Hyperosmolality-mediated peritoneal microvascular vasodilation is linked to aquaporin function.

Glucose-based peritoneal dialysis (PD) solutions dilate the parietal and visceral peritoneal microvasculature by endothelium-dependent mechanisms that primarily involve hyperosmolality. This PD-mediated dilation occurs by active intracellular glucose uptake and adenosine Al receptor activation, and by hyperosmolality-stimulated glibenclamide-sensitive potassium channels. Both pathways invoke NO as a second messenger for vasodilation. We hypothesized that during crystalloid-induced osmosis, the osmotic water flux through the transendothelial water-exclusive aquaporin 1 (AQP1) channels is the primary mechanism whereby the endothelium is being stimulated to instigate hyperosmolality-driven vasodilation. Four microvascular levels (diameters in the range 6 - 100 microm) were visualized by intravital videomicroscopy of the terminal ileum in anesthetized rats. Microvascular diameters and flow were measured after topical exposure to a 5% hypertonic mannitol or 2.5% glucose-based PD solution, at baseline and after brief tissue pre-treatment (with 0.1% glutaraldehyde for 10 seconds) or after combined tissue pre-treatment and pharmacologic blockade of AQP1 with HgCl2 (100 micromol/L). Vascular endothelial integrity was verified by the response to acetylcholine (10(-4) mol/L) and sodium nitroprusside (10(-4) mol/L). The hyperosmolar solutions both caused rapid and sustained vasodilation at all microvascular levels, which was not altered by tissue pre-treatment. Inhibition of AQP1 completely abolished the mannitol-induced vasodilation and markedly attenuated the PD fluid-mediated vasodilation. Neither glutaraldehyde pre-treatment nor HgCl2 affected tissue integrity or endothelial cell function. We conclude that the peritoneal microvascular vasodilation caused by hyperosmolar PD fluid is instigated by the osmotic water flux through AQP1. Clinical PD solutions have components other than hyperosmolality that can induce endothelium-dependent peritoneal microvascular vasodilation independent of the AQP1-mediated osmosis.

Molecular mechanisms of peritoneal dialysis-induced microvascular vasodilation.

Peritoneal dialysis (PD) solutions dilate microvessels by undefined mechanisms. This vasodilation directly affects ultrafiltration and solute exchange during a PD dwell and is thought to account for the variable mass transfer area coefficient for small solutes during a glucose-based hypertonic dwell. We hypothesized that PD-mediated vasodilation occurs by endothelium-dependent mechanisms that involve endothelium energy-dependent K+ channels (K(ATP)), adenosine A1 receptor activation, and NO release. We used intravital videomicroscopy to study 3 levels of microvessels (A1 inflow arterioles about 100 microm diameter to pre-capillary A3 arterioles 10 - 15 microm diameter) in the terminal ileum of anesthetized rats under control conditions in vivo in a tissue bath. Ileum was bathed with hypertonic mannitol or 2.5% glucose-based PD solution (Delflex: Fresenius Medical Care North America, Waltham, MA, U.S.A.) with or without topical application of individual or combined specific inhibitors of the endothelium-dependent dilation pathways.: NO (L-NMMA), prostaglandin I2 (mefenamic acid), endothelium hyperpolarizing factor (glibenclamide), and adenosine A1 receptor antagonist (DPCPX). The mannitol and PD solutions induced rapid and sustained peritoneal vasodilation whose magnitude depended on microvascular level and osmotic solute. Combined inhibition of endothelium-dependent dilation pathways completely abolished the mannitol-induced hyperosmolality-mediated dilation at all microvascular levels, but selectively eliminated the PD solution-mediated A3 dilation. The K(ATP) and adenosine receptor antagonists, individually or combined, remarkably attenuated dilation in the smaller pre-capillary arterioles; NO inhibition, alone or combined with K(ATP) and adenosine receptor antagonists, eliminated the PD solution-induced dilation. The cyclooxygenase pathway is not involved in PD-induced dilation. Solutions for PD dilate the visceral peritoneal microvasculature by endothelium-dependent mechanisms, primarily the NO pathway. Adenosine receptor-activated NO release and K(ATP) channel-mediated endothelium hyperpolarization significantly contribute to vasodilation in the smaller peritoneal pre-capillary arterioles.