Comparative analysis of the nitrogen monoxide content and optical-morphometric characteristics of erythrocyte-containing blood components during storage

Capa

Citar

Texto integral

Acesso aberto Acesso aberto
Acesso é fechado Acesso está concedido
Acesso é fechado Somente assinantes

Resumo

Flow cytometry was used to analyze the content of intracellular nitrogen monoxide in erythrocyte-containing blood components during blood storage with hemopreservative for 4 weeks. It was found that storing of blood is accompanied by increased levels of intracellular nitrogen monoxide in erythrocytes and thus by a change in optical and morphometric parameters of red blood cells. In the early stages of storage, erythrocytes were represented by discocytes, and during long storage erythrocytes became more spherical (spherocytes) as the percentage of microcytes that accumulated nitrogen monoxide increased and their intracellular hemoglobin levels were decreased.

Sobre autores

N. Akulich

National Antidoping Laboratory

Email: akulichn@gmail.com
Minsk Region, Belarus

V. Zinchuk

Grodno State Medical University

Grodno, Belarus

Bibliografia

  1. K. Thangaraju, S. Neerukonda, U. Katneni, et al., Int. J. Mol. Sci., 22, 153 (2021).
  2. V.V. Zinchuk, D. D. Zhadko, Nitric Oxide 1 (84) 45 (2019).
  3. А. И. Костин, О. А. Майорова, А. В. Ложкин и др., Трансфузиология, 12 (2), 12 (2011).
  4. В. В. Зинчук и Е. С. Билецкая, Биофизика, 65, 915 (2020).
  5. C. Donadee, N. J. Raat, T. Kanias, et al., Circulation
  6. (4), 465 (2011). M. García-Roa, M. Del Carmen Vicente-Ayuso, M. Bobes, et al., Blood Transfus., 15 (3), 22 (2017).
  7. R. Stapley, B. Y. Owusu, and A. Brandon, Biochem. J., 446 (3), 499 (2012).
  8. F. J. Willekens, J. M. Werre, Y. A. Groenen-Döpp, et al., Br. J. Haematol., 141 (4), 549 (2008).
  9. N. Li, J. Sul, and P. Haydon, Neuroscitnce, 23, 10302 (2003).
  10. C. Briggs, R. Rogers, B. Tompson, et al., Sysmex J.Int., 11 (2), 63 (2001).
  11. J. T. Alexander, A. M. El-Ali, J. L. Newman, et al., Transfusion, 53 (11), 2619 (2013).
  12. B. Sandhagen, C. F. Hogman, C-H de Verdier, et al., Vox Sang, 55, 139 (1988).
  13. C. Liu, X. Liu, J. Janes, et al., Redox Biol., 2, 211 (2014).
  14. В. П. Реутов, Успехи биол. наук, 35, 189 (1995).
  15. S. Suriany, I. Xub H. Liu, et al., Free Radic. Biol. Med., 171, 143 (2021).
  16. A. H. Tayer, N. Amirizadeh, M. Ahmadinejad, et al., Transfus. Med. Hemother., 46 (4), 224 (2019).
  17. C. Donadee, N. J. Raat, T. Kanias, et al., Circulation, 124, 465 (2011).

Declaração de direitos autorais © Russian Academy of Sciences, 2023

Este site utiliza cookies

Ao continuar usando nosso site, você concorda com o procedimento de cookies que mantêm o site funcionando normalmente.

Informação sobre cookies