Patients with end-stage renal disease suffer from complex hemostatic disorders. Uremic patients show a bleeding diathesis that is mainly due to abnormalities of primary hemostasis; in particular, platelet dysfunction and impaired platelet-vessel wall interaction. However, despite decreased platelet function, these patients have a high prevalence of cardiovascular and thrombotic complications. Platelet dysfunction in uremic patients is partially due to uremic toxins present in circulating blood. Dialysis improves platelet abnormalities and reduces, but does not eliminate, the risk of hemorrhage. Hemodialysis can even contribute to the bleeding through the continuous platelet activation induced by the interaction between blood and artificial surfaces. Thrombocytopenia, glomerular thrombosis, and thrombi in small arteries and glomerular capillaries are common pathological features in many renal diseases. Platelets are also involved directly in the pathogenesis of glomerular diseases through a variety of mechanisms, including release of active molecules, by enhancing immune complex deposition, and by altering glomerular permeability.
Bleeding is a common and potentially serious complication of acute and chronic renal failure. The pathogenesis of bleeding in uremia is multifactorial; however, the major role is played by abnormalities in platelet-platelet and platelet-vessel wall interaction. Platelet dysfunction is partially due to uremic toxins present in circulating blood. Despite decreased platelet function, abnormalities of blood coagulation and fibrinolysis predispose the uremic patients to a hypercoagulable state carrying the risk of cardiovascular and thrombotic complications. Dialysis improves platelet abnormalities and reduces, but does not eliminate, the risk of hemorrhage. Hemodialysis can even contribute to the bleeding through the continuous platelet activation induced by the interaction between blood and artificial surfaces and the use of anticoagulants. Correction of anemia improves hemostasis in uremic patients. Therapeutic management of bleeding in patients with uremia is discussed.
Nitric oxide (NO), a potent vasodilator which also inhibits platelet adhesion and aggregation, is generated by endothelial cells and platelets from its precursor L-arginine. Since N-monomethyl-L-arginine (L-NMMA), an inhibitor of NO synthesis, normalizes the prolonged bleeding time of uremic rats, it has been suggested that bleeding associated with uremia was due to an excessive NO formation. With the present study we sought to evaluate whether in patients with chronic renal failure--like in uremic rats--defective platelet aggregation were associated with excessive formation of NO and whether uremic plasma promotes NO synthesis by cultured vascular endothelium. Data indicated that plasma L-arginine was higher in uremics than in controls, uremic platelets generated more NO than control platelets, and intraplatelet levels of cGMP (the NO second messenger) were also higher in uremic than in control platelets. Moreover, uremic plasma potently induced NO synthesis by cultured endothelial cells, a phenomenon which was further amplified by adding to uremic plasma endotoxin and interferon gamma. Increased NO biosynthesis may contribute to platelet dysfunction and possibly other manifestations of uremic syndrome, including hemodialysis hypotension.
Adriamycin (ADR) nephrosis and a model of unilateral ADR-induced proteinuria were produced in Sprague-Dawley (S.D.) rats to investigate the mechanism of sodium retention by the nephrotic kidney. Plasma volume, as measured by the dilution principle using radioiodinated serum albumin, was significantly higher in nephrotic animals than in control ones (NS: 69.61 +/- 15.02: control: 47.05 +/- 5.32 ml/kg: P less than 0.01). Similarly plasma levels of immunoreactive ANP (iANP) were significantly higher in nephrotic animals compared to controls (NS 104.22 +/- 36.41: control 59.94 +/- 20.88 pg/ml; P less than 0.05). Using the unilateral model we found a markedly reduced diuretic and natriuretic response to the infusion of synthetic rat atrial natriuretic peptide (ANP 1-28) in proteinuric kidney but not in contralateral kidney, despite a comparable increase in glomerular filtration rate. To explain the blunted diuresis and natriuresis in the presence of normal glomerular response to ANP, we investigated the possibility of an abnormality at post-glomerular level by studying ANP receptor density and affinity of the inner stripe of outer medulla and the inner medulla in ADR-and vehicle-treated rats. The inner stripe of outer medulla and the inner medulla receptor density and affinity were not significantly different in ADR rats as compared to animals given the vehicle alone.(ABSTRACT TRUNCATED AT 250 WORDS)
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