Duration of Red Cell Storage Influences Mortality After Trauma

Jordan A Weinberg; Gerald McGwin, Jr; Marianne J Vandromme; Marisa B Marques; Sherry M Melton; Donald A Reiff; Jeffrey D Kerby; Loring W Rue, III

doi:10.1097/TA.0b013e3181fa0019

. Author manuscript; available in PMC: 2011 Jul 15.

Published in final edited form as: J Trauma. 2010 Dec;69(6):1427–1432. doi: 10.1097/TA.0b013e3181fa0019

Duration of Red Cell Storage Influences Mortality After Trauma

Jordan A Weinberg ¹, Gerald McGwin Jr ¹, Marianne J Vandromme ¹, Marisa B Marques ¹, Sherry M Melton ¹, Donald A Reiff ¹, Jeffrey D Kerby ¹, Loring W Rue III ¹

PMCID: PMC3136808 NIHMSID: NIHMS305488 PMID: 21150522

Abstract

Background

Although previous studies have identified an association between the transfusion of relatively older red blood cells (RBCs) (storage ≥14 days) and adverse outcomes, they are difficult to interpret because the majority of patients received a combination of old and fresh RBC units. To overcome this limitation, we compared in-hospital mortality among patients who received exclusively old versus fresh RBC units during the first 24 hours of hospitalization.

Methods

Patients admitted to a Level I trauma center between January 2000 and May 2009 who received ≥1 unit of exclusively old (≥14 days) vs. fresh (<14 days) RBCs during the first 24 hours of hospitalization were identified. Risk ratios (RRs) and 95% confidence intervals (CIs) were calculated for the association between mortality and RBC age, adjusted for patient age, Injury Severity Score, gender, receipt of fresh frozen plasma or platelets, RBC volume, brain injury, and injury mechanism (blunt or penetrating).

Results

One thousand six hundred forty-seven patients met the study inclusion criteria. Among patients who were transfused 1 or 2 RBC units, no difference in mortality with respect to RBC age was identified (adjusted RR, 0.97; 95% CI, 0.72–1.32). Among patients who were transfused 3 or more RBC units, receipt of old versus fresh RBCs was associated with a significantly increased risk of mortality, with an adjusted RR of 1.57 (95% CI, 1.14–2.15). No difference was observed concerning the mean number of old versus fresh units transfused to patients who received 3 or more units (6.05 vs. 5.47, respectively; p = 0.11).

Conclusion

In trauma patients undergoing transfusion of 3 or more RBC units within 24 hour of hospital arrival, receipt of relatively older blood was associated with a significantly increased mortality risk. Reservation of relatively fresh RBC units for the acutely injured may be advisable.

Keywords: Transfusion, Blood storage, Trauma

Although current techniques for allogenic red cell preservation allow for red blood cell (RBC) shelf life of up to 42 days, a number of morphologic and biochemical changes occur during storage before product expiry, and these changes may hinder erythrocyte viability and function after transfusion.^1–6 Despite a relatively large body of literature detailing the metabolic and structural deterioration that occurs during RBC storage, evidence for a significant detrimental clinical effect related to the transfusion of older blood remains less conclusive, limited primarily to observations in retrospective studies.^7,8

The association between the transfusion of relatively older blood and morbidity and mortality has been demonstrated in multiple retrospective studies of trauma patients using various study designs.^9–15 It is notable, however, that a majority of patients in those studies received both relatively fresh and old units with respect to storage age, making evaluation of the independent role of storage age on outcomes quite complex. To overcome this limitation, we conducted a retrospective cohort study to evaluate the association between the age of transfused blood and in-hospital mortality among trauma patients who received exclusively old versus fresh RBC units during the first 24 hours of hospitalization.

METHODS

This study was approved by the Institutional Review Board of the University of Alabama at Birmingham (UAB). The study base consisted of those trauma patients admitted to the UAB University Hospital between January 2000 and May 2009. From the study base, patients who received at least one RBC transfusion during the first 24 hours after arrival to hospital were selected for inclusion. Each patient’s transfusion history was obtained from blood bank records and the storage age (days) of each RBC unit transfused during the first 24 hours of hospitalization was determined. During the study period, all RBC units transfused had undergone prestorage leukoreduction, a practice implemented in our center in 1999. Red cells were leukoreduced within 24 hours of collection by high-efficiency filters.

As previous reports suggest that the deleterious effect of RBC transfusion becomes evident at a storage age beyond 2 weeks, each unit of RBC transfused was categorized as being less than 14 days old (i.e., “fresh” blood) or 14 or more days old (i.e., “old” blood).^11,15,16 Patients who received both fresh and old units during the first 24 hours of hospitalization were excluded from analysis.

Patients were grouped according to RBC storage age and number of units transfused (1–2 vs. ≥3 units). Demographic and injury characteristics were compared between patients in the old and fresh blood groups using t- and χ² tests for continuous and categorical variables, respectively. Poisson regression was used to calculate risk ratios (RRs) and 95% confidence intervals (CIs) for the association between mortality and blood age (old vs. fresh) with adjustment for etiologically relevant variables selected a priori: patient age, gender, Injury Severity Score (ISS), mechanism of injury, total number of RBC units transfused in the first 24 hours of hospitalization, receipt of fresh frozen plasma (FFP) or platelets, and presence of head injury. p values ≤0.05 (two sided) were considered statistically significant.

RESULTS

During the period of study, 25,920 patients were admitted to the trauma service of UAB University Hospital. Of these patients, 2,890 were transfused at least one RBC unit within the first 24 hours after hospital arrival. Exclusion of patients who received both fresh and old units left 1,647 patients for analysis.

For patients transfused 1 unit to 2 units, comparison of clinical variables is demonstrated in Table 1. No significant differences concerning demographic and injury characteristics were noted between the old blood and fresh blood groups. Similarly, no significant difference in the volume of RBC, FFP, or platelets was observed between groups.

TABLE 1.

Comparison of Demographic and Clinical Characteristics by Storage Age Among Patients Transfused 1 to 2 RBC Units

	RBC Storage Age

	Fresh	Old	p
No. patients	393	654
Mean age (SD; yr)	42 (18)	41 (19)	0.40
Male (%)	66	63	0.40
Mean ISS (SD)	25 (14)	24 (14)	0.69
Mechanism (% blunt)	76	76	0.82
Brain injury (%)	27	26	0.55
Mean RBC units (SD)	1.67 (0.47)	1.68 (0.47)	0.79
Mean FFP (SD)	0.61 (1.42)	0.79 (1.51)	0.06
Mean platelets (SD)	0.06 (0.26)	0.06 (0.28)	0.84

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For patients transfused 3 or more units, comparison of clinical variables is demonstrated in Table 2. It is notable that mean patient age was significantly higher in the fresh blood group (44 years vs. 40 years, p < 0.03). The fresh blood group also had a higher prevalence of head injury (32% vs. 24%, p < 0.03). Both groups were transfused a similar volume of RBC and platelets. Patients in the old blood group, however, received a significantly higher volume of FFP (3.47 units vs. 2.76 units, p < 0.03).

TABLE 2.

Comparison of Demographic and Clinical Characteristics by Storage Age Among Patients Transfused 3 or More RBC Units

	RBC Storage Age

	Fresh	Old	p
No. patients	189	411
Mean age (SD; yr)	44 (21)	40 (19)	0.03
Male (%)	72	71	0.63
Mean ISS (SD)	29 (16)	30 (16)	0.52
Mechanism (% blunt)	71	72	0.83
Brain injury (%)	32	24	0.03
Mean RBC units (SD)	5.47 (3.38)	6.05 (4.39)	0.11
Mean FFP (SD)	2.76 (3.08)	3.47 (3.75)	0.02
Mean platelets (SD)	0.39 (0.67)	0.51 (0.93)	0.11

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Among patients transfused 1 unit to 2 units, crude in-hospital mortality was similar between the fresh blood and old blood groups (14.0% vs. 13.5%, p = 0.80). The adjusted RR for the receipt of old versus fresh blood was also not significant (adjusted RR, 0.97; 95% CI, 0.72–1.32; Table 3). Among patients transfused 3 or more units, crude in-hospital mortality was lower in the fresh blood group, but no statistically significant difference was observed (20.1% vs. 27.0%, p = 0.08). However, once adjusted for etiologically relevant variables, the adjusted RR for the receipt of old versus fresh blood was statistically significant (adjusted RR, 1.57; 95% CI, 1.14 –2.15; p = 0.006; Table 3).

TABLE 3.

Results of Poisson Regression Evaluating Association Between RBC Storage Age and Mortality

	RR (95% CI)	p
1–2 RBC units
Old blood	0.97 (0.72–1.32)	0.85
Age	1.01 (1.00–1.02)	0.01
ISS	1.04 (1.03–1.05)	<0.0001
Male gender	1.09 (0.79–1.51)	0.60
Units FFP	0.99 (0.91–1.08)	0.88
Head injury	1.75 (1.24–2.47)	0.002
Units RBC	1.29 (0.9–1.84)	0.17
Blunt mechanism of injury	0.55 (0.38–0.78)	0.001
≥3 RBC units
Old blood	1.57 (1.14–2.15)	0.01
Age	1.01 (1.01–1.02)	<0.0001
ISS	1.03 (1.02–1.03)	<0.0001
Male gender	1.33 (0.98–1.80)	0.07
Units FFP	0.96 (0.91–1.01)	0.16
Units platelets	0.87 (0.71–1.05)	0.15
Head injury	1.74 (1.26–2.40)	0.001
Units RBC	1.10 (1.06–1.13)	<0.0001
Blunt mechanism of injury	0.70 (0.50–0.99)	0.05

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DISCUSSION

In clinical practice, blood is often transfused with the goal of augmenting tissue oxygen delivery. Nonetheless, there has been increasing skepticism as to the effectiveness of transfusion in this regard, particularly as related to the duration of red cell storage.^3,6 In human studies concerning posttransfusion tissue oxygenation, observations have been somewhat contradictory. Marik and Sibbald¹⁷ observed a decreased gastric pH, a measure of gastric mucosal oxygenation status, in patients receiving blood that had been stored beyond 15 days. Walsh et al.,¹⁸ however, were unable to replicate these findings. In a prospective, double-blind trial of critically ill intensive care unit, patients randomized to receive leukodepleted red cells stored either ≤5 days or ≥20 days, Walsh et al. observed no significant differences in gastric pH measurements or other indices of global tissue oxygenation. Recently, Kiraly et al.¹⁹ evaluated peripheral tissue oxygenation as measured by near infrared spectroscopy during the course of red cell transfusion. The authors observed that patients transfused with blood stored 21 days or longer had a statistically significant decline in tissue oxygen saturation compared with those transfused with blood <21 days old. Whether or not the magnitude of the observed decline is clinically meaningful in any way remains uncertain.

Concerning clinical outcomes among trauma patients, the association between the transfusion of relatively older blood and morbidity and mortality has been demonstrated in multiple retrospective studies using various study designs. Zallen et al.¹⁵ examined the association between red cell storage age and multiple organ failure (MOF) in a matched case-control study concerning trauma patients that received between 6 and 20 RBC units in the first 12 hours after injury. The authors identified that the mean age of transfused blood was significantly greater in the MOF positive patients (30.5 days vs. 24 days). Multivariate analysis identified mean age of blood, number of units older than 14 days, and number of units older than 21 days as independent risk factors for MOF. Offner et al.¹¹ evaluated the association between transfusion of relatively older blood and postinjury infection in a similar patient cohort and observed that patients who developed infections had received 11.7 units and 9.9 units of red cells older than 14 days and 21 days, respectively, compared with 8.7 units and 6.7 units in patients who did not develop infections. Recently, Spinella et al.¹² evaluated the effect of storage age on mortality in a group of 202 trauma patients and found that increased storage age was independently associated with mortality (odds ratio, 4.00; 95% CI, 1.34 –11.61).

As evident in the studies described above, the evaluation of the independent role of storage age on outcomes in patient populations that received a heterogeneous distribution of relatively old and fresh blood is far from straightforward. Studies that report the mean or median age of all units transfused to a given patient have been particularly problematic in this regard in that they assume that relatively fresh units offset the proposed deleterious effect of older blood. Moreover, this counterbalancing effect is not uniform and depends on the total volume of old and fresh units. Given the present understanding of the storage lesion, there is no evident rationale for this assumption. Alternatively, analyses that focus on the volume of old blood transfused, while avoiding this assumption of mechanism, are hindered by the fact that patients receiving more blood are likely to be more severely injured. Thus, the observed associations between the transfusion of relatively older blood and morbidity or mortality may be more reflective of the residual effect of total transfusion volume (i.e., injury severity) rather than blood storage age.

It is therefore important to consider not only the age of the blood transfused but also the volume and to not treat them in an independent manner. If the associations between older blood and outcomes as outlined above were actually secondary to the residual confounding of transfusion volume, the associations between outcome and the volume of fresh blood transfused would be expected to be similar. With this in mind, we recently evaluated the association between mortality and the transfusion of both relatively old and fresh blood, respectively.¹³ Among 1,813 severely injured patients (mean ISS, 26) who received one or more units of blood within the initial 24 hours of hospitalization, it was observed that while larger volumes of blood, irrespective of storage age, were associated with an increased odds of mortality, the transfusion of blood stored beyond 14 days appeared to significantly potentiate this association, suggesting the existence of a veritable association between storage age and outcome. Subgroup analysis concerning only those patients who received exclusively fresh or old blood demonstrated that among those patients receiving a total of three or more red cell units, receipt of old blood was associated with an over threefold increased odds of death, consistent with the results reported herein.

In this study, we sought to simplify the evaluation of storage age’s effect on mortality by limiting the study population to those who received exclusively old versus fresh blood in the first 24 hours in a relatively large cohort. In addition, as previous studies have been criticized for the lack of accounting for the confounding potential of the administration of blood products other than RBCs, we adjusted for the transfusion of fresh frozen plasma and platelets. Our results further support the notion that the transfusion of relatively older blood potentiates the risk of death after trauma.

Nonetheless, there are limitations to this study that deserve consideration. Multivariable analyses, unlike randomized trials, do not adjust for unknown confounders. Despite our best attempts to control for differences in baseline characteristics between groups, it is possible that a latent confounder could explain some or all the mortality difference observed if elucidated. Additionally, the incorporation of data concerning the rate of transfusion would certainly inform the study, given that differences in both baseline characteristics and outcomes would be anticipated in patients that received the same number of units of blood within 24 hours, but in temporally different patterns. Precise data regarding transfusion times, however, are not recorded in our trauma registry dataset.

It is notable that in this study, all patients were transfused with blood that had undergone prestorage leukoreduction. Although leukoreduction has well documented efficacy related to specific clinical circumstances, a generalized benefit remains unproven.²⁰ Indeed, Nathens et al.²¹ performed a randomized trial comparing prestorage leukoreduced versus standard nonleukoreduced transfusions to evaluate whether or not leukoreduction might improve outcomes among trauma patients, and found no difference in mortality or infectious morbidity among the 268 patients eligible for analysis. This study demonstrates a mortality association with older blood despite universal leukoreduction, suggesting that leukoreduction does not mitigate the deleterious clinical effects that have been associated with the storage lesion.

Although the growing body of literature demonstrating the deleterious effects of relatively old blood is compelling, as highlighted above, the difficulty in distinguishing the effect of storage age from the effect of transfusion volume in these studies is not insignificant. It remains quite possible that prospective evaluation of the effect of storage age on outcome might yield contradictory results. Certainly, confirmation of the effect of blood storage on morbidity and mortality by a prospective randomized trial is now warranted. Schulman et al.²² attempted such a trial in the setting of a single-center Level I trauma center, randomizing patients to receive exclusively young (<11 days) versus old (>20 days) blood during the first 24 hours of hospitalization. Unfortunately, in 1 year, they were only able to enroll a small number of patients secondary to limitations of the blood bank. It is reasonable to expect that other institutions would face a similar challenge given the tight supply of blood. It is clear that only interinstitutional cooperation in the form of a multi-institutional trial will be successful in the recruitment of enough patients for a robust analysis. Hebert et al.²³ performed a multicenter feasibility study in Canada and reported that a large scale study would be feasible, but challenged by the maintenance of a sufficient blood supply to allow for randomization between old and fresh groups with a limited number of subsequent group crossovers. Until such studies have been completed and produce confirmative results, it would be premature to recommend any modification of current transfusion practice regarding storage age. Nonetheless, the implication that the transfusion of blood of relatively longer storage age may have negative consequences demands attention and, most importantly, further rigorous evaluation.

Acknowledgments

Supported, in part, by the National Heart, Lung, and Blood Institute grant R01HL095468.

The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Heart, Lung, and Blood Institute or the National Institutes of Health.

EDITORIAL COMMENT

Changes occurring during the storage of blood have been long recognized and felt not to be of benefit to recipients of transfusions.¹ The term “storage lesion” has been in use since at least 1985,² and there is a tremendous body of literature characterizing such changes in vitro. The clinical consequences of the storage lesion have been more difficult to evaluate rigorously. The preponderance of retrospective data suggests that aged red blood cells (RBC) are associated with increased morbidity and mortality. Weinberg et al.³ have contributed to this body of knowledge with their comparison of exclusively old versus exclusively fresh blood which has confounded previous publications.

The investigators report a retrospective analysis of trauma patients admitted to a single institution during a 9.5-year period from January 2000 through May 2009. Among patients who received one or more units of RBCs during the first 24 hours of admission, two patient groups were defined: those who received blood that was exclusively fresh (<14 days) and those who received blood that was exclusively old (≥14 days)—patients receiving both fresh and old blood were excluded. The primary endpoint was overall mortality. Although no survival difference was noted for patients receiving 1 unit to 2 units of blood, an association with mortality was noted for patients receiving ≥3 units of old blood on multivariate regression analysis. This study is also notable in that all RBCs were prestorage leukoreduced. Although it has been shown that leukoreduction reduces the extent of changes during RBC storage,⁴ this study highlights that it does not appear that leukoreduction completely abrogates the deleterious clinical effects that have been associated with the storage lesion.

What does one do with these data? As this is a retrospective analysis, these data can only show an association and cannot prove causality. Therefore, the status quo remains. Some institutions and blood banks have policies in place to provide “fresh blood” to patients requiring massive transfusion, a relatively uncommon event for civilian trauma centers.⁵ The logistics of inventory supply are strained by a “last in, first out” policy for RBC units which increases wastage of units that are unused and become outdated. The findings from this study showing an association with increased mortality in patients receiving ≥3 units of blood (a much more common scenario than massive transfusion) certainly would have to be considered carefully.

Some institutions have not made changes to provide fresh blood for trauma patients, reasonably arguing that retrospective data are inconclusive and such policy changes must await the results from prospective clinical trials. The National Heart Lung and Blood Institute is sponsoring just such a clinical trial.⁶ The Red Cell Storage Duration Study, or RECESS (NCT00991341), is a large, multicenter, randomized clinical trial intended to determine whether RBC storage time affects the postoperative outcomes of heart surgery patients. Although this is not a study specifically in trauma patients, one would hope that this effort would provide sufficient and clear insight into the clinical consequences of aged blood.

Jeremy G. Perkins, MD, FACP

Hematology/Oncology, Chair, Walter Reed Army Medical Center, Washington, DC, Associate Professor of Medicine, Uniformed Services University of the Health Sciences, Bethesda, MD, LTC, US Army, Medical Corps

REFERENCES

1. Valtis DJ. Defective gas-transport function of stored red blood-cells. Lancet. 1954;263:119 –125.

2. Wolfe LC. The red cell membrane and the storage lesion. Clin Haematol. 1985;14:259 –276.

3. Weinberg JA, McGwin G, Vandromme MJ, et al. Duration of Red Cell Storage Influences Mortality After Trauma. J Trauma. 2010;69:1427–1430.

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EDITORIAL COMMENT

It is a standard practice to provide neonates aged up to 4 months with packed red blood cells (PRBCs) that are a maximum of 7 days old. Sickle cell and thalassemia patients require fresh blood, as do patients with end-stage renal disease. Cardiac surgery patients receive fresh blood, at least up to a prearranged limit. A few years ago, studies indicated that fresh blood might be advantageous for patients with HIV; hence, there was brief clamor for such blood utilization in the context of HIV. Evidence to support its use in trauma patients with severe hemorrhage is lacking.

PRBC and their storage media undergo characteristic morphologic and biochemical changes with ex vivo banking. These changes are collectively referred to as the “red cell storage lesion” and include lipid peroxidation of the red cell membranes, loss of deformability, loss of 2,3 diphosphoglycerate (and thus an increased oxygen affinity), and depletion of adenosine triphosphate that results in crenation, spicule formation, and cell swelling. Indeed, this age effect has been clinically shown to result in higher mortality rates, multiorgan failure rates, and infection rates in critically ill patients. So then, why do not we use only fresh blood in our patients in extremis? To justify providing fresh blood to trauma patients, a clinical trial would have to prove that fresh blood improves outcomes in trauma resuscitation and that the advantage is large enough to justify diverting fresh blood away from other patients. This would require determining the expected consumption of fresh PRBCs for traumas, the patient benefit per unit consumed, and the effect such consumption will have on the availability of fresh PRBCs for other patients. Because the blood supply network in this country is an astonishingly efficient producer and distributor of just-in-time blood products, it would be necessary to determine the extent to which consumption of fresh blood in traumas would lead to expiration of older, unused PRBC units. The marginal loss of such a scarce, life-saving resource at a cost of well >$200 per expired PRBC unit could be quite significant.

Before deciding to allocate fresh PRBCs to trauma patients, it would also be necessary to establish which subpopulations would derive the maximum benefit. If it were learned that only trauma patients in extremis would derive benefit from receiving fresh PRBCs, then we would need to treat patients accordingly. A catch-all approach of giving fresh PRBCs to all trauma patients would not be appropriate—if it were, we would need to ask whether everyone who required a transfusion for any reason might not benefit from fresh blood.

Weinberg et al.¹ notes that a large, multi-institutional study would be needed to enroll enough subjects to perform a prospective randomized trial. They acknowledge that the crucial limitation to performing such a trial is the tight blood supply. The burden of proof for starting such a trial is demanding: If a large, multi-institutional clinical trial will have a significant impact on blood allocation in participating hospitals, it is mandatory to use the best currently available evidence to justify performing the study. At minimum, the evidence must show a likelihood of success and demonstrate that a positive outcome will change clinical practice. So far, the evidence in favor of fresh red cells for trauma patients falls far short of that mark.

Juan C. Duchesne, MD, FACS, FCCP

Associate Professor of Surgery, Director Tulane Surgical Intensive Care Unit, New Orleans, Louisiana

James M. Barbeau, MD, JD, FCAP

Spirit of Charity Hospital, New Orleans, Louisiana

REFERENCE

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PERMALINK

Duration of Red Cell Storage Influences Mortality After Trauma

Jordan A Weinberg, MD

Gerald McGwin Jr, MS, PhD

Marianne J Vandromme, MD

Marisa B Marques, MD

Sherry M Melton, MD

Donald A Reiff, MD

Jeffrey D Kerby, MD, PhD

Loring W Rue III, MD

Abstract

Background

Methods

Results

Conclusion

METHODS

RESULTS

TABLE 1.

TABLE 2.

TABLE 3.

DISCUSSION

Acknowledgments

EDITORIAL COMMENT

EDITORIAL COMMENT

REFERENCES

ACTIONS

PERMALINK

RESOURCES

Cite

Add to Collections

PERMALINK

Duration of Red Cell Storage Influences Mortality After Trauma

Jordan A Weinberg, MD

Gerald McGwin Jr, MS, PhD

Marianne J Vandromme, MD

Marisa B Marques, MD

Sherry M Melton, MD

Donald A Reiff, MD

Jeffrey D Kerby, MD, PhD

Loring W Rue III, MD

Abstract

Background

Methods

Results

Conclusion

METHODS

RESULTS

TABLE 1.

TABLE 2.

TABLE 3.

DISCUSSION

Acknowledgments

EDITORIAL COMMENT

EDITORIAL COMMENT

REFERENCES

ACTIONS

PERMALINK

RESOURCES

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