Evaluation of novel storage or processing technology for human red blood cells (RBCs) involves in vitro tests on the red cells to determine biochemical changes and in vivo studies in healthy human volunteers with radiolabeled red cells to determine in vivo recovery 24 hours post infusion. In vivo studies are needed because our understanding of red cell storage lesions is not sufficient to identify an in vitro test(s) that would adequately predict red cell performance in vivo. The clinical studies with radiolabeled cells are used as the gold standard for evaluation prior to approval of a novel technology by the FDA. However, in vivo studies require time and funds and can be a significant hurdle in the development of new products. An animal model that could predict performance of human red cells in vivo would be useful in the development process. We previously reported that severe combined immunodeficient (SCID) mice could be used as a model to identify damaged human platelets (
2,3-DPG Levels (mM/L) Pre- and Post-Rejuvenation . | |||
---|---|---|---|
. | Fresh RBCs . | Aged for 42 Days . | Aged for 100 Days . |
Control | 3.25±0.40 | 0.17±0.04 | 0.38 ±0.06 |
Rejuvenated | 8.58±0.82 | 4.56±0.17 | 2.31±0.13 |
2,3-DPG Levels (mM/L) Pre- and Post-Rejuvenation . | |||
---|---|---|---|
. | Fresh RBCs . | Aged for 42 Days . | Aged for 100 Days . |
Control | 3.25±0.40 | 0.17±0.04 | 0.38 ±0.06 |
Rejuvenated | 8.58±0.82 | 4.56±0.17 | 2.31±0.13 |
Fresh red cells exhibited recovery of 58.4±4.4 % of total cells injected. Aged RBCs showed a reduced in vivo recovery of 35.7±7.3 % and 5.7±1.6 % of total cells injected for 42 and 100 day old RBC, respectively. Gamma-irradiated fresh RBCs and irradiated fresh RBCs stored for 28 days showed a recovery of 66.7±8.6 % and 55±13.2 % respectively, whereas the recovery of control fresh RBCs and control fresh RBCs stored for 28 days showed a recovery of 58.4±4.4 % and 49.1±7.0 % (p=0.44) respectively (Table 2).
In VivoRecovery . | ||||
---|---|---|---|---|
. | Fresh RBCs . | Stored for 28 days . | Aged for 42 Days . | Aged for 100 Days . |
nd - not determined | ||||
Control | 58.4±4.5 | 49.1±7.0 | 35.7±7.3 | 5.17±1.6 |
Rejuvenated | 52.5±11.5 | nd | 55.4±7.1 | 21.3±5.0 |
Irradiated (25Gy) | 66.7±8.6 | 55±13.2 | nd | nd |
In VivoRecovery . | ||||
---|---|---|---|---|
. | Fresh RBCs . | Stored for 28 days . | Aged for 42 Days . | Aged for 100 Days . |
nd - not determined | ||||
Control | 58.4±4.5 | 49.1±7.0 | 35.7±7.3 | 5.17±1.6 |
Rejuvenated | 52.5±11.5 | nd | 55.4±7.1 | 21.3±5.0 |
Irradiated (25Gy) | 66.7±8.6 | 55±13.2 | nd | nd |
Our data indicate that the SCID mouse model can distinguish between fresh and aged red cells and that rejuvenation of the red cells increases intracellular 2,3-DPG levels and in vivo recovery of aged red cells. The SCID mouse model could be used to develop or improve existing methods of red cell storage and processing. The findings and conclusions in this abstract have not been formally disseminated by the Food and Drug Administration and should not be construed to represent any Agency determination or policy.
Disclosures: No relevant conflicts of interest to declare.