EFFECTS OF HIGH-MOLECULAR-WEIGHT SOLUTES ON FLUID FLUX ACROSS THE ARTERIAL-WALL

被引:6
作者
KARMAKAR, N [1 ]
LEVER, MJ [1 ]
机构
[1] UNIV LONDON IMPERIAL COLL SCI TECHNOL & MED,CTR BIOL & MED SYST,PHYSIOL FLOW STUDIES UNIT,LONDON SW7 2BY,ENGLAND
来源
HEART AND VESSELS | 1994年 / 9卷 / 06期
关键词
ARTERY; HYDRAULIC CONDUCTIVITY; FILTRATION; CONCENTRATION POLARIZATION; ATHEROSCLEROSIS;
D O I
10.1007/BF01745092
中图分类号
R5 [内科学];
学科分类号
1002 ; 100201 ;
摘要
To investigate the mechanisms controlling the flux of plasma proteins into and through the walls of blood vessels, we have studied the effects of two inert protein analogues, Dextran 500 and Poly(ethylene)oxide (PEO) on fluid transport across the walls of intact rabbit common carotid arteries. Transmural fluxes were first measured in vessls pressurized to 150 cm H2O with a solution containing 10 mg/ml albumin alone (control solution) and then with one containing 10 mg/ml albumin plus 10 or 50 mg/ml dextran, or 10 or 30 mg/ml PEO (test solutions). The macromolecule solutions caused a decrease in transmural filtration; the ratios of fluxes with the test solutions to those with the control solutions were 0.89 +/- 0.11 (7), 0.63 +/- 0.08 (8), 0.69 +/- 0.24 (9) and 0.41 +/- 0.09 (4), respectively (Mean +/- SD (n)). These reductions in fluid movement through the vessel wall may be explained quantitatively in terms of the formation of concentration-polarized layers of the macromolecules at the luminal surface or interactions of the macromolecules with the endothelial glycocalyx, causing a decrease in its permeability.
引用
收藏
页码:275 / 282
页数:8
相关论文
共 24 条
  • [1] Yuan F., Chien S., Weinbaum S., A new view of convective-diffusive transport processes in the arterial intima, ASME J Biomech Eng, 113, pp. 314-329, (1991)
  • [2] Fry D.L., Mass transport, atherogenesis and risk, Arteriosclerosis, 7, pp. 88-100, (1987)
  • [3] Meyer G., Merval R., Tedgui A., Synergy between pressure-induced wall stretching and pressure-driven convection in LDL accumulation in the arterial wall, Circulation, 86, (1992)
  • [4] Colton C.K., Friedman S., Wilson D.E., Lees R.A., Ultrafiltration of lipoproteins through a synthetic membrane, J Clin Invest, 51, pp. 2472-2481, (1972)
  • [5] Tarbell J.M., Lever M.J., Caro C.G., The effect of varying albumin concentration on the hydraulic conductivity of the rabbit common carotid artery, Microvasc Res, 35, pp. 204-220, (1988)
  • [6] Dull R.O., Jo H., Sill H., Hollis T.M., Tarbell J.M., The effect of varying albumin concentration and hydrostatic pressure on hydraulic conductivity and albumin permeability of cultured endothelial monolayers, Microvasc Res, 41, pp. 390-407, (1991)
  • [7] Mason J.C., Curry F.E., Michel C.C., The effects of protein upon the filtration coefficient of single frog mesenteric capillaries, Microvasc Res, 13, pp. 185-202, (1977)
  • [8] Sanabria P., Vargas F.F., Effect of albumin on the width of channels in venous endothelium, Am J Physiol, 255, pp. H638-H645, (1988)
  • [9] Curmi P., Renaud G., Juan L., Tedgui A., Influence of LDL receptors on the LDL transport in arterial linings, Archives des maladies du coeur et des vaisseaux., 79, 4, (1986)
  • [10] Truskey G.A., Colton C.K., Smith K.A., Quantitative analysis of protein transport in the arterial wall, Structure and function of the circulation, vol. III, pp. 289-355, (1981)
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