Manufacture of red cells in additive solution from whole blood refrigerated for 5 days or remanufactured from red cells stored in plasma

Background and Objectives: To investigate methods for the production of red cell concentrates (RCC) in saline, adenine, glucose and mannitol (SAG‐M), from whole blood or red cells stored in plasma for 5 or 6 days and to provide evidence that exchange transfusion RCC in citrate phosphate dextrose (CPD) plasma or citrate, phosphate, dextrose, adenine (CPDA‐1) plasma are of comparable quality. Methods and Materials: Ten RCC in SAG‐M were produced following the remanufacture of red cells in CPD plasma on day 5/6 or after 5 days hold as leucodepleted CPD whole blood. In addition, 10 RCC in CPD plasma and 9 in CPDA‐1 plasma were stored without further processing. Units were assessed for red cell parameters including haemolysis, adenosine triphosphate (ATP), 2,3‐diphosphoglycerate (2,3‐DPG) and extracellular potassium. Results: Units in SAG‐M produced by remanufacture of RCC in plasma or by delayed manufacture of whole blood had comparable levels of haemolysis, ATP and 2,3‐DPG. Furthermore, these units underwent biochemical changes similar to reference SAG‐M units, with the exception of haemolysis which was greater at the end of shelf life and supernatant potassium which was lower following remanufacture. As expected, the decline in ATP was greater in red cells stored in CPD plasma compared with CPDA‐1 plasma. In general, units in CPD plasma were of similar quality at day 28 compared to those in CPDA‐1 plasma at day 35. Conclusions: RCC produced following the remanufacture of RCC in plasma or the delayed manufacture of whole blood are of acceptable in vitro quality and should be assigned the same shelf life as standard RCC in SAG‐M.     

RBC-derived vesicles during storage: ultrastructure, protein composition, oxidation, and signaling components

BACKGROUND: Red cells (RBCs) lose membrane in vivo, under certain conditions in vitro, and during the ex vivo storage of whole blood, by releasing vesicles. The vesiculation of the RBCs is a part of the storage lesion. The protein composition of the vesicles generated during storage of banked RBCs has not been studied in detail. STUDY DESIGN AND METHODS: Vesicles were isolated from the plasma of nonleukoreduced RBC units in citrate‐phosphate‐dextrose‐adenine, at eight time points of the storage period and shortly afterward. The degree of vesiculation, ultrastructure, oxidation status, and protein composition of the vesicles were evaluated by means of electron microscopy and immunoblotting. RBCs and ghost membranes were investigated as controls. RESULTS: The total protein content of the vesicle fraction and the size of the vesicles increased but their structural integrity decreased over time. The oxidation index of the vesicles released up to Day 21 of storage was greater than that of the membrane ghosts of the corresponding intact RBCs. The vesicles contain aggregated hemoglobin, band 3, and lipid raft proteins, including flotillins. They also contain Fas, FADD, procaspases 3 and 8, caspase 8 and caspase 3 cleavage products (after the 10th day), CD47 (after the 17th day), and immunoglobulin G. CONCLUSION: These data indicate that the vesicles released during storage of RBCs contain lipid raft proteins and oxidized or reactive signaling components commonly associated with the senescent RBCs. Vesiculation during storage of RBCs may enable the RBC to shed altered or harmful material.     

Automation of the glycerolization of red blood cells with the high-separation bowl in the Haemonetics ACP 215 instrument

BACKGROUND: The FDA has approved a closed-system red blood cell (RBC) glycerolization procedure with the ACP 215 (Haemonetics), which requires a centrifuge to prepare RBCs before and after glycerolization. In the study reported here, the Haemonetics high-separation bowl was evaluated in an attempt to automate these two concentration steps. STUDY DESIGN AND METHODS: Ten units of nonleukoreduced citrate phosphate dextrose (CPD)-anticoagulated whole blood were stored at 4 degrees C for 2 to 6 days before glycerolization and freezing as nonrejuvenated RBCs. Twenty-five units of nonleukoreduced CPD whole blood were stored at 4 degrees C for 2 to 8 days and then biochemically treated with a solution containing pyruvate, inosine, phosphate, and adenine (PIPA) before glycerolization and freezing as indated-rejuvenated RBC. Twenty units of leukoreduced CPD and AS-1 RBCs were stored at 4 degrees C for a mean of 48 days and treated with PIPA solution before glycerolization and freezing as outdated-rejuvenated RBCs. The glycerolized RBCs were frozen for at least 2 weeks at -80 degrees C, deglycerolized in the Haemonetics ACP 215 with the 325-mL bowl, and stored in AS-3 at 4 degrees C for 21 days. RESULTS: It took approximately 50 minutes to glycerolize the nonrejuvenated and rejuvenated RBCs. After freezing, deglycerolization, and postwash storage at 4 degrees C in AS-3 for 2 weeks, the quality was similar to that of RBCs processed by the current FDA-approved method. CONCLUSION: Processing time and need for technical expertise were significantly reduced with the completely automated functionally closed glycerolization procedure with the high-separation bowl in the Haemonetics ACP 215 instrument.     

Infusion of P-Capt prion-filtered red blood cell products demonstrate acceptable in vivo viability and no evidence of neoantigen formation

BACKGROUND: Transmission of variant Creutzfeldt‐Jacob disease (vCJD) is a major concern in blood transfusion. The P‐Capt filter has been shown to remove around 4 log ID₅₀ prion infectivity from prion‐spiked human red blood cells (RBCs). STUDY DESIGN AND METHODS: Two independent, single‐center, randomized, open‐label studies were designed to analyze the safety of P‐Capt–filtered RBCs. RBCs prepared from leukoreduced whole blood from 43 eligible subjects were randomly assigned to P‐Capt filtration and/or storage in plasma or SAGM and stored for 28 or 42 days. Stored RBCs were analyzed for in vivo 24‐hour recovery, hemolysis, metabolic variables, blood group antigen expression, neoantigen formation, and safety after autologous infusion. RESULTS: Mean P‐Capt filtration times for leukoreduced RBCs were 41 (SAGM) to 51 (plasma) minutes. Thirteen of 14 subjects receiving P‐Capt–filtered RBCs had 24‐hour RBC recoveries of 75% or more after 42‐day storage, with a mean hemolysis of less than 0.6%. No loss of RBC antigen expression or formation of neoantigens was observed. In both studies, RBCs had white blood cell counts of less than 1 × 10⁶/unit after leukofiltration. P‐Capt prion filtration provided an additional greater than 0.8 log leukoreduction. No serious or unexpected adverse events were observed after infusion of P‐Capt–filtered full‐volume RBC units. CONCLUSIONS: P‐Capt–filtered, stored RBCs demonstrated acceptable viability and no detectable neoantigen expression, immunogenic responses. or safety issues after infusion of a complete unit. The additional filtration time and modest reduction in RBC content are within acceptable levels for implementation in countries with transfusion transmission of vCJD.     

The 24-hour posttransfusion survival of baboon red blood cells preserved in citrate phosphate dextrose/ ADSOL (CPD/AS-1) for 49 days.

The purpose of this study was to evaluate the baboon as an animal model for evaluating red blood cell (RBC) preservation by comparing the 24-h posttransfusion survival of baboon RBCs preserved in citrate phosphate dextrose/ADSOL (CPD/AS-1) solution at 4 degrees C for 49 days to that of human RBCs preserved under similar conditions. CPD/AS-1 originally was approved by the Food and Drug Administration for 49-day storage of RBCs, but this period subsequently was reduced to 42 days. Adult male baboons (Papio anubis and P. cynocephalus) were autotransfused with RBCs that had been harvested using CPD and that had been resuspended and stored in AS-1 solution at 4 degrees C for as long as 49 days. The 24-h posttransfusion survival was measured using the 51Cr/125I-albumin method. The 24-h posttransfusion survival (mean +/- standard deviation) was 74% +/- 7% for seven units of CPD/AS-1-treated RBCs stored for 35 days, 65% +/- 15% for 12 units stored for 42 days, and 43% +/- 16% for seven units stored for 49 days. The mean 24-h posttransfusion survival rate for autologous baboon RBCs stored in CPD/AS-1 at 4 degrees C for 35 days (74%) was similar to that for autologous human RBCs stored in a similar manner. Further storage for 42 and 49 days resulted in lower values for baboon RBCs compared with human RBCs.     

The effects of long-term storage of human red blood cells on the glutathione synthesis rate and steady-state concentration

BACKGROUND: Banked red blood cells (RBCs) undergo changes that reduce their viability after transfusion. Dysfunction of the glutathione (GSH) antioxidant system may be implicated. We measured the rate of GSH synthesis in stored RBCs and applied a model of GSH metabolism to identify storage‐dependent changes that may affect GSH production. STUDY DESIGN AND METHODS: RBC units (n = 6) in saline‐adenine‐glucose‐mannitol (SAGM) solution were each divided into four transfusion bags and separate treatments were applied: 1) SAGM (control), 2) GSH precursor amino acids, 3) aminoguanidine, and 4) glyoxal. RBCs were sampled during 6 weeks of storage. Rejuvenated RBCs were also analyzed. RESULTS: After 6 weeks, the ATP concentration declined to 50 ± 5.5% (p < 0.05) of that in the fresh RBCs. For control RBCs, the GSH concentration decreased by 27 ± 6.5% (p < 0.05) and the rate of GSH synthesis by 45 ± 8% (p < 0.05). The rate of GSH synthesis in rejuvenated and amino acid–treated RBCs was unchanged after 6 weeks. Modeling identified that the decline in GSH synthesis was due to decreased intracellular substrate concentrations and reduced amino acid transport, secondary to decreased ATP concentration. CONCLUSION: This study has uniquely shown that the glutathione synthesis rate decreased significantly after 6 weeks in stored RBCs. Our results have identified potential opportunities for improvement of banked blood storage.     

Collection and storage of red blood cells with anticoagulant and additive solution with a physiologic pH

BACKGROUND: A donation of whole blood is most commonly collected in acidic citrate‐phosphate‐dextrose (CPD) variants with pH 5.2 to 6.2 as anticoagulants. Previously, we have shown that the initial pH after red blood cell (RBC) preparation can have an effect on RBCs during storage. First, we investigated the effect of the pH of the anticoagulant on RBCs. Second, we investigated the possibility of decreasing the pH of our new additive solution (AS) phosphate‐adenine‐glucose‐guanosine‐gluconate‐mannitol (PAGGGM) from pH 8.2 to 7.4 in combination with an anticoagulant with a physiologic pH. STUDY DESIGN AND METHODS: Whole blood was collected in CPD (pH 5.6) or trisodiumcitrate (TNC; pH 7.4), and leukoreduced units were prepared using saline‐adenine‐glucose‐mannitol as AS. Second, whole blood was collected in TNC (pH 7.4), and leukoreduced units were prepared using PAGGGM (pH 7.4) or PAGGGM (pH 8.2) as AS. During cold storage, several in vitro characteristics were analyzed. RESULTS: In agreement with our previous findings, the initial pH of whole blood has an effect during storage of RBCs. In the second part we show that there are no differences between PAGGGM (pH 7.4) and PAGGGM (pH 8.2) units when an anticoagulant with a physiologic pH was used. CONCLUSION: These results indicate that the pH of the anticoagulant used during whole blood collection has an effect during storage of RBCs. When an anticoagulant with a physiologic pH is used during whole blood collection, the pH of PAGGGM can be decreased to physiologic levels, while maintaining adenosine triphosphate and 2,3‐diphosphoglycerate levels.     

Immunosuppressive effects of red blood cells on monocytes are related to both storage time and storage solution

BACKGROUND: Reduced monocyte function is associated with adverse outcomes from critical illness. Red blood cells (RBCs) are thought to impair monocyte function but relationships between RBC storage solution and monocyte suppression are unknown. This study was designed to test the hypothesis that immunosuppressive effects of RBCs on monocytes are related to both storage time and preservative solution. STUDY DESIGN AND METHODS: Monocytes from healthy adult donors were co‐cultured with RBCs that had been stored in AS‐1, AS‐3, or CPD only for 7, 14, or 21 days. Cells were then stimulated with lipopolysaccharide (LPS) and their supernatants assayed for tumor necrosis factor (TNF)‐α and interleukin (IL)‐10. Transwell experiments were performed to evaluate the role of cell‐to‐cell contact. Monocyte mRNA expression was quantified by real‐time–polymerase chain reaction. RESULTS: LPS‐induced TNF‐α production capacity was reduced compared to controls for all groups, but CPD‐only RBCs suppressed monocyte function more than RBCs stored in AS‐1 (p = 0.007) and AS‐3 (p = 0.006). IL‐10 production was preserved or augmented in all groups. A longer storage time was associated with reduced TNF‐α production capacity for AS‐1 and AS‐3 groups but not CPD. Preventing cell‐to‐cell contact did not eliminate the inhibitory effect of RBCs on monocyte responsiveness. RBC exposure was associated with decreased LPS‐induced TNFA mRNA expression (p < 0.05 for all groups). CONCLUSIONS: CPD‐only RBCs suppressed monocyte function more than RBCs stored with additive solutions. TNF‐α production was reduced even in the absence of cell‐to‐cell contact and was impaired at the mRNA level. Further work is needed to understand the role of preservative solutions in this process.     

The effects of phosphate, pH, and AS volume on RBCs stored in saline-adenine-glucose-mannitol solutions

BACKGROUND: RBC ATP concentrations are the most important correlate of RBC viability. Tests were performed to determine whether increased AS volume, pH, and phosphate content increased stored RBC ATP concentrations. STUDY DESIGN AND METHODS: In three studies, packed RBCs were pooled in groups of 3 or 4 units and realiquoted as combined units to reduce intradonor differences. Pooled units were stored in the licensed ASs, AS-1 or AS-5, which contain saline, adenine, glucose, and mannitol (SAGM), or in experimental ASs (EASs) containing SAGM and disodium phosphate. Ten pools were stored in AS-1 at RBC concentrations equivalent to 100, 200, or 300 mL of AS. Six pools were stored in 100, 200, 300, or 400 mL volumes of EAS-61. Ten pools were stored in 100 mL of AS-5, 200 mL of EAS-61, or 300 mL of EAS-64. RBC ATP concentration and other measures of RBC metabolism and function were measured weekly. RESULTS: RBC ATP concentrations decreased sooner with storage in increasing volumes of AS-1. In EAS-61 and EAS-64, RBC ATP concentrations initially increased and stayed elevated longer with increasing AS volume. CONCLUSIONS: The addition of disodium phosphate to SAGM AS increases the RBC ATP concentrations. Reducing storage Hct appears to have a separate beneficial effect in reducing hemolysis.     

Red blood cell endothelial nitric oxide synthase does not modulate red blood cell storage hemolysis

BACKGROUND: The red blood cell (RBC) endothelial nitric oxide synthase (eNOS) has been shown to regulate intrinsic RBC rheologic properties, such as membrane deformability, suggesting that a functional eNOS could be important in RBC viability and function during storage. This study examines the correlation between RBC eNOS deficiency and the propensity of RBCs to hemolyze under selected stress conditions including prolonged hypothermic storage. STUDY DESIGN AND METHODS: Fresh or stored RBCs from normal and eNOS knockout (KO) mice or from healthy human volunteers were subjected to selected hemolytic stress conditions including mechanical stress hemolysis, osmotic stress hemolysis, and oxidation stress hemolysis and evaluated during standard storage in CPDA‐1 solutions. RESULTS: Fresh RBCs from normal and eNOS KO mice demonstrated comparable susceptibility to hemolysis triggered by mechanical stress (mechanical fragility index 6.5 ± 0.5 in eNOS KO vs. 6.4 ± 0.4 for controls; n = 8‐9), osmotic stress, and oxidative stress. Additionally, RBCs from both mouse groups exhibited similar hemolytic profile at the end of 14‐day hypothermic storage, analogous to 42 days of human RBC storage. Storage of human RBCs (28 days in CPDA‐1) in the presence of NOS cofactors (l ‐arginine and tetrahydro‐l ‐biopterin) or inhibitor (N⁵‐[imino(methylamino)methyl]‐l ‐ornithine monoacetate) did not affect cell recovery or hemolytic response to the selected stressors. CONCLUSION: These studies suggest that RBC eNOS does not modulate susceptibility to hemolysis in response to selected stress conditions or prolonged hypothermic storage. Other strategies to increase nitric oxide (NO) bioactivity after prolonged storage utilizing NOS‐independent pathways such as the nitrate–nitrite–NO pathway may prove a more promising approach.     

Transfusion of banked red blood cells and the effects on hemorrheology and microvascular hemodynamics in anemic hematology outpatients

BACKGROUND: The aim of this study was to investigate the effects of red blood cell (RBC) transfusion on the hemorrheologic properties and microcirculatory hemodynamics in anemic hematology outpatients receiving 2 to 4 RBC units of either “fresh” (leukoreduced storage for less than 1 week) or “aged” (leukoreduced storage for 3‐4 weeks) RBCs. STUDY DESIGN AND METHODS: Measurements were performed before and 30 minutes after RBC transfusion in hematology outpatients. Leukoreduced RBC suspensions were stored in saline‐adenine‐glucose‐mannitol (SAGM) additive solution. Whole blood viscosity was measured using Couette low‐shear viscometry, RBC deformability and aggregability were measured using laser‐assisted optical rotational cell analysis, and microcirculatory density and perfusion were assessed using sidestream dark field imaging. RESULTS: One group of patients (n = 10) received a median (interquartile range) of 3 (2‐3) RBC bags that were stored for 7 (5‐7) days (fresh) and the other group of patients (n = 10) received 3 (3‐3) RBC bags that were stored for 23 (22‐28) days (aged). After transfusion of fresh versus aged RBCs, hematocrit increased to 32 ± 3% versus 31 ± 2% (p < 0.363), whole blood viscosity increased to 4.2 ± 0.4 Pa/sec versus 4.2 ± 0.6 Pa/sec (p < 0.912), RBC deformability index remained unaffected, RBC aggregability index increased to 55 ± 10 versus 55 ± 13 (p = 0.967), microcirculatory flow remained unaffected, and microcirculatory density increased to 19.3 ± 2.5 mm/mm² versus 18.7 ± 1.9 mm/mm² (p = 0.595), respectively. CONCLUSION: Storing leukoreduced SAGM‐suspended RBCs for 3 to 4 weeks did not affect their ability to improve hemorrheologic properties and microcirculatory hemodynamics in our small group of anemic hematology outpatients. Larger studies are needed to confirm this finding.     

An improved red blood cell additive solution maintains 2,3‐diphosphoglycerate and adenosine triphosphate levels by an enhancing effect on phosphofructokinase activity during cold storage

BACKGROUND: Current additive solutions (ASs) for red blood cells (RBCs) do not maintain constant 2,3‐diphosphoglycerate (DPG) and adenosine triphosphate (ATP) levels during cold storage. We have previously shown that with a new AS called phosphate‐adenine‐glucose‐guanosine‐gluconate‐mannitol (PAGGGM), both 2,3‐DPG and ATP could be maintained throughout storage for 35 days. STUDY DESIGN AND METHODS: In this study, the mechanism underlying the effect of PAGGGM on RBC storage was studied in more detail. By using double‐erythrocytapheresis units (leukoreduced), a direct comparison could be made between the current AS saline‐adenine‐glucose‐mannitol (SAGM) and the experimental solution PAGGGM. During cold storage, several in vitro characteristics were analyzed. RESULTS: In agreement with our previous findings with single RBCs, PAGGGM maintained 2,3‐DPG and ATP levels for 35 days of cold storage. Furthermore, glucose consumption and lactate production were higher in PAGGGM units during the first 21 days of cold storage. Fructose‐1,6‐diphophate and dihydroxyacetone phosphate levels were also increased during the first 21 days of storage in PAGGGM units. CONCLUSION: These results indicate that it is likely that phosphofructokinase (PFK) activity is enhanced in PAGGGM units relative to SAGM units. After 21 days, PFK activity also decreases in PAGGGM units, but sufficient metabolic reserve in these units prevents depletion of 2,3‐DPG and ATP.     

Removal of white cells from red cells by transfusion through a new filter

The effectiveness of a new filter (RC100) for the preparation of white cell-depleted red cells (RBCs) at the bedside was evaluated in vitro and in vivo using three RBC products: standard RBC concentrate (CPDA units), RBCs suspended in saline-adenine-glucose-mannitol additive solution after the removal of plasma (SAGM units), and RBCs suspended in SAGM after the removal of plasma and buffy coat (SAGM-BC units). Median RBC recovery was at least 92 percent when 2 units were administered through one filter; median values for residual white cells and platelets were less than or equal to 20 × 10(6) and less than or equal to 2.5 × 10(9) per 2 units, respectively. The in vivo study was carried out in 80 multiply transfused patients with thalassemia, 35 of whom had experienced frequent nonhemolytic transfusion reactions when given standard or buffy coat-free RBCs. During the 6-month study, each patient was given two transfusions of each type of RBC product One febrile nonhemolytic transfusion reaction occurred in each of two patients receiving SAGM-BC units, but in no other case. If the flow rate is not reduced, the median transfusion time is 35 minutes per CPDA unit and 15 minutes per SAGM and SAGM-BC unit. It is concluded that the transfusion of RBCs through the RC100 is a simple and effective procedure to administer white cell-depleted RBCs prepared at the bedside.     

IMMUNOHEMATOLOGY: Storage of murine red blood cells enhances alloantibody responses to an erythroid‐specific model antigen

BACKGROUND: Red blood cell (RBC) alloimmunization can be a serious complication of blood transfusion, but factors influencing the development of alloantibodies are only partially understood. Within FDA‐approved time limits, RBCs are generally transfused without regard to length of storage. However, recent studies have raised concerns that RBCs stored for more than 14 days have altered biologic properties that may affect medical outcomes. To test the hypothesis that storage time alters RBC immunogenicity, we utilized a murine model of RBC storage and alloimmunization. STUDY DESIGN AND METHODS: Blood from transgenic HOD donor mice, which express a model antigen (hen egg lysozyme [HEL]) specifically on RBCs, was filter leukoreduced and stored for 14 days under conditions similar to those used for human RBCs. Fresh or 14‐day‐stored RBCs were transfused into wild‐type recipients. The stability of the HOD antigen and posttransfusion RBC survival were analyzed by flow cytometry. RBC alloimmunization was monitored by measuring circulating anti‐HEL immunoglobulin levels. RESULTS: Transfusion of 14‐day‐stored, leukoreduced HOD RBCs resulted in 10‐ to 100‐fold higher levels of anti‐HEL alloantibodies as detected by enzyme‐linked immunosorbent assay than transfusion of freshly collected, leukoreduced RBCs. RBC expression of the HOD antigen was stable during storage. CONCLUSIONS: These findings demonstrate that HOD murine RBCs become more immunogenic with storage and generate the rationale for clinical trials to test if the same phenomenon is observed in humans. Length of storage of RBCs may represent a previously unappreciated variable in whether or not a transfusion recipient becomes alloimmunized.     

Double red cell concentrates –in vitro quality after delayed refrigeration

Automated collection of red cell concentrates (RCC) presents a number of potential advantages to donors, blood services and recipients, and allows the collection of finished components from sites that are remote from a blood centre. However, data are lacking on how long the collected RCC may be stored at ambient temperature prior to their final storage at 4 °C. In this study, the Haemonetics Cymbal device was used to collect RCC using citrate, phosphate and dextrose (CPD‐50) anticoagulant. A total of 10 procedures each yielded two leucodepleted RCC in saline, adenine, glucose and mannitol (SAGM) additive solution. One of each pair of RCC was kept warm in an insulated transport bag for 8 h and the other for 6 h. In vitro assessments of the quality of the RCC were made during subsequent 42‐day storage of the RCC at 2–6 °C, and compared with reference data. All collected RCC were within UK and European limits for volume, haematocrit and haemoglobin content. Haemolysis was within specification at Day 42 and was no different in RCC held warm for 6 or 8 hours, but tended to be higher than reference data from whole blood derived RCC. ATP, 2,3 DPG and supernatant potassium levels were all similar in RCC held warm for 6 or 8 hours and reference data. We conclude that the Cymbal device may be used to collect two RCC in SAGM, and the in vitro assessment indicates that RCC may be stored without refrigeration for up to 8 h following collection, prior to final storage at 4 °C.     

Alkaline CPD and the preservation of RBC 2,3-DPG

BACKGROUND: Concentrations of 2,3-DPG decline rapidly in the first week of RBC storage because of the low pH of conventional storage solutions. Alkaline additive solutions, which can preserve RBCs for up to 11 weeks, still do not preserve 2,3-DPG because the starting pH is below 7.2. STUDY DESIGN AND METHODS: Alkaline CPD (pH=8.7) was made with trisodium citrate, dextrose, and disodium phosphate. Twelve units of whole blood were collected into heparin and pooled in groups of four units. Each pool was then aliquoted into four units; 63 mL of CPD with pH 5.7, 6.5, 7.5, or 8.7 was added to one unit of each pool, and 300 mL of the alkaline experimental additive solution-76 was added. In Study 2, 12 units were collected into alkaline CPD, pooled in groups of four, aliquoted as described, and stored in four variants of experimental additive solution-76 containing 0, 9, 18, and 27 mM of disodium phosphate. RBC ATP and 2,3-DPG concentrations, intracellular and extracellular pH and phosphate concentrations, hemolysis, and other measures of RBC metabolism and function were measured weekly. RESULTS: RBCs stored in more alkaline conditions made 2,3-DPG, but at the expense of ATP. Concentrations of 2,3-DPG decreased after 2 weeks storage, but ATP concentrations never fully recovered. Providing more phosphate both increased the duration of 2,3-DPG persistence and raised ATP concentrations in the later stages of storage. CONCLUSIONS: Maintaining both 2,3-DPG and ATP requires both high pH and high concentrations of phosphate.     

Altered processing of thawed red cells to improve the in vitro quality during postthaw storage at 4 degrees C

BACKGROUND: The use of a functionally closed system (ACP215, Haemonetics) for the glycerolization and deglycerolization of red blood cell (RBC) units allows for prolonged postthaw storage. In this study, the postthaw quality of previously frozen, deglycerolized RBCs resuspended in saline-adenine-glucose-mannitol (SAGM) or additive solution AS-3 was investigated. STUDY DESIGN AND METHODS: Leukoreduced RBC units were frozen with 40 percent glycerol and stored at -80 degrees C for at least 14 days. The thawed units were deglycerolized with the ACP215, resuspended in SAGM or AS-3, and stored at 2 to 6 degrees C for up to 21 days. RESULTS: The mean +/- standard deviation in vitro freeze-thaw-wash recovery was 81 +/- 5 percent. During storage, hemolysis of deglycerolized cells remained below 0.8 percent for 2 days in SAGM and for 14 days in AS-3. This difference was explained by the protective effect of citrate, which is present in AS-3. Cells stored in AS-3 showed a lower glycolytic activity and a faster decline in adenosine 5'-triphosphate (ATP) than cells in SAGM. Increasing the internal pH of cells before storage in AS-3 by use of phosphate-buffered saline (PBS) in the deglycerolization procedure resulted in elevated lactate production and better maintenance of intracellular ATP content. After 3 weeks of storage, the ATP content of PBS-washed cells amounted to 2.5 +/- 0.5 micromol per g of hemoglobin (Hb), whereas for saline/glucose-washed cells this value was decreased to 1.0 +/- 0.3 micromol per g of Hb. CONCLUSIONS: Leukoreduced, deglycerolized RBCs can be stored for 48 hours in SAGM. Improved ATP levels during refrigerated storage can be observed with thawed cells, resuspended in AS-3, when PBS is used as a washing solution.     

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.     

Refrigerated storage of lyophilized and rehydrated, lyophilized human red cells

Human red cells (RBCs) were collected in CPDA-1 and then freeze-dried in lyoprotective solution. The lyophilized RBCs were then stored at -20 degrees C for 7 days. At the end of the storage period, the lyophilized RBCs were rehydrated and washed in dextrose saline. The washed, reconstituted, lyophilized RBCs were resuspended in final wash solutions of ADSOL, CPDA-1, or a special additive solution containing glucose, citrate, phosphate, adenine, and mannitol, and then they were stored at 4 degrees C for an additional 7 days. The main purpose of this study was to determine whether human RBCs can be lyophilized in such a manner that normal metabolic, rheologic, and cellular properties are maintained during rehydration and subsequent storage in standard blood bank preservative solutions. Our results show that reconstituted, lyophilized RBCs maintained levels of ATP, 2,3 DPG, lactate, and cellular properties that are equal to or better than those in control nonlyophilized RBCs stored for a comparable period in CPDA-1. Reconstituted, lyophilized RBCs stored at 4 degrees C after rehydration also show better maintenance of ATP, 2,3 DPG, and lactate than do control RBCs stored in the same preservative solutions for comparable periods.     

Red blood cell storage and cell morphology

Aim: In this study, we performed weekly assessment of morphology‐related parameters through monitoring of CPD‐SAGM leuco‐filtered erythrocyte concentrates from blood withdrawal until the 42nd day of storage. Background: Liquid storage of red blood cells (RBCs) delivers a blood‐derived therapeutic, which is safe, available, effective and affordable for most patients who need transfusion therapy in developed countries. However, a growing body of accumulating controversial evidences, from either biochemical or retrospective clinical studies, prompted safety concerns about longer stored RBCs. Methods: Statistical image analysis through scanning electron microscope was coupled to osmotic fragility and erythrocyte sedimentation rate. Results: We could observe that by day 21 more than 50% of RBCs displayed non‐discocyte phenotypes. This observation was related to an increase in osmotic fragility, which was totally overlapped in day 0 controls and day 7 RBCs while only slightly augmented in day 14 samples. Cation dysregulation (pH internal/external alteration and potassium) might both reflect and trigger a negative feedback loop with metabolic fluxes and membrane cation pumps. Conclusion: Morphology parameters suggest that significant alterations to RBC morphology over storage duration occur soon after the 14th day of storage, as to become significant enough within the 21st day.