Evaluation of renal oxygen homeostasis in a preclinical animal model to elucidate difference in blood quality after transfusion

BACKGROUND: Red blood cell (RBC) oxygen (O2 ) delivery may be impacted at the tissue, cellular, and molecular levels after storage duration, preservation strategies, and pathogen reduction. Collectively, the preclinical measurement of arterial and venous PO2 , systemic blood flow, tissue hypoxia-inducible factors (HIFs), pimonidazole adduction, and erythropoietin (EPO) regulation can serve to elucidate differential RBC quality after storage and processing. STUDY DESIGN AND METHODS: Donor guinea pig blood was collected, leukoreduced, and stored at 4°C in AS-3 for 1 (fresh) or 14 (stored) days. RBC variables-2,3-diphosphoglycerate, adenosine triphosphate, hemoglobin, morphology, deformability, and in vivo recovery at 24 hours-were measured at each storage duration. Recipient guinea pigs were exchange transfused until 80% volume replacement was achieved. Arterial and venous blood gases, systemic blood flow, renal HIF-1α and HIF-2α, renal EPO mRNA, plasma EPO, and renal tissue pimonidazole adduction were measured after transfusion. RESULTS: RBC variables declined significantly with storage; however, hemolysis and in vivo recovery remained within the allowable limits for human blood storage. Posttransfusion arterial and venous PO2 and systemic blood flow decreased, and renal HIFs, EPO mRNA, and pimonidazole adducts increased. Subsequently, EPO accumulated in plasma indicating decreased O2 availability in the kidneys. Conversely, all variables remained at basal levels in the fresh blood group. CONCLUSION: The evaluation of renal O2 homeostasis after transfusion represents an effective approach to defining RBC quality between predicate and novel processing. Methods are adapted from standardized techniques and ideal for preclinical evaluation.