Academic literature on the topic 'Drug-induced valvulopathy'

Drug-induced valvulopathy is a serious liability for certain compound classes in development and for some marketed drugs intended for human use. Reports of valvulopathy led to the withdrawal of fenfluramines (anorexigens) and pergolide (antiparkinson drug) from the United States market in 1997 and 2007, respectively. The mechanism responsible for the pathogenesis of valvulopathy by these drugs is likely a result of an “off-target” effect via activation of 5-hydroxytryptamine (5-HT) 2B receptor (5-HT2BR) expressed on heart valve leaflets. Microscopically, the affected valve leaflets showed plaques of proliferative myofibroblasts in an abundant extracellular matrix, composed primarily of glycosaminoglycans. However, the valvular effects caused by fenfluramines and pergolide were not initially predicted from routine preclinical toxicity studies, and to date there are no specific validated animal models or preclinical/toxicologic screens to accurately predict drug-induced valvulopathy. This review covers the structure and function of heart valves and highlights major advances toward understanding the 5-HT2BR-mediated pathogenesis of the lesion and subsequently, development of appropriate animal models using novel techniques/experiments, use of functional screens against 5-HT2BR, and more consistent sampling and pathologic evaluation of valves in preclinical studies that will aid in avoidance of future drug-induced valvulopathy in humans.

Serotonergic drugs, such as pergolide, have been associated with the development of cardiac valvular myxoid thickening and regurgitation in humans and more recently in rats. These effects are potentially mediated by the 5-hydroxytryptamine (5-HT)2B receptor (5-HT2BR). Therefore, we sought to determine whether cyproheptadine, a 5-HT2BR antagonist, might prevent toxic valvulopathy in an animal model of pergolide-induced valvular heart disease. For this purpose, 50 male Wistar rats received daily intraperitoneal injections of pergolide (0.5 mg/kg, n = 14), pergolide (0.5 mg/kg) combined with cyproheptadine (10 mg/kg, n = 12), cyproheptadine (10 mg/kg, n = 12), or no injections (control, n = 12) for 20 wk. Echocardiography was performed blindly at baseline and at 10 and 20 wk followed by pathology. At baseline, no differences between groups were found with echocardiography. At 20 wk, aortic regurgitation was present in all pergolide-treated animals, whereas it was less frequently observed in the other groups ( P < 0.0001). For the other valves, this difference was less pronounced. On histopathology, not only aortic but also mitral valves were thicker, myxoid, and exhibited more 5-HT2BR-positive cells in pergolide-treated animals compared with the other groups. Moreover, regurgitant aortic and mitral valves were thicker than nonregurgitant aortic and mitral valves. In conclusion, we found that cyproheptadine prevented pergolide-induced valvulopathy in rats, which was associated with a reduced number of 5-HT2BR-positive valvular cells. This may have important clinical implications for the prevention of serotonergic drug-induced valvular heart disease.

Abstract Context.—Few published studies of the pathology of fenfluramine-phentermine (fen-phen) valvulopathy, described by Connolly and colleagues in 1997, have appeared. Objectives.—To define temporal changes in the morphology of the stuck-on plaques and to determine whether the plaques progress or regress after cessation of fen-phen. Methods.—The available clinical information and pathology material from 35 aortic valves (AVs) and 43 mitral valves (MVs) from 64 patients were reviewed. Results.—The valves fell into 3 groups: 17 AVs and 28 MVs had fen-phen lesions only, 2 AVs and 7 MVs had fen-phen changes associated with other valve diseases, and 16 AVs and 8 MVs had no fen-phen changes. Fenfluramine-phentermine–attributable dysfunction was regurgitation in all instances. Typical plaques showed proliferation of myofibroblastic cells with myxoid stroma. Small vascular channels and slight lymphocytic accumulations were often present. Deeper parts of some plaques had dense fibroelastic tissue underlying typical plaque. Conclusions.—Considerable individual variation in the time course of anorectic agent use and the severity of fen-phen valvulopathy was observed. Possible plaque regression could not be assessed from this study. The observations suggest that in some patients fen-phen–induced plaques may continue to have surface proliferation despite drug withdrawal.

This is a joint position statement of the British Society of Echocardiography, the British Heart Valve Society and the Society for Endocrinology on the role of echocardiography in monitoring patients receiving dopamine agonist (DA) therapy for hyperprolactinaemia. (1) Evidence that DA pharmacotherapy causes abnormal valve morphology and dysfunction at doses used in the management of hyperprolactinaemia is extremely limited. Evidence of clinically significant valve pathology is absent, except for isolated case reports around which questions remain. (2) Attributing change in degree of valvular regurgitation, especially in mild and moderate tricuspid regurgitation, to adverse effects of DA in hyperprolactinaemia should be avoided if there are no associated pathological changes in leaflet thickness, restriction or retraction. It must be noted that even where morphological change in leaflet structure and function may be suspected, grading is semi-quantitative on echocardiography and may vary between different machines, ultrasound settings and operators. (3) Decisions regarding discontinuation of medication should only be made after review of serial imaging by an echocardiographer experienced in analysing drug-induced valvulopathy or carcinoid heart disease. (4) A standard transthoracic echocardiogram should be performed before a patient starts DA therapy for hyperprolactinaemia. Repeat transthoracic echocardiography should then be performed at 5 years after starting cabergoline in patients taking a total weekly dose less than or equal to 2 mg. If there has been no change on the 5-year scan, repeat echocardiography could continue at 5-yearly intervals. If a patient is taking more than a total weekly dose of 2 mg, then annual echocardiography is recommended.

Un lien entre certaines dysfonctions du système sérotoninergique et la survenue de valvulopathies a été suggéré par les lésions valvulaires observées au cours de l’utilisation chronique de certains agonistes des récepteurs 5-HT2 (dérivés de l’ergot de seigle, fenfluramine) et les atteintes tumorales carcinoïdes (qui entrainent une augmentation des taux de 5-HT circulante). Les lésions dégénératives associent une fibrose, une sténose et/ou une régurgitation des valves pouvant conduire à de nombreuses complications cardiovasculaires. À l’heure actuelle, il n’existe aucune thérapeutique pouvant freiner ou faire régresser les lésions. Nos travaux démontrent à partir de modèles animaux et cellulaires, l’implication effective des récepteurs 5-HT2B et 5-HT2A dans l’initiation des lésions. L’analyse histologique des valves à partir de nos modèles animaux a révélé la contribution des cellules endothéliales au cours des stades précoces. Ces cellules sont des progéniteurs endothéliaux (CD34+) recrutés à partir de la moelle au sein de la valve sous la stimulation des récepteurs 5-HT2 et par un mécanisme intracellulaire impliquant la eNOS. Des travaux ultérieurs permettront de mieux caractériser les différents types cellulaires et les biomarqueurs d’initiation du processus afin de déterminer de nouvelles pistes thérapeutiques
Several studies have reported a strong correlation between the development of cardiac valve injury and some dysfunctions of the serotonergic system. Valve lesions are observed during the chronic use of some 5-HT2 receptors agonists (ergot derivates or fenfluramine derivatives) or are secondary to metastatic carcinoid tumours (with increased circulating 5-HT amount). These lesions show fibrosis, with thickened leaflets, valves stenosis and/or regurgitation followed by several cardiovascular complications. There is no medical treatment to stop or alter the natural course of the lesions. Surgical replacement by prosthesis is the only effective therapy. Our study based on animal and cellular pharmacological models, demonstrates the serotonergic system contribution through 5-HT2B and 5-HT2A receptors in the pathogenesis of valve degeneration. Histological analysis of the lesions reveals the contribution of endothelial cells to the initiation process. These cells are probably endothelial progenitors (CD34+) recruited inside the valve implying a NO-dependent mechanism. Further studies will characterize the specific cells to find biomarkers of valve remodelling initiation and at term, will identify best therapeutic targets around the serotonergic system