Repopulation of the mesothelial monolayer during long-term experimental peritoneal dialysis.

Background: Repopulation of the mesothelial monolayer after focal exfoliation, having the monolayer in vivo and in situ exposed to dialysis solutions, has not been thoroughly investigated. This study describes repopulation of a 'doughnut' like mesothelial ring exfoliated from the anterior liver surface of rats.

Methods: Animals were divided into 5 groups of 20 rats each.

Osmotic agents hamper mesothelial repopulation as seen in the doughnut in vivo model.

Background: The problem of mesothelial cell injury derived from the use of peritoneal dialysis solutions has been explored deeply. Conversely, the eventual detrimental effects upon mesothelial cell regeneration have awaked less investigative efforts than those focused on injury.

Objective: To evaluate in the in vivo and in situ rat "doughnut" model of mesothelial repopulation, the eventual effect of peritoneal lavage with Hank's Balanced Salt Solution (HBSS) as well as that of 4.

A short review of experimental peritoneal sclerosis: from mice to men.

Peritoneal sclerosis has been induced in rodents in vivo by exposing the membrane to a variety of experimental interventions: asbestos, 0.1% chlorexidine, iron dextran, glucose degradation products, AGE deposits derived from uremia per se, sodium hypochlorite, lypopolysaccharide, low pH, pure water, silica or zymosan. With a few exceptions (pure water, chlorhexidine and low pH), the other substances mentioned operate setting out different degrees of oxidative stress.

Acute oxidative stress induces peritoneal hyperpermeability, mesothelial loss, and fibrosis.

We explored the acute and long-term effects of short-lived, intense oxidative stress on peritoneal permeability and structure, induced with intraperitoneal injection of the oxidant agent deoxycholate, in rats. Ten minutes after the experimental intervention, peritoneal dialysis, performed over an exposure time of 60 minutes, revealed an increased urea dialysate/plasma ratio, greater glucose absorption, increased albumin losses in the effluent dialysate, and a reduced ultrafiltration rate. Mesothelial-cell imprints taken from the anterior liver surface indicated a substantially decreased density in the cell population.

Icodextrin-induced lipid peroxidation disrupts the mesothelial cell cycle engine.

Fluids commonly used for peritoneal dialysis hold poor biocompatibility vis a vis the peritoneal membrane, basically due to the presence of osmotic agents. When rat mesothelium was exposed to glucose-enriched dialysis solutions for 2 h in vivo, an early and short-lived acceleration of cell life cycle was observed, which, after 30 d of exposure, resulted in a depopulated monolayer of senescent cells. These changes appear to result from persistent oxidative stress due to continuous exposure to high concentration of glucose and to substances generated by the Maillard reaction.

Peritoneal transport after long-term exposure to Icodextrin in rats.

Background: Icodextrin, an effective osmotic substance that has been proposed as an alternative agent for peritoneal dialysis induces ultrafiltration over long dwells. This study examines the peritoneal transport after exposure to Icodextrin in rats.

Methods: Animals were divided in 4 groups and injected daily for 30 days with Icodextrin 7.

Mesothelial dysplastic changes and lipid peroxidation induced by 7.5% icodextrin.

Background: The issue of icodextrin biocompatibility is somehow ambiguous. Whereas some experimental data point at better bicompatibility of icodextrin compared with high glucose concentration fluid, other reports showed substantial cytotoxic effects upon monocytes and cultured mesothelial cells. The present investigation exposes the first attempt to investigate the biocompatibility issue in an in vivo and in situ setup.

Protective effect of aminoguanidine upon capillary and submesothelial anionic sites.

This study evaluates albuminuria and peritoneal permeability to albumin in control and diabetic rats, as well as in diabetic animals treated with subcutaneously injected aminoguanidine hydrochloride (Ag) (5 mg/100 g/day), during a follow-up period of 6 months. Aminoguanidine effectively prevented albuminuria and albumin extravasation in the mesenteric interstitial tissue (control, 0.43 +/- 0.

High glucose accelerates the life cycle of the in vivo exposed mesothelium.

Background: Mouse mesothelium exposed in vivo for 30 days to high glucose solutions develop morphological changes that characterize a population of cells near the end of their life span.

Methods: The present study was designed to explore, in mesothelial cell imprints, whether these changes could derive from an early acceleration of the cell population life cycle in mice exposed for periods of up to 30 days to a 4.25% glucose fluid (236 mmol/L/L) prepared in Hank's balanced salt solution (HBSS).

Protective effect of pyruvate upon cultured mesothelial cells exposed to 2 mM hydrogen peroxide.

Rat peritoneal mesothelial cells in culture have the capability of generating hydrogen peroxide. Exposure of these cells to glucose-enriched, lactated-buffered fluids for peritoneal dialysis significantly increases the production of H(2)O(2). Increased liberation of oxygen radicals also involves the risk of damaging the peritoneal membrane.

High glucose induces a hypertrophic, senescent mesothelial cell phenotype after long in vivo exposure.

Previous studies, done using our mouse model for population analysis of the mesothelium, showed evidence indicating that in vivo, long-term exposure (up to 30 days) of the peritoneum to high-glucose (4.25% D-glucose) concentration dialysis solutions resulted in a hypertrophic mesothelial phenotype characterized by increased cell surface area, multinucleation, low proliferative capabilities, reduced cell viability, and enhanced enzymatic activity. These elements that define a senescent population of cells were not related to the pH of the fluid and its osmolality, or to the presence of buffer lactate.

Effect of hyperosmolality upon the mesothelial monolayer exposed in vivo and in situ to a mannitol-enriched dialysis solution.

Studies done using the in vivo mouse model of population analysis of mesothelium showed that dialysis solutions containing high concentrations of glucose induced the development of a hypertrophic phenotype. Since these changes were neither related to the low pH nor to the presence of lactate buffer, we hypothesized that the presence of glucose was at the origin of the observed alterations. Theoretical analysis of the problem points to three possible mechanisms: hyperosmolality; metabolic changes derived from the high-glucose concentration itself, and/or the presence of products derived from the nonenzymatic degradation of glucose.

Biocompatibility of a glucose-free, acidic lactated solution for peritoneal dialysis evaluated by population analysis of mesothelium.

Glucose-enriched, racemic lactate buffered solutions for peritoneal dialysis induce a significant reduction of cell viability as well as a hypertrophic, senescent phenotype of the exposed monolayer. The present study was designed to verify whether the aforementioned changes resulted form the buffer, from the osmotic agent, or from a combined effect of both. Mice were acutely (2 h) and long-term (15 and 30 days) exposed to daily intraperitoneal injections of a racemic lactate, heat-sterilized, low-pH (5.

Population analysis of mesothelium in situ and in vivo exposed to bicarbonate-buffered peritoneal dialysis fluid.

Population analysis of mesothelium (PAM) done using the in vivo and almost in situ technique of mesothelial cell imprints revealed that lactate-buffered solutions had detrimental effects upon cell viability, that high glucose concentration affected cytokinesis, whereas the association of both components led to a decreased density population of cells showing a larger surface area. In the present study, PAM was done on mesothelium of mice exposed to bicarbonate-buffered peritoneal dialysis fluid (BBF) with glucose concentrations of 1.5 and 4.

The cytochemical profile of visceral mesothelium under the influence of lactated-hyperosmolar peritoneal dialysis solutions.

Male albino mice had one daily intraperitoneal injection of 4.25 g/100 ml glucose concentration fluid for peritoneal dialysis at pH 5.0-5.