Human platelet osmotic water and nonelectrolyte transport

The osmotic water (Pf) and nonelectrolyte permeability (Ps) properties of human platelets were characterized using the stopped-flow light-scattering technique. At 37 degrees C, Pf = 0.007 +/- 0.001 cm/s, the urea reflection coefficient (sigma urea) = 0.95 +/- 0.04, and Ps for a series of permeant nonelectrolytes was (in cm X s-1 X 10(-6)) 2.1 (urea), 3.5 (glycerol), 3.8 (thiourea), 17 (ethylene glycol), 18 (acetamide), 23 (formamide), and 24 (butyramide). Pf did not depend on the size of the osmotic gradient or on the direction of volume flow. Mercurial sulfhydryl reagents did not inhibit osmotic water transport, and phloretin and phenylurea did not inhibit urea transport. There was a discontinuity in the temperature dependence for both Pf and urea permeability (P urea) at 36 degrees C; enthalpy (delta H) = 25 (greater than 36 degrees C) and 4.4 kcal/mol (less than 36 degrees C) for Pf, and delta H = 26 (greater than 36 degrees C) and 7 kcal/mol (less than 36 degrees C) for P urea. In contrast to the facilitated water and urea transport systems in the red blood cell, these results suggest that the mechanism for water and urea transport in the platelet is primarily by diffusion through membrane phospholipid. A computer-simulated model of platelet circulation through the renal medulla, based on the measured values for Pf, P urea, and sigma urea, indicated that platelets undergo an approximately 40% decrease in volume in the inner medulla and an approximately 20% overshoot in volume as they return to the external isosmotic environment.

Effects of sulfur dioxide on pore populations of canine tracheal epithelium

The bioelectric and barrier properties of the tracheal epithelium in nose-breathing dogs and in dogs that had been exposed for 75 min to compressed air or to two high concentrations of SO2 were measured and compared. We also studied tissues that had been treated with chloroform. Based on a model of restrictive diffusion we demonstrated heteropores (6 and 250 A) in the control tissues. Bioelectric changes due to 100-ppm SO2 were minimal. After exposure to 500 ppm SO2, adverse changes in the bioelectric properties were focal; they were marked in 8 out of 12 animals but were less striking in the other 4. Nonelectrolyte permeability increased with an increase in SO2 concentrations. Small pores were still present in the tissues severely affected by SO2 but they were absent in chloroform-treated tissues. Scanning electron microscopy of tissues from animals exposed to 500 ppm SO2 showed that in the same dog tissue appearance varied from normal to one of repair (normal bioelectric properties) or one of marked exfoliation of ciliated cells (abnormal bioelectric measurements).

Nonelectrolyte permeability of canine tracheal epithelium

We examined the nonelectrolyte permeability characteristics of canine tracheal epithelium in vitro and confirmed that the transepithelial potential difference was 26.3 +/- 2.2 mV, lumen negative. Exposure of the epithelium to a sucrose osmotic load resulted in a streaming potential (SP); a linear relationship was noted between osmotic load and SP. The presence of an osmotic load did not change the short-circuit current and the SP disappeared after removal of the osmotic load. The SP developed with urea, thiourea, D-xylose, and l-glycine were similar to the SP developed for equimolar concentrations of sucrose. The urea and insulin spaces were similar magnitude. When the bulk phase was stirred at 600 rpm, the effective thickness of the unstirred water layer (UWL) external to the epithelial surface was 144 +/- 12 micron. These results support the suggestion that the Staverman reflection coefficients (sigma) of these probe molecules are similar, the estimates of sigma are valid despite the presence of an UWL, and the tracheobronchial epithelium has a pore size smaller than the hydrodynamic radius of urea.

The nonelectrolyte permeability of planar lipid bilayer membranes.

The permeability of lecithin bilayer membranes to nonelectrolytes is in reasonable agreement with Overton's rule. The is, Pd alpha DKhc, where/Pd is the permeability coefficient of a solute through the bilayer, Khc is its hydrocarbon:water partition coefficient, and D is its diffusion coefficient in bulk hydrocarbon. The partition coefficients are by far the major determinants of the relative magnitudes of the permeability coefficients; the diffusion coefficients make only a minor contribution. We note that the recent emphasis on theoretically calculated intramembranous diffusion coefficients (Dm'S) has diverted attention from the experimentally measurable and physiologically relevant permeability coefficients (Pd'S) and has obscured the simplicity and usefulness of Overton's rule.