ABSTRACT
Units of red blood cell (RBC) concentrates with rare phenotypes are typically not included in method validation studies for cryopreservation processes; rather, they are reserved for patients with rare blood needs. Some rare RBC phenotypes may demonstrate membrane abnormalities, like acanthocytosis as observed for RBCs with the McLeod phenotype, and are specifically banked for these rare attributes; however, the impact that rare RBC phenotypes have on post-thaw quality has not been well studied. To evaluate how a rare RBC phenotype is affected by the cryopreservation process, 4 RBC units, cryopreserved in 1993 using manual methods, were selected for evaluation. These RBCs included one with the McLeod phenotype and three with phenotypes not known to cause significant membrane changes. Post-thaw, an altered deglycerolization protocol, implemented to reduce supernatant glycerol after cryopreservation, was used before processing RBCs on an automated closed system (ACP 215; Haemonetics, Boston, MA) to accommodate the use of a closed system cell processor not available when the RBC units were previously cryopreserved. RBC quality was tested at 24 hours, 7 days, and 14 days post-deglycerolization. Before deglycerolization, an extracted sample from the thawed glycerolized RBC unit was used to obtain genetic material for phenotype confirmation. Genotyping confirmed the McLeod phenotype. When comparing McLeod with non-McLeod units, RBCs from the McLeod donor exhibited acanthocytosis, higher rigidity, and lower morphology scores than RBCs from the non-McLeod units post-deglycerolization. Hemolysis, however, was comparable across all 4 units, meeting regulatory standards. Therefore, McLeod RBCs can withstand cryopreservation, suggesting that units from these donors, glycerolized using older methods, can be deglycerolized using the ACP 215 and stored hypothermically for 14 days. It was also determined that genotyping can be performed on non-leukocyte-reduced cryopreserved RBCs, allowing for confirmation of genetic profiles of donor units banked before the implementation of molecular methods.Units of red blood cell (RBC) concentrates with rare phenotypes are typically not included in method validation studies for cryopreservation processes; rather, they are reserved for patients with rare blood needs. Some rare RBC phenotypes may demonstrate membrane abnormalities, like acanthocytosis as observed for RBCs with the McLeod phenotype, and are specifically banked for these rare attributes; however, the impact that rare RBC phenotypes have on post-thaw quality has not been well studied. To evaluate how a rare RBC phenotype is affected by the cryopreservation process, 4 RBC units, cryopreserved in 1993 using manual methods, were selected for evaluation. These RBCs included one with the McLeod phenotype and three with phenotypes not known to cause significant membrane changes. Post-thaw, an altered deglycerolization protocol, implemented to reduce supernatant glycerol after cryopreservation, was used before processing RBCs on an automated closed system (ACP 215; Haemonetics, Boston, MA) to accommodate the use of a closed system cell processor not available when the RBC units were previously cryopreserved. RBC quality was tested at 24 hours, 7 days, and 14 days post-deglycerolization. Before deglycerolization, an extracted sample from the thawed glycerolized RBC unit was used to obtain genetic material for phenotype confirmation. Genotyping confirmed the McLeod phenotype. When comparing McLeod with non-McLeod units, RBCs from the McLeod donor exhibited acanthocytosis, higher rigidity, and lower morphology scores than RBCs from the non-McLeod units post-deglycerolization. Hemolysis, however, was comparable across all 4 units, meeting regulatory standards. Therefore, McLeod RBCs can withstand cryopreservation, suggesting that units from these donors, glycerolized using older methods, can be deglycerolized using the ACP 215 and stored hypothermically for 14 days. It was also determined that genotyping can be performed on non-leukocytereduced cryopreserved RBCs, allowing for confirmation of genetic profiles of donor units banked before the implementation of molecular methods.
Subject(s)
Blood Preservation , Cryopreservation , Erythrocytes , Glycerol , HumansABSTRACT
To determine the incidence and prognostic value of increased serum cardiac troponin I and T concentrations over 12 months in chronic hemodialysis patients, we performed a retrospective chart review in 16 patients undergoing chronic renal hemodialysis randomly selected from the Regional Kidney Disease Program without prior knowledge of their cardiac status. Serum markers of myocardial injury (cardiac troponin I [cTnI], cardiac troponin T [cTnT], and creatine kinase MB [CK-MB]) were measured and clinical outcomes were assessed. At the beginning of the study, 12 of 16 (75%) patients had increased serum enzyme-linked immunosorbent assay (ELISA) cTnT concentrations greater than 0.20 micrograms/L, eight (50%) had increased serum CK-MB greater than 5.0 micrograms/L, and three (19%) had an increased cTnI greater than 0.8 micrograms/L. Over the 1-year study period, the cardiac event rate (n = 4 with fatal myocardial infarction) was correlated to the patients who displayed the higher elevations of cTnT, CK-MB, and cTnI. In the remaining 12 patients studied at the end of 1 year, seven (58%) had increased ELISA cTnT levels and five (42%) had increased CK-MB levels; no patients had elevated cTnI levels. Reanalysis of ELISA cTnT values with a newly formulated Enzymun cTnT assay showed no significant differences. Our data suggest that whereas substantial increases in cardiac markers tended to have a poor prognostic outcome, there was a high incidence of increased cTnT and CK-MB concentrations without evidence of myocardial injury in chronic hemodialysis patients. The lack of absolute cardiospecificity of cTnT and CK-MB may prove cTnI to be the desired serum marker for the detection of myocardial injury in patients with chronic renal disease.