Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0042373 (vascular disease)
 17,070 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Monocrotaline (MCT) is an 11-membered macrocyclic pyrrolizidine alkaloid (PA) that causes a pulmonary vascular syndrome in rats characterized by proliferative pulmonary vasculitis, pulmonary hypertension, and cor pulmonale. Current hypotheses of the pathogenesis of MCT-induced pneumotoxicity suggest that MCT is activated to a reactive metabolite(s) in the liver and is then transported by red blood cells (RBCs) to the lung, where it initiates endothelial injury. While several lines of evidence support the requirement of hepatic metabolism for pneumotoxicity, the mechanism and relative importance of RBC transport remain undetermined. The endothelial injury does not appear to be acute cell death but rather a delayed functional alteration that leads to disease of the pulmonary arterial walls by unknown mechanisms. The selectivity of MCT for the lung, as opposed to that of other primarily hepatotoxic PAs, appears likely to be a consequence of the differences in hepatic metabolism and blood kinetics of MCT. A likely candidate for a reactive metabolite of MCT is the dehydrogenation product monocrotaline pyrrole (MCTP). Secondary or phase II metabolism of MCT through glutathione (GSH) conjugation has been characterized recently and appears to represent a detoxification pathway. The role of inflammation in the progression of MCT-induced pulmonary vascular disease is uncertain. Both perivascular inflammation and platelet activation have been proposed as processes contributing to the response of the vascular media. This review presents the experimental evidence supporting these hypotheses and outlines additional questions that arise from them.
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PMID:Mechanisms and pathology of monocrotaline pulmonary toxicity. 148 9

Studies were conducted to determine whether experimental pulmonary hypertension is associated with alterations in pulmonary vascular smooth muscle responsiveness. Adult male rats were given a single s.c. injection of monocrotaline (105 mg/kg) or saline and were sacrificed 4, 7 or 14 days later. Segments of the main trunk and right extrapulmonary artery and an intrapulmonary artery were isolated for determination of vascular reactivity to contractile and relaxant agonists. Monocrotaline treatment caused changes in mechanical properties of pulmonary arteries in that vessels isolated from rats 14 days after monocrotaline administration required greater passive loads to achieve maximal active force development. Cumulative concentration-response curves were generated to potassium chloride, angiotensin II, norepinephrine, isoproterenol and acetylcholine. Vascular contractility was enhanced in main pulmonary artery 4 days after monocrotaline injection but no differences in responsiveness between control and monocrotaline exposed vessels were observed 7 days post-treatment. In contrast, significant decreases in contractility with a specific loss in the response to angiotensin II were observed in pulmonary arteries isolated from rats 14 days after monocrotaline administration. These vessels also were less responsive to the relaxant effects of isoproterenol and acetylcholine when compared to control vessels. These results demonstrate that changes in pulmonary vascular smooth muscle responsiveness occur during evolution of pulmonary hypertension induced by monocrotaline. Enhanced contractility may contribute to inappropriate vasoconstriction early in the development of hypertensive pulmonary vascular disease but does not appear to be involved in sustained elevations in pulmonary artery pressure. Diminished relaxation observed after pulmonary hypertension was well established may contribute to the loss in efficacy of vasodilators in the long-term management of pulmonary hypertension.
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PMID:Altered pulmonary vascular smooth muscle responsiveness in monocrotaline-induced pulmonary hypertension. 308 May 84

To test a hypothesis that reduction in pulmonary perfusion pressure and flow affect underlying vascular disease, pulmonary pathology was studied in monocrotaline-treated rats undergoing single lung transplantation. Inbred rats were treated with 40 mg/kg (group T1, n = 6) and 80 mg/kg of monocrotaline (group T2, n = 9), received a left lung isograft 2 and 4 weeks after medication, and were killed 4 and 6 weeks after single lung transplantation, respectively. For each group, rats receiving the same amount of monocrotaline (M1, M2) or vehicle (N1, N2) served as controls. Monocrotaline-treated rats developed pulmonary vascular disease and right heart failure, resulting in severe exercise intolerance in M1 or death in M2 unless single lung transplantation had been carried out. At death, pulmonary blood flow was directed toward the left lung isograft, and the retained right lung received a significantly reduced fraction of cardiac output. Right to left ventricular weight ratio was significantly reduced in both groups as compared to the respective control rats, suggesting reduced perfusion pressure. Although thickness of media in small pulmonary arteries (media/radius) was normal (34% +/- 4%) in the lung isografts, it was significantly increased in the contralateral lung (group T1, 45% +/- 5%; group T2, 48% +/- 3%), which was not significantly different from that of monocrotaline-treated control rats, respectively (group M1, 47% +/- 7%; group M2, 49% +/- 6%). Although single lung transplantation reduced perfusion pressure and flow toward the monocrotaline-treated native lung, it failed to affect vascular morphology significantly.
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PMID:Monocrotaline-induced pulmonary vascular disease after contralateral lung transplantation in the rat. 847 5

Right ventricular hypertrophy (RVH) and RV failure contribute to morbidity and mortality in pulmonary arterial hypertension (PAH). The cause of RV dysfunction and the feasibility of therapeutically targeting the RV are uncertain. We hypothesized that RV dysfunction and electrical remodeling in RVH result, in part, from a glycolytic shift in the myocyte, caused by activation of pyruvate dehydrogenase kinase (PDK). We studied two complementary rat models: RVH + PAH (induced by monocrotaline) and RVH + without PAH (induced by pulmonary artery banding (PAB)). Monocrotaline RVH reduced RV O(2)-consumption and enhanced glycolysis. RV 2-fluoro-2-deoxy-glucose uptake, Glut-1 expression, and pyruvate dehydrogenase phosphorylation increased in monocrotaline RVH. The RV monophasic action potential duration and QT(c) interval were prolonged due to decreased expression of repolarizing voltage-gated K(+) channels (Kv1.5, Kv4.2). In the RV working heart model, the PDK inhibitor, dichloroacetate, acutely increased glucose oxidation and cardiac work in monocrotaline RVH. Chronic dichloroacetate therapy improved RV repolarization and RV function in vivo and in the RV Langendorff model. In PAB-induced RVH, a similar reduction in cardiac output and glycolytic shift occurred and it too improved with dichloroacetate. In PAB-RVH, the benefit of dichloroacetate on cardiac output was approximately 1/3 that in monocrotaline RVH. The larger effects in monocrotaline RVH likely reflect dichloroacetate's dual metabolic benefits in that model: regression of vascular disease and direct effects on the RV. Reduction in RV function and electrical remodeling in two models of RVH relevant to human disease (PAH and pulmonic stenosis) result, in part, from a PDK-mediated glycolytic shift in the RV. PDK inhibition partially restores RV function and regresses RVH by restoring RV repolarization and enhancing glucose oxidation. Recognition that a PDK-mediated metabolic shift contributes to contractile and ionic dysfunction in RVH offers insight into the pathophysiology and treatment of RVH.
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PMID:The inhibition of pyruvate dehydrogenase kinase improves impaired cardiac function and electrical remodeling in two models of right ventricular hypertrophy: resuscitating the hibernating right ventricle. 1994 38