화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korea-Australia Rheology Journal, Vol.16, No.3, 141-146, September, 2004
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Shear induced damage of red blood cells monitored by the decrease of their deformability
Sung Sik Lee, Kyung Hyun Ahn, Seung Jong Lee, Kyung Sun1, Petrus T. Goedhart2, and Max. R. Hardeman2
  • School of Chemical Engineering, Seoul National University, Seoul, Korea
  • 1Department of Thoracic and Cardiovascular Surgery, Korea University, Seoul, Korea
  • 2Department of Clinical Physiology, Academy Medical Center, Amsterdam, Netherlands
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Shear-induced damage of Red Blood Cell (RBC) is an imminent problem to be solved for the practical application of artificial organs in extra corporeal circulation, as it often happens and affects physiological homeostasis of a patient. To design and operate artificial organs in a safe mode, many investigations have been set up to correlate shear and shear-induced cell damage. Most studies were focused on hemolysis i.e. the extreme case, however, it is important as well to obtain a clear understanding of pre-hemolytic mechanical damage. In this study, the change in deformability of RBC was measured by ektacytometry to investigate the damage of RBC caused by shear. To a small magnitude of pre-shear, there is little difference, but to a large magnitude of pre-shear, cell damage occurs and the effect of shear becomes significant depending on both the magnitude and imposed time of shearing. The threshold of mechanical hemolysis but is large enough to occur in vitro as in the extra corporeal circulation during open-heart surgery or artificial heart. In conclusion, it was found and suggested that the decrease of deformability can be used as an early indication of cell damage, in contrast to measuring plasma hemoglobin. As cell damage always occurs during flow in artificial organs, the results as well as the approach adopted here will be helpful in the design and operation of artificial organs.
Keywords:cell damage;ektacytometry;red blood cell deformability;extra corporeal circulation;artificial organ;LORCA
  1. Brody JP, Han Y, Austin RH, Bitensky M, Biophys. J., 68, 2224 (1995)
  2. Bronkhorst PJH, Streekstra GJ, Grimbergen JN, Sixma JJ, Brakenhoff GJ, Biophys. J., 69, 1666 (1995)
  3. Dintenfass L, Nature, 219, 956 (1968) 
  4. Discher DE, Mohandas N, Evans EA, Science, 266(5187), 1032 (1994) 
  5. Fisher TM, Wenby RB, Meiselman HJ, Biorheology, 29, 185 (1992)
  6. Fuller GG, Leal LG, Rheol. Acta, 19, 580 (1980) 
  7. Hardeman MR, Goedhart P, Breederveld D, Clin. Chim. Acta, 165, 227 (1987) 
  8. Hardeman MR, Ince C, Clin. Hemorheol., 14, 619 (1994)
  9. Hardeman HR, Dobbe JGG, Ince C, Clin. Hemorheol. Microcirc., 25, 1 (2001)
  10. Hirayama T, Herlitz H, Johnson O, Roberts D, Scand. J. Thorac. Cardiovasc., 20, 253 (1986)
  11. Huruta RR, Barjas-Castro ML, Saat STO, Costa FF, Fontes A, Barbosa LC, Cesar CL, Blood, 92, 2975 (1998)
  12. Kameneva MV, Undar A, Antaki JF, Watach MJ, Cal-hoon JH, Borovetz HS, ASAIO J., 45, 307 (1999)
  13. Kaneta T, Makihara J, Imasaka T, Anal. Chem., 73, 5791 (2001) 
  14. Kikichi Y, Sato K, Mizuguchi Y, Microvasc. Res., 47, 126 (1994) 
  15. Lenormand GM, Henon S, Richert A, Simeon J, Gallet F, Biophys. J., 81, 43 (2001)
  16. Mizuno T, Tomonori T, Yoshiyuki T, Eisuke T, Tomohiro N, Hiroyako O, Mitsuo O, Koichi S, Kyoko S, Yoshiaki T, Hisateru T, ASAIO J., 48, 668 (2002) 
  17. Mohandas N, Clark MR, Jacobs MS, Shohet SB, J. Clin. Invest., 66, 563 (1980)
  18. Mokken FC, Kedaria M, Henny CP, Hardeman MR, Gelb AA, Ann. Hematol., 64, 113 (1992) 
  19. Needham D, Nunn RS, Biophys. J., 58, 997 (1990)
  20. Sallam AM, Hwang NHC, Biorheology, 21, 783 (1984)
  21. Sharp MK, Mohammand SF, Ann. Biomed. Eng., 26, 788 (1998) 
  22. Sutton N, Tracey C, Johnson D, Greeenaway RS, Rampling MW, Microvasc. Res., 53, 272 (1997)