Wikkelsø Anne, Wetterslev Jørn, Møller Ann Merete, Afshari Arash
Department of Anaesthesiology and Intensive Care Medicine, Hvidovre Hospital, University of Copenhagen, Kettegård Alle 30,, Hvidovre, Denmark, 2650.
Cochrane Database Syst Rev. 2016 Aug 22;2016(8):CD007871. doi: 10.1002/14651858.CD007871.pub3.
Severe bleeding and coagulopathy are serious clinical conditions that are associated with high mortality. Thromboelastography (TEG) and thromboelastometry (ROTEM) are increasingly used to guide transfusion strategy but their roles remain disputed. This review was first published in 2011 and updated in January 2016.
We assessed the benefits and harms of thromboelastography (TEG)-guided or thromboelastometry (ROTEM)-guided transfusion in adults and children with bleeding. We looked at various outcomes, such as overall mortality and bleeding events, conducted subgroup and sensitivity analyses, examined the role of bias, and applied trial sequential analyses (TSAs) to examine the amount of evidence gathered so far.
In this updated review we identified randomized controlled trials (RCTs) from the following electronic databases: Cochrane Central Register of Controlled Trials (CENTRAL; 2016, Issue 1); MEDLINE; Embase; Science Citation Index Expanded; International Web of Science; CINAHL; LILACS; and the Chinese Biomedical Literature Database (up to 5 January 2016). We contacted trial authors, authors of previous reviews, and manufacturers in the field. The original search was run in October 2010.
We included all RCTs, irrespective of blinding or language, that compared transfusion guided by TEG or ROTEM to transfusion guided by clinical judgement, guided by standard laboratory tests, or a combination. We also included interventional algorithms including both TEG or ROTEM in combination with standard laboratory tests or other devices. The primary analysis included trials on TEG or ROTEM versus any comparator.
Two review authors independently abstracted data; we resolved any disagreements by discussion. We presented pooled estimates of the intervention effects on dichotomous outcomes as risk ratio (RR) with 95% confidence intervals (CIs). Due to skewed data, meta-analysis was not provided for continuous outcome data. Our primary outcome measure was all-cause mortality. We performed subgroup and sensitivity analyses to assess the effect based on the presence of coagulopathy of a TEG- or ROTEM-guided algorithm, and in adults and children on various clinical and physiological outcomes. We assessed the risk of bias through assessment of trial methodological components and the risk of random error through TSA.
We included eight new studies (617 participants) in this updated review. In total we included 17 studies (1493 participants). A total of 15 trials provided data for the meta-analyses. We judged only two trials as low risk of bias. The majority of studies included participants undergoing cardiac surgery.We found six ongoing trials but were unable to retrieve any data from them. Compared with transfusion guided by any method, TEG or ROTEM seemed to reduce overall mortality (7.4% versus 3.9%; risk ratio (RR) 0.52, 95% CI 0.28 to 0.95; I(2) = 0%, 8 studies, 717 participants, low quality of evidence) but only eight trials provided data on mortality, and two were zero event trials. Our analyses demonstrated a statistically significant effect of TEG or ROTEM compared to any comparison on the proportion of participants transfused with pooled red blood cells (PRBCs) (RR 0.86, 95% CI 0.79 to 0.94; I(2) = 0%, 10 studies, 832 participants, low quality of evidence), fresh frozen plasma (FFP) (RR 0.57, 95% CI 0.33 to 0.96; I(2) = 86%, 8 studies, 761 participants, low quality of evidence), platelets (RR 0.73, 95% CI 0.60 to 0.88; I(2) = 0%, 10 studies, 832 participants, low quality of evidence), and overall haemostatic transfusion with FFP or platelets (low quality of evidence). Meta-analyses also showed fewer participants with dialysis-dependent renal failure.We found no difference in the proportion needing surgical reinterventions (RR 0.75, 95% CI 0.50 to 1.10; I(2) = 0%, 9 studies, 887 participants, low quality of evidence) and excessive bleeding events or massive transfusion (RR 0.38, 95% CI 0.38 to 1.77; I(2) = 34%, 2 studies, 280 participants, low quality of evidence). The planned subgroup analyses failed to show any significant differences.We graded the quality of evidence as low based on the high risk of bias in the studies, large heterogeneity, low number of events, imprecision, and indirectness. TSA indicates that only 54% of required information size has been reached so far in regards to mortality, while there may be evidence of benefit for transfusion outcomes. Overall, evaluated outcomes were consistent with a benefit in favour of a TEG- or ROTEM-guided transfusion in bleeding patients.
AUTHORS' CONCLUSIONS: There is growing evidence that application of TEG- or ROTEM-guided transfusion strategies may reduce the need for blood products, and improve morbidity in patients with bleeding. However, these results are primarily based on trials of elective cardiac surgery involving cardiopulmonary bypass, and the level of evidence remains low. Further evaluation of TEG- or ROTEM-guided transfusion in acute settings and other patient categories in low risk of bias studies is needed.
严重出血和凝血功能障碍是严重的临床病症,与高死亡率相关。血栓弹力图(TEG)和血栓弹力测定法(ROTEM)越来越多地用于指导输血策略,但其作用仍存在争议。本综述首次发表于2011年,并于2016年1月更新。
我们评估了在出血的成人和儿童中,采用血栓弹力图(TEG)或血栓弹力测定法(ROTEM)指导输血的利弊。我们研究了各种结局,如总死亡率和出血事件,进行了亚组分析和敏感性分析,检查了偏倚的作用,并应用试验序贯分析(TSA)来检查迄今收集的证据量。
在本次更新的综述中,我们从以下电子数据库中识别随机对照试验(RCT):Cochrane对照试验中心注册库(CENTRAL;2016年第1期);医学期刊数据库(MEDLINE);Embase数据库;科学引文索引扩展版;国际科学网;护理学与健康领域数据库(CINAHL);拉丁美洲和加勒比卫生科学数据库(LILACS);以及中国生物医学文献数据库(截至2016年1月5日)。我们联系了试验作者、既往综述的作者以及该领域的制造商。最初的检索于2010年10月进行。
我们纳入了所有随机对照试验,无论是否采用盲法或语言,这些试验将TEG或ROTEM指导的输血与临床判断指导的输血、标准实验室检查指导的输血或两者结合指导的输血进行比较。我们还纳入了包括TEG或ROTEM与标准实验室检查或其他设备相结合的干预算法。主要分析包括关于TEG或ROTEM与任何对照的试验。
两位综述作者独立提取数据;我们通过讨论解决任何分歧。我们以风险比(RR)和95%置信区间(CI)的形式呈现了对二分结局的干预效果的合并估计值。由于数据呈偏态分布,未对连续结局数据进行荟萃分析。我们的主要结局指标是全因死亡率。我们进行了亚组分析和敏感性分析,以评估基于TEG或ROTEM指导算法的凝血功能障碍的存在,以及在成人和儿童中各种临床和生理结局的影响。我们通过评估试验方法学组成部分来评估偏倚风险,并通过TSA评估随机误差风险。
在本次更新的综述中,我们纳入了八项新研究(617名参与者)。我们总共纳入了17项研究(1493名参与者)。共有15项试验提供了荟萃分析的数据。我们仅将两项试验判定为低偏倚风险。大多数研究纳入了接受心脏手术的参与者。我们发现有六项正在进行的试验,但无法从中检索到任何数据。与任何方法指导的输血相比,TEG或ROTEM似乎降低了总死亡率(7.4%对3.9%;风险比(RR)0.52,95%CI 0.28至0.95;I² = 0%,8项研究,717名参与者,证据质量低),但只有八项试验提供了死亡率数据,其中两项是零事件试验。我们的分析表明,与任何对照相比,TEG或ROTEM在输注浓缩红细胞(PRBC)的参与者比例上有统计学显著效果(RR 0.86,95%CI 0.79至0.94;I² = 0%,10项研究,832名参与者,证据质量低),新鲜冰冻血浆(FFP)(RR 0.57,95%CI 0.33至0.96;I² = 86%,8项研究,761名参与者,证据质量低),血小板(RR 0.73,95%CI 0.60至0.88;I² = 0%,10项研究,832名参与者,证据质量低),以及FFP或血小板的总体止血输血(证据质量低)。荟萃分析还显示,依赖透析的肾衰竭参与者较少。我们发现需要再次手术干预的比例没有差异(RR 0.75,95%CI 0.50至1.10;I² = 0%,9项研究,887名参与者,证据质量低),以及过度出血事件或大量输血(RR 0.38,95%CI 0.38至1.77;I² = 34%,2项研究,280名参与者,证据质量低)。计划的亚组分析未显示任何显著差异。基于研究中的高偏倚风险、大异质性、低事件数、不精确性和间接性,我们将证据质量评为低。TSA表明,就死亡率而言,迄今仅达到所需信息规模的54%,而对于输血结局可能存在有益证据。总体而言,评估的结局与TEG或ROTEM指导的输血对出血患者有益的结果一致。
越来越多的证据表明,应用TEG或ROTEM指导的输血策略可能减少血液制品的需求,并改善出血患者的发病率。然而,这些结果主要基于涉及体外循环的择期心脏手术试验,证据水平仍然较低。需要在低偏倚风险研究中对急性情况下和其他患者类别中TEG或ROTEM指导的输血进行进一步评估。
