Erythrocyte rheology and oxygen transfer in microcirculatory system

Q4 Engineering Journal of Biorheology Pub Date : 2015-01-01 DOI:10.17106/JBR.29.2
N. Maeda
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引用次数: 3

Abstract

The molecular investigation on the structure-function relationship of hemoglobin carried out in the Postgraduate School of Nara Medical College has been systematically and fortunately developed to those on the oxygen delivery from blood to peripheral tissues in microcirculatory system in Medical School, Ehime University. Microcirculatory system contributes to the delivery of essential substrates such as oxygen and nutrients to tissues, and to the removal of by-products accumulated in the tissues, mainly through capillaries with the surface area of more than 6,000 m2. Therefore, the function of microcirculation is critical for all organs in living body. Particularly, rheological properties of blood are fundamentally important for understanding the function of the microcirculation. The International Society of Biorheology and the Japanese Society of Biorheology have played an important role in the fields of microcirculation and hemorheology. The activity of the International Society of Biorheology has been universally introduced together that of the International Society of Clinical Hemorheology [O’Rear E, et al: The International Society of Biorheology. Rheology Bulletin. 73: 9–11, 2004]. The microcirculation is particularly influenced by the flow behavior of erythrocytes, because the cells occupy nearly half of blood volume [1, 2]. I have exhaustively analyzed rheological properties of erythrocytes in micro-to macro level for understanding the relationship between blood flow in microcirculatory system and oxygen transport from erythrocytes to tissues [3, 4]. The erythrocytes deform under high shear force to reduce their flow resistance by lessening their hydrodynamic effective volume. On the other hand, the erythrocytes aggregate under low shear force, and increase the flow resistance in the microcirculatory system. Thus the flow behavior of erythrocytes and their aggregates in microcirculatory system seems to affect the oxygen transport. Under strong gravitational field, flow of erythrocytes in a blood vessel occasionally deviates from the central axis to the wall, and the cells accumulate. In this essay, I describe mainly about the effect of erythrocyte aggregation/accumulation on the flow behavior of the cells and the oxygen release from the cells, because such conditions seem to be more commonly encountered in clinical medicine and under various physical circumstances.
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红细胞流变学与微循环系统氧转移
奈良医科大学研究生院开展的关于血红蛋白结构-功能关系的分子研究已经系统而幸运地发展到爱媛大学医学院关于血液向微循环系统外周组织输送氧气的研究。微循环系统主要通过表面积超过6000平方米的毛细血管,将氧气和营养物质等基本底物输送到组织中,并清除组织中积累的副产物。因此,微循环的功能对生物体的所有器官都至关重要。特别是,血液的流变特性对于理解微循环的功能至关重要。国际生物流变学会和日本生物流变学会在微循环和血液流变学领域发挥了重要作用。国际生物流变学会的活动与国际临床血液流变学会的活动被普遍介绍[O 'Rear E, et al: The International Society of Biorheology]。流变学通报,23(3):998 - 998。微循环尤其受红细胞流动行为的影响,因为红细胞占据了近一半的血容量[1,2]。我详尽地分析了红细胞从微观到宏观的流变特性,以了解微循环系统血流与红细胞向组织输送氧的关系[3,4]。红细胞在高剪切力作用下变形,通过减小其流体动力有效体积来减小其流动阻力。另一方面,红细胞在低剪切力下聚集,增加了微循环系统的流动阻力。因此,红细胞及其聚集体在微循环系统中的流动行为似乎影响着氧的运输。在强引力场作用下,红细胞在血管内的流动偶有偏离中轴向管壁的现象,细胞聚集。在这篇文章中,我主要描述红细胞聚集/积累对细胞流动行为和细胞氧释放的影响,因为这种情况似乎在临床医学和各种物理情况下更常见。
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来源期刊
Journal of Biorheology
Journal of Biorheology Engineering-Mechanical Engineering
CiteScore
0.50
自引率
0.00%
发文量
5
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