Influence of cell-free Hb on local tissue perfusion and oxygenation in acute anemia after isovolemic hemodilution

BACKGROUND: Oxygen-carrying solutions are intended to eliminate the blood transfusion trigger. Their ability to maintain microvascular perfusion and to deliver oxygen to tissue when they replace the RBCs as oxygen carriers has not been directly measured. STUDY DESIGN AND METHODS: Microvascular response to exchange transfusion with a polymerized bovine cell-free Hb (PBH) solution after acute isovolemic hemodilution with a plasma expander was investigated by using the hamster window model. In vivo functional capillary density (FCD), blood flow, and high-resolution oxygen distribution in microvascular networks were measured by noninvasive methods. RESULTS: Exchange transfusion of PBH solution after a 60-percent isovolemic hemodilution with dextran 70 (MW, 70 kDa) resulted in a Hct of 11 percent and a Hb content of 6.7 g per dL. FCD was 0.37 of baseline. Interstitial pO2 was reduced from 21.0 mm Hg to 0.3 mmHg. Arteriolar and venular blood flows were ratios of 0.75 and 0.76 relative to baseline. In a previous study, tissue pO2 after hemodilution to 5.6 g of Hb per dL with dextran 70 was 23.0 mmHg. Hypervolemic injection of PBH solution increased blood pressure and caused vasoconstriction. CONCLUSION: Using PBH solution to replace RBC oxygen-carrying capacity during low Hb content conditions (<50%) causes abnormally low tissue oxygenation and FCD, while the same level of hemodilution with dextran maintains normal microvascular conditions.     

Transfusion of stored red blood cells adhere in the rat microvasculature

BACKGROUND: Ex vivo storage of red blood cells (RBCS) for transfusions is associated with a “storage lesion,” which decreases RBC deformability and increases RBC adhesiveness to vascular endothelium. This may impair microcirculatory flow with deleterious effects on oxygen delivery after transfusion. Previous studies have shown that human RBCs adhere to endothelial monolayers in vitro with prolonged storage and is reduced by prestorage leukoreduction (LR). The objective of this study was to determine whether duration of RBC storage and LR influence RBC adhesion in vivo in capillaries. STUDY DESIGN AND METHODS: Rat RBCs were collected and stored in CPDA‐1 under standard blood bank conditions. Three RBC products were compared: 1) fresh RBCs, less than 24 hours of storage (n = 6); 2) nonleukoreduced (NLR) RBCs stored for 7 days (n = 6); and 3) prestorage LR RBCs stored for 7 days (n = 6). RBCs were labeled with fluorescein isothiocyanate (FITC) 24 hours before transfusion and reinjected in an isovolemic manner into healthy rats. The FITC‐labeled RBCs were visualized in the extensor digitorum longus muscle using intravital video microscopy (20× magnification). The number of RBCs adherent in capillaries was counted 1 hour after transfusion in 10 random fields and the median values were compared with one‐way analysis of variance. RESULTS: Stored RBCs showed increased levels of adherence in capillaries compared to their fresh counterparts (p < 0.05). Prestorage LR decreased RBC adherence to levels equivalent to those of fresh RBCs (p < 0.05 for stored LR vs. stored NLR). CONCLUSION: Rat RBCs stored under conditions that closely mimicked clinical transfusion adhere in capillaries. The decreased RBC adherence with LR suggest a direct effect of white blood cells or their byproducts on RBC deformability and/or adhesiveness to microvascular endothelium. Further study will examine the mechanism of adherence and the impact it has on microcirculatory flow and oxygen delivery in the critically ill host.     

Transfusion restores blood viscosity and reinstates microvascular conditions from hemorrhagic shock independent of oxygen carrying capacity

Systemic and microvascular hemodynamic responses to transfusion of oxygen using functional and non-functional packed fresh red blood cells (RBCs) from hemorrhagic shock were studied in the hamster window chamber model to determine the significance of RBCs on rheological and oxygen transport properties. Moderate hemorrhagic shock was induced by arterial controlled bleeding of 50% of the blood volume, and a hypovolemic state was maintained for 1h. Volume restitution was performed by infusion of the equivalent of 2.5 units of packed cells, and the animals were followed for 90 min. Resuscitation study groups were non-oxygen functional fresh RBCs where the hemoglobin (Hb) was converted to methemoglobin (MetHb) [MetRBC], fully oxygen functional fresh RBCs [OxyRBC] and 10% hydroxyethyl starch [HES] as a volume control solution. Measurement of systemic variables, microvascular hemodynamics and capillary perfusion were performed during the hemorrhage, hypovolemic shock and resuscitation. Final blood viscosities after the entire protocol were 3.8 cP for transfusion of RBCs and 2.9 cP for resuscitation with HES (baseline: 4.2 cP). Volume restitution with RBCs with or without oxygen carrying capacity recovered higher mean arterial pressure (MAP) than HES. Functional capillary density (FCD) was substantially higher for transfusion versus HES, and the presence of MetHb in the fresh RBC did not change FCD or microvascular hemodynamics. Oxygen delivery and extraction were significantly lower for resuscitation with HES and MetRBC compared to OxyRBC. Incomplete re-establishment of perfusion after resuscitation with HES could also be a consequence of the inappropriate restoration of blood rheological properties which unbalance compensatory mechanisms, and appear to be independent of the reduction in oxygen carrying capacity.     

Fatigue during acute isovolemic anemiain healthy, resting humans

BACKGROUND: Transfusion guidelines recommend that clinicians assess patients for signs and symptoms of anemia before the transfusion of RBCs. However, studies of signs and symptoms associated with acute isovolemic anemia are limited. The objective of this study was to determine whether acute reduction of Hb concentration to 5 g per dL would result in fatigue, tachycardia, or hypotension in resting, young, healthy, isovolemic humans, and whether changes were reversible with RBC transfusion. STUDY DESIGN AND METHODS: Conscious, resting, healthy adults less than 35 years old (n = 8) underwent acute isovolemic hemodilution to Hb of 5 g per dL and self-scored their energy level at various Hb concentrations. Heart rate and blood pressure were also measured. For controls, measurements of each subject were made during a comparable period of rest without hemodilution. RESULTS: During acute isovolemic hemodilution, energy levels decreased progressively and were lower at Hb of 7, 6, and 5 g per dL than at baseline (p<0.01) or in control sessions (p<0.05). The energy level was lower at Hb 7 g per dL than at 14 ( p = 0.005), lower at Hb 6 g per dL than at 7 (p = 0.01), and lower at Hb 5 g per dL than at 6 (p =0.01). Energy levels rose and were not different from baseline or control levels after transfusion of all autologous RBCs. Similarly, median heart rate increased with hemodilution to Hb of 7, 6, and 5 g per dL and decreased with transfusion of autologous RBCs. Supine blood pressure did not decrease with isovolemic hemodilution. CONCLUSION: In resting, young, healthy humans, acute isovolemic anemia to Hb levels of 7, 6, and 5 g per dL results in decreased self-scored energy levels and in an increase in heart rate but not in hypotension. Changes in energy and heart rate are reversible with the transfusion of autologous RBCs.     

Inositol hexaphosphate–loaded red blood cells prevent in vitro sickling

BACKGROUND: Hypoxia is a major cause of painful vaso‐occlusive crisis in sickle cell disease (SCD). Simple transfusion and red blood cell (RBC) exchange are commonly used as preventive therapies whose aim is to dilute hemoglobin (Hb)S‐containing RBCs (SS‐RBCs) with normal RBCs (AA‐RBCs) to prevent sickling. We hypothesized that the effectiveness of transfusion could be improved by the encapsulation of inositol hexaphosphate (IHP), an allosteric Hb effector, in transfused AA‐RBCs. Indeed, apart from their diluting effect on SS‐RBCs, IHP‐loaded RBCs (IHP‐RBCs) with increased oxygen release capacity could palliate in vivo oxygen deprivation and reduce sickling. STUDY DESIGN AND METHODS: The study was designed to investigate the therapeutic effect of IHP‐RBCs transfusion on in vitro sickling of SS‐RBCs collected from 20 SCD patients. Patients' RBCs were diluted with various proportions of IHP‐RBCs or AA‐RBCs (processed or stored RBCs as controls). Resulting suspensions were subjected to deoxygenation followed by partial reoxygenation at 5% oxygen. Sickling was evaluated by microscopy. RESULTS: Stored RBCs (50% dose) used to mimic simple transfusion exhibited a poor antisickling effect (5.6%) and a low response rate (65%). In contrast, IHP‐RBCs treatment was seven times more effective resulting in 35% of sickling reduction and a 94% response rate. Sickling was inhibited in a dose‐dependent manner: 9.9, 25.1, and 35.0% for IHP‐RBCs in percentages of 10, 30, and 50%, respectively. CONCLUSION: Our results indicate that IHP‐RBCs prevent in vitro sickling and suggest that it could improve conventional transfusion therapy in terms of transfused volume, frequency, and efficacy.     

Effect of prophylactic transfusion of stored RBCs on oxygen reserve in response to acute isovolemic hemorrhage in a rodent model

BACKGROUND: The storage of RBCs results in a time-related decline in 2,3 DPG that may reduce the ability to unload oxygen (O(2)) to tissue. The objective of this study was to compare the effect that transfusion of stored 2,3 DPG-depleted rat blood (7 days in CPDA-1) had on the O(2) reserve in conscious rats, with that of the transfusion of fresh blood (<2-hour storage). STUDY DESIGN AND METHODS: Anemic rats (Hb, 80 g/L) received either fresh packed RBCs or stored RBCs to raise Hb levels to 140 g per L. They then underwent isovolemic hemorrhage mimicking surgical blood loss to the point of O(2) supply dependency (OSD). Critical O(2) delivery (DO(2)crit), Hb concentration, and O(2) extraction at OSD were measured in a metabolic chamber. RESULTS: After transfusion, RBC DPG decreased by 50 percent in the stored-blood group, and the p50 value decreased by 5 mmHg (32.1 +/- 2.5 mmHg vs. 37.5 +/- 3.0). DO(2)crit was similar in the two groups (fresh blood: 2.79 +/- 0.44 mL/min x g(-1); stored blood, 2.99 +/- 0.76 mL/min x g(-1)). The critical Hb concentration at DO(2)crit was higher in the stored-blood group (44 +/- 4 g/L) than in the fresh-blood group (38 +/- 5 g/L); the cardiac index and O(2) extraction ratio in the two groups were not different. Under conditions of severe normovolemic anemia in rats, depletion of DPG and a decrease in p50 had only minor effects on the O(2) reserve. At OSD, under these conditions, O(2) consumption is not limited by diffusion. CONCLUSION: The physiologic impact of DPG depletion in transfused stored blood on oxygen availability in normal rats appears to be small and may be clinically inconsequential.     

Rejuvenation of stored human red blood cells reverses the renal microvascular oxygenation deficit in an isovolemic transfusion model in rats

BACKGROUND: Storage of red blood cells (RBCs) results in various biochemical changes, including a decrease in cellular adenosine triphosphate and 2,3-diphosphoglycerate acid. Previously it was shown that stored human RBCs show a deficit in the oxygenation of the microcirculation in the gut of anesthetized rats. In this study, the effect of RBCs on rat kidney oxygenation and the effect of rejuvenation of stored RBCs on their ability to deliver oxygen were investigated.
STUDY DESIGN AND METHODS: Washed RBCs, derived from leukoreduced RBCs stored in saline-adenine-glucose-mannitol, were tested in an isovolemic transfusion model in rats after hemodilution until 30 percent hematocrit (Hct). The cells were derived from RBCs stored for up 3 days or from RBCs stored for 5 to 6 weeks with or without incubation in Rejuvesol to rejuvenate the cells. Renal microvascular oxygen concentrations (µPO₂) were determined by Pd-porphyrin phosphorescence lifetime measurements.
RESULTS: Isovolemic transfusion exchange of 5- to 6-week-stored RBCs resulted in a significantly larger decrease in renal µPO₂ than RBCs stored for up to 3 days: 16.1 ± 2.3 mmHg versus 7.1 ± 1.5 mmHg, respectively (n = 5). Rejuvenation of stored RBCs completely prevented this deficit in kidney oxygenation. The differences in oxygen delivery were not due to different recoveries of the human RBCs in the rat circulation.
CONCLUSION: This study shows that the storage-induced deficit of human RBCs to oxygenate the rat kidney microcirculation at reduced Hct is completely reversible. Prevention of metabolic changes during storage is therefore a valid approach to prevent this deficit.     

Hemodilution and intravenous perflubron emulsion as an alternative to blood transfusion: effects on tissue oxygenation during profound hemodilution in anesthetized dogs

BACKGROUND: Intravenously administered perfluorocarbon (PFC) emulsions increase oxygen solubility in plasma. PFC might therefore temporarily replace red cells (RBCs) lost during intraoperative hemorrhage. In patients who have undergone hemodilution, the return of autologous blood may be delayed by the administration of PFC, and autologous RBCs may be saved for transfusion after surgical bleeding is stopped and PFC is cleared by the reticuloendothelial system. STUDY DESIGN AND METHODS: In 22 anesthetized, hemodiluted dogs (hemoglobin [Hb] 7 g/dL) breathing 100-percent O2, an intraoperative volume-compensated blood loss was simulated. The efficacy of three therapeutic regimens in maintaining tissue oxygenation was compared: 1) RBC group (n = 7): maintenance of a Hb > 7 g per dL by transfusion of autologous RBCs; 2) PFC group (n = 7): bolus application of a second-generation PFC emulsion (60% wt/vol perflubron) and further acute normovolemic hemodilution (ANH) to a Hb of 3 g per dL; and 3) control group (n = 7): further ANH alone to a Hb of 3 g per dL. Systemic and myocardial oxygenation status and tissue oxygenation were assessed. RESULTS: Autologous RBCs transfused to maintain a Hb of 7 g per dL preserved hemodynamics and tissue oxygenation during blood loss. In the PFC and control groups, heart rate and cardiac index increased significantly in response to further ANH. Tissue oxygenation was not different in the PFC and the RBC groups. Direct comparison of the PFC and control groups revealed better tissue oxygenation in the PFC group, as reflected by significantly higher mixed venous, coronary venous, and local tissue pO2 on liver and skeletal muscle. CONCLUSION: Bolus intravenous administration of 60- percent (wt/vol) perflubron emulsion and further hemodilution from a Hb of 7 g per dL to one of 3 g per dL were as effective as autologous RBC transfusion in maintaining tissue oxygenation during volume-compensated blood loss designed to mimic surgical bleeding.     

Posttransfusion recovery of stored red blood cells in very low birth weight infants using a hemoglobin balance model

BACKGROUND: A Hb balance model was used in very low birth weight (VLBW) infants to predict posttransfusion Hb levels from which we inferred allogeneic RBC recovery after transfusion of RBCs stored for varying periods of time. STUDY DESIGN AND METHODS: Premature VLBW infants receiving RBC transfusions during the 1st month of life were evaluated retrospectively for RBC survival of stored donor blood. Actual Hb levels measured in infant blood 1 and 2 days after RBC transfusions were compared to those predicted using a Hb balance model based on factors affecting blood Hb loss and gain. Transfusions were subgrouped according to whether or not infants were clinically stable at the time of RBC transfusion. Model-predicted RBC recovery was also evaluated relative to duration of RBC storage. RESULTS: Model-predicted mean (+/- SD) Hb levels 2 days after transfusion among the 30 VLBW infants receiving a total of 57 RBC transfusions were only 4 percent higher than actual values observed (15.2 +/- 1.2 g/dL vs. 14.7 +/- 1.4, respectively; p < 0.05). The infant's clinical status at the time of transfusion did not affect predicted 1- and 2-day posttransfusion RBC recovery. Model-predicted recovery of transfused RBCs was modestly, but significantly, decreased with increasing duration of donor RBC storage (i.e., 10% lower by 42 days-the maximal allowed storage period for donor blood [p < 0.01]). CONCLUSIONS: Our model-predicted RBC survival results are consistent with-but not direct evidence of-hemolysis of donor blood after RBC transfusion. Although observed post-RBC Hb levels 2 days after transfusion averaged only 4 percent less than predicted, model-predicted survival of donor RBCs at 42 days suggested a modest decrease (i.e., by 10%).     

Transfusion of fresh murine red blood cells reverses adverse effects of older stored red blood cells

BACKGROUND: Although a subset of recent studies have suggested that red blood cell (RBC) storage length is associated with adverse patient outcomes, others have shown no such relationship. Adults may be transfused with RBC units of different storage lengths, and existing studies do not take into consideration that fresh RBCs may alter responses to concurrently transfused stored RBCs. To test this possibility, we utilized a murine model and investigated transfusion outcomes of fresh, stored, or fresh‐plus‐stored RBCs. STUDY DESIGN AND METHODS: Fresh, 14‐day‐stored or fresh plus 14‐day‐stored leukoreduced RBCs from HOD‐transgenic donors (with RBC‐specific expression of hen egg lysozyme, ovalbumin, and human Duffy^b) were transfused into naïve C57BL/6 recipients. Serum cytokines and anti‐HOD alloimmunization were evaluated after transfusion. RESULTS: In six of six experiments (n = 90 mice total), a proinflammatory serum cytokine storm of interleukin‐6, keratinocyte‐derived chemokine/CXCL1, and monocyte chemoattractant protein‐1 was observed in transfusion recipients of stored but not fresh RBCs, along with high degrees of anti‐HOD alloimmunization. However, concurrent transfusion of fresh HOD RBCs along with stored HOD RBCs significantly decreased these adverse outcomes (p < 0.05). CONCLUSIONS: These results are consistent with fresh murine HOD RBCs losing protective properties during storage, and introduce a previously unrecognized variable in RBC storage studies. If translatable to humans, uniform “old blood” groups may be needed in future clinical studies to more accurately investigate the biologic effects of older RBC units.     

Diabetes augments and inhaled nitric oxide prevents the adverse hemodynamic effects of transfusing syngeneic stored blood in mice

BACKGROUND: Stored red blood cells (RBCs) undergo progressive deleterious functional, biochemical, and structural changes. The mechanisms responsible for the adverse effects of transfusing stored RBCs remain incompletely elucidated. STUDY DESIGN AND METHODS: Awake wild‐type (WT) mice, WT mice fed a high‐fat diet (HFD‐fed WT) for 4 to 6 weeks, and diabetic (db/db) mice were transfused with syngeneic leukoreduced RBCs or supernatant with or without oxidation (10% of total blood volume) after storage for not more than 24 hours (FRBCs) or 2 weeks (SRBCs). Inhaled nitric oxide (NO) at 80 parts per million was administered to a group of mice transfused with SRBCs. Blood and tissue samples were collected 2 hours after transfusion to measure iron and cytokine levels. RESULTS: SRBCs had altered RBC morphology and a reduced P₅₀. Transfusion of SRBCs into WT or HFD‐fed WT mice did not produce systemic hemodynamic changes. In contrast, transfusion of SRBCs or supernatant from SRBCs into db/db mice induced systemic hypertension that was prevented by concurrent inhalation of NO. Infusion of washed SRBCs or oxidized SRBC supernatant into db/db mice did not induce hypertension. Two hours after SRBC transfusion, plasma hemoglobin (Hb), interleukin‐6, and serum iron levels were increased. CONCLUSION: Transfusion of syngeneic SRBCs or the supernatant from SRBCs produces systemic hypertension and vasoconstriction in db/db mice. It is likely that RBC storage, by causing in vitro hemolysis and posttransfusion hemoglobinemia, produces sustained NO scavenging and vasoconstriction in mice with endothelial dysfunction. Vasoconstriction is prevented by oxidizing the supernatant of SRBCs or breathing NO during SRBC transfusion.     

The effect of the transfusion of stored RBCs on intestinal microvascular oxygenation in the rat

BACKGROUND: Although it is known that the transfusion of stored RBCs does not always improve tissue O(2) consumption under conditions of limited tissue oxygenation, the efficiency of O(2) delivery to the microcirculation by stored RBCs has never been determined. STUDY DESIGN AND METHODS: In a rat hemorrhagic shock model, the effects of resuscitation with fresh or 28-day-old RBCs stored in CPD plasma, saline-adenine-glucose-mannitol, and CPDA-1 plasma were investigated. Systemic hemodynamic and intestinal oxygenation measures were monitored. Intestinal microvascular PO(2) was determined with the O(2)-dependent quenching of palladium-porphyrin phosphorescence, and the RBC deformability was measured with a Laser-assisted optic rotational cell analyzer. RESULTS: Hemodynamic and oxygenation measures were significantly decreased during hemorrhagic shock. Intestinal oxygen consumption and mesenteric venous pO(2) were restored with the transfusion of both fresh and stored RBCs, except for CPD-stored RBCs. The intestinal microvascular pO(2) improved only with the transfusion of fresh RBCs. Deformability of the stored RBCs was significantly decreased. CONCLUSION: In contrast to that of fresh RBCs, the transfusion of stored RBCs did not restore the microcirculatory oxygenation, possibly because of impaired O(2) unloading, but, except for CPD-stored RBCs, the storage-induced changes were not enough to impair intestinal VO(2) and mesenteric venous pO(2).     

Is resuscitation from hemorrhagic shock limited by blood oxygen-carrying capacity or blood viscosity?

Systemic and microvascular hemodynamic responses to volume restoration from hemorrhagic shock were studied in the hamster window chamber model to determine the significance of blood rheological and oxygen transport properties. Moderated hemorrhage was induced by means of arterial controlled bleeding of 50% of the blood volume. The hypovolemic shock state was maintained for 1 h before resuscitation. The animals were resuscitated by infusion of 25% of blood volume using either fresh plasma or blood and were studied for 90 min. Transfusion was performed with either oxygen-carrying fresh red blood cells (RBCs) or non-oxygen-carrying RBCs whose hemoglobin was converted to methemoglobin (MetHb). Systemic parameters, including cardiac output, vital organ blood flow distribution, microvascular hemodynamics, and capillary perfusion (functional capillary density [FCD]), were measured during the resuscitation period. Fluorescent-labeled microspheres were used to measure organ blood flow (brain, heart, kidney, liver, lung, spleen, and window chamber). The blood viscosities at the end of the 90-min period were 2.4 cP after resuscitation with plasma, and 2.9 to 3.0 cP after blood transfusion (baseline, 4.2 cP). Resuscitation with RBCs with or without oxygen-carrying capacity had greater mean arterial pressure than did the plasma resuscitation group. The FCD was substantially higher for RBC transfusions (0.56% +/- 7% of baseline) compared with plasma (46% +/- 7% of baseline), and the presence of MetHb in the fresh RBC did not change the FCD or the microvascular hemodynamics. Oxygen delivery and extraction levels were significantly lower for resuscitation with plasma and MetHb-loaded RBCs compared with oxygen-carrying RBCs. The curtailed recovery of systemic and microvascular conditions after volume restitution with plasma seems to be due to the decrease in blood viscosity. Conversely, the restoration of blood rheological properties improves resuscitation independently of the restitution of oxygen-carrying capacity.     

Rapid clearance of transfused murine red blood cells is associated with recipient cytokine storm and enhanced alloimmunogenicity

BACKGROUND: Fourteen‐day stored red blood cells (RBCs) containing an RBC‐specific transgenic antigen (HOD) induce a recipient proinflammatory cytokine storm and are significantly more immunogenic compared to fresh RBCs. Given that recipient mice clear transfused stored RBCs more rapidly than fresh RBCs, we hypothesized that rapid RBC clearance was associated with adverse transfusion outcomes. STUDY DESIGN AND METHODS: HOD RBCs were treated by two distinct methods known to lead to rapid posttransfusion RBC clearance: phenylhydrazine or heat. HOD antigen expression was analyzed on the treated cells before transfusion, and RBC recovery, recipient cytokine response, and recipient anti‐HOD alloimmunization response were measured after transfusion. RESULTS: Phenylhydrazine and heat treatment each led to near complete RBC clearance in recipients by 24 hours posttransfusion, without significantly altering HOD antigen expression on the transfused RBCs. Recipients of phenylhydrazine‐ or heat‐treated RBCs had elevated circulating levels of keratinocyte‐derived chemokine/CXCL‐1, monocyte chemoattractant protein‐1, and interleukin‐6 after transfusion. Furthermore, phenylhydrazine‐ or heat‐treated RBCs were significantly more immunogenic than control RBCs, with a mean 25.1‐ and 10.3‐fold enhancement, respectively, of anti‐HOD alloimmunization magnitude by flow cytometric crossmatch. CONCLUSIONS: Three separate insults to RBCs (storage, phenylhydrazine, or heat treatment) result in rapid posttransfusion clearance, with a recipient proinflammatory cytokine storm and enhanced alloimmunogenicity. These data are consistent with the hypothesis that rapid clearance of RBCs is causally involved in these outcomes and suggest that human donor RBCs with favorable posttransfusion clearance profiles may be less immunogenic.     

A novel mouse model of red blood cell storage and posttransfusion in vivo survival

BACKGROUND: Storage of red blood cells (RBCs) is necessary for an adequate blood supply. However, reports have identified potential negative sequelae of transfusing stored RBCs. An animal model would be useful to investigate the pathophysiology of transfusing stored RBCs. However, it has been reported that storage of rat RBCs in CPDA-1 resulted in an unexpected sudden decline in posttransfusion survival. A mouse model of RBC storage and transfusion was developed to assess survival kinetics of mouse RBCs.
STUDY DESIGN AND METHODS: RBCs expressing green fluorescent protein were collected in CPDA-1, filter leukoreduced, adjusted to a 75% hematocrit, and stored at 4°C. At weekly intervals, stored RBCs were transfused into C57BL/6 recipients. RBC survival was measured by flow cytometry and chromium-51 labeling. Phosphatidylserine externalization and CD47 expression was also evaluated.
RESULTS: Mean 24-hour survivals of transfused RBCs were 99, 91, 64, 54, 30, and 18% after 0, 7, 14, 21, 28, and 35 days of storage, respectively. Stored RBCs showed an initial rapid clearance with subsequent extended survival. Increased surface phosphatidylserine and decreased CD47 expression were also observed.
CONCLUSIONS: Mouse RBCs showed a progressive decline in survival, as a function of storage time, unlike the precipitous loss of viability reported for rat RBCs. Moreover, changes in the measured surface markers were analogous to trends reported for human RBCs. Together, these findings provide an initial characterization of a novel mouse model of RBC storage with the potential to serve as an experimental platform for studying the pathophysiologic consequences of transfusing stored RBCs.     

The effect of storage time of human red cells on intestinal microcirculatory oxygenation in a rat isovolemic exchange model

OBJECTIVE: To determine whether the storage time of human leukodepleted red blood cell concentrates compromises intestinal microvascular oxygen concentration oxygen (muPo(2)) during isovolemic exchange transfusion at low hematocrit. DESIGN: Prospective, randomized, controlled study. SETTING: University research institute laboratory. SUBJECTS: Male Wistar rats. INTERVENTIONS: Intestinal muPo(2) was determined by Pd-porphyrin phosphorescence life-time measurements. MEASUREMENTS AND MAIN RESULTS: Rats were brought near to a state of oxygen supply dependency by hemodilution with a pasteurized plasma protein solution to a hematocrit of 14.3 +/- 1.1% (n = 24). Subsequently, an isovolemic exchange transfusion with human leukodepleted red blood cells, stored for 2-6 days (fresh, n = 8), 2-3 wks (intermediate, n = 8), or 5-6 wks (old, n = 8), was performed to determine whether intestinal muPo(2) would be preserved. Immunologic reactions were avoided by washing the red blood cell concentrates three times before use. Isovolemic exchange with fresh and intermediate red blood cells maintained muPo(2) whereas old cells decreased muPo(2) with 26%. Subsequent transfusion with red blood cells (hematocrit approximately 60%) until reaching a hematocrit of 32.4 +/- 2.1 % (n = 24) increased intestinal muPo(2) in all three groups to the same extent between 28% and 32%. No changes in red blood cell deformability, as determined by a Laser-assisted Optical Rotational Cell Analyzer, could be demonstrated during 5 wks of storage. CONCLUSION: This study shows that at low hematocrit, the oxygen-delivering capacity of human red blood cells stored 5-6 wks is reduced compared with fresh cells and red blood cells stored for an intermediate period. Although red blood cells stored for 2-3 wks are completely devoid of 2,3-diphosphoglycerate, their oxygen-delivering capacity to the intestines was the same as fresh red blood cells. Our study showed that red blood cell deformability was preserved during storage, suggesting that other mechanisms may account for the observed decrease in oxygen delivery by red blood cells stored 2-3 wks.     

Red blood cell transfusion compared with gelatin solution and no infusion after cardiac surgery: effect on microvascular perfusion,vascular density,hemoglobin, and oxygen saturation

BACKGROUND: After cardiac surgery, red blood cell (RBC) transfusion may improve systemic hemodynamics and thereby microvascular blood flow and O₂ delivery (DO₂). STUDY DESIGN AND METHODS: In a nonrandomized prospective observational study on post–cardiac surgery patients, systemic hemodynamics and microvascular blood flow, vascular density (sidestream dark‐field imaging), hemoglobin (Hb) content, and saturation (reflectance spectrophotometry) were measured before and 1 hour after start of transfusion of 1 to 2 units of leukoreduced RBCs (270 ± 203 mL), 500 mL of gelatin solution, or control (no infusion), when patients were considered clinically hypovolemic with (RBC group, n = 12) or without (gelatin group, n = 14) anemia (Hb < 10 g/dL) or not (n = 13), respectively. RESULTS: Systemic Hb was lower and increased in the RBC transfusion but not in gelatin and control groups. There were no differences in changes in systemic DO₂, O₂ uptake, and extraction between groups. RBC transfusion, compared with gelatin or control, increased medium‐sized vascular density, Hb content, and saturation in the microcirculation, while blood flow remained unchanged. Changes of microvascular Hb and saturation paralleled changes in systemic Hb. CONCLUSION: The data argue in favor of efficacy of RBC transfusion after cardiac surgery. RBC transfusion increases systemic Hb and this in turn increases medium‐sized vascular density and DO₂ in the sublingual microcirculation, independently of systemic hemodynamics and volume status.     

Advanced glycation end products on stored red blood cells increase endothelial reactive oxygen species generation through interaction with receptor for advanced glycation end products

BACKGROUND: Recent evidence suggests that storage‐induced alterations of the red blood cell (RBC) are associated with adverse consequences in susceptible hosts. As RBCs have been shown to form advanced glycation end products (AGEs) after increased oxidative stress and under pathologic conditions, we examined whether stored RBCs undergo modification with the specific AGE N‐(carboxymethyl)lysine (N^ε‐CML) during standard blood banking conditions. STUDY DESIGN AND METHODS: Purified, fresh RBCs from volunteers were compared to stored RBCs (35‐42 days old) obtained from the blood bank. N^ε‐CML formation was quantified using a competitive enzyme‐linked immunosorbent assay. The receptor for advanced glycation end products (RAGE) was detected in human pulmonary microvascular endothelial cells (HMVEC‐L) by real‐time polymerase chain reaction, Western blotting, and flow cytometry. Intracellular reactive oxygen species (ROS) generation was measured by the use of 5‐(and 6‐)chloromethyl‐2′,7′‐dichlorodihydrofluorescein diacetate, acetyl ester–based assays. RESULTS: Stored RBCs showed increased surface N^ε‐CML formation when compared with fresh RBCs. HMVEC‐L showed detectable surface RAGE expression constitutively. When compared to fresh RBCs, stored RBCs triggered increased intracellular ROS generation in both human umbilical vein endothelial cells and HMVEC‐L. RBC‐induced endothelial ROS generation was attenuated in the presence of soluble RAGE or RAGE blocking antibody. CONCLUSIONS: The formation of the AGE N^ε‐CML on the surface of stored RBCs is one functional consequence of the storage lesion. AGE‐RAGE interactions may be one mechanism by which transfused RBCs cause endothelial cell damage.     

Red blood cell use outside the operating theater: a prospective observational study with modeling of potential blood conservation during severe blood shortages

BACKGROUND: National guidance recommends planning for future blood shortages, but few studies have evaluated how reduced demand could be achieved acutely.
STUDY DESIGN AND METHODS: A trained observer collected data concerning red blood cell (RBC) transfusion events outside the operating theater during 68 hours of blood bank monitoring over 7 weeks. Data were gathered at the patients' bedside from clinical staff and charts. Transfusions were classified according to the presence of bleeding and medical specialty (medical, surgical, other). Hemoglobin (Hb) transfusion triggers, RBCs transfused, and posttransfusion Hb values were collected. Evidence-based scenarios were used to model the potential RBC savings that could be achieved if acute shortages occurred, incorporating ischemic heart disease as a potential decision modifier.
RESULTS: A total of 83 patients received 100 transfusion events, comprising 207 RBC units, during the sampling periods. The relative use of RBC units across specialties was as follows: medical, 74%; surgical, 22%; and other, 4%. For medical and surgical patients, respectively, 31 and 10% of all RBC units were transfused for anemia without evidence of bleeding, and 38 and 12% were transfused for non–life-threatening bleeding. Eight-five percent of all patients who received transfusions had stable vital signs before transfusion. Our model suggested that only 11% of RBCs would be conserved by cancellation of major surgery, whereas 23% to 47% of all RBCs could be conserved by controlling transfusions to medical patients.
CONCLUSION: In institutions with patterns of blood use similar to ours, control of transfusions to medical patients is the most effective response to acute blood shortages.     

Plasma expander and blood storage effects on capillary perfusion in transfusion after hemorrhage

BACKGROUND: Treating hemorrhage with blood transfusions in subjects previously hemodiluted with different colloidal plasma expanders, using fresh autologous blood or blood that has been stored for 2 weeks, allows identifying the interaction between type of plasma expander and differences in blood storage. STUDY DESIGN AND METHODS: Studies used the hamster window chamber model. Fresh autologous plasma, 130‐kDa starch‐based plasma expander (hydroxyethyl starch [HES]), or 4% polyethylene glycol–conjugated albumin (PEG‐Alb) was used for 20% of blood volume (BV) hemodilution. Hemodilution was followed by a 55% by BV 40‐minute hemorrhagic shock period, treated with transfusion of fresh or blood that was stored for 2 weeks. Outcome was evaluated 1 hour after blood transfusion in terms of microvascular and systemic variables. RESULTS: Results were principally dependent on the type of colloidal solution used during hemodilution, 4% PEG‐Alb yielding the best microvascular recovery evaluated in terms of the functional capillary density. This result was consistent whether fresh blood or stored blood was used in treating the subsequent shock period. Fresh blood results were significantly better in systemic and microvascular terms relative to stored blood. HES and fresh plasma hemodilution yielded less favorable results, a difference that was enhanced when fresh versus stored blood was compared in their efficacy of correcting the subsequent hemorrhage. CONCLUSION: The type of plasma expander used for hemodilution influences the short‐term outcome of subsequent volume resuscitation using blood transfusion, 4% PEG‐Alb providing the most favorable outcome by comparison to HES or fresh plasma.