented using a standardized data extraction form. This included information regarding randomization, blinding, methodology, type of surgical procedure, target population, and treatment outcomes. The following data were reported for each selected study: year of publication, authors, study characteristics, inclusion and exclusion criteria, dose and timing of TXA administration, description of control group, and sample size.

The primary outcome was intraoperative blood loss, and secondary outcomes were need for perioperative blood transfusion, thromboembolic events, and mortality.

For the purpose of statistical analysis, the procedures were grouped into abdominal (urology, general and vascular surgery) and pelvic (obstetrics and gynaecology) operations.

Assessment of risk of bias

Studies that met the inclusion criteria were assessed for risk of bias using the Cochrane Collaboration’s tool. The following domains were assessed for each study: selection bias, performance bias, detection bias, attrition, and reporting bias. A risk-of-bias table was completed using Review Manager (RevMan version 5.4) software (The Nordic Cochrane Centre, Copenhagen, Denmark).

Statistical analysis

Meta-analyses of the pooled data were performed using RevMan version 5.4. Effects for dichotomous outcomes were summarized as odds ratios (ORs) with 95 per cent confidence intervals. For continuous outcomes, the results were presented as weighted mean differences (MDs) with 95 per cent confidence intervals. Statistical heterogeneity of the included studies was measured by using the I statistic, with upper limits of 25, 50 and 75 per cent considered to represent statistically low, moderate, and high levels of heterogeneity respectively. Publication bias was assessed as described by Eggers and colleagues, using visual inspection for asymmetry of the funnel plot based on the primary outcome.

Protocol registration

The protocol for this systematic review was registered with Open Science Framework Registries.

Results

Study selection

A total of 533 studies were retrieved () with a further 15 studies identified by hand-searching. After excluding duplicates, 479 abstracts were reviewed, and 20 full publications identified as potentially eligible. After critical appraisal of the studies, one was excluded owing to ambiguous randomization techniques, leaving 19 RCTs that met the eligibility criteria with a total of 2205 participants (1119 TXA, 1086 control).

PRISMA diagram showing selection of articles for review

Study characteristics

Included studies were published between 2008 and 2020 (). There were seven trials from Asia, seven from the Middle East, four from Europe, and one from Africa. Trials included procedures in vascular surgery (1), urology (2),, general surgery (3), gynaecology (6), and obstetrics (7).

Description of dose regimen

In 13 of 19 trials, TXA was given as a single bolus before operation (). In the other trials, it was administered as a bolus before surgery followed by a continuous infusion (4 trials), or as a preoperative bolus with subsequent additional doses (2 trials). The most common TXA dosing was based on patient weight (11 of 19 trials).

TXA was compared with placebo in 16 trials, and normal standard of care in three. Two trials, had three arms, whereby the authors compared two TXA doses with placebo. For the purpose of this analysis, data from the two TXA subgroups were combined to allow a pooled comparison of outcomes between patients receiving TXA and control, irrespective of dosage.

Meta-analysis

Intraoperative blood loss

Twelve studies,,,,, reported the effect of TXA on intraoperative blood loss (). Compared with the control group, TXA had a statistically significant effect in reducing intraoperative blood loss (MD –188.35 (95 per cent c.i. –254.98 to –121.72) ml), albeit with significant heterogeneity between studies (I2 = 89 per cent). In separate analyses of abdominal and pelvic surgery, there was acceptable heterogeneity in intraoperative blood loss in the abdominal group (I2 = 11 per cent). Statistical heterogeneity for the pelvic group remained substantial (I2 = 92 per cent), and was not resolved by further stratification into gynaecology and obstetrics.

Meta-analysis of the effect of tranexamic acid on intraoperative blood loss

An inverse-variance random-effects model was used for meta-analysis. Mean differences are shown with 95 per cent confidence intervals. *values are mean(s.d.). TXA, tranexamic acid.

Need for perioperative blood transfusion

Fifteen studies,, reported on the need for perioperative blood transfusion (). TXA significantly reduced the proportion of patients requiring a transfusion (OR 0.43, 95 per cent c.i. 0.28 to 0.65), with acceptable statistical heterogeneity across all surgery types, with and without subgroup analyses (overall I2 = 36 per cent).

Meta-analysis of the effect of tranexamic acid on the need for blood transfusion

A Mantel–Haenszel random-effects model was used for meta-analysis. Odds ratios are shown with 95 per cent confidence intervals. TXA, tranexamic acid.

Unit volume of blood transfused

Only four studies,,, reported on the unit volume of blood transfused (). Administration of TXA did not affect the volume of blood transfused (MD –0.16 (95 per cent c.i. –0.56 to 0.25) units).

Meta-analysis of the effect of tranexamic acid on units of blood transfused

An inverse-variance random-effects model was used for meta-analysis. Mean differences are shown with 95 per cent confidence intervals. *values are mean(s.d.). TXA, tranexamic acid.

Thromboembolic events

Of 15 studies,, that reported on thromboembolic complications (), 12 had no thromboembolic events in either arm. Of the three trials that found thromboembolic events, there was no statistical difference between the TXA and control groups (OR 0.49, 95 per cent c.i. 0.18 to 1.35).

Meta-analysis of the effect of tranexamic acid on thromboembolic events

A Mantel–Haenszel random-effects model was used for meta-analysis. Odds ratios are shown with 95 per cent confidence intervals. TXA, tranexamic acid.

Mortality

Only five studies,,,, considered mortality as an outcome. The duration of follow-up in these studies ranged from the hospital admission to 1 year. There were no deaths reported in any study.

Risk of bias

Overall, five trials had a low risk, six a high risk, and eight an unclear risk of bias (). The random sequence generation was adequate in 14 trials, whereas the allocation was concealed adequately in 12. Risk of bias for blinding was adequate in seven trials.

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

+, Low risk of bias; ?, unclear risk of bias; –, high risk of bias.

Of the 12 studies reporting intraoperative blood loss, five had a low risk of blinding bias, three had a high risk, and four an unclear risk. The risk of bias of blinding was similar in studies that reported the need for transfusion (6 studies low risk, 4 studies high risk, and 5 studies unclear risk) and thromboembolic events (6 studies low risk, 4 studies high risk, and 5 studies unclear risk).

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Table 1

Study characteristics

Reference	Study interval	Setting	No. of participants	Surgery type	Procedure(s) performed
Monaco et al.50	2015–2018	Italy (single centre)	100	Vascular	Open repair of AAA^
Abbas et al.62	2016–2017	Egypt (single centre)	62	Obstetrics	Caesarean section
Abdul et al.56	2017–2018	Nigeria (single centre)	80	Gynaecology	Abdominal myomectomy
Sallam and Shady57	2015–2017	Egypt (single centre)	86*	Gynaecology	Abdominal hysterectomy
Prasad et al.53	Unknown	India	60	General Surgery	Bilateral adrenalectomy Abdominoperineal resection Hemicolectomy Uterine myomectomy Radical nephrectomy Radical cystectomy Hysterectomy Pancreatectomy Sigmoidectomy
Shady et al.58	2015–2017	Egypt (single centre)	70	Gynaecology	Abdominal myomectomy
Alhomoud54	2014	Kuwait (single centre)	50	General surgery	Laparoscopic sleeve gastrectomy
Sujata et al.63	2012–2013	India (single centre)	60	Obstetrics	Caesarean section
Topsoee et al.59	2013–2014	Denmark (4 centres)	332	Gynaecology	Hysterectomy
Lundin et al.60	2008–2012	Sweden (4 centres)	100	Gynaecology	Open radical debulking surgery for ovarian cancer
Goswami et al.64	2009–2011	India (single centre)	90	Obstetrics	Caesarean section
Kumar et al.51	2011–2012	India (single centre)	200	Urology	Percutaneous nephrolithotomy
Sentürk et al.65	2010	Turkey (single centre)	223	Obstetrics	Caesarean section
Shahid and Khan66	2009–2011	Pakistan (single centre)	74	Obstetrics	Caesarean section
Xu et al.67	2008–2011	China (single centre)	174	Obstetrics	Caesarean section
Pfizer55	2009–2011	India (single centre)	44	General surgery	Biliary tract surgical procedures Pancreatoduodenectomy Oesophagectomy Colectomy Gastrectomy
Crescenti et al.52	2008–2010	Italy (single centre)	200	Urology	Retropubic prostatectomy
Movafegh et al.68	2009–2010	Iran (single centre)	100	Obstetrics	Caesarian section
Caglar et al.61	2004	Turkey (single centre)	100	Gynaecology	Myomectomy

*The study recruited 129 patients; however only 86 were eligible for inclusion in this current analysis. ^AAA, abdominal aortic aneurysm.