Ma Bajo

Epithelial-to-mesenchymal transition of mesothelial cells is an early event during peritoneal dialysis and is associated with high peritoneal transport.

Ultrafiltration (UF) failure is a consequence of long-term peritoneal dialysis (PD). Fibrosis, angiogenesis, and vasculopathy are causes of this functional disorder after 3-8 years on PD. Epithelial-to-mesenchymal transition (EMT) of mesothelial cell (MC) is a key process leading to peritoneal fibrosis with functional deterioration. Our purpose was to study the peritoneal anatomical changes during the first months on PD, and to correlate them with peritoneal functional parameters. We studied 35 stable PD patients for up to 2 years on PD, with a mean age of 45.3+/-14.5 years. Seventy-four percent of patients presented loss of the mesothelial layer, 46% fibrosis (>150 microm) and 17% in situ evidence of EMT (submesothelial cytokeratin staining), which increased over time. All patients with EMT showed myofibroblasts, while only 36% of patients without EMT had myofibroblasts. The number of peritoneal vessels did not vary when we compared different times on PD. Vasculopathy was present in 17% of the samples. Functional studies were used to define the peritoneal transport status. Patients in the highest quartile of mass transfer area coefficient of creatinine (Cr-MTAC) (>11.8 ml min(-1)) showed significantly higher EMT prevalence (P=0.016) but similar number of peritoneal vessels. In the multivariate analysis, the highest quartile of Cr-MTAC remained as an independent factor predicting the presence of EMT (odds ratio 12.4; confidence interval: 1.6-92; P=0.013) after adjusting for fibrosis (P=0.018). We concluded that, during the first 2 PD years, EMT of MCs is a frequent morphological change in the peritoneal membrane. High solute transport status is associated with its presence but not with increased number of peritoneal vessels.

Cyclooxygenase-2 Mediates Dialysate-Induced Alterations of the Peritoneal Membrane

During peritoneal dialysis (PD), exposure of the peritoneal membrane to nonphysiologic solutions causes inflammation, ultimately leading to altered structure and function. Myofibroblasts, one of the cell types that contribute to dysfunction of the peritoneal membrane, can originate from mesothelial cells (MCs) by epithelial-to-mesenchymal transition (EMT), a process that has been associated with an increased rate of peritoneal transport. Because cyclooxygenase-2 (COX-2) is induced by inflammation, we studied the role of COX-2 in the deterioration of the peritoneal membrane. We observed that nonepithelioid MCs found in peritoneal effluent expressed higher levels of COX-2 than epithelioid MCs. The mass transfer coefficient for creatinine correlated with MC phenotype and with COX-2 levels. Although COX-2 was upregulated during EMT of MCs in vitro, COX-2 inhibition did not prevent EMT. In a mouse model of PD, however, COX-2 inhibition with Celecoxib resulted in reduced fibrosis and in partial recovery of ultrafiltration, outcomes that were associated with a reduction of inflammatory cells. Furthermore, PD fluid with a low content of glucose degradation products did not induce EMT or COX-2; the peritoneal membranes of mice treated with this fluid showed less worsening than mice exposed to standard fluid. In conclusion, upregulation of COX-2 during EMT may mediate peritoneal inflammation, suggesting COX-2 inhibition as a potential strategy to ameliorate peritoneal deterioration in PD patients.

Peritoneal dialysis solutions inhibit the differentiation and maturation of human monocyte-derived dendritic cells: effect of lactate and glucose-degradation products

Peritoneal dialysis (PD) is a well‐established therapy for end‐stage renal failure, but its efficiency is limited by recurrent peritonitis. As PD solutions impair local inflammatory responses within the peritoneal cavity, we have analyzed their influence on the in vitro maturation of human monocyte‐derived dendritic cells (MDDC). Evaluation of MDDC maturation parameters [expression of adhesion and costimulatory molecules, receptor‐mediated endocytosis, allogeneic T cell activation, production of tumor necrosis factor α, interleukin (IL)‐6 and IL‐12 p70, and nuclear factor (NF)‐κB activation] revealed that currently used PD solutions differentially inhibit the lipopolysaccharide (LPS)‐induced maturation of MDDC, an inhibition that correlated with their ability to impair the LPS‐stimulated NF‐κB activation. Evaluation of PD components revealed that sodium lactate and glucose‐degradation products impaired the acquisition of maturation parameters and NF‐κB activation in a dose‐dependent manner. Moreover, PD solutions impaired monocyte‐MDDC differentiation, inhibiting the acquisition of DC markers such as CD1a and DC‐specific intercellular adhesion molecule‐3 grabbing nonintegrin (CD209). These findings have important implications for the initiation of immune responses under high lactate conditions, such as those occurring within tumor tissues or after macrophage activation.

IL-17A is a novel player in dialysis-induced peritoneal damage

The classical view of the immune system has changed by the discovery of novel T-helper (Th) subsets, including Th17 (IL-17A-producing cells). IL-17A participates in immune-mediated glomerulonephritis and more recently in inflammatory pathologies, including experimental renal injury. Peritoneal dialysis patients present chronic inflammation and Th1/Th2 imbalance, but the role of the Th17 response in peritoneal membrane damage has not been investigated. In peritoneal biopsies from dialyzed patients, IL-17A immunostaining was found mainly in inflammatory areas and was absent in the healthy peritoneum. IL-17A-expressing cells included lymphocytes (CD4+ and γδ), neutrophils, and mast cells. Elevated IL-17A effluent concentrations were found in long-term peritoneal dialysis patients. Studies in mice showed that repeated exposure to recombinant IL-17A caused peritoneal inflammation and fibrosis. Moreover, chronic exposure to dialysis fluids resulted in a peritoneal Th17 response, including elevated IL-17A gene and protein production, submesothelial cell infiltration of IL-17A-expressing cells, and upregulation of Th17 differentiation factors and cytokines. IL-17A neutralization diminished experimental peritoneal inflammation and fibrosis caused by chronic exposure to dialysis fluids in mice. Thus, IL-17A is a key player of peritoneum damage and it may be a good candidate for therapeutic intervention in peritoneal dialysis patients.

Are low concentrations of serum triiodothyronine a good marker for long-term mortality in hemodialysis patients?

INTRODUCTION Low serum free triiodothyronine (FT3) concentrations have been reported in a high percentage of chronic renal failure patients and have been considered as an independent predictor of mortality in dialysis patients. OBJECTIVE Our aim has been to evaluate the prognostic value of FT3 levels for long-term mortality in stable hemodialysis patients surviving at least 12 months. PATIENTS AND MEASUREMENTS We retrospectively analyzed 89 stable hemodialysis patients (50 males; mean age 67.9 +/- 11.8 years). All patients had a baseline clinical and analytical evaluation. We analyzed the relationship between baseline FT3 and mortality by means of survival analysis (Kaplan-Meier) and Cox regression analysis. RESULTS Mean values of thyroid function test were: thyrotropin (TSH) 2.02 +/- 1.5 microU/ml, free thyroxine (FT4) 1.26 +/- 0.23 ng/dl, and FT3 2.7 +/- 0.4 pg/ml. During a median follow-up time of 33.6 +/- 14.9 (12 - 62) months, 41 patients died. FT3 was similar in patients who died or survived (2.6 +/- 0.5 vs. 2.7 +/- 0.4 pg/ml ns). Kaplan-Meier analysis did not show significant differences in mean survival according to tertiles of FT3. In multivariate Cox regression analysis, FT3 was not a predictor of mortality (RR 0,001; 95% CI; 0.000 to 1.73). CONCLUSIONS These data suggest that low FT3 levels are not predictive for mortality in a subgroup of stable HD patients who could survive more than 12 months.

Myofibroblastic differentiation in simple peritoneal sclerosis

Objective To analyze the presence of myofibroblasts in a series of peritoneal dialysis (PD) patients with simple sclerosis and non-PD, uremic patients. Since there is a close correlation between active fibrosis and myofibroblastic differentiation we wanted to test if myofibroblasts are present in uremic, non-PD peritoneal samples. To determine if there are correlations between myofibroblastic presence and other functional and morphologic peritoneal parameters. Methods Biopsies were collected from three patient groups: 1) Normal control samples (n=15) of parietal and visceral peritoneum 2) non-PD uremic patients (n=16); and 3) uremic patients on PD (n=32). Peritoneal morphologic and functional parameters and immunohistochemical expression of α-smooth muscle actin was analyzed in each case. Vascular endothelial growth factor (VEGF), bcl-2 anti-apoptotic protein, and progesterone receptor was evaluated in a subset of cases. Results Myofibroblasts were present in 56.3% of the patients with PD-related simple sclerosis. In most cases they were distributed in the upper submesothelial area. None of the biopsies from normal controls and uremic, non-PD patients showed myofibroblasts. Within the group of PD patients, myofibroblasts showed no correlation with time on dialysis, urea/creatinine MTAC, episodes of peritonitis, submesothelial thickening, hyalinizing vasculopathy or mesothelial status. In a subset of PD patients VEGF expression was observed in submesothelial fibroblastic cells. No expression of progesterone receptor or bcl-2 was observed. Conclusions Myofibroblasts are a reliable and simple indicator of fibrosis since they appear in early stages of PD treatment and in patients with minor morphologic anomalies. They are not exclusive of patients with sclerosing peritonitis, ultrafiltration loss or long standing treatment. Their absence in non-PD, uremic patients suggest that uremia-related fibrosis takes place without a significant participation of myofibroblasts.

Preventing peritoneal membrane fibrosis in peritoneal dialysis patients.

Long-term peritoneal dialysis causes morphologic and functional changes in the peritoneal membrane. Although mesothelial-mesenchymal transition of peritoneal mesothelial cells is a key process leading to peritoneal fibrosis, and bioincompatible peritoneal dialysis solutions (glucose, glucose degradation products, and advanced glycation end products or a combination) are responsible for altering mesothelial cell function and proliferation, mechanisms underlying these processes remain largely unclear. Peritoneal fibrosis has 2 cooperative parts, the fibrosis process itself and the inflammation. The link between these 2 processes is frequently bidirectional, with each one inducing the other. This review outlines our current understanding about the definition and pathophysiology of peritoneal fibrosis, recent studies on key fibrogenic molecular machinery in peritoneal fibrosis, such as the role of transforming growth factor-β/Smads, transforming growth factor-β β/Smad independent pathways, and noncoding RNAs. The diagnosis of peritoneal fibrosis, including effluent biomarkers and the histopathology of a peritoneal biopsy, which is the gold standard for demonstrating peritoneal fibrosis, is introduced in detail. Several interventions for peritoneal fibrosis based on biomarkers, cytology, histology, functional studies, and antagonists are presented in this review. Recent experimental trials in animal models, including pharmacology and gene therapy, which could offer novel insights into the treatment of peritoneal fibrosis in the near future, are also discussed in depth.

Actinomyces peritonitis: removal of the peritoneal catheter unnecessary for resolution

Peritonitis is one of the most frequent complications in peritoneal dialysis (PD) patients. Most of them have a bacterial origin, especially gram-positive microorganisms. Actinomyces peritonitis is rare in PD patients, in spite of being part of the normal flora in the oral cavity, gastrointestinal and genital tracts [1]. Actinomyces is a filamentous gram-positive bacterium that lives in aerobic and anaerobic conditions [1]. It has a low virulence potential, usually causing opportunistic diseases. Factors that predispose towards abdominal Actinomyces infections include surgery, trauma, neoplasia or a perforated viscus. Penicillin is still the treatment of choice, but there are other effective antibiotics, such as erythromycin, clindamycin or tetracycline [2]. Actinomyces israelii is the major human pathogen of this species. We report a peritoneal infection due to Actinomyces neuii, a microorganism firstly described in 1985. In the present case, the removal of the catheter was not necessary for healing, unlike other cases published in the literature.