Authors: K. Santacruz-Gomez, E. Silva-Campa, S. Álvarez-García, V. Mata-Haro, D. Soto-Puebla, M. Pedroza-Montero

Abstract:

Blood gamma irradiation is the only available method to prevent transfusion associated graft versus host disease (TAGVHD). However, when blood is irradiated, determine blood shelf time is crucial. Non irradiated blood have a self-time from 21 to 35 days when is preserved with anticoagulated solution and stored at 4°C. During their storage, red blood cells (RBC) undergo a series of biochemical, biomechanical and molecular changes involving what is known as storage lesion (SL). SL include loss of structural integrity of RBC, decrease of 2,3-diphosphatidylglyceric acid levels, and increase of both ion potassium concentration and hemoglobin (Hb). On the other hand, Atomic force Microscopy (AFM) represents a versatile tool for a nano-scale high resolution topographic analysis in biological systems. In order to evaluate SL in irradiated and nonirradiated blood, RBC topography and morphometric parameters were obtained from an AFM XE-BIO system. Cell viability was followed using flow cytometry. Our results showed that early markers as nanoscale roughness, allow us to evaluate blood quality since other perspective.

Keywords: AFM, Blood γ-irradiation, roughness, Storage lesion.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1094122

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References:

[1] Klein, H. G., & Anstee, D. J. (2013). Mollison's blood transfusion in clinical medicine. John Wiley & Sons.
[2] Antonelou, M. H., Tzounakas, V. L., Velentzas, A. D., Stamoulis, K. E., Kriebardis, A. G., & Papassideri, I. S. (2012). Effects of pre-storage leukoreduction on stored red blood cells signaling: a time-course evaluation from shape to proteome. Journal of proteomics, 76, 220-238.
[3] Högman, C. F., & Meryman, H. T. (1999). Storage parameters affecting red blood cell survival and function after transfusion. Transfusion medicine reviews, 13(4), 275-296.
[4] Chin-Yee, I., Arya, N., & d'Almeida, M. S. (1997). The red cell storage lesion and its implication for transfusion. Transfusion science, 18(3), 447-458.
[5] Scheidt, W. R., & Reed, C. A. (1981). Spin-state/stereochemical relationships in iron porphyrins: implications for the hemoproteins. Chemical Reviews, 81(6), 543-555.
[6] Monod, J., Wyman, J., & Changeux, J. P. (1965). On the nature of allosteric transitions: a plausible model. Journal of molecular biology, 12(1), 88-118.
[7] Arnone, A. (1972). X-ray diffraction study of binding of 2, 3- diphosphoglycerate to human deoxyhaemoglobin. Nature, 237(5351), 146-149.
[8] Lenfant, C., Torrance, J., English, E., Finch, C. A., Reynafarje, C., Ramos, J., & Faura, J. (1968). Effect of altitude on oxygen binding by hemoglobin and on organic phosphate levels. Journal of Clinical Investigation, 47(12), 2652.
[9] Ho, J., Sibbald, W. J., & Chin-Yee, I. H. (2003). Effects of storage on efficacy of red cell transfusion: when is it not safe?. Critical care medicine, 31(12), S687-S697.
[10] Young, J. A., Lichtman, M. A., Cohen, j., & Murphy, M. (1973). Reduced red cell 2, 3-diphosphoglycerate and adenosine triphosphate, hypophosphatemia, and increased hemoglobin-oxygen affinity after cardiac surgery. Circulation, 47(6), 1313-1318.
[11] Vandromme MJ, McGwin G Jr, Weinberg JA. Blood transfusion in the critically ill: does storage age matter? Scand J Trauma Resusc Emerg Med. 2009
[12] Tsai, A. G., Hofmann, A., Cabrales, P., & Intaglietta, M. (2010). Perfusion vs. oxygen delivery in transfusion with "fresh” and "old” red blood cells: the experimental evidence. Transfusion and Apheresis Science, 43(1), 69-78.
[13] Donadee, C., Raat, N. J., Kanias, T., Tejero, J., Lee, J. S., Kelley, E. E., ... & Gladwin, M.
[13] T. (2011). Nitric oxide scavenging by red blood cell microparticles and cell-free hemoglobin as a mechanism for the red cell storage lesion. Circulation, 124(4), 465-476.
[14] Hess, J. R., Sparrow, R. L., Van Der Meer, P. F., Acker, J. P., Cardigan, R. A., & Devine,
[14] D. V. (2009). Blood Components: Red blood cell hemolysis during blood bank storage: using national quality management data to answer basic scientific questions. Transfusion, 49(12), 2599-2603.
[15] Yalcin, O., Ortiz, D., Tsai, A. G., Johnson, P. C., & Cabrales, P. (2014). Microhemodynamic aberrations created by transfusion of stored blood. Transfusion, 54(4), 1015-1027.
[16] Relevy H, Koshkaryev A, Manny N, Yedgar S, Barshtein G. Blood banking-induced alteration of red blood cell flow properties. Transfusion 2008;48:136–46.
[17] Gladwin, M. T., & Kim-Shapiro, D. B. (2009). Storage lesion in banked blood due to hemolysis-dependent disruption of nitric oxide homeostasis. Current opinion in hematology, 16(6), 515-523.
[18] Klein, H. G., Spahn, D. R., & Carson, J. L. (2007). Red blood cell transfusion in clinical practice. The Lancet, 370(9585), 415-426.
[19] Weinberg, J. A., McGwin Jr, G., Marques, M. B., Cherry III, S. A., Reiff, D. A., Kerby, J. D., & Rue III, L. W. (2008). Transfusions in the less severely injured: does age of transfused blood affect outcomes?. Journal of Trauma-Injury, Infection, and Critical Care, 65(4), 794-798.
[20] Tse, W. T., & Lux, S. E. (1999). Red blood cell membrane disorders. British journal of haematology, 104(1), 2-13.
[21] Moroz, V. V., Chernysh, A. M., Kozlova, E. K., Borshegovskaya, P. Y., Bliznjuk, U. A., Rysaeva, R. M., & Gudkova, O. Y. (2010). Comparison of red blood cell membrane microstructure after different physicochemical influences: atomic force microscope research. Journal of critical care, 25(3), 539-e1.
[22] Wang H, Hao X, Shan Y, Jiang J, Cai M, Shang X. Preparation of cell membranes for high resolution Imaging by AFM(2010). Ultramicroscopy. 2010 Mar;110(4):305-12.