Treatment with the biocompatible polysulfone SF dialyser seems to be better suited to lower serum AGE levels and to eliminate their precursors.
The effect of peritoneal dialysate on the capacity of peripheral blood polymorphonuclear (PMNL) and mononuclear leukocytes (MNC) to release leukotriene B4 (LTB4) and tumor necrosis factor alpha (TNFα) was investigated in vitro. Following density gradient separation, aliquots of 5 × 106 PMNL or MNC were incubated in peritoneal dialysis fluid containing 1.5% glucose or Hanks’ buffer ( = control) for 1–2 h at 37°C. TNFα and LTB4 production was stimulated with Escherichia coli lipopolysaccharide (LPS) and calcium ionophore A23187, respectively. MNC incubated in buffer and LPS produced (mean ± SD) 1,006 ± 522 pg TNFα/5 × 106 cells; no significant amounts of TNFα were detectable in the presence of dialysate. An inhibition of TNFα release was also observed in MNC exposed to bicarbonate-buffered dialysates (pH 7.40) and 4.25% and 1.5% glucose solution with physiologic osmolality. Incubation of PMNL in Hanks’ buffer followed by A23187 stimulation led to production of 29.1 ± 19.2 ng LTB4/5 × 106 cells, whereas glucose-incubated cells were refractory to ionophore stimulation ( < 0.l ng LTB4/5 × 106 cells). The failure of dialysate-exposed leukocytes to release inflammatory mediators in response to adequate stimuli may contribute to the impairment of cellular host defense in the setting of continuous ambulatory peritoneal dialysis.
In patients on continuous ambulant peritoneal dialysis (CAPD) treatment, the peritoneal membrane is continuously exposed to the high glucose concentration contained in the dialysate. This may lead to the local generation of advanced glycation end-products (AGEs). To test this hypothesis we evaluated the plasma and dialysate AGE concentrations in five CAPD patients. The dialysate was measured after a 1 h and after a 12 h dwell time. Additionally, in two patients an immunohistochemical investigation of the peritoneal membrane for AGE was performed. For the determination of AGE an ELISA using a polyclonal antibody against AGE bovine serum albumin was used; the immunohistochemical staining was performed using the streptavidin-biotin complex method. We found only low concentrations of AGE in the dialysate after a 1 h dwell time; after 12 h, however, the dialysate AGE was even greater than the plasma concentration. In both peritoneal specimens we found positive staining for AGE in the interstitium of the mesothelial layer. The dialysate AGE contained a high proportion of high-molecular-weight AGE proteins and low-molecular-weight AGE was found to be in the same concentration range as the total serum AGE. We conclude that there is local generation of AGE in the peritoneal membrane and a 'washing out' of AGE from the peritoneal membrane during longer dwell times. We speculate that the accumulation of AGE might lead to some of the functional and morphological alterations observed after long-term CAPD.
A new peritoneal dialysate containing pyruvate anions has been tested for its effects on cell functions and compared with conventional lactate and bicarbonate based solutions. The dialysate has a final pH of 5.4 to 5.6 and is composed of 1.36 to 3.86% glucose-monohydrate, 132 mmol/liter sodium, 1.75 mmol/liter calcium, 0.75 mmol/liter magnesium, 102 mmol/liter chloride and 35 mmol/liter pyruvate. For cytotoxicity testing peritoneal macrophages and peripheral blood mononuclear cells (PBMC) were exposed to conventional lactate dialysate, pyruvate dialysate, bicarbonate dialysate and a control medium RPMI 1640 (Biochrom KG, Berlin, Germany), followed by activation with different bacterial stimuli. In addition, the study further investigated the effect of varying glucose concentration in the different dialysates ranging from 0 to 3.86% and pH changes between 5.2 and 7.4 on the cytotoxicity effect on the selected cells. Mononuclear cells exposed to pyruvate-based dialysate before stimulation with endotoxin exhibited a tumor necrosis factor (TNF)-mRNA signal comparable to those of cells exposed to RPMI. In contrast, exposure to lactate-based dialysate completely inhibited TNF-mRNA synthesis. In addition, cytokine synthesis in macrophages and PBMCs after exposure to pyruvate was less inhibited when compared to the corresponding levels measured after exposure to lactate. The chemotactic response of polymorphonuclear cells and O-2 generation in all tested cell types after exposure to pyruvate was found not to be inhibited, whereas a complete inhibition was observed after exposure to lactate. The results demonstrate that cytotoxicity effects of peritoneal dialysate on cell lines can be minimized by using a new dialysate formulation containing pyruvate anions instead of lactate.
Toxic effects of commercially available peritoneal dialysate (PD) fluid include damage to mesothelial cells (MC), causing a severely disturbed proliferation of cultured MC. We investigated the injury to the cell membrane (by release of lactate dehydrogenase, LDH), the proliferation (by cell counts and by 3H-thymidine incorporation), and optional the cytokine generation (by IL-1 receptor-antagonist production, IL-1 ra) of cultured human MC during the 48 hours after a 30 minute exposure to PD containing either 35 mmol/liter sodium lactate or sodium pyruvate. All solutions had a pH of 5.2 to 5.6 and were composed as standard PD. Glucose contents of 1.36 and 3.86 mmol/liter were tested. After exposure to the lactate-PD containing 1.36% glucose, LDH activity was increased by more than 30%, proliferation of MC was inhibited by more than 30%, and IL-1 ra production was reduced significantly when compared to pyruvate-PD and the control solution. After preincubation with 3.86% glucose containing PD, all negative effects became even more pronounced in the lactate group whereas the MC maintained their integrity, rate of proliferation and IL-1 ra release after pre-exposure to pyruvate containing PD. These results suggest that the acute toxic effects of commercially available PD on the integrity, proliferation and IL-1 ra production of MC can be avoided by the use of sodium pyruvate instead of sodium lactate.
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