Abstract
Rationale: A major abnormality that characterizes the red cell “storage lesion” is increased hemolysis and reduced red cell lifespan after infusion. Low levels of intravascular hemolysis after transfusion of aged stored red cells disrupt nitric oxide (NO) bioavailabity, via accelerated NO scavenging reaction with cell-free plasma hemoglobin. The degree of intravascular hemolysis post-transfusion and effects on endothelial-dependent vasodilation responses to acetylcholine have not been fully characterized in humans.
Objectives: To evaluate the effects of blood aged to the limits of Food and Drug Administration–approved storage time on the human microcirculation and endothelial function.
Methods: Eighteen healthy individuals donated 1 U of leukopheresed red cells, divided and autologously transfused into the forearm brachial artery 5 and 42 days after blood donation. Blood samples were obtained from stored blood bag supernatants and the antecubital vein of the infusion arm. Forearm blood flow measurements were performed using strain-gauge plethysmography during transfusion, followed by testing of endothelium-dependent blood flow with increasing doses of intraarterial acetylcholine.
Measurements and Main Results: We demonstrate that aged stored blood has higher levels of arginase-1 and cell-free plasma hemoglobin. Compared with 5-day blood, the transfusion of 42-day packed red cells decreases acetylcholine-dependent forearm blood flows. Intravascular venous levels of arginase-1 and cell-free plasma hemoglobin increase immediately after red cell transfusion, with more significant increases observed after infusion of 42-day-old blood.
Conclusions: We demonstrate that the transfusion of blood at the limits of Food and Drug Administration–approved storage has a significant effect on the forearm circulation and impairs endothelial function.
Clinical trial registered with www.clinicaltrials.gov (NCT 01137656)
Keywords: nitric oxide, cell-free plasma hemoglobin, vasoreactivity, red cell transfusion, storage lesion
At a Glance Commentary
Scientific Knowledge on the Subject
Prior studies evaluating the effects of transfusion of aged stored blood on human endothelial function have been limited by the noninvasive evaluation of vascular function.
What This Study Adds to the Field
This study demonstrates that intraarterially infused red blood cells stored for 6 weeks, representing the limits of Food and Drug Administration–approved cold storage time, impairs endothelial function, as measured by the reduced forearm blood flow responses to acetylcholine, an endothelium NO synthase–dependent vasodilator. These effects are associated with hemolysis-dependent release of cell-free plasma hemoglobin and arginase-1, both of which reduce the bioavailability of nitric oxide.
In the United States approximately 11 million units of red blood cells (RBCs) are transfused annually (1). The Food and Drug Administration (FDA) permits red cells to be stored up to 42 days before transfusion. In general, blood banks deliver the oldest units of red cells available to minimize blood product disposal.
As stored red cells age, complex biochemical, molecular, and metabolic alterations occur within the erythrocytes and storage medium leading to energetic compromise, characterized by ATP and DPG depletion, and loss of red cell membrane integrity (2). Subsequent decreased membrane deformability with increased fragility result in red cell hemolysis and release of red cell contents into the storage medium and into the intravascular space after transfusion. These changes in red cell structure and function during blood banking and storage have been referred to as the red cell storage lesion (3–8).
Observational studies have demonstrated an increased risk associated with red cell transfusions (9–11). This risk seems to be related to both the age and number of the units transfused. These findings have been observed in cohort studies and summarized in retrospective reports and meta-analyses, suggesting that the transfusion of older stored blood is associated with increased mortality (12–14). As few as one to two RBC transfusions in susceptible patients, such as post-cardiopulmonary bypass surgery, have been associated with increased morbidity and mortality (15). This association of the age of blood and transfusion risk remains controversial, secondary to multiple confounding variables associated with transfusion of older units, including but not limited to the number of units, the recipient severity of illness, and changes in depletion of O antigen blood in the older unit pool.
Two recent large multicenter randomized clinical trials evaluating the effect of the age of red cells have been published (16, 17). Both studies failed to show a difference in primary outcomes between those transfused with fresher units and older units. However, in these studies the mean ages of older blood were only 22 and 28.3 days, respectively, and very few units of blood were transfused at the extreme limits of FDA-approved storage of 42 days (16–18). Thus, although transfusion of blood may increase risk (12, 13, 15, 19), whether this risk is compounded by storage age, especially at the limits of storage and in the setting of larger transfusion volumes, remains unclear (20–24).
The mechanisms by which blood transfusion may contribute to organ injury, dysfunction, and death remain uncertain. We have proposed that storage and post-transfusion hemolysis may cause endothelial dysfunction, mediated by the nitric oxide (NO) and l-arginine scavenging effects of cell-free plasma hemoglobin (CFPHb) and arginase-1, respectively. Multiple studies have supported this hypothesis in animal models, including the infusion of supernatant from aged banked red cells into rats, which resulted in vasoconstriction and hypertension (22). The transfusion of aged stored blood into dogs with Staphylococcus aureus pneumonia produced significant hemolysis that increased pulmonary pressures and mortality (20, 25). Similar findings have been demonstrated in mice, guinea pigs, and lambs (26–30).
Several recent studies have assessed vascular endothelial function in normal human volunteers after transfusion of autologous blood (23, 24, 31). Berra and colleagues (31) reported that 1-U transfusion of 40-day-aged red cells did not affect the reactive hyperemia index, a noninvasive measure of endothelial function, compared with transfusions of 3-day-aged red cells. In contrast, in a follow-up study the same group evaluated a single unit transfusion of autologous 40-day-stored leukoreduced red cells into subjects with endothelial dysfunction and demonstrated increased post-transfusion levels of CFPHb, NO consumption, and pulmonary artery pressures estimated by Doppler echocardiography (23, 31). Similarly, Neuman and colleagues (24) demonstrated that individuals with anemia receiving aged blood (>21 d) had evidence of endothelial dysfunction at 24 hours post-transfusion.
A limitation of all normal volunteer studies is the amount of autologous blood that can be safely transfused, which may be insufficient to affect vascular function systemically. In our studies described in detail next, we transfused fresh or aged stored autologous blood directly into the forearm brachial artery to expose the vessel to higher concentrations of transfused blood and model more significant transfusion exposures. We also tested endothelial function invasively, using infusions of acetylcholine (Ach), an endothelium-dependent vasodilator.
To test whether blood storage adversely affects vascular function, we enrolled normal volunteers to donate 1 U of blood, which was leukoreduced and split in half. The volunteers then returned after approximately 1 week (range, 5–7 d) and 6 weeks (range, 40–42 d) for autologous transfusion of the blood into the forearm brachial artery. Immediately after the transfusion forearm endothelial function was tested with Ach infusions, which stimulate muscarinic receptors to activate endothelial NO synthesis and promote vasodilation. Compared with fresh blood we hypothesized that aged blood will demonstrate increased levels of hemolysis (resulting in increased CFPHb) measured in vivo after transfusion and in the stored blood supernatant; and reduce the vasodilatory response to intraarterial infusion of Ach, caused by direct scavenging of NO or oxidative inactivation of NO released from the endothelium.
Methods
The investigation enrolled a total of 18 healthy individuals at the University of Pittsburgh who were evaluated with strain-gauge plethysmography before and after autologous infusion of blood to evaluate forearm blood flow and vasodilatory responses to Ach (Table 1). Inclusion and exclusion criteria are reported the Methods section of the online supplement and in prior studies (22). The institutional review board at the University of Pittsburgh (#PRO09100113) approved the study. Written informed consent was obtained from subjects. An NHLBI independent data, safety, and monitoring board monitored the study.
Table 1.
n | 18 |
Sex | |
Male | 11 (61.1%) |
Female | 7 (38.9%) |
Age, yr | 28.8 ± 7.4 |
Race | |
White | 12 (73.4%) |
Asian | 4 (13.3%) |
African American | 2 (13.3%) |
Hemoglobin, g/dl | 14.2 ± 1.1 |
Creatinine, mg/dl | 0.9 ± 0.2 |
Body mass index, kg/m2 | 24.5 ± 2.5 |
Laboratory studies were drawn before blood donation.
Values are expressed as mean ± SD.
Blood Donation
Subjects donated 500 ml of whole blood at the Central Blood Bank Donor Centers, Pittsburgh, to produce an apheresis unit. The blood was collected, processed, and leukoreduced according to current strict FDA and AABB requirements. Units were preserved in ADSOL solution, split into two equal volumes, and stored in a monitored temperature-controlled refrigerator at 1–6°C until needed, according to standard blood-banking practice. Half of the unit was stored for 5 days (range, 5–7) after donation and the second half-unit was stored until 42 days (range, 40–42) after donation.
Blood Infusion
The intravenous access procedure is described in the Methods section of the online supplement. On the first testing day (range, 5–7 d) the subjects received a 0.5 U of blood, approximately 138 ± 9 ml (mean ± SD), transfused through a brachial artery line into the nondominant arm. On the second testing day (range, 40–42 d) the remainder of the unit was transfused. Blood was intraarterially transfused for a total duration ranging from 9 to 12 minutes. The volume of blood in each 0.5 U influenced the duration of each transfusion. On average, the first transfusion of 140 ± 16 ml and second transfusion of 138 ± 22 ml lasted approximately 11.1 ± 1.2 and 10.9 ± 1.4 minutes, respectively. The sequentially increasing rates of transfusion were 5 ml per minute for 2 minutes (300 ml/h), 10 ml per minute for 2 minutes (600 ml/h), and finally 15 ml per minute until the unit was fully transfused (900 ml/h) (Figure 1). Before the study we confirmed that transfusion of red cells through a 20-gauge brachial artery angiocatheter at infusion rates of 300, 600, and 900 ml per hour through the same infusion pump, filter, and tubing system did not produce any artifactual hemolysis (see Figure E1 in the online supplement).
Forearm Blood Flow Measurements
Forearm blood flow measurements with venous occlusion strain-gauge plethysmography (Hokanson, Bellevue, WA) (32–34) are summarized in the Methods section of the online supplement.
Study Design
Figure 1 demonstrates the concentration, duration, and timing of the intraarterial infusions; the timing of venous blood sampling; and the forearm blood flow measurements. Eighteen participants underwent the same protocol on Days 5 and 42 with the exception of the age of blood infused. These subjects received sequential infusion of Ach, autologous RBC transfusion, and the repeat Ach infusion. Subjects refrained from drinking alcohol and caffeine for 8 hours and fasted overnight. Nonsteroidal antiinflammatory drugs were not permitted 1 week before to the study. All studies were performed in the morning to reduce circadian variation, in a quiet, temperature-controlled room.
Miochol-E powder (Novartis Pharmaceuticals, Inc., Hanover, NJ) was used as the source of sterile Ach for use in this study. The University of Pittsburgh Medical Center Investigational Drug Service prepared the Ach solution for use. Ach acts as an endothelium-dependent vasodilator, stimulating endothelial cell muscarinic receptors to increase intracellular calcium and activate the endothelial NO synthase enzyme to synthesize NO from arginine, which relaxes vascular smooth muscle. Ach was continuously infused into the brachial artery with three sequentially increasing doses, each for 3 minutes at 7.5, 15, and 30 μg per minute before and after the intraarterial infusion of autologous blood. These Ach doses corresponded to infusion rates of 15, 30, and 60 ml per hour (Figure 1). Ach was infused with a normal saline carrier at decreasing rates of 105, 90, and 60 ml per hour, respectively, to maintain a constant fluid rate of 120 ml per hour to control for volume effects on blood flow measurements.
Measurement of Blood Biomarkers from the Antecubital Vein after Transfusions
Plasma levels of arginase-1 were measured by ELISA (Hycult Biotechnology BV, Uden, the Netherlands) according to the manufacturer’s instructions and our previous publications (35). CFPHb was determined by human Hb ELISA (Human hemoglobin ELISA kit, Cat#E88–135; Bethyl Laboratories, Montgomery, TX) according to the manufacturer’s instructions; repeat CFPHb levels were confirmed by the conversion to cyanomethemoglobin with Drabkin reagent, as previously described (22).
NO Consumption Assay
The ability of CFPHb to scavenge NO was measured with a previously published and validated NO consumption assay using an NO ozone-based chemiluminescence analyzer (Sievers, Boulder, CO) (36).
Preparation of Whole-Blood Platelet Samples
See the Methods section of the online supplement for details.
Blood Viscosity of Old Blood Compared with New Blood
See the Methods section of the online supplement for details.
Statistical Analysis
We estimated that a total sample size of at least 15 subjects would be needed to achieve a 90% power to detect a 25% decrease in the forearm blood flow response to Ach in normal volunteers during the infusion of aged blood compared with fresh blood, with a type I error rate of 5% (two-sided α). Because of the intensity of the study requirements and risk of dropout, we screened 58 subjects and overenrolled into the study to ensure that at least 15 subjects completed the study.
Analysis was performed with Microsoft Office Excel 2007/2011 (Redmond, WA), and GraphPad Prism version 5 for Windows and 6 for Macintosh, (GraphPad Software, La Jolla, CA; www.graphpad.com). Subject venous and bag blood samples were tested for Gaussian distribution with the D’Agostino and Pearson omnibus normality test. Pairs of data sets were analyzed by either paired Student’s t test for normally distributed data or Wilcoxon matched-pairs signed rank test for data that were not normally distributed. The forearm blood flow data were evaluated by paired Student’s t test and repeated-measure one-way analysis of variance Tukey analysis for multiple comparisons post-test. Statistical significance was set at less than 0.05.
Results
Study Population
Eighteen subjects completed the study as outlined in Table 1.
Markers of Hemolysis Are Increased in Aged Stored Blood
During standard RBC storage, products of RBC hemolysis accumulate in the ADSOL preservation solution (22). In our study, hemolysis products were measured in stored leukoreduced units of blood before infusions. As shown in Figure 2A, compared with fresh blood, aged blood demonstrated median levels (interquartile range) of CFPHb of 96.9 (48.9–114.1) versus 27.7 (18.2–37.8) μM (P < 0.0001), increased levels of lactate dehydrogenase 255 (192–330) versus 133 (103–191) IU (P = 0.0001), and increased levels of plasma arginase-1 334.9 (192.2–509.6) versus 608.1 (334.2–688.9) ng/ml (P = 0.0003). The total hemoglobin in the stored blood did not change from Day 5 to 42.
NO Consumption Increases in Aged Stored Blood Units
Normal human plasma reduces ferric heme (Fe+3-Hb) to ferrous heme (Fe+2-Hb) (36). We have shown that blood aged beyond 35 days contains at least 92% of the CFPHb in the ferrous oxyhemoglobin form (22). We now demonstrate that measured levels of NO consumption from the units of stored blood highly correlated with levels of CFPHb on both 5-day (r = 0.91; P < 0.0001) and 42-day (r = 0.73; P = 0.0006) blood (Figure 2B). This confirms that the CFPHb remains reduced in the ferrous oxyhemoglobin form (Fe+2-O2), which is capable of reacting with NO via the dioxygenation reaction.
Aged Blood Adversely Affects Endothelial Function as Measured by Forearm Blood Flow Responses to Ach Infusions
Before and after transfusion of stored blood we infused Ach at 7.5, 15, and 30 μg per minute. Our primary predefined endpoint of the study was the percentage change in Ach-induced blood flow after infusion of 42-day-aged stored blood compared with 5-day-aged stored blood. For each Ach infusion the % change from baseline was significantly lower for post-RBC infusion on Day 42 compared with post-RBC infusion on Day 5. Both values for the absolute and % change from baseline blood flows for Day 42 post-RBC infusion were lower with a P value of less than 0.05 (Figure 3A). In fact, blood flow responses after transfusion of 42-day-old blood were lower than that of all other Ach infusions on Days 5 and 42 (Figure 3B). This demonstrates that a brief intraarterial infusion of aged stored blood has an effect on the forearm circulation that reduces the responsiveness to Ach, suggesting that aged stored blood impairs endothelial function.
There was no effect of fresh 5-day-stored blood on the responses to Ach (Figure 3B), suggesting no adverse effect of fresh blood on endothelial function.
Blood Transfusion Increases Shear Vasodilation during Infusion into an Artery
Paradoxically, whereas the supernatant from the aged stored blood and the venous levels after transfusion had high levels of CFPHb and arginase-1, which was associated with impaired endothelial function after infusion, we observed an increase in blood flow acutely during the actual red cell transfusion into the brachial artery. The increase in forearm blood flow was associated with the rate of RBC infusion (5, 10, and 15 ml/min), such that the higher the rate of infusion increased the blood flow. We also observed a significant increase in the forearm blood flow on Day 42 compared with Day 5 stored blood, despite opposing effects on endothelial function (Figure 3C). Interestingly, more than 90% of normal volunteers reported an increased sensation of “warmth” and “pins and needles” in the forearm during the infusion of 42-day blood, but not with infusion of fresh blood. These data are consistent with an increase in either shear-mediated or metabolic vasodilation of aged stored blood.
In support of this it has been reported that aged stored blood has increased viscosity compared with fresh blood (37). We tested the viscosity of 5- versus 42-day-stored blood using a capillary viscometer (see the Methods section in the online supplement), and indeed found that the older blood had a viscosity that was 34.6% higher than that of fresh blood (Figure 4A). Because shear force is related to viscosity times flow, this is expected to almost double shear at all flows. These findings suggest a viscosity shear-mediated effect on blood flow. We also evaluated the effects of saline infusions into the brachial artery at different flow rates to determine if the rate of fluid infusion into the brachial artery affects shear-mediated vasodilation. As shown in Figure 4B, we observed a rate-dependent increase in blood flow in response to saline, albeit to a lesser effect than observed with more viscous blood (Figure 3C). In aggregate these data support the hypothesis that aged stored blood infusions into the brachial artery exhibit acute shear-mediated vasodilation, whereas at the same time impair blood flow responses to Ach after infusion.
Subject Venous Samples Demonstrate Increased Intravascular Hemolysis after the Intraarterial Infusion of Blood
Immediately after the intraarterial infusion of red cells on Days 5 and 42, hemolysis markers were measured from the study arm vein while the upper arm–cuff was inflated to limit blood escape from the forearm circulation. This represents local forearm vasculature levels of hemolysis. The levels of CFPHb and arginase-1 were significantly increased pre- and post-blood infusion on Days 5 and 42, respectively (Figure 5). Median (interquartile range) CFPHb levels increased from 4.3 (1.5–12.0) to 7.9 (3.1–12.5) μM (P = 0.18) on Days 5 and 6.5 (2.2–8.1) to 10.8 (5.6–14.8) μM (P = 0.04) on Day 42. Plasma arginase-1 increased from 31.2 (16.6–62.8) to 53.1 (23.9–103.1) ng/ml (P = 0.009) on Day 5 and 27.0 (20.1–57.0) to 76.1 (39.7–107.8) ng/ml (P < 0.0001) on Day 42. The total venous hemoglobin, aspartate aminotransferase, and lactate dehydrogenase values also increased after transfusion.
Systemic Arterial Blood Pressures (Mean Arterial Pressures) Increase on Day 5 and Day 42 after the Infusion of Red Cells
Five- and 42-day mean arterial pressures increased immediately after blood infusion from (mean ± SD) 87.3 ± 9.0 to 89.6 ± 8.9 mm Hg (P = 0.039) and from 84.6 ± 9.1 to 88.6 ± 9.7 mm Hg (P = 0.001), respectively (Figure 6). There was no associated increase in heart rate on either transfusion day. The pressor response was likely related to increased blood volume, CFPHb, and/or arginase-1 release during red cell infusion, as previously demonstrated (22).
Platelet Activation Was Not Increased after Red Cell Transfusion on Day 5 or Day 42
Platelets are activated during red cell storage through adenosine diphosphate and CFPHb release, which enhances platelet activation by lowering NO bioavailability and stimulating purinurgic receptors (38). There was no observed effect of red cell transfusion on platelet activation, possibly related to the citrate preservative in the stored blood (see Figure E3).
Discussion
This is the first study to invasively and directly assess human endothelial-dependent vascular function using the intraarterial infusion of Ach before and after an autologous transfusion at the extremes of FDA red cell storage. We found significant effects of transfusion of aged stored blood, with increases in storage and post-transfusion hemolysis, increased plasma NO scavenging, and impaired endothelial function. We observed significant individual donor variability in the rate of storage hemolysis, suggesting donor-specific genetic factors in addition to storage time effects.
Our study used sensitive and specific measures of vascular endothelial function by infusing the endothelium-dependent vasodilator Ach coupled to blood flow assessments using strain-gauge plethysmography. We also exposed the forearm vasculature with a relatively larger transfusion exposure by infusing the blood directly into the brachial artery circulation. Prior studies in humans assessed vascular endothelial function by noninvasive measures of flow-mediated vasodilation after the systemic transfusion of 1 U of packed RBCs (PRBCs) (23, 24, 31). Transfusion studies in normal volunteers are limited by the amount of RBCs that can be infused. Our invasive method of intraarterial transfusion aimed to address this shortcoming by delivery of blood into a smaller circulation volume and vascular bed. The intraarterial transfusion of 42-day RBCs into the forearm circulation attempted to model the intravascular effects of a more significant transfusion.
Our findings in the systemic circulation are consistent with data recently reported for the pulmonary circulation by Berra and colleagues (23) who demonstrated that the autologous transfusion of leukoreduced red cells stored for 40 days and transfused into subjects with endothelial dysfunction increased CFPHb, NO consumption, and pulmonary artery pressures measured by Doppler echocardiography. The increased pulmonary artery pressures were ameliorated with inhaled NO, which oxidized the plasma hemoglobin to methemoglobin, inhibited NO consumption, and vasodilated the pulmonary circulation. Combined, both our and the Berra and colleagues (23) findings demonstrate that aged red cell infusions acutely increase the levels of CFPHb and are associated with decreases in NO-dependent blood flows and increased vasoconstriction.
The storage lesion refers to alterations within stored red cells resulting in multiple changes leading to a loss of membrane integrity, and release and accumulation of CFPHb and microparticles containing hemoglobin (22, 39, 40). The reported levels of CFPHb have ranged between 28 and 593 μM after 35 days of storage in citrate-phosphate-dextrose-adenine anticoagulant (41, 42). We demonstrate that the concentration of CFPHb from leukoreduced red cells aged for 42 days in ADSOL is 96.9 μM, which is consistent with our previously published data of 81–88 μM in nonleukoreduced blood (22). This suggests that there are limited differences in rates of hemolysis between leukoreduced and nonleukoreduced units of blood (22, 43).
The classic dioxygenation reaction shows that NO exposed to oxyhemoglobin results in the rapid consumption of NO, producing methemoglobin and nitrate. This near diffusion-limited fast reaction (k = 107 − 108 M−1s−1) is irreversible and inactivates NO in blood.
When hemoglobin is sequestered within the red cell membrane, NO is scavenged 1,000 times slower, compared with CFPHb (22). In our study we infused fresh and aged blood containing varying degrees of hemolysis measured in stored blood and measured within the vein of recently transfused subjects. We demonstrate that samples taken from the vein immediately after red cell infusion have elevated levels of CFPHb and arginase-1 on Day 42. We have previously shown that small amounts of CFPHb result in reduced NO bioavailability with levels as low as 1 μM in kinetic models and 6 μM in animal models (32, 43). The venous levels of CFPHb on Days 5 and 42 were 7.9 and 10.8 μM, respectively, which are higher than the levels previously shown to impair NO signaling in animals and in computational models. Patients experiencing a sickle-cell vasoocclusive crisis hemolyze red cells with CFPHb measured at 9.6 μM (32, 43). These values are similar to that of our measured CFPHb venous levels from Day 42. In trauma patients, massive transfusion can result in the transfusion of at least 10 U of PRBCs in a 24-hour period (44). Such exposure to aged PRBCs could lead to over 20 times the exposure to CFPHb contributing to significant systemic effects on endothelial function.
Arginase is a critical component of the urea cycle that is released from erythrocytes during hemolysis and has been proposed to contribute to the development of pulmonary hypertension in patients with hemolytic anemias (45–47). Plasma levels of the arginase-1 isoform strongly correlate with CFPHb (22, 45), because both are released from red cells during hemolysis (45). Increased levels of arginase catalyze the conversion of l-arginine to ornithine, reducing the bioavailability of arginine, the precursor to NO, contributing to endothelial dysfunction (45, 48). Our levels of arginase-1 were significantly elevated by Day 42 of storage, but not to the extent of previously published levels by Donadee and coworkers (22): 608.1 ng/ml compared with 4,633 ng/ml at 39 days of storage. It is unclear if leukoreduction led to the difference in arginase-1 levels.
Red cell microparticles were not measured in this study, as in our prior publication (22). However, we previously documented the percentage of hemoglobin CFPHb that was contained in the form of microparticles. We found that 17.9 ± 4.8% of plasma hemoglobin was contained in microparticles in 6 U of 42-day-old stored blood centrifuged at 750 × g. Within the microparticles the hemoglobin concentration was 31.9 ± 9.3 μmol/L. This suggests that approximately 15% of the measured plasma hemoglobin in the current study is contained in microparticles. Similarly, Stapley and colleagues (21) demonstrated that microparticle levels increased during red cell storage, with the highest levels measured at 42 days of storage. Kinetic modeling demonstrated that there was a 40-fold increase in red cell–dependent NO scavenging with 42-day blood compared with fresh blood.
Two large multicenter randomized clinical trials evaluating the effect of the age of red cells have been published (16, 17). The RECESS (Red Cell Storage Duration) study of 1,098 cardiac surgery patients in the United States randomized patients to red cells stored less than or equal to 10 days or greater than or equal to 21 days. The primary outcome was the change in multiorgan dysfunction score through Day 7. The ABLE (Age of BLood Evaluation) study of 2,420 intensive care unit patients in Canada randomized patients to red cells stored less than or equal to 7 days versus standard of care, approximately 22 days. The primary outcome was 90-day mortality. Both studies failed to show a difference in primary outcomes between those transfused with fresher units and older units.
One of the limitations of the RECESS and ABLE studies is the mean ages of older blood were only 28.3 and 22 days, respectively. For ethical and technical reasons very few units of blood were transfused at the extreme limits of FDA storage of 42 days (16, 18). What the RECESS and ABLE studies have compared were the effects of fresh blood with the usual practice of standard-issue blood, not to the extremes of approved RBC storage as tested in our current study (18). We have previously demonstrated in Donadee and colleagues that after approximately 20 days of storage the degree of hemolysis and CFPHb, free iron, and arginase release rises significantly and exponentially, so that at 35–42 days the hemolysis of aged blood would be maximal (22).
There are several important limitations in this study to highlight. The study represents a small sample size of healthy individuals and the transfused blood was autologous rather than allogeneic. Subjects had received blood intraarterially, which may affect forearm blood flow via shear affects, as described previously. However, this approach allowed for the exposure of the forearm microcirculation to a relatively high concentration of transfused blood. Additionally we were also unable to determine what degree the increased venous levels of CFPHb were a consequence of CFPHb added by transfusion or caused by the immediate intravascular hemolysis of transfused RBCs. However, we have shown conclusively that there is minimal artifactual hemolysis of the stored blood infusion through our tubing, pumps, and filters (see Figure E1).
We were also limited to two transfusions at the extremes of cold storage. This was a highly technical study, requiring blood collection and processing, intraarterial blood infusions, arterial catheters, and the need to obtain FDA Investigational New Drug for use of Ach, and was focused on addressing the physiologic effects of blood at the limits of cold storage that are currently FDA approved. We were limited by the institutional review board in this extremely complex study in normal volunteers of autologous blood storage and transfusion to two infusions because the maximal blood we could collect was one large pheresis unit of 400–450 ml of PRBC. We note in the data published in Donadee and colleagues (22) that after 20 days of storage the degree of hemolysis and hemoglobin, free iron, and arginase release increases significantly and exponentially, so that at Weeks 5–6 the risk would be greatest.
In summary, we demonstrate that human blood at the limits of approved cold storage time undergoes significant hemolysis and increases CFPHb and arginase-1 levels in the forearm circulation after transfusion. This results in both the scavenging of available NO and produces endothelial dysfunction, as directly assessed by observed reductions in the vasodilatory effect of intraarterial infusion of Ach (Figure 7). Thus, although recent clinical trials suggest that fresh blood has similar safety as blood stored to a mean of 22–28 days, the extreme last week of storage has not been evaluated with sufficient power. Our data confirm preclinical data and raise important questions about safety and pathophysiologic effects of transfused blood from the last week of cold storage.
Acknowledgments
Acknowledgment
The authors thank the University of Pittsburgh CTRC nursing staff for their expertise, patience, and tireless efforts during this study.
Footnotes
Supported by National Institutes of Health grants 2R01HL098032, 1R01HL125886-01, P01HL103455, T32 HL110849, and T32 HL007563 (M.T.G.); the Institute for Transfusion Medicine (M.T.G.); and the Hemophilia Center of Western Pennsylvania (M.T.G).
Author Contributions: M.G.R. contributed to study design, performed arterial line placement, the forearm blood flow studies, interpreted data, performed analysis of the forearm blood flows, performed statistical analysis, and wrote and edited the manuscript. T.K. performed laboratory tests, interpreted data, and edited the manuscript. D.T. set up blood banking procedures. C.D. contributed to study design and staff training for forearm blood flow measurement. S.B. contributed to study design and was the study coordinator. J.B. performed laboratory tests, interpreted data, and edited the manuscript. S.J. performed laboratory analysis of the platelet data. A.M.B. collected and performed laboratory tests. D.B.K.-S. contributed to study design, oversaw work at Wake Forest, and edited the manuscript. M.T.G. contributed to study conception and design, provided laboratory support, data analysis, and edited the manuscript.
This article has an online supplement, which is accessible from this issue's table of contents at www.atsjournals.org
Originally Published in Press as DOI: 10.1164/rccm.201501-0145OC on July 29, 2015
Author disclosures are available with the text of this article at www.atsjournals.org.
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