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Blood transfusion after percutaneous coronary intervention and risk of subsequent adverse outcomes: a systematic review and meta-analysis
Kwok CS, Sherwood MW, Watson SM, Nasir SB, Sperrin M, NolanJ, Kinnaird T, Kiatchoosakun S, Ludman PF, de Belder MA, et al
JACC: Cardiovascular Interventions. 2015;8((3):):436-46.
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Abstract
OBJECTIVES This study sought to define the prevalence and prognostic impact of blood transfusions in contemporary percutaneous coronary intervention (PCI) practice. BACKGROUND Although the presence of anemia is associated with adverse outcomes in patients undergoing PCI, the optimal use of blood products in patients undergoing PCI remains controversial. METHODS A search of EMBASE and MEDLINE was conducted to identify PCI studies that evaluated blood transfusions and their association with major adverse cardiac events (MACE) and mortality. Two independent reviewers screened the studies for inclusion, and data were extracted from relevant studies. Random effects meta-analysis was used to estimate the risk of adverse outcomes with blood transfusions. Statistical heterogeneity was assessed by considering the I(2) statistic. RESULTS Nineteen studies that included 2,258,711 patients with more than 54,000 transfusion events were identified (prevalence of blood transfusion 2.3%). Crude mortality rate was 6,435 of 50,979 (12.6%, 8 studies) in patients who received a blood transfusion and 27,061 of 2,266,111 (1.2%, 8 studies) in the remaining patients. Crude MACE rates were 17.4% (8,439 of 48,518) in patients who had a blood transfusion and 3.1% (68,062 of 2,212,730) in the remaining cohort. Meta-analysis demonstrated that blood transfusion was independently associated with an increase in mortality (odds ratio: 3.02, 95% confidence interval: 2.16 to 4.21, I(2) = 91%) and MACE (odds ratio: 3.15, 95% confidence interval: 2.59 to 3.82, I(2) = 81%). Similar observations were recorded in studies that adjusted for baseline hematocrit, anemia, and bleeding. CONCLUSIONS Blood transfusion is independently associated with increased risk of mortality and MACE events. Clinicians should minimize the risk for periprocedural transfusion by using available bleeding-avoidance strategies and avoiding liberal transfusion practices.Copyright 2015 American College of Cardiology Foundation. Published by Elsevier Inc. All rights reserved.
Clinical Commentary
What is known?
Allogenic red cell transfusion is associated with adverse clinical outcomes in many clinical settings.
What did this paper set out to examine?
The authors conducted a systematic review of the evidence that relates to the relationship between red cell transfusion and adverse clinical outcomes in patients undergoing percutaneous coronary interventions (PCI). The study is timely because the increasingly elderly population referred for PCI are at increased risk of anaemia and acute haemorrhage, the two key indications for red cell transfusion.
What did they show?
The authors conducted a robust and well described systematic review of relevant databases. They identified 19 observational analyses that included 2,258,711 patients met their eligibility criteria; reporting of transfusions, death and Major Adverse Cardiac Events (MACE). The included studies were of mixed quality and showed differences in their design, definitions of primary and secondary exposures, duration of follow up, and type of analyses. Pooled effect estimates demonstrated strong associations between transfusion, mortality and MACE, although these analyses also demonstrated significant heterogeneity. Sub group analyses that included only studies with longer follow-up, or that contained adjustment for confounders such as transfusion volume or anaemia showed consistent associations between transfusion and harm, with some reduction in heterogeneity.
What are the implications for practice and for future work?
Implications for future research: The authors conclude that their data cannot demonstrate a causal relationship between transfusion and adverse outcomes in these patients. However they do discuss the possible pathological effects of transfusion and conclude that their data should support more restrictive transfusion practice. Implications for future practice: This study generates the hypothesis that reduced exposure to red cells may have benefits in these high risk patients. This hypothesis should be tested in a randomised controlled clinical trial. It is premature to suggest that the evidence presented here makes a case for restrictive practice.
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Risks associated with red blood cell transfusion in the trauma population, a meta-analysis
Patel SV, Kidane B, Klingel M, Parry N
Injury. 2014;45((10):):1522-33.
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Abstract
INTRODUCTION A previous meta-analysis has found an association between red blood cell (RBC) transfusions and mortality in critically ill patients, but no review has focused on the trauma population only. OBJECTIVES To determine the association between RBC transfusion and mortality in the trauma population, with secondary outcomes of multiorgan failure (MOF) and acute respiratory distress syndrome (ARDS) or acute lung injury (ALI). DATA SOURCES EMBASE (1947-2012) and MEDLINE (1946-2012). STUDY ELIGIBILITY CRITERIA Randomized controlled trials and observational studies were to be included if they assessed the association between RBC transfusion and either the primary (mortality) or secondary outcomes (MOF, ARDS/ALI). PARTICIPANTS Trauma patients. EXPOSURE Red blood cell transfusion. METHODS A literature search was completed and reviewed in duplicate to identify eligible studies. Studies were included in the pooled analyses if an attempt was made to determine the association between RBC and the outcomes, after adjusting for important confounders. A random effects model was used for and heterogeneity was quantified using the I(2) statistic. Study quality was assessed using the Newcastle-Ottawa Scale. RESULTS 40 observational studies were included in the qualitative review. Including studies which adjusted for important confounders found the odds of mortality increased with each additional unit of RBC transfused (9 Studies, OR 1.07, 95%CI 1.04-1.10, I(2) 82.9%). The odds of MOF (3 studies, OR 1.08, 95%CI 1.02-1.14, I(2) 95.9%) and ARDS/ALI (2 studies, OR 1.06, 95%CI 1.03-1.10, I(2) 0%) also increased with each additional RBC unit transfused. CONCLUSIONS We have found an association between RBC transfusion and the primary and secondary outcomes, based on observational studies only. This represents the extent of the published literature. Further interventional studies are needed to clarify how limiting transfusion can affect mortality and other outcomes. Copyright 2014 Elsevier Ltd. All rights reserved.
Clinical Commentary
Dr Annemarie Docherty, University of Edinburgh, Edinburgh, UK.
What is known?
Death from haemorrhage is the second most common cause of death in the trauma population and a high proportion of severely injured patients receive red blood cell transfusions. Evidence from randomised controlled trials in critically ill patients support a restrictive transfusion threshold, however the effect of transfusion on outcomes in trauma may differ due to the timing and amount of transfusion required. Trauma patients may be unstable or actively bleeding, as opposed to the slow decline in haemoglobin often seen in critical care. Evidence in the trauma population is based primarily on small observational studies.
What did this paper set out to examine?
This systematic review and meta-analysis set out to assess the association between red blood cell transfusion and mortality in the trauma population. Secondary outcomes included acute respiratory distress syndrome or acute lung injury (ARDS/ALI) and multiorgan failure. Comparative observational and interventional studies were eligible for inclusion.
What did they show?
The authors included 40 studies in the qualitative review. No randomised controlled trials addressed the study question. All studies were observational cohort studies, which increased the risk of selection bias and confounding. Particularly relevant confounders were injury severity and other measures of shock which were strongly associated with the study outcomes. The authors assessed the quality of the studies using the Newcastle-Ottawa Scale, and the quality of the meta-analysis using the GRADE guidelines.
There was significant heterogeneity. Study size varied from 29 to 25,299. Timing of red blood cell transfusion varied considerably from studies that included transfusion within 24-48 hours only, total in-hospital transfusion, to studies that excluded patients transfused within 48 hours of admission. There were also marked differences in the categorisation of red blood cell transfusion: continuous variable (per unit change), binary variable (transfused/not transfused) and a categorical variable. In addition to this, patient populations also varied: multiply injured patients, patients with only one system injured, massively transfused patients, patients only admitted to the intensive care unit, surgical patients only, intubated patients only, and various injury severity score cutoffs.
Seventeen studies attempted to determine the effect of transfusion on mortality after adjusting for important confounders, and nine of these had enough information to be pooled in the meta-analysis. Eight studies found that red blood cell transfusion was associated with increased odds of mortality, and the adjusted pooled analysis showed an increase in the odds of mortality with each additional unit transfused (OR 1.07, 95%CI 1.04-1.10, p<0.001, I^2=94.6%). The authors graded this evidence as low.
Six studies attempted to determine the adjusted association with multiorgan failure. The odds of multiorgan failure increased with each additional unit of blood (OR 1.08, 95%CI 1.02-1.14, p=0.012, I^2=95.9%). The grade of evidence was moderate.
Six studies assessed the adjusted association between transfusion and ARDS, but only two had enough information to be included in the meta-analysis (transfused vs not transfused: OR 2.04, 95%CI 1.47-2.83, p<0.001, I^2=0%). The authors graded this evidence as very low.
What are the implications for practice and for future work?
The observational studies all showed an association between transfusion and mortality and other negative outcomes. However, there was considerable heterogeneity between the studies, and as the authors acknowledge, it is likely that significant confounding persisted even after attempts to adjust for injury and illness severity. The authors have graded the evidence as very low to moderate, and it is not possible to refine red blood cell transfusion practice in trauma on the basis of these observational studies.
This systematic review highlights the lack of evidence for red blood cell transfusion in trauma, and the need for a robust randomised controlled trial in this population. This would minimise confounding and bias, and give a definitive answer regarding the effect of red blood cell transfusion on mortality.
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Association of red blood cell transfusion and in-hospital mortality in patients admitted to the intensive care unit: a systematic review and meta-analysis
Zheng Y, Lu C, Wei S, Li Y, Long L, Yin P
Critical Care (London, England). 2014;18((6):):515.
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Abstract
INTRODUCTION Previous research has debated whether red blood cell (RBC) transfusion is associated with decreased or increased mortality in patients admitted to the intensive care unit (ICU). We conducted a systematic review and meta-analysis to assess the relationship of RBC transfusion with in-hospital mortality in ICU patients. METHODS We carried out a literature search on Medline (1950 through May 2013), Web of Science (1986 through May 2013) and Embase (1980 through May 2013). We included all prospective and retrospective studies on the association between RBC transfusion and in-hospital mortality in ICU patients. The relative risk for the overall pooled effects was estimated by random effects model. Sensitivity analyses were conducted to assess potential bias. RESULTS The meta-analysis included 28,797 participants from 18 studies. The pooled relative risk for transfused versus nontransfused ICU patients was 1.431 (95% CI, 1.105 to 1.854). In sensitivity analyses, the pooled relative risk was 1.211 (95% CI, 0.975 to 1.505) if excluding studies without adjustment for confounders, 1.178 (95% CI, 0.937 to 1.481) if excluding studies with relative high risk of bias, and 0.901 (95% CI, 0.622 to 1.305) if excluding studies without reporting hazard ratio (HR) or relative risk (RR) as an effect size measure. Subgroup analyses revealed increased risks in studies enrolling patients from all ICU admissions (RR 1.513, 95%CI 1.123 to 2.039), studies without reporting information on leukoreduction (RR 1.851, 95%CI 1.229 to 2.786), studies reporting unadjusted effect estimates (RR 3.933, 95%CI 2.107 to 7.343), and studies using odds ratio as an effect measure (RR 1.465, 95%CI 1.049 to 2.045). Meta-regression analyses showed that RBC transfusion could decrease risk of mortality in older patients (slope coefficient -0.0417, 95%CI -0.0680 to -0.0154). CONCLUSIONS There is lack of strong evidence to support the notion that ICU patients who receive RBC transfusion have an increased risk of in-hospital death. In studies adjusted for confounders, we found that RBC transfusion does not increase the risk of in-hospital mortality in ICU patients. Type of patient, information on leukoreduction, statistical method, mean age of patient enrolled and publication year of the article may account for the disagreement between previous studies.
Clinical Commentary
Dr Annemarie Docherty, University of Edinburgh, Edinburgh, UK.
What is known?
Anaemia is prevalent in critically ill patients, and is associated with poor outcomes including acute myocardial infarction, heart failure, chronic kidney disease and risk of death. In critically ill patients, the standard method of reversing anaemia is with transfusion of red blood cells, with the aim of improving oxygen delivery to the tissues. However, blood transfusion is not without risks. These include immunosuppression, risk for infection, transfusion reactions and transfusion-related acute lung injury. There is conflicting evidence surrounding the association between red blood cell transfusion and mortality, with some studies suggesting a higher risk of death in transfused patients, and others finding a lower risk of death.
What did this paper set out to examine?
The authors have set out to examine whether there is an association between red blood cell transfusion and mortality in critically ill patients. The authors have performed a meta-analysis of all published retrospective and prospective observational studies comparing red blood cell transfused with non-transfused ICU patients, looking at all-cause in-hospital mortality, and risk factors of death in transfused patients.
What did they show?
The authors identified 18 observational studies which looked at mortality of transfused patients. Eight studies were prospective, and the other ten retrospective, six studies were very high overall quality, nine studies high overall quality and three studies median overall quality. The overall pooled risk ratio of in-hospital mortality of transfused patients compared to non-transfused patients was 1.431 (95%CI 1.105 to 1.854). However, in order to account for the impact of the observational design of the studies on the results, they performed several sensitivity analyses, including only studies that adjusted for confounders, only high quality studies, and only studies that included risk or hazard ratios. When only including studies that adjusted for confounding (of particular importance in observational studies), the RR was 1.211 (95%CI 0.795 to 1.505). The authors performed a subgroup analysis looking at different types of admission (sepsis and shock, surgical, trauma, and other). There was no association between RBC transfusion and mortality in each type of admission, however the pooled effect estimate suggested that type of admission was a significant predictor of in-hospital mortality. Other significant predictors were age of patient, and year of publication. Recent studies were more likely to report lower risk ratios, which the authors suggest means that blood transfusion may have got safer over time.
What are the implications for practice and for future work?
As a result of these observational limitations, although this systematic review suggests that RBC transfusion is not linked to in-hospital mortality, a randomised controlled trial designed and powered to answer this question would be required to determine causality. This review suggests that in the heterogenous ICU population, there is no association between RBC transfusion and in-hospital mortality after adjustment for confounders. Clinicians can perhaps be reassured that there does not appear to be an inherent risk with RBC transfusion, and that the decision to transfuse should be based on assessment of the patient’s physiological status and comorbidity.