Background and purpose: 1-methylnicotinamide (MNA) has been considered to be an inactive metabolite of nicotinamide. Here we assessed the anti-thrombotic activity of MNA in vivo. Experimental approach: Antithrombotic action of MNA was studied in normotensive rats with extracorporeal thrombus formation (thrombolysis), in renovascular hypertensive rats with intraarterial thrombus formation (arterial thrombosis) and in a venous thrombosis model in rats (venous thrombosis). Key results: MNA (3-100 mg kg À1 ) induced a dose-dependent and sustained thrombolytic response, associated with a rise in 6-keto-PGF 1a in blood. Various compounds structurally related to MNA were either inactive or weaker thrombolytics. Rofecoxib (0.01-1 mg kg À1 ), dose-dependently inhibited the thrombolytic response of MNA, indomethacin (5 mg kg À1 ) abolished it, while L-NAME (5 mg kg À1 ) were without effect. MNA (3-30 mg kg À1 ) also reduced arterial thrombosis and this effect was abrogated by indomethacin (2.5 mg kg À1 ) as well as by rofecoxib (1 mg kg À1 ). MNA, however, did not affect venous thrombosis. In vitro MNA did not modify platelet aggregation nor induce vasodilation. Conclusions and implications: MNA displayed a profile of anti-thrombotic activity in vivo that surpasses that of closely related compounds. MNA inhibited platelet-dependent thrombosis by a mechanism involving cyclooxygenase-2 and prostacyclin. Our findings suggest that endogenous MNA, produced in the liver by nicotinamide N-methyltransferase, could be an endogenous activator of prostacyclin production and thus may regulate thrombotic as well as inflammatory processes in the cardiovascular system.
Inhibition of platelet aggregation by CO released by a novel, water-soluble CORM is not mediated by activation of soluble guanylate cyclase. In contrast to NO and PGI(2), CO effectively inhibits platelets even when cells are activated excessively. We suggest that despite the fact that CO is not a potent inhibitor of platelet activation, it may gain importance when NO and PGI(2) alone are insufficient to overcome excessive platelet activation.
Profiles of the local nitric oxide (.NO) diffusion-concentration product across the egg yolk phosphatidylcholine membrane in the absence and presence of 30 mol% cholesterol were obtained using line-broadening electron paramagnetic resonance (EPR) and lipid-soluble nitroxide spin labels. Membrane .NO permeability coefficients were calculated from these profiles. At 20 degrees C, values of 93 and 77 cm/s for membranes in the absence and presence of cholesterol were obtained, compared with 73 and 66 cm/s for water layers of the same thickness as the membranes. Fluid-phase membranes are not barriers to .NO transport. Cholesterol significantly increases .NO transport in the center of the lipid bilayer.
Carbon monoxide (CO) and CO-releasing molecules (CO-RMs) inhibit platelet aggregation in vitro. Herein, we compare the anti-platelet action of CORM-3, which releases CO rapidly (t½ 1 min), and CORM-A1, which slowly releases CO (t½ = 21 min). The anti-platelet effects of NO donors with various kinetics of NO release were studied for comparison. The effects of CO-RMs and NO donors were analyzed in washed human platelets (WP), platelets rich plasma (PRP), or whole blood (WB) using aggregometry technique. CORM-3 and CORM-A1 inhibited platelet aggregation in human PRP, WP, or WB, in a concentration-dependent manner. In all three preparations, CORM-A1 was more potent than CORM-3. Inhibition of platelets aggregation by CORM-A1 was not significantly affected by a guanylate cyclase inhibitor (ODQ) and a phosphodiesterase-5 inhibitor, sildenafil. In contrast, inhibition of platelet aggregation by NO donors was more potent with a fast NO releaser (DEA-NO, t½ = 2 min) than slow NO releasers such as PAPA-NO (t½ = 15 min) or other slow NO donors. Predictably, the anti-platelet effect of DEA-NO and other NO donors was reversed by ODQ while potentiated by sildenafil. In contrast to NO donors which inhibit platelets proportionally to the kinetics of NO released via activation of soluble guanylate cyclase (sGC), the slow CO-releaser CORM-A1 is a superior anti-platelet agent as compared to CORM-3 which releases CO instantly. The anti-platelet action of CO-RMs does not involve sGC activation. Importantly, CORM-A1 or its derivatives representing the class of slow CO releasers display promising pharmacological profile as anti-platelet agents.
This report confirms evidence that selective nonsteroidal anti-inflammatory drugs (NSAIDs), such as celecoxib, can lead to thrombotic cardiovascular events. Aspirin, a nonselective COX-1 (cyclo-oxygenase) and COX-2 inhibitor may result in gastric toxicity. For this reason, selective COX-2 inhibitors have been developed to reduce erosion of the gastric mucosa. Both selective and nonselective NSAIDs reduce prostacyclin formation in the infarcted heart; they accomplish this by tipping the balance of prostacyclin/thromboxane in favor of thromboxane, a prothrombotic eicosanoid. The relative increase in thromboxane, coupled with a diminution in prostacyclin in infarcted heart muscle, can lead to the development of thrombotic cardiovascular events. This may be prevented by the addition of a nitric oxide donor to NSAIDs.
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