Capillary endothelial surface layer selectively reduces plasma solute distribution volume.

We previously reported that a 0.4- to 0.5-microm-thick endothelial surface layer confines Dextran 70 (70 kDa) to the central core of hamster cremaster muscle capillaries. In the present study we used a variety of plasma tracers to probe the barrier properties of the endothelial surface layer using combined fluorescence and brightfield intravital microscopy. No permeation of the endothelial surface layer was observed for either neutral or anionic dextrans >/=70 kDa, but a neutral Dextran 40 (40 kDa) and neutral free dye (rhodamine, 0.4 kDa) equilibrated with the endothelial surface layer within 1 min. In contrast, small anionic tracers of similar size (0. 4-40 kDa) permeated the endothelial surface layer relatively slowly with half-times (tau(50)) between 11 and 60 min, depending on tracer size. Furthermore, two plasma proteins, fibrinogen (340 kDa) and albumin (67 kDa), moved slowly into the endothelial surface layer at the same rates, despite greatly differing sizes (tau(50) approximately 40 min). Dextran 70, which did not enter the glycocalyx over the course of these experiments, entered at the same rate as free albumin when it was conjugated to albumin. These findings demonstrate that for anionic molecules size and charge have a profound effect on the penetration rate into the glycocalyx. The equal rates of penetration of the glycocalyx demonstrated by the different protein molecules suggests that multiple factors may influence the penetration of the barrier, including molecular size, charge, and structure.

[1]  Luft Jh Fine structures of capillary and endocapillary layer as revealed by ruthenium red. , 1966 .

[2]  J. Pappenheimer,et al.  Filtration, diffusion and molecular sieving through peripheral capillary membranes; a contribution to the pore theory of capillary permeability. , 1951, The American journal of physiology.

[3]  J. Levick,et al.  An analysis of the permeability of a fenestra. , 1987, Microvascular research.

[4]  V. Huxley,et al.  Single capillary permeability to proteins having similar size but different charge. , 1988, The American journal of physiology.

[5]  S. Ito Structure and function of the glycocalyx. , 1969, Federation proceedings.

[6]  J. Leypoldt,et al.  Molecular charge influences transperitoneal macromolecule transport. , 1993, Kidney international.

[7]  G. Clough,et al.  Relationship between microvascular permeability and ultrastructure. , 1991, Progress in biophysics and molecular biology.

[8]  P. Wieringa,et al.  Evidence that cell surface charge reduction modifes capillary red cell velocity‐flux relationships in hamster cremaster muscle. , 1995, The Journal of physiology.

[9]  R. D. Lynch,et al.  Interaction of native and chemically modified albumin with pulmonary microvascular endothelium. , 1990, The American journal of physiology.

[10]  E. M. Renkin Cellular Aspects of Transvascular Exchange: A 40‐Year Perspective , 1994, Microcirculation.

[11]  L. Kjellén,et al.  Proteoglycans: structures and interactions. , 1991, Annual review of biochemistry.

[12]  F. Curry,et al.  A fiber matrix model of capillary permeability. , 1980, Microvascular research.

[13]  B. Duling,et al.  Identification of distinct luminal domains for macromolecules, erythrocytes, and leukocytes within mammalian capillaries. , 1996, Circulation research.

[14]  E. M. Renkin,et al.  Effects of histamine and some other substances on molecular selectivity of the capillary wall to plasma proteins and dextran. , 1974, Microvascular research.

[15]  F. Curry Determinants of Capillary Permeability: A Review of Mechanisms Based on Single Capillary Studies in the Frog , 1986, Circulation research.

[16]  B. Duling,et al.  Measurement uncertainties associated with the use of bright-field and fluorescence microscopy in the microcirculation. , 1995, Microvascular research.