Peritoneal dialysis fluid bioincompatibility and new vessel formation promote leukocyte-endothelium interactions in a chronic rat model for peritoneal dialysis.

Peritoneal dialysis (PD)-induced peritonitis leads to dysfunction of the peritoneal membrane. During peritonitis, neutrophils are recruited to the inflammation site by rolling along the endothelium, adhesion, and transmigration through vessel walls. In a rat PD-model, long-term effects of PD-fluids (PDF) on leukocyte-endothelium interactions and neutrophil migration were studied under baseline and inflammatory conditions. Rats received daily conventional-lactate-buffered PDF (Dianeal), bicarbonate/lactate-buffered PDF (Physioneal) or bicarbonate/lactate buffer (Buffer) during five weeks. Untreated rats served as control. Baseline leukocyte rolling and N-formylmethionyl-leucyl-phenylalanine (fMLP) induced levels of transmigration in the mesentery were evaluated and quantified by intra-vital videomicroscopy and immunohistochemistry. Baseline leukocyte rolling was unaffected by buffer treatment, approximately 2-fold increased after Physioneal and 4-7-fold after Dianeal treatment. After starting fMLP superfusion, transmigrated leukocytes appeared outside the venules firstly after Dianeal treatment (15 minutes), thereafter in Physioneal and Buffer groups (20-22 minutes), and finally in control rats (>25 minutes). Newly formed vessels and total number of transmigrated neutrophils were highest in Dianeal-treated animals, followed by Physioneal and Buffer, and lowest in control rats and correlated for all groups to baseline leukocyte rolling (r = 0.78, P < 0.003). This study indicates that the start of inflammatory neutrophil transmigration is related to PDF bio(in)compatibility, whereas over time neutrophil transmigration is determined by the degree of neo-angiogenesis.

Low arginine/asymmetric dimethylarginine ratio deteriorates systemic hemodynamics and organ blood flow in a rat model.

OBJECTIVE: Both arginine and asymmetric dimethylarginine (ADMA) play a crucial role in the arginine-nitric oxide pathway. Low arginine and high ADMA levels can be found in critically ill patients after major surgery. The aim of this study was to evaluate the effects of low arginine plasma concentrations in combination with high ADMA plasma concentrations on hemodynamics and organ blood flow. DESIGN: Randomized, placebo-controlled animal laboratory investigation. SUBJECTS: Male Wistar rats (n = 21), anesthetized. INTERVENTIONS: Rats were randomly assigned to three groups: a control group, an ADMA group, or an arginase (ASE)/ADMA group. In the control group, rats received (at t = 0) an intravenous (IV) infusion of 1.5 mL 0.9% NaCl during a 20-minute period. After 60 minutes (t = 60), rats received an IV bolus of 1.0 mL 0.9% NaCl. In the ADMA group, rats received an IV infusion of 1.5 mL 0.9% NaCl during a 20-minute period and at t = 60 an IV bolus of 1.0 mL ADMA (20 mg/kg). In the ASE/ADMA group, rats received an IV infusion of 1.5 mL ASE (3200 IU) solution during a 20-minute period and at t = 60 an IV bolus of 1.0 mL ADMA (20 mg/kg). MEASUREMENTS AND MAIN RESULTS: Infusion of ADMA (20 mg/kg) and ASE (3200 IU) resulted in increased plasma ADMA levels and decreased arginine levels. During the whole experiment, systemic hemodynamics (heart rate, mean arterial pressure [MAP], and cardiac output) were measured. In addition, organ blood flow was measured at t = 90 and t = 180 minutes, using fluorescent microspheres. Compared with the control group, MAP and systemic vascular resistance were increased after infusion of ADMA. Infusion of ASE in combination with ADMA significantly deteriorated systemic hemodynamics (MAP, cardiac output, stroke volume, and systemic vascular resistance) and organ blood flow through the kidney and spleen. In addition, an initial decrease in arterial flow, followed by a later major increase, and panlobular apoptosis and necrosis of the liver was observed. CONCLUSIONS: The current study shows that low arginine plasma levels in combination with high ADMA plasma levels deteriorates systemic hemodynamics and reduces blood flow through the kidney and spleen and liver. These data suggest that a diminished nitric oxide production may be involved in the onset of organ failure.

Mechanisms of the urinary concentration defect and effect of desmopressin during endotoxemia in rats.

Acute renal failure during human sepsis is often nonoliguric. To study the underlying mechanisms, renal function was assessed in endotoxic and control male Wistar rats during and after saline loading and treatment with the selective V2 receptor agonist desmopressin. Escherichia coli endotoxin (dose, 8 mg/kg) was administered from time (t)=0 to t=60 min; saline loading (rate, 5 mL/100 g per hour) was administered from t=0 to t=120 min. Thereafter, half of each group received desmopressin (dose, 10 microg) for 1 h. The inner medullary (IM) osmolality, hematocrit, plasma, and urinary concentrations of sodium, potassium, urea, and osmolality were measured; then, aquaporin 2 (AQP2) immunohistochemistry was performed. Plasma vasopressin concentrations were measured at t=180 min. Saline loading increased urine volume in all rats. In the endotoxic group, mean arterial pressure decreased when saline loading was stopped. Despite increased hematocrit and vasopressin levels (>16 pg/mL), the endotoxin group had a low IM osmolality (mean +/- SEM, 412+/-0.04 mOsm/kg H2O) in comparison with the control group (mean +/- SEM, 1,094+/-0.17 mOsm/kg H2O) and was not able to either decrease urine volume or raise urine osmolality. Desmopressin treatment in endotoxin-treated rats maintained mean arterial pressure, increased sodium reabsorption, IM osmolality, and urine osmolality, and decreased urine flow. The AQP2 intensity decreased in the endotoxin group, and the apical localization disappeared; both were not affected by desmopressin. Our results indicate that endotoxemia in rats acutely diminishes renal urinary concentration capacity and is associated with a decreased IM osmolality and diminished apical AQP2 localization. These findings may help to explain nonoliguric acute renal failure in human septic shock.

Renal microvascular constriction to membrane depolarization and other stimuli: pivotal role for rho-kinase.

Contraction of vascular smooth muscle is determined not only by levels of intracellular free calcium but also by the sensitivity of its contractile apparatus. A potential modulator of the latter is rho-kinase. We addressed the question of a possible central role for rho-kinase in the regulation of periglomerular microvascular tone. In the rat hydronephrotic kidney model, diameter changes of distal interlobular arteries, afferent and efferent arterioles were measured using three distinctly different stimuli: intravascular pressure changes, angiotensin II (AngII) and membrane depolarization, which is a physiological component of many signaling pathways, as evoked in two ways. Two selective, structurally different rho-kinase inhibitors, Y-27632 and HA-1077, were employed, as well as a selective protein kinase C alpha inhibitor. Preglomerular vasoconstriction induced by direct membrane depolarization, increases in pressure or AngII all depended for their effect on rho-kinase. A differing role for rho-kinase in efferent arteriolar constriction to AngII as compared to preglomerular microvessels was not found. In conclusion, our data indicate that in the kidney, rho-kinase is involved in a variety of signaling pathways leading to microvascular constriction. It plays a pivotal role not only in preglomerular but also in postglomerular tone.

Beneficial effects of aminoguanidine on peritoneal microcirculation and tissue remodelling in a rat model of PD.

BACKGROUND: The formation of glucose degradation products (GDPs) and accumulation of advanced glycation end products (AGEs) partly contribute to the bioincompatibility of peritoneal dialysis fluids (PDF). Aminoguanidine (AG) scavenges GDPs and prevents the formation of AGEs. METHODS: In a peritoneal dialysis (PD) rat model, we evaluated the effects of the addition of AG to the PDF on microcirculation and morphology of the peritoneum, by intravital microscopy and quantitative morphometric analysis. RESULTS: AG-bicarbonate effectively scavenged different GDPs from PDF. Daily exposure to PDF for 5 weeks resulted in a significant increase in leucocyte rolling in mesenteric venules, which could be reduced for approximately 50% by addition of AG-bicarbonate (P<0.02). Vascular leakage was found in rats treated with PDF/AG-bicarbonate, but not with PDF alone. Evaluation of visceral and parietal peritoneum showed the induction of angiogenesis and fibrosis after PDF instillation. PDF/AG-bicarbonate significantly reduced vessel density in omentum and parietal peritoneum (P<0.04), but not in mesentery. PDF-induced fibrosis was significantly reduced by AG (P<0.02). PDF instillation led to AGE accumulation in mesentery, which was inhibited by supplementation of AG. Since addition of AG-bicarbonate to PDF raised pH from 5.2 to 8.5, a similar experiment was performed with AG-hydrochloride that did not change the fluid acidity. We could reproduce most of the results obtained with AG-bicarbonate; however, AG-hydrochloride induced no microvascular leakage and had a minor effect on angiogenesis. CONCLUSION: The supplementation of either AG reduced a number of PDF-induced alterations in our model, emphasizing the involvement of GDPs and/or AGEs in the PDF-induced peritoneal injury.

Better preservation of the peritoneum in rats exposed to amino acid-based peritoneal dialysis fluid.

BACKGROUND: Glucose-containing peritoneal dialysis fluids (PDF) show impaired biocompatibility, which is related partly to their high glucose content, presence of glucose degradation products, low pH, and lactate buffer, or a combination of these factors. In a rat chronic peritoneal exposure model, we compared effects of an amino acid-based PDF (AA-PDF) with a glucose-containing PDF on the peritoneal microcirculation and morphology. METHOD: Two groups of rats received 10 mL of either fluid daily for 5 weeks via peritoneal catheters connected to implanted subcutaneous mini vascular access ports. Leukocyte-endothelium interactions in the mesenteric venules were investigated by intravital microscopy. Quantification of angiogenesis and fibrosis and inspection of the mesothelial cell layer were performed by light and electron microscopy. RESULTS: Daily exposure to glucose-containing PDF resulted in a significant increase in the number of rolling leukocytes in mesenteric venules, whereas instillation of AA-PDF did not change the level of leukocyte rolling. Glucose-containing PDF evoked a significantly higher number of milky spots in the omentum, whereas this response was significantly reduced in animals exposed to the AA-PDF (p < 0.02). Chronic instillation of glucose-containing PDF induced angiogenesis in various peritoneal tissues, accompanied by fibrosis in the mesentery and parietal peritoneum. Quantitative morphometric evaluation of omentum and mesentery showed a clear trend toward less angiogenesis after treatment with the AA-PDF compared to the glucose-containing PDF, which reached statistical significance in the parietal peritoneum (p < 0.04). Instillation of AA-PDF resulted in approximately 50% reduction of fibrosis in the mesentery (p < 0.04) and approximately 25% reduction in the parietal peritoneum (p < 0.009) compared to glucose-containing PDF. Glucose-containing PDF damaged the mesothelial cell layer, whereas the mesotheium was intact after AA-PDF treatment, as evidenced by electron microscopy. CONCLUSION: Our data in a rat chronic peritoneal exposure model clearly demonstrate reduced immune activation (evidenced by decreased number of rolling leukocytes and decreased induction of omental milky spots) and reduced neoangiogenesis, fibrosis, and mesothelial damage of the peritoneal membrane after treatment with AA-PDF compared to glucose-containing PDF.

Arteriolar changes in nitric oxide activity and sensitivity during the course of streptozotocin-induced diabetes.

Nitric oxide (NO) may play an important role in the pathogenesis of diabetic microangiopathy. However, arteriolar changes in NO activity and sensitivity to NO may be dependent on both the type of arteriole and the duration of diabetes. Therefore, we assessed, in the in situ spinotrapezius muscle preparation of streptozotocin-diabetic rats and of controls, inside diameters of A2-A4 arterioles and the reactivity to topically applied acetylcholine and nitroprusside, before and after N(G)-nitro-L-arginine (L-NNA) at 2, 4, 6 and 12 weeks of diabetes. In A2 arterioles, basal diameters and the contribution of NO to basal diameter were not affected during the course of streptozotocin-induced diabetes. However, the maximal response to acetylcholine in these arterioles was attenuated after 2 until 4 weeks, and from 4 weeks on a sustained decrease in reactivity to sodium nitroprusside was observed. In A3 arterioles, both the basal diameter and the contribution of NO to basal diameter were decreased after 2 weeks and increased after 6 weeks, while the response to sodium nitroprusside was unaffected. In A4 arterioles, a significant increase in basal diameter was observed after 6 weeks only. Thus, this study shows that streptozotocin-induced diabetes causes microvascular changes in NO activity and sensitivity that depend on the type of arteriole. For each order of arteriole, these changes show a specific pattern during the course of diabetes.

The flux of arginine after ischemia-reperfusion in the rat kidney.

BACKGROUND: Renal arginine synthesis is regulated by arginine plasma levels. The amino acid arginine is synthesized in the proximal tubule of the kidney. Renal ischemia reperfusion (I-R) injury as seen after shock, trauma and major vascular surgery, leading to acute tubular necrosis, might reduce arginine production. METHODS: Wistar rats received either bovine liver arginase (ASE), to lower arginine plasma levels, or saline (SAL). Following the ASE or SAL infusion, rats were randomized to receive a renal artery clamp for 70 minutes, followed by 150 minutes of reperfusion. Renal arteriovenous blood samples were measured and plasma flow was calculated in the I-R kidney (SAL/I-R and ASE/I-R) and the contralateral kidney (SAL/C-L and ASE/C-L) in order to determine renal arginine metabolism. RESULTS: Arginase infusion resulted in lower arginine plasma levels compared to SAL treatment (SAL/I-R vs. ASE/I-R, P < 0.005, and SAL/C-L vs. ASE/C-L, P < 0.005). Renal plasma flow was similar for all groups. The kidney switched from arginine production into arginine uptake after ischemia reperfusion (SAL/I-R vs. SAL/C-L, P < 0.01, and ASE/I-R vs. ASE/C-L, P < 0.01). Renal uptake of glutamine and citrulline increased after ischemia reperfusion (SAL/I-R vs. SAL/C-L and ASE/I-R vs. ASE/C-L, both P < 0.01). Histopathological slices of the kidney showed significantly higher counts of hyperchromasia, pyknosis, nuclear fragmentation and mitoses in individual kidney cells after ischemia reperfusion. CONCLUSION: Decreased renal arginine production is observed with unilateral ischemia-reperfusion, and this change in arginine flux could contribute to or slow the recovery from the low plasma levels of arginine seen in conditions like trauma, shock, or after vascular procedures.

Increased leukocyte rolling in newly formed mesenteric vessels in the rat during peritoneal dialysis.

OBJECTIVE: Long-term peritoneal dialysis (PD) is associated with the development of functional and structural alterations of the peritoneal membrane. The present study reports the effects of chronic exposure to PD fluid on mesenteric leukocyte-endothelium interactions, using intravital video microscopy. METHODS: Rats (n = 7) received 10 mL lactate-buffered 3.86% glucose-containing PD fluid daily during a 5-week period via a subcutaneously implanted mini access port that was connected via a catheter to the peritoneal cavity. In a first control group (n = 8), catheters were implanted but no fluid was instilled; a second control group (n = 8) remained untreated. The number of rolling and adherent leukocytes as well as blood flow and other fluid dynamic variables were analyzed in mesenteric postcapillary (diameter 10-25 mu) and collecting (diameter 26-40 mu) venules. Neovascularization was semiquantitatively assessed after inspection of video images and by light and electron microscopy. Using FITC-labeled albumin, microvascular leakage was examined. RESULTS: Rats exposed to PD fluid showed a more than twofold increase in the number of rolling leukocytes (p < 0.01); the number of adherent leukocytes was not changed. Furthermore, exposure to PD fluid induced severe neovascularization in rat mesentery. No microvascular leakage was observed in the various groups. The observed differences could not be explained by differences in systemic or local hemodynamic parameters or peripheral leukocyte counts, but is most likely associated with new vessel formation. CONCLUSIONS: Exposure of rat peritoneal membrane to conventional PD fluid for 5 weeks affected local leukocyte-endothelium interactions. In addition, severe angiogenesis was induced, whereas microvascular permeability remained unaltered.