Effects of Perfusion Rate on Permeability of Frog and Rat Mesenteric Microvessels to Sodium Fluorescein |
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| Authors: | D. Montermini&dagger ,C. P. Winlove&dagger ,C. C. Michel |
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| Affiliation: | Division of Biomedical Sciences, Faculty of Medicine, Imperial College of Science Technology and Medicine, Exhibition Road, London SW7 2AZ;Medical Biophysics Group, School of Physics, University of Exeter, Exeter EX4 4XL, UK |
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| Abstract: | The permeability, P S, to sodium fluorescein (Stokes-Einstein radius = 0.45 nm) has been measured in single mesenteric capillaries of pithed frogs and anaesthetised rats as perfusion velocity, U , was varied over a range from 400 up to 2000–10 000 μm s−1. P S increased linearly with U . In 20 frog capillaries, mean (± S.E.M.) P S (in μm s−1) = 9.35 (± 1.55) U × 10−5+ 0.244 (± 0.0291). Similarly, in nine rat venules, mean P S= 1.62 (± 0.385) U × 10−4+ 0.375 (± 0.025). The flow-dependent component of permeability could be reversibly abolished in frog capillaries by superfusing with 100 μM noradrenaline and by superfusing rat venules with the nitric oxide synthase inhibitor, N G-nitro-L-arginine (20 μM). It was shown that changes in microvascular pressure accompanying changes in U during free perfusion could account for only 15 % of the changes in P S, i.e. 85 % of the changes in P S were changes in the permeability coefficient itself. A comparison between the changes in P S with U and the previously described changes in microvascular permeability to K+ with U , suggest that if the flow-dependent component of permeability is modelled as a population of pores of constant size, these have radii of 0.8 nm. Such a pathway would limit flow-dependent permeability to small hydrophilic molecules and have minimal effect on net fluid exchange. |
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