Blood preservation 33. Phosphate enhancement of ribose maintenance of 2,3-DPG and ATP

Blood storage in CPD-adenine supplemented with 25 mM inosine and 10 mM phosphate gave 2,3-DPG levels as high as 140 per cent of normal for six weeks of blood storage at 4 C. Lower but normal 2,3-DPG levels were maintained throughout six weeks with inosine or inosine plus ribose. Ribose alone provided marginally increased DPG maintenance over the control, but ribose with phosphate maintained 2,3-DPG levels above 70 per cent of normal for five weeks of storage and two weeks longer than the control preservative. ATP levels were maintained at normal or above for six weeks with phosphate plus ribose or inosine. 2,3-DPG maintenance has previously been shown to be impaired by phosphate, unless inosine is also present. The ribose and inosine effects on 2,3-DPG maintenance are not additive. Phosphate also has an enhancement effect on ATP maintenance in the presence of either ribose or inosine.     

Blood preservation. XXVIII. Galactose and maltose maintain red blood cell 2,3-DPG and ATP

Because there may be inadequate dextrose in the newly licensed CPD- adenine for five or six weeks storage of high hematocrit red blood cells, this laboratory has examined some alternate sugars for their ability to maintain red blood cell metabolism during storage. In the current study, dextrose and fructose were studied as model or prototype nutrients. A third six carbon monosacharide, galactose, three dissacharides, lactose, maltose, and sucrose were studied in the same experiment. Of these, fructose best maintained ATP and 2,3-DPG during the fourth to sixth week of whole blood storage at 4 C. Dextrose was next best during this time and was nearly equivalent to fructose in the first three weeks of storage. Galactose and maltose both maintained ATP and 2,3-DPG, but not nearly so well as did fructose and dextrose. Sucrose and lactose were associated with the most rapid deterioration of ATP and DPG levels and they failed to maintain the progressive fall in pH which is usually associated with continuing, useful metabolism.     

Blood storage XXIV: red blood cell 2,3-DPG and ATP maintenance for six weeks in CPD-adenine with higher phosphate, pyruvate, and dihydroxyacetone

The individual and collective effects of various phosphate, pyruvate and dihydroxyacetone concentrations on 2,3-DPG and ATP maintenance during blood storage with CPD-adenine (0.25 mM), were studied. Phosphate concentrations ranged from 2 to 100 mM. Low concentations were best for 2,3-DPG maintenance during the first three weeks, after which there was no difference. ATP concentrations were better maintained by the highest phosphate concentrations in the first week. After the second week the lower concentrations of phosphate were better. With pyruvate 40 and 60 mM were the best for 2,3-DPG levels through six weeks of storage. ATP concentrations were poorest with high pyruvate. Maintenance of 2,3-DPG was above half normal for six weeks of storage in the 60, 80 and 100 mM DHA preservatives. ATP concentrations were best maintained in the preservative lacking DHA. Combinations of phosphate, pyruvate and DHA in concentrations which had been found to be effective when used individually were studied. Best maintenance of 2,3-DPG (above half normal levels) for six weeks was afforded by pyruvate, phosphate and DHA, and by pyruvate and DHA. ATP maintenance was best afforded by CPD-adenine alone and CPD-adenine with pyruvate and phosphate. Pyruvate alone maintained ATP less well and the pyruvate- DHA was worst. Intermediate in maintenance of ATP was the preservative containing pyruvate, phosphate and DHA.     

Blood storage XXII. Improvement in red blood cell 2,3-DPG levels at six weeks by 20 mM PO4 in CPD-adenine-inosine

Inorganic phosphate has been known to assist red blood cell maintenance of ATP and in the presence of inosine to assist in the maintenance of 2,3-DPG. High concentrations of phosphate, while helping ATP maintenance, were found to be deleterious to 2,3-DPG maintenance in CPD- adenine preservatives. However, in the presence of inosine, concentrations of phosphate as high as 10 mM were advantageous to 2,3- DPG maintenance. The present study extends the observations on ATP and 2,3-DPG maintenance in CPD-adenine-inosine preservatives from the previous 10 mM to 20 mM phosphate. A high phosphate (20 mM) effect has been seen as improved maintenance of 2,3-DPG levels during the fifth and sixth weeks of storage of whole blood at 4C. This supports the previously reported observation of improved maintenance of 2,3-DPG in a 10 mM phosphate preservative. This is ten times the 2 mM phosphate concentration in CPD-adenine. In the low phosphate preservative (2 mM), 2,3-DPG maintenance is less than that in all of the higher phosphate preservatives after the second week of storage. ATP concentrations in this experiment show good maintenance throughout six weeks of storage.     

Depletion and Regeneration of 2,3-diphosphoglyceric Acid in Stored Red Blood Cells

2,3-diphosphoglyceric acid appears to be an important regulator of the oxygen dissociation curve of hemoglobin in intact red blood cells. The rate of loss of 2,3-DPG under various storage conditions therefore was investigated. 2,3-DPG disappeared rapidly from conventional preservative media, CPD, and ACD solutions. After only two weeks' storage, 65 per cent to 85 per cent of erythrocyte 2,3-DPG had been lost from ACD-stored blood and slightly less from CPD-stored blood. Although the addition of adenine to ACD solution aided in the maintenance of ATP levels, it hastened the rate of loss of 2,3-DPG. The rate of 2,3-DPG depletion was strongly dependent on pH. In more alkaline storage media, levels of this compound were relatively well maintained for as long as two, or even three weeks. However, under these circumstances ATP maintenance was less satisfactory. The levels of 2,3-DPG and ATP in red blood cells incubated in fresh plasma at 37 C, pH 7.4, to simulate the conditions after reinfusion of stored cells also was investigated. ATP levels remained relatively stable under these circumstances and 2,3-DPG levels were restored gradually. However, the repletion of 2,3-DPG was sufficiently slow so that even after eight hours only approximately one third of the 2,3-DPG which had been lost was regenerated. Thus, stored blood may fail to transport oxygen efficiently for many hours after reinfusion.     

The Effect of Ascorbate and Dihydroxyacetone on the 2,3-Diphosphoglycerate and ATP Levels of Stored Human Red Cells

Fifty ml aliquots of blood were stored in modified CPD-adenine preservative solutions at pH 4.8, 5.6, and 7.0 containing either dihydroxyacetone alone, ascorbic acid alone, or a combination of both. Red blood cell ATP and 2,3-DPG determinations showed that the effect of dihydroxyacetone and ascorbic acid were synergistic at all pH levels, and that even at the lowest pH levels excellent 23-DPG maintenance was observed. A reciprocal relationship existed between 2,3-DPG and ATP maintenance. Studies in 500 ml units of blood containing both dihydroxyacetone and ascorbate gave similar results to those in 50 ml aliquots. There was excellent maintenance of 2,3-DPG levels throughout the 28-day storage period.     

Blood preservation. XXIX. Pyruvate maintains normal red cell 2,3-DPG for six weeks of storage in CPD-adenine

Pyruvate was placed in experimental CPD-adenine (0.25 mM) blood preservative mixtures in four concentrations ranging from 40 to 320 mM. In the 320 mM pyruvate preservative, 2,3-DPG levels were elevated above normal for six weeks of whole blood storage at 4 C. The lower pyruvate concentrations maintained elevated or normal 2,3-DPG levels for less time: four weeks with 160 mM, two weeks with 80 mM, and one week or less with 40 mM or the control. ATP values were best maintained in the control. The higher pyruvate concentrations resulted in the most rapid decreases at ATP. However, even the 320 mM pyruvate did not cause ATP to fall below 2 microM/gm of Hb. The higher pyruvate concentrations produced and maintained a higher pH during storage. On the other hand, 2,3-DPG levels increased with pyruvate during the first week of storage when the pH was decreasing rapidly. This could be the result of its oxidation of NADH to NAD. The high pyruvate concentration which maintained elevated 2,3-DPG levels throughout the six weeks might be simulating the effect reported in pyruvate kinase-deficient red blood cells, in which blockage of glycolysis at that step is preventing 2,3- DPG catabolism.     

Blood storage XXIII: 2,3-DPG maintenance for six weeks in a CPD-adenine- inosine preservative with and without methylene blue

In a pilot study the optimal concentration of inosine for 2,3-DPG maintenance in a CPD-adenine (0.25 mM) preservative was confirmed to be at lease 10 mM. In these experiments, 2,3-DPG maintenance was nearly normal for six weeks of storage in CPD-adenine-inosine (10 mM) preservative with or without methylene blue. The control preservative lacking inosine showed a statistically significant decrease in 2,3-DPG concentrations after the 3rd week. Finally, 2,3-DPG levels were significantly better maintained in CPD-adenine preservatives that contained 15 mM concentrations of inosine, whether methylene blue was present or not (10(-6)M), compared to CPD-adenine-inosine preservatives that contained 5 mM inosine, with or without methylene blue. The methylene blue effect, while it can be demonstrated in most experiments to help the red blood cell maintain 2,3-DPG during prolonged blood storage, is judges to be a slight value. However, inosine is of great value in maintaining 2,3-DPG for prolonged (five to six weeks) liquid storage.     

Reversal of the storage lesion of CPD bank blood: a problem in clinical medicine

The effect of phosphate buffer on the course of pH, ATP, and 2,3-PDG of CPD red blood cells stored at three temperatures was observed. Basic phosphate at an equilibrated level of 10 mM (as iP) maintained pH above 7.00 and ATP and 2,3-DPG above 70 per cent of initial value in cells stored at 37 C for 24 hours. In contrast however, at 25 and 4 C no buffering was obtained with basic phosphate concentrations up to 50 mM, but values for both ATP and 2,3-DPG were higher in phosphate treated aliquots than in controls throughout storage. When the pH of blood stored at 4 C was adjusted into the range 7.15 to 7.25 with tromethamine and the level of iP raised to 10 mM by addition of Na2HPO4 on day seven, it was found that ATP and 2,3-DPG levels were maintained at 90 and 120 per cent, while control levels fell to 60 and 12 per cent, respectively at 21 days. The process described parallels the normal repair of damaged red blood cells of bank blood that occurs in vivo following transfusion.     

Blood preservation. XLIII. Studies on the ascorbate mechanisms of maintaining red cell 2,3-DPG

Our previous experiments on the mechanisms of ascorbate's effect on the red blood cell failed to show an effect of iodoacetate (IA), a sulfydryl inhibitor. In this study, in contrast to the previous, iodoacetate (85 micromolar) was seen to prevent continued red blood cell metabolism. During the first weeks there was an absence of a continual fall in pH; ATP levels were depressed below half normal; and 2,3-DPG levels fell to very low values within the first week. ATP was best maintained in the control preservative and next best maintained, at adequate levels, with ascorbate, 5 mM, with and without glutathione, 5 mM. 2,3-DPG levels were well maintained with ascorbate and ascorbate with glutathione. Poor ATP maintenance and rapid decreases in 2,3-DPG were observed with iodoacetate, IA plus ascorbate, and IA plus ascorbate and glutathione.     

Blood storage XXV: Ascorbic acid (vitamin C) and dihydroxyacetone (DHA) maintenance of 2,3-DPG for six weeks in CPD-adenine

In experiments in which ascorbate was included in CPD-adenine preservatives, 2,3-DPG levels were maintained above normal for 28 days with an ascorbate concentration of 10 mM or higher and concentrations of 20 to 80 had no greater effect on 2,3-DPG maintenance. Less ascorbate (5 mM) provided better 2,3-DPG maintenance than was obtained with no ascorbate throughout six weeks of storage but was not as good as the higher concentrations after the third week. ATP concentrations were adversely affected by the presence of ascorbate. The highest ATP concentrations were without ascorbate, next highest with 5 mM, and the worst ATP was with 80 mM. The pH values did not differ from one preservative to another.     

Blood preservation XLIV. 2,3-DPG maintenance by dehydroascorbate better than D-ascorbic acid

A study was designed to compare the effects of D-ascorbate and dehydroascorbate on red blood cell metabolism during blood storage. Dehydroascorbate increased red blood cell concentrations of 2,3-DPG such that the levels are above normal for four weeks and normal at six weeks of storage. In contrast, there is a gradual decrease in 2,3-DPG levels with D-ascorbate such that the levels are approximately 80 per cent of normal after six weeks. ATP levels were adversely effected such that the worst levels were produced by 10 and 5 mM dehydroascorbate, with 10 mM having a more adversive effect than 5 mM. Intermediate levels of ATP were produced by D-ascorbate, with the 10 mM concentration. The control CPD-adenine preservative maintained near normal ATP levels for the entire six-week storage period. pH values were initially slightly lower with dehydroascorbate compared to the other preservatives early in storage, the difference being slightly over 0.1 pH units.     

Blood preservation. XXXIV. DHA maintains 2,3-DPG and its adverse effect on ATP is reversed with extra phosphate

We have found that the addition of 10 mM inorganic phosphate to DHA in CPD-adenine maintains ATP levels at normal or higher than normal values for six weeks of storage. 2,3-DPG values are slightly lowered by the extra phosphate, but are still maintained at approximately half normal for four weeks by the DHA. The addition of a higher phosphate concentration, 20 mM, to DHA produced lower levels of ATP and 2,3-DPG than those observed with 10 mM phosphate, although both levels were better than in the CPD-adenine control. pH values in this experiment were lowest in the three preservatives containing DHA, probably indicating increased lactate production due to metabolism of this triose sugar, in addition to dextrose present in CPD.     

Blood preservation 35. Red cell 2,3-DPG and ATP maintained by DHA- ascorbate-phosphate

DHA (dihydroxyacetone, 60 mM) with ascorbic acid (d-ascorbate, 10 mM) kept 2,3-DPG concentrations above normal for six weeks. Levels of 2,3- DPG were below normal after four weeks with DHA alone and after two weeks with DHA-ascorbate-phosphate. As in previous studies, high phosphate concentrations decreased 2,3-DPG maintenance. ATP maintenance was best achieved with the following (in order of performance): DHA- phosphate (20 mM); DHA-phosphate (10 mM); the control, CPD-adenine preservative; Phosphate 20 mM; and DHA. DHA with ascorbate provides normal 2,3-DPG for six weeks. The adverse effects of DHA and DHA with ascorbate on ATP levels are modified by 10 mM phosphate.     

The in vitro evaluation of modifications in CPD-adenine anticoagulated- preserved blood at various hematocrits

Erythrocytes stored in the new CPD-adenine anticoagulant (CPDA-1) barely met the 70 per cent 24-hour postinfusion 51Cr recoveries on day 35 when stored at hematocrit greater than or equal to 75 per cent. CPDA- 1 differs from CPD in that it has 1.25 times the glucose concentration plus 17.3 mg adenine/63 ml. In an effort to improve the survivability (or viability) of red blood cells following extended storage (35+ days), two new CPD-adenine anticoagulants have been tested in vitro. CPDA-2 and CPDA-3 (both of which contain 34.6 mg/63 ml of anticoagulant or 0.50 mM adenine [final blood concentration], and either 1.75 times or 2.0 times respectively the amount of glucose used in CPD) have been tested for whole blood or red blood cell storage to 42 days. Red blood cell ATP concentrations were better maintained throughout 42 days of storage in both of these formulations than in CPDA-1 at hematocrits that ranged from 40 to 85. Other biochemical parameters (2,3-DPG, pH, plasma hemoglobin) were similar to those of blood stored in CPD or CPDA- 1.     

Blood preservation 42: improvement of ascorbate's ability to maintain 2,3-DPG with inosine

Inosine and ascorbate have been shown to maintain normal 2,3-DPG levels during three to four weeks of blood storage. With the introduction of CPD-adenine, which allows five weeks of storage, the desire for 2,3-DPG maintenance may receive new emphasis. Red blood cell 2,3-DPG remained at normal or higher levels for six weeks whenever 10 or 15 mM inosine and 10 mM vitamin C (L-ascorbate) or D-ascorbate were present in the CPD-adenine preservative. Provision by inosine of a five-carbon sugar for 2,3-DPG synthesis, bypassing the rate-limiting phosphofructokinase reaction, may allow NADH oxidation by ascorbate to provide an increased supply of substrate for the Rappoport-Luebering shunt, thus affecting the net increase and maintenance of 2,3-DPG.     

Hemoglobin function in stored blood. IX. Preservative with pH to maintain red blood cell 2,3-DPG (function) and ATP (viability)

An optimal pH was sought to maintain hemoglobin function, ATP, and red blood cell viability during liquid storage under blood banking conditions. Ten units of blood from normal volunteers were subjected to an automated analytical system for determining concentrations of 2,3-DPG and ATP. Each unit was split during donation into five parts containing citrate—dextrose solutions of pH 5.0, 5.5, 6.0, 6.5, and 7.0. Significant differences at the 95 per cent level were based on the paired t-test. In addition, osmotic fragility and methylene blue uptake were determined to assess their possible usefulness as indicators of either red blood cell viability or ATP. With pH 5.0 preservative 2,3-DPG fell from day 0 to day 3, with pH 5.0 and 5.5 preservatives from day 3 to day 7, and from day 7 to day 14 in all pH groups. A plot of 2,3-DPG versus hydrogen ion concentration showed that in excess of 1 × 10^?7hydrogen ion, corresponding to pH 7.0, 2,3-DPG concentration falls at a rapid rate. From 2,3-DPG and ATP data, a preservative with pH higher than 5.5 would seem to be optimal for maintaining hemoglobin function and red blood cell viability, but adenine may be needed to maintain adequate ATP levels.     

Prolonged maintenance of 2,3-DPG in liquid blood storage: use of an internal CO2 trap to stabilize pH.

A close relationship exists between the decrease in concentration of 2,3-diphosphoglycerate (2,3-DPG) and a fall in the pH of stored blood. Buffering the stored red cells with bicarbonate is one solution to the problem of maintaining pH during storage. The effectiveness of this buffer depends upon loss from the stored blood of carbonic acid in the form of CO2. We describe a system in which the CO2 is trapped in a small internal package which contains calcium hydroxide, or calcium hydroxide embedded in Silastic. A medium containing bicarbonate, adenine, glucose, phosphate and mannitol (BAGPM) is added after initial packing of the erythrocytes. With this approach, it has been possible to maintain 2,3-DPG at 92 percent of original, and ATP was approximately 62 percent of initial levels at the end of 42 days of storage if an internal Silastic bag containing calcium was used in bags agitated once weekly. More frequent agitation (five times weekly) produced acceptable maintenance of both 2,3-DPG (78 percent of original) and ATP (44 percent of original) after 42 days of storage when a Silastic block impregnated with calcium hydroxide was utilized to absorb CO2.     

Improved red blood cell storage using optional additive systems (OAS) containing adenine, glucose and ascorbate-2-phosphate

Red blood cells were treated with optional additive system (OAS) solutions to provide component-specific metabolic enhancement for improved storage. Red blood cell viability, as monitored by ATP concentrations, was maintained by use of adenine and extra glucose. Red blood cell oxygen offloading characteristics were improved by maintenance of red blood cell 2,3-DPG concentrations with ascorbate-2- phosphate (AsP). The use of CPD-collected red blood cells with an OAS containing adenine, glucose, and AsP, or CPD-adenine collected red blood cells with an OAS containing AsP demonstrates the potential to store red blood cells at least 42 days and to maintain red blood cell 2,3-DPG.     

Blood preservation using metabolic regulators and nutrients: XXI. Further studies on pyruvate and DHA (dihydroxyacetone)

CPD-adenine is being adopted in Europe for five weeks for regular blood bank storage and six weeks for emergency use storage. There may be a need to maintain normal levels of 2,3-DPG during this prolonged storage time. In a pilot study from this laboratory, improved 2,3-DPG maintenance was noted with DHA and pyruvate during the fifth and sixth weeks of storage. DHA and pyruvate are relatively unstable in aqucous solutions and in the present study extra care was taken with their experimental use. The additive effect of using DHA and pyruvate together in maintaining 2,3-DPG was confirmed in this study in which significant improvements were seen as early as the seventh day of storage.