Twelve-week RBC storage

BACKGROUND: Better storage can improve RBC availability and safety. Optimizing RBC ATP production and minimizing hemolysis has allowed progressively longer storage. STUDY DESIGN AND METHODS: In the first study, 24 units of packed CPD RBCs were pooled in groups of four, realiquoted, and added to 300 mL of one of four variants of experimental additive solution 76 (EAS-76) containing 45, 40, 35, or 30 mEq per L NaCl. Units were sampled weekly for 12 weeks for morphologic and biochemical measures. In the second study, 10 volunteers donated 2 units of RBCs for a crossover comparison of Tc/Cr 24-hour in vivo recovery of 6-week storage in AS-1 versus 12-week storage in EAS-76 variant 6 (EAS-76v6) having 30 mEq per L NaCl. RESULTS: RBCs stored in the lower salt variants of EAS-76 had higher concentrations of RBC ATP with less hemolysis and microvesiculation. RBC 2,3 DPG was preserved for two weeks. RBCs stored for 12 weeks in EAS-76v6 exhibited 78 +/- 4 percent 24-hour in vivo recovery. CONCLUSIONS: It is possible to store RBCs for 12 weeks with acceptable recovery and 0.6 percent hemolysis and with normal 2,3 DPG concentrations for 2 weeks.     

Prolonged maintenance of 2,3-diphosphoglycerate acid and adenosine triphosphate in red blood cells during storage

BACKGROUND: Current additive solutions (ASs) for red cells (RBCs) do not maintain a constant level of critical metabolites such as adenosine triphosphate (ATP) and 2,3-diphosphoglycerate acid (2,3-DPG) during cold storage. From the literature it is known that the intracellular pH is an important determinant of RBC metabolism. Therefore, a new, alkaline, AS was developed with the aim to allow cold storage of RBCs with stable product characteristics. STUDY DESIGN AND METHODS: Whole blood-derived RBCs (leukoreduced) were resuspended in experimental medium phosphate-adenine-guanosine-glucose-gluconate-mannitol (PAGGG-M; pH 8.2) with and without washing in the same medium. During cold storage several in vitro variables, such as intracellular pH, 2,3-DPG, ATP, and hemolysis, were analyzed. RESULTS: During cold storage, RBCs resuspended in PAGGG-M showed a constant ATP level (approx. 6 mumol/g Hb) and a very limited hemolysis (<0.2%). The 2,3-DPG content showed an increase until Day 21 (150% of initial level), followed by a slow decrease, with at Day 35 still 100 percent of the initial level. RBCs washed in PAGGG-M even showed a continuous increase of 2,3-DPG during 35 days, with a maximum level of 200 percent of the initial value. The effect of PAGGG-M appears to be related to long-lasting effects of the initial intracellular pH shortly after production. CONCLUSION: Resuspension of RBCs in our alkaline medium PAGGG-M resulted in a RBC unit of high quality during storage for up to at least 35 days, with 2,3-DPG levels of higher than 10 mumol per g Hb, hemolysis of less than 0.2 percent, and ATP levels of higher than 5 mumol per g Hb.     

The effects of additive solution pH and metabolic rejuvenation on anaerobic storage of red cells

BACKGROUND: Red cell (RBC) storage can be extended to 9 weeks under anaerobic or alkaline conditions. Simultaneous use of these approaches has not provided additive benefit. Our objective was to determine whether anaerobic storage with acidified additive solution (AS) coupled with metabolic rejuvenation might further improve the benefits of anaerobic storage. STUDY DESIGN AND METHODS: RBC storage in AS with a pH value of 6.5, 7.4, or 8.3 in aerobic or anaerobic conditions was examined using a panel of in vitro biochemical and RBC markers. RBC rejuvenation during cold storage was also evaluated. A randomized crossover radiolabeled recovery study (eight subjects) evaluated anaerobic RBC storage using AS65 with cold rejuvenation for up to 16 weeks of storage. RESULTS: Adenosine triphosphate (ATP) and diphosphoglycerate acid (DPG) were better maintained in anaerobic storage than in aerobic storage. Acidic or neutral AS preserved ATP concentration better, while a neutral or basic pH AS favored maintenance of DPG levels at higher levels for a longer period. AS pH had less of an effect on exposure of phosphatidylserine (PS), vesicle protein release, and hemolysis. Rejuvenation of RBCs during cold, anaerobic storage resulted in increases in ATP and DPG levels and a reversal of PS exposure. Anaerobic storage of RBCs in pH 6.5 AS rejuvenated at 7 weeks of storage yielded RBC 24‐hour recoveries of 77.3 ± 12.5 percent after 10 weeks' storage time. After a second rejuvenation at Week 11, six subjects' units demonstrated a recovery of 75.9 ± 7.3 percent at 12 weeks of storage. CONCLUSION: Extended RBC storage may be achieved using anaerobic conditions combined with low‐pH AS and rejuvenation during storage.     

Rejuvenation capacity of red blood cells in additive solutions over long-term storage

BACKGROUND: Red blood cells (RBCs) are Food and Drug Administration (FDA)‐approved for 42‐day storage with the use of additive solutions (ASs). However, adenosine triphosphate (ATP) and 2,3‐diphosphoglycerate (2,3‐DPG) levels in the RBCs decline over this time. These constituents may be restored by treatment with rejuvenation (REJ) solutions. This study was done to assess the response capability of RBCs from 30 to 120 days of storage in three FDA‐licensed RBC storage solutions after incubation with a rejuvenating solution of pyruvate, inosine, phosphate, and adenine. STUDY DESIGN AND METHODS: Three units each of RBCs in approved AS (AS‐1 [Adsol, Fenwal, Inc.], AS‐3 [Nutricel, Medsep Corp.], and AS‐5 [Optisol, Terumo Corp.]) were stored under standard conditions at 1 to 6°C for up to 120 days. Aliquots (4 mL) on Days 30, 42, 60, 80, 100, and 120 (±2 days) were REJ by incubating with Rejuvesol (Encyte Corp.). Control untreated and REJ aliquots were extracted using perchloric acid and stored at ?80°C until assayed for 2,3‐DPG and ATP. RESULTS: RBCs responded to REJ by increasing DPG and ATP contents. The response declined linearly at 0.070 ± 0.008 µmol DPG/g hemoglobin (Hb)/day and 0.035 ± 0.004 µmol ATP/g Hb/day with no differences between ASs. CONCLUSION: We conclude that Rejuvesol is able to restore ATP and 2,3‐DPG levels in RBCs stored up to 120 days in AS. The response diminishes as storage time increases. This rejuvenation (REJ) capability does not seem useful for routine assessment of RBC anabolic capacity in research programs, but may be useful to the investigator when studying unique and novel treatment methods.     

Evaluation of a concurrent multicomponent collection system for the collection and storage of WBC-reduced RBC apheresis concentrates

BACKGROUND: Multicomponent apheresis procedures offer the possibility of collecting blood components that are standardized, as compared to those available with whole-blood donations. A new separator program for the concurrent collection of RBCs, platelets, and plasma (Amicus, Baxter Healthcare) was evaluated. STUDY DESIGN AND METHODS: Apheresis donors (n = 47) underwent concurrent collection of RBCs, platelets, and plasma by use of the single-needle procedure of the Amicus blood cell separator. A standardized RBC volume (100% Hct) of 200 mL was targeted with either 1 or 2 platelet concentrate units, depending on the donor's predonation characteristics. After collection, the RBC component was sterilely connected to an RBC collection set (Amicus) to allow for the addition of 100 mL of saline-adenine-glucose-mannitol preservative solution and WBC reduction at either ambient temperature or 4 degrees C. The RBC units were subsequently stored at 2 to 6 degrees C for 42 days, and the following in vitro measures were evaluated over the storage period: blood cell counts including Hct and total Hb, plasma Hb, potassium, pH, ATP, and 2,3 DPG. RESULTS: Procedure time averaged 74 +/- 9 minutes, and no adverse events were reported. The absolute RBC volume collected averaged 198 +/- 11 mL with an average Hct value of 83 +/- 2 percent. After filtration, the Hb content averaged 58.2 +/- 2.4 g per unit and residual WBCs averaged 0.038 +/- 0.015 x 10(6) per unit. Day 42 results showed that all units had on average more than 70-percent ATP maintenance, and all of the units had less than 0.8 percent he-molysis. All units had pH values higher than 6.5 on Day 42. CONCLUSION: The concurrent multicomponent collection system (Amicus) can reliably collect a standardized RBC unit of good quality. In vitro testing of the RBCs collected and stored for 42 days met the Council of Europe criteria for transfusion.     

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.     

Viability and in vitro properties of AS-1 red cells after gamma irradiation

BACKGROUND: Irradiation has been shown to adversely affect both in vivo 24-hour recovery (recovery [%]) and in vitro properties of stored red cells (RBCs). There is uncertainty as to how these changes are related to the day of irradiation and the length of storage after irradiation. STUDY DESIGN AND METHODS: Four protocols used day of irradiation and storage time after irradiation as the independent variables. At the conclusion of the storage period, viability was measured with radiolabeled RBCs as the recovery and the long-term survival time for RBCs that were circulating beyond 24 hours. In addition, in vitro values including RBC ATP, hemolysis level, and supernatant potassium were measured. Each subject donated 2 units of whole blood (CPD) and received autologous irradiated and untreated control RBCs (AS-1) on two separate occasions. RESULTS: Reduced recovery in irradiated units was noted when compared to that in control units, and the reduction was most apparent with long periods of storage after irradiation, irrespective of the day of irradiation. With irradiation on Day 1 of storage and a total storage period of 28 days, mean +/- SD recovery (single label) was 84.2 +/- 5.1 percent for control RBCs and 78.6 +/- 5.9 percent for irradiated RBCs (n = 16; p<0.01). With irradiation on Day 14 and storage through Day 42, the recoveries were 76.3 +/- 7.0 percent for control RBCs and 69.5 +/- 8.6 percent for irradiated RBCs (n = 16; p<0.01). Less reduction in recovery was observed with shortening of the postirradiation storage time. When the total storage period was reduced to 28 days after Day 14 irradiation, the recoveries were not significantly different. With an additional 2-day storage period after irradiation on Day 26, the recoveries were also comparable. Long-term survival times for control and irradiated RBCs were not significantly different in any of the four protocols. RBC ATP levels and hemolysis were minimally, but significantly influenced by irradiation. Supernatant potassium levels, however, were substantially increased after irradiation in each of the four protocols. CONCLUSION: Irradiation has only a small effect on the properties of RBCs treated and stored according to the utilized protocols. Longer storage times after irradiation resulted in progressively reduced recovery while long-term survival remained unaffected.     

Serial oxygen equilibrium and kinetic measurements during RBC storage

Objectives: To contribute to the understanding of the biochemical changes associated with the RBC storage lesion. Aim: To investigate changes in O₂ equilibrium and on/off kinetic rates during routine cold storage. Background: As RBCs are stored between 1 and 6°C numerous biochemical changes occur within the RBCs, including changes in the properties of the haemoglobin itself. This study serially analysed for the first time the O₂ equilibrium and on/off kinetic rates across the RBC membrane during routine storage. Methods/Materials: The oxygen binding (k_on) and offloading (k_off) constants were measured in fresh RBCs and then in AS‐5‐preserved RBCs at weekly intervals, along with oxygen equilibrium curves (OECs), 2,3‐Diphosphoglycerate (2,3‐DPG), p50 and the Hill number (n). Results: The k_on increased slightly as the 2,3‐DPG and p50 decreased during storage, whereas the k_off remained largely unchanged. The OECs demonstrated the expected increase in O₂ affinity, whereas the Hill number was unchanged during storage. Conclusion: In spite of the biochemical, structural and functional changes associated with the storage of RBCs, their in vitro interactions with oxygen were largely preserved through 42 days of storage.     

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.     

A comparison of biochemical and functional alterations of rat and human erythrocytes stored in CPDA-1 for 29 days: implications for animal models of transfusion

Animal models of transfusion are employed in many research areas yet little is known about the storage-related changes occurring in the blood used in these studies. This study assessed storage-related changes in red blood cell (RBC) biochemistry, function and membrane deformability in rat and human packed RBCs when stored in CPDA-1 at 4 degrees C over a 4-week period. Human blood from five volunteers and five bags of rat RBC concentrates (five donor rats per bag) were collected and stored at 4 degrees C. RBC function was assessed by post-transfusion viability and the ability to regenerate adenosine triphosphate (ATP) and 2,3-diphosphoglycerate (DPG) when treated with a rejuvenation solution. Membrane deformability was determined by a micropipette aspiration technique. ATP in rat RBCs declined more rapidly than human RBCs; after 1 week rat ATP fell to the same level as human cells after 4 weeks of storage (rat, 2.2 +/- 0.2 micromol g(-1) Hb; human, 2.5 +/- 0.3 micromol g(-1) Hb). Baseline DPG concentrations were similar in rat and human RBCs (16.2 +/- 2.3 micromol g(-1) Hb and 13.7 +/- 2.4 micromol g(-1) Hb) and declined very rapidly in both species. Human RBCs fully regenerated ATP and DPG when treated with a rejuvenation solution after 4 weeks of storage. Rat RBCs regenerated ATP but not DPG. Post-transfusion viability in rat cells was 79%, 26% and 5% after 1, 2 and 4 weeks of storage, respectively. In rats, decreased membrane deformability became significant (- 54%) after 7 days. Human RBC deformability decreased significantly by 34% after 4 weeks of storage. The rejuvenation solution restored RBC deformability to control levels in both species. Our results indicate that rat RBCs stored for 1 week in CPDA-1 develop a storage lesion similar to that of human RBCs stored for 4 weeks and underscores significant species-specific differences in the structure and metabolism of these cells.     

Automated blood component collection with the MCS 3p cell separator: evaluation of three protocols for buffy coat-poor and white cell- reduced packed red cells and plasma

BACKGROUND: Automated collection of blood components with a cell separator (MCS 3p, Haemonetics), was performed according to three protocols. STUDY DESIGN AND METHODS: The first protocol provided 2 units of fresh-frozen plasma (FFP); and one buffy coat-poor red cell (RBC) concentrate in additive solution. The second protocol included an additional in-line filtration of the RBC in a closed system after storage at 4 degrees C for 24 hours. In the third protocol, an additional platelet concentrate (PC) was recovered from the buffy coat. Cell counts and biochemical characterization of the RBCs (n=20 each) were determined on Days 0, 1, 14, 28, and 49. RESULTS: The RBC volume was 336 +/? 9 mL (first protocol), 337 +/? 7 mL (second protocol) and 293 +/? 12 mL (third protocol) with a hematocrit of 59 +/? 2, 53 +/? 3, and 61 +/? 5, percent respectively. On Day 49, hemolysis was 0.24 +/? 0.1 percent (first protocol), 0.33 +/? 0.32 percent (second protocol), and 0.38 +/? 0.1 percent (third protocol). The filtered RBC concentrate met the international standards for white cell-reduced RBCs. Filtration resulted in a clinically irrelevant increase of hemolysis. The in vitro RBC values (lactate dehydrogenase, 2-hydroxybutyrate dehydrogenase, hemolysis, potassium, 2,3 DPG, ATP) were at least equal to those in RBCs collected by conventional whole-blood donation. There is a trend toward extended preservation of 2,3 DPG in RBCs collected by apheresis. Two units of FFP could be collected with each donation (first protocol: 420 +/? 55 mL, 5.4 +/? 7 WBCs/microL, 6.5 +/? 5 × 10(3) platelets/microL; second protocol: 440 +/? 33 mL, 3 +/? 5.2 WBCs/microL, 32 +/? 12 × 10(3) platelets/microL; third protocol: 398 +/? 32 mL, 5 +/? 12 WBCs/microL; 3.4 +/? 3.5 × 10(3) platelets/microL). PCs prepared from the buffy coat collected by the third protocol contained 90 +/? 30 × 10(9) platelets in 88 +/? 14 mL of plasma. In vitro test results in these PCs were superior to those in PCs collected by conventional whole-blood donation. The procedure was well tolerated by all donors. No adverse reactions appeared. CONCLUSION: Erythroplasmapheresis with the MCS 3p cell separator is a useful alternative to conventional whole-blood donation and separation.     

Blood bank conditions and RBCs: the progressive loss of metabolic modulation

BACKGROUND: Human RBC metabolism is modulated by the cell oxygenation state. Among other mechanisms, competition of deoxyhemoglobin and some glycolytic enzymes for the cytoplasmic domain of band 3 is probably involved in modulation. This metabolic modulation is connected to variations in intracellular NADPH and ATP levels as a function of the oxygenation state of the cell, and, consequently, it should have physiologic relevance. The present study investigates the effect of storage on this metabolic modulation and its relationship with the alteration of membrane protein composition. STUDY DESIGN AND METHODS: RBCs stored in CPD-saline-adenine-glucose-mannitol were assayed for glucose uptake and partition between glycolysis and the pentose phosphate pathway at high and low oxygen saturation by nuclear magnetic resonance spectroscopy after 1, 14, 21, 35, and 42 days of storage. Membrane protein composition was determined by SDS-PAGE on Days 1, 14, 35, and 42. Metabolic values and 2,3 DPG concentration were also measured after rejuvenation for 1 hour at 37 degrees C with pyruvate-inosine-phosphate-adenine solution on Day 21. RESULTS: Metabolic differences between RBCs incubated at high and low oxygen saturation decreased during storage, and, on Day 35, the two groups did not have significant differences (p = 0.111). SDS-PAGE showed that membrane protein composition was concurrently modified. The percentage of unmodified band 3 decreased during storage, principally between Days 14 and 35. In rejuvenated RBCs, oxygen-dependent modulation was not restored. CONCLUSIONS: RBCs stored in CPD-saline-adenine-glucose-mannitol do show a progressive loss of oxygen-dependent metabolic modulation, which is not restored after rejuvenation and which seems partly related to modifications in membrane proteins, mainly band 3.     

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.     

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.     

Elevated red blood cell 2,3-diphosphoglycerate levels in black blood donors

Mean levels of 2,3-diphosphoglycerate (DPG) were significantly increased in erythrocytes (RBC) from 43 nonanemic black blood donors (4.80 +/- 0.06 micromoles/l RBC) compared with 22 white donors 4.47 +/- 0.08 micromoles/l RBCs from eight of the 12 black donors with DPG levels greater than 5 micromoles/l RBC. Although a potentially hemolytic disorder could be defined in four (AS hemoglobin, beta-Thalassemia minor, G6PD deficiency), reticulocyte counts were normal. However, when RBCs from the subgroup were compared to RBCs from an additional 25 unselected white donors, the following suggested an abnormally large population of young RBCs in the subgroup: 1) normal or elevated RBC-ATP with normal serum phosphate level; 2) significantly increased activities of RBC age-dependent enzymes hexokinase (p less than 0.02), pyruvate kinase (p less than 0.05), and glutamicoxaloacetic transaminase (p less than 0.01), with normal activity of phosphoglycerate kinase, an age-independent enzyme; 3) decreased dense (older) RBCs as determined by sedimentation in phthalate esters. Since DPG is increased in young RBCs and falls as the RBC ages, loss of older relatively DPG depleted RBCs due to shortened survival could account for the elevated DPG levels seen in the subgroup.     

Hemoglobin Function and 2,3‐DPG Levels of Blood Stored at 4 C in ACD and CPD pH Effect

Normal hemoglobin function depends on adequate erythrocyte levels of 2,3‐diphosphoglycerate (2,3‐DPG), a compound which is poorly maintained in acid‐citrate‐dextrose (ACD). Since 2,3‐DPG is better maintained in citrate‐phosphate‐dextrose (CPD) and this preservative has a higher pH (5.5) than ACD (pH = 5.0), these preservatives were prepared at each pH and studied. The CPD preservatives (pH 5.0, 5.5) had similar amounts of phosphate so the differences between them, obtained by altering the buffer ratio, should relate to pH. The ACD solutions (pH 5.0, 5.5) contained no phosphate. Hemoglobin function, expressed as P₅₀ (the Po₂ at 50 per cent oxygenation, an inverse but direct measure of oxygen affinity), and 2,3‐DPG were better maintained in ACD and CPD of pH 5.5. The lower pH (5.0) preservatives, whether ACD or CPD, showed rapidly declining hemoglobin function and 2,3‐DPG levels. The values at the higher pH remained close to normal for two weeks and above those of the lower pH preservatives for most of the four‐week storage period.     

Storage of saline-adenine-glucose-mannitol-suspended red cells in a new plastic container: polyvinylchloride plasticized with butyryl-n- trihexyl-citrate

Blood collection and component preparation have been performed in integrally connected multiple plastic containers made with a new plastic. This polyvinylchloride (PVC) container plasticized with butyryl-n-trihexyl-citrate (BTHC) is a new material for blood storage; it contains no di(2-ethylhexyl)phthalate (DEHP). After removal of plasma and buffy coat, the red cells were suspended in saline-adenine-glucose-mannitol (SAGM) medium. After 42-day refrigerator storage, the total adenine nucleotide concentration remained the same as the initial concentration in the red cells, whereas ATP levels had decreased to 61 percent of the initial value. The 2,3 DPG concentration was 62 percent of normal on Day 7 and 21 percent on Day 14. Glucose consumption, lactate production, potassium leakage from red cells, and pH levels were similar to those found after storage in DEHP-plasticized containers under the same conditions. After 42 days, hemolysis levels were 0.56 +/- 0.21 percent and 0.42 +/- 0.17 percent in two series of units mixed weekly and 0.70 +/- 0.27 percent in units stored unmixed. Although even higher levels of hemolysis were observed in the units stored unmixed and used for 24-hour posttransfusion survival, the autologous red cell recovery results were excellent (83.2 +/- 5.1%, n = 8). BTHC-plasticized PVC is found to be a suitable material for 42-day storage of red cells in SAGM solution.     

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.     

Preservation of Red Blood Cell 2,3‐Diphosphoglycerate in Stored Blood Containing Dihydroxyacetone

In a search for red blood cell metabolites which would preserve 2,3‐DPG during storage of blood, it was discovered that dihydroxyacetone (DHA) prolonged the maintenance of 2,3‐DPG levels for up to four weeks of storage, compared to about one week for presently used preservatives such as CPD. Four‐week preservation of 2,3‐DPG at normal levels was desired. CPD‐adenine was used as the starting point and a formulation having a pH of 7.0 and a DHA concentration of 20 millimoles per liter of blood was developed. The 2,3‐DPG level at four weeks of storage was proportional to DHA concentration in the 5 to 20 mM range. The osmotic fragility, red blood cell ATP levels, and plasma sodium, potassium, and hemoglobin during four weeks of storage in CPD‐adenine‐DHA were similar to those in blood stored in CPD‐adenine.     

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.