Siska Mortier

Effects of Conventional and New Peritoneal Dialysis Fluids on Leukocyte Recruitment in the Rat Peritoneal Membrane

Peritonitis remains an important cause of morbidity and technique failure in peritoneal dialysis (PD). Conventional peritoneal dialysate fluids (PDF) inhibit peritoneal leukocyte function in vitro and may thus adversely affect the immune response to peritonitis. New PDF have been designed with neutral pH, low glucose degradation product (GDP) contents, and bicarbonate as buffer. The present intravital microscopy study examined the effects of conventional and new PDF on leukocyte behavior in the peritoneal microcirculation of Wistar rats. The visceral peritoneum was superfused by a control solution (EBSS), a conventional (CAPD), or a new bicarbonate-buffered PDF with neutral pH and low GDP content (CAPD BicaVera). In addition, spent conventional and new PDF were tested. The number of rolling, adhering, and extravasated leukocytes and leukocyte rolling velocity were assessed at different time intervals after exposure to lipopolysaccharide (LPS) or cell-free supernatants of coagulase-negative staphylococci (CNS-CFS). Exposure to LPS or CNS-CFS dissolved in EBSS dramatically increased the number of rolling, adhering and extravasated leukocytes and decreased leukocyte rolling velocity. Superfusion by CAPD abolished the LPS- or CNS-CFS-induced leukocyte recruitment, whereas CAPD BicaVera had significantly fewer depressant effect. Spent PDF affected the leukocyte response in a similar way as fresh PDF. High lactate concentrations, GDP, and hypertonicity appeared to be mainly responsible for the inhibition of leukocyte recruitment. In conclusion, conventional PDF abolish in vivo leukocyte recruitment in response to potent inflammatory stimuli. Bicarbonate-buffered pH-neutral PDF with low GDP contents have fewer depressant effects and may therefore contribute to a better preservation of peritoneal host defense.

Endothelium-Derived Hyperpolarizing Factor–Mediated Renal Vasodilatory Response Is Impaired During Acute and Chronic Hyperhomocysteinemia

Background—Endothelial dysfunction is an early event in the development of vascular complications in hyperhomocysteinemia. Endothelial cells release a number of vasodilators, including NO and prostacyclin. Several lines of evidence have indicated the existence of a third vasodilator pathway, mediated by endothelium-derived hyperpolarizing factor (EDHF). EDHF is a major determinant of vascular tone in small resistance vessels. The influence of hyperhomocysteinemia on EDHF is unknown. The present in vivo study evaluates the integrity of the EDHF pathway in the renal microcirculation of rats with acute and chronic hyperhomocysteinemia. Methods and Results—EDHF-mediated vasodilation was evaluated as the renal blood flow (RBF) response to intrarenal acetylcholine during systemic NO synthase and cyclooxygenase inhibition. Acute hyperhomocysteinemia induced by intravenous homocysteine did not affect EDHF-mediated vasodilation. In contrast, intravenous methionine with subsequent hyperhomocysteinemia impaired the EDHF-mediated RBF response. When the methionine infusion was preceded by adenosine periodate oxidized to prevent the cleavage of S-adenosylhomocysteine to homocysteine and adenosine, a similar impairment of EDHF was observed, but with normal homocysteine levels. Animals with chronic hyperhomocysteinemia induced by a high-methionine, low–B vitamin diet during 8 weeks had a severely depressed EDHF-mediated vasodilation compared with those on a standard diet. Endothelium-independent vasodilation to deta-NONOate and pinacidil was not affected in acute and chronic hyperhomocysteinemia, demonstrating intact vascular smooth muscle reactivity. Conclusions—EDHF-dependent responses are impaired in the kidney of hyperhomocysteinemic rats. Because EDHF is a major regulator of vascular function in small vessels, these findings have important implications for the development of microangiopathy in hyperhomocysteinemia.

Increased angiogenesis and permeability in the mesenteric microvasculature of rats with cirrhosis and portal hypertension: an in vivo study

Abstract: Background: In vivo evidence for angiogenesis in the splanchnic vasodilation in portal hypertension (PHT) and cirrhosis is lacking. Vascular endothelial growth factor (VEGF) and endothelial nitric oxide synthase (eNOS) are mediators of angiogenesis. The present study visualises in vivo structural changes (angiogenesis and vascular hyperpermeability) and examines the presence of VEGF and eNOS in the mesenteric microvasculature of animal models of PHT with and without cirrhosis.

Recent Concepts in the Molecular Biology of the Peritoneal Membrane – Implications for More Biocompatible Dialysis Solutions

This paper reviews some important recent findings on the molecular biology of the peritoneal membrane. It attempts to correlate in vitro and in vivo experimental results with the possible clinical consequences. The most common functional alteration during long-term CAPD is increased peritoneal small-solute transport rate, resulting in impaired ultrafiltration and decreased dialysis efficiency. This contribution first discusses the most relevant advances in the biochemistry and molecular biology of the peritoneal membrane following peritonitis and as consequence of the continuous exposure to unphysiological dialysis fluids. In a second part the preliminary experimental and clinical experience with more biocompatible fluids is summarized. The most relevant structural and functional alterations of the membrane following repeated peritonitis is the consequence of the response of the peritoneum to infective organisms involving the inflammatory cytokines and the interaction between membrane resident cell populations: macrophages, mesothelial cells and fibroblasts. In this setting, human biopsy studies and animal experiments have identified an increase in the peritoneal-associated vasculature, which seems to be the primary cause of increased solute transport. The structural and functional alterations in the membrane in long-term peritoneal dialysis are thought to be the consequence of the toxicity of glucose, either directly or indirectly through the generation of glucose degradation products or the formation of advanced glycation end-products. In particular, an important role for vascular endothelial growth factor and nitric oxide as downstream mediators of the alterations has been suggested. Finally, the last part of this paper reviews the actual and future research aimed at an amelioration of the biocompatibility of the dialysis fluids. Replacing glucose by other osmotic agents, changing the sterilization process, replacing the lactate buffer by bicarbonate, blocking the formation of reactive carbonyl products and of the neoangiogenesis are the most promising changes to enhance the biocompatibility. Finally, gene therapy may in the future have an important contribution. Ex vivo gene therapy involves harvesting peritoneum samples to isolate mesothelial cells that will be genetically modified before re-implantation into the peritoneal cavity.

Effects of new peritoneal dialysis solutions on leukocyte recruitment in the rat peritoneal membrane.

Objectives: Peritonitis remains a principal cause of dropout in peritoneal dialysis (PD). The physiological host response to a peritoneal infection involves a rise in numbers of circulating leukocytes to the peritoneal cavity. We evaluated the effects of (1) conventional peritoneal dialysis fluid (PDF), (2) bicarbonate-based PDF, low in glucose degradation products, and (3) non-glucose PDF on peritoneal leukocyte recruitment in response to an inflammatory stimulus using intravital microscopy. Methods: The visceral peritoneum was exposed to EBSS, conventional lactate-buffered and bicarbonate/lactate-buffered glucose-based PDF and three lactate-buffered non-glucose PDF – icodextrin, amino acid-based PDF and amino acid/glycerol-based PDF. The number of rolling, adhering and extravasated leukocytes and leukocyte rolling velocity was assessed at different time intervals after stimulation with lipopolysaccharide (LPS). Results: Exposure to LPS dissolved in EBSS dramatically increased the number of rolling, adhering and extravasated leukocytes and decreased leukocyte rolling velocity. Conventional PDF completely abolished LPS-induced leukocyte recruitment. Bicarbonate/lactate-buffered PDF only minimally affected the process of leukocyte recruitment, whereas icodextrin PDF resulted in partial inhibition of the immune response. The amino acid-based and the amino acid/glycerol-based PDF inhibited leukocyte recruitment to a similar extent as conventional PDF. Conclusions: Bicarbonate/lactate-buffered PDF has superior biocompatibility towards peritoneal host defense, in spite of its high glucose concentrations. Lactate-buffered non-glucose containing PDF has substantial inhibitory effects on leukocyte recruitment, indicating that the bioincompatibility of high lactate concentrations and/or low pH may not be underestimated.

Effects of Peritoneal Dialysis on the Vascular Bed of Peritoneal Membrane

The vascularization of the peritoneal membrane is a key factor in the effectiveness of peritoneal dialysis as a dialysis modality. Over the last years, our understanding of how the peritoneal vasculature reacts to instillation of peritoneal dialysate has substantially improved. The changes in the structure of the peritoneal function over time on peritoneal dialysis as found in functional tests has been confirmed in biopsy studies performed on patients. These show both neoangiogenesis and fibrosis as the underlying morphological changes contributing to these phenomena. A thorough understanding of the biological processes involved in these alterations will be the clue for improvement of the treatment and a key to develop strategies to avoid these deformations.