In vivo model of drug-induced valvular heart disease in
Transcription
In vivo model of drug-induced valvular heart disease in
Preclinical research European Heart Journal (2007) 28, 2156–2162 doi:10.1093/eurheartj/ehm263 In vivo model of drug-induced valvular heart disease in rats: pergolide-induced valvular heart disease demonstrated with echocardiography and correlation with pathology Steven Droogmans1,4,*, Philippe R. Franken2,4, Christian Garbar3,5, Caroline Weytjens1,4, Bernard Cosyns1,4, Tony Lahoutte2,4, Vicky Caveliers2,4, Miriam Pipeleers-Marichal3,5, Axel Bossuyt2,4, Danny Schoors1, and Guy Van Camp1,4 1 Department of Cardiology, UZ Brussel, Brussels, Belgium; 2Department of Nuclear Medicine, UZ Brussel, Brussels, Belgium; Department of Pathology, UZ Brussel, Brussels, Belgium; 4In Vivo Cellular and Molecular Imaging Center (ICMIC), Vrije Universiteit Brussel (VUB), Brussels, Belgium; and 5Experimental Pathology (EXPA), Faculty of Medicine and Pharmacy, Vrije Universiteit Brussel (VUB), Brussels, Belgium 3 Received 10 January 2007; revised 18 April 2007; accepted 31 May 2007; online publish-ahead-of-print 18 July 2007 KEYWORDS Aims Valvular heart disease (VHD), inducing valvular regurgitation, has been described in carcinoid heart disease and recently in Parkinson’s patients treated with pergolide. The aim of this study was to develop an in vivo model of drug-induced valvulopathy with pergolide in rats. Methods and results Thirty male Wistar rats were given daily injections of either pergolide (0.5 mg/kg intraperitoneally) (n ¼ 8), serotonin (20 mg/kg subcutaneously) (n ¼ 8), or the vehicle only (n ¼ 14) for 5 months. At 20 weeks, echocardiography demonstrated the presence of aortic regurgitation (AR) and/or mitral regurgitation (MR) in serotonin (86% AR, P ¼ 0.0001; 57% MR, P ¼ 0.006) and in pergolide animals (67% AR, P ¼ 0.003; 67% MR, P ¼ 0.003) compared with none in placebo. Pulmonary regurgitation (PR) and tricuspid regurgitation (TR) were found in the serotonin (71% PR, P ¼ 0.19; 100% TR, P ¼ 0.06 vs. placebo), pergolide (100% PR, P ¼ 0.014; 83% TR, P ¼ 0.35 vs. placebo), and placebo groups (36% PR; 57% TR). Tricuspid regurgitant area ratio (jet/atrium), however, was more severe in the serotonin [median 26.5 (range 17–42)%; P ¼ 0.02] and pergolide animals [32 (17–39) %; P ¼ 0.03] compared with placebo [12.5 (5–33)%]. We found a good correlation between valvular regurgitation and histologically assessed valvular thickness. Histological examination revealed the presence of diffusely thickened and myxoid aortic, mitral, and tricuspid valves in serotonin and pergolide animals as seen in VHD. Conclusion We demonstrated, for the first time, that long-term pergolide administration led to VHD in rats. This small animal model will permit further in vivo investigation of drug-induced valvulopathies. Introduction During the last decade, several drugs have been identified to cause cardiac valvulopathy. Ergot derivatives (ergotamine, methysergide) and appetite-suppressants (fenfluramine) were the first drugs described to cause valvular heart disease (VHD).1,2 This entity is characterized by thickening of the leaflets and thickening and shortening of the subvalvular apparatus, finally leading to valvular insufficiency. Recently we described the occurrence of VHD in 26 of 78 patients with Parkinson’s disease treated with pergolide.3 The involvement of ergot-derived dopamine agonists (pergolide, cabergoline) in the development of VHD is still an important topic of investigation.4,5 * Corresponding author. Tel: þ32 2 477 6010; fax: þ32 2 477 6840. E-mail address: steven_droogmans@yahoo.com Drug-induced VHD has a histological resemblance with the carcinoid syndrome showing myxoid valvular changes, fibrosis and extracellular deposits of proliferative plaque-like material containing fibroblasts, myofibroblasts, and smooth muscle cells.2,6 Although many pathophysiological mechanisms remain to be elucidated, it is clear that serotonin [5-hydroxytryptamine (5-HT)] plays a central role. Cell culture studies indicated the mitogenic effects of 5-HT on different cell types such as fibroblasts7 and aortic smooth muscle cells.8–10 A recent animal study confirmed the development of carcinoid like valvular deposits in rats after 3 months of daily subcutaneous serotonin injections.11 Deficiency of the 5-HT transmembrane transporter in mice led to valvular fibrosis, providing further support for a direct link between 5-HT and cardiac valvulopathy.12 Functional recombinant receptor assays suggested that the effects of these valvulopathic drugs are mainly mediated & The European Society of Cardiology 2007. All rights reserved. For Permissions, please e-mail: journals.permissions@oxfordjournals.org Downloaded from by guest on October 28, 2014 Echocardiography; Pathology; Drugs; Small animals; Valves Drug-induced valvular heart disease in rats 2157 by the 5-HT2b receptor.13–15 These data also demonstrated that pergolide potently activates the 5-HT2b receptor.14,16,17 Until now, most of the studies were performed in vitro to evaluate the response of valvular and cardiac cells to 5-HT, ergot-related drugs, and fenfluramine derivates. Therefore, important questions such as dose dependency, reversibility, and possible protective effects of antagonists remain unanswered. Hence, an in vivo model of drug-induced VHD is needed for future studies. The aim of this study was to develop and characterize an in vivo model of drug-induced valvulopathy. For that purpose we studied the effect of daily injections of pergolide compared with serotonin and placebo on the cardiac valves of male Wistar rats using echocardiography. At the end of the study, the animals were sacrificed and the clinical data were compared with the histological findings. with 2D colour Doppler or continuous-wave Doppler, regurgitation was considered absent. The severity of the regurgitant aortic flow was assessed as the colour-Doppler ratio of regurgitant jet width to the left ventricular outflow tract diameter. For the mitral and tricuspid valve, the regurgitant area ratio (jet/atrium) was calculated in the view with the largest colour Doppler signal (long axis or four chamber view). The pulmonary regurgitant flows were coded as present or absent in the short-axis view. Left ventricular chamber diameter in end-systole (LVESD) and end-diastole (LVEDD), left ventricular anterior wall thickness in endsystole and end-diastole, and left ventricular posterior wall thickness in end-systole and end-diastole, as well as left ventricular fractional shortening (FS% ¼ [(LVEDD2LVESD)/LVEDD] 100) were determined from the M-mode tracings in a short-axis view (average of three consecutive cycles) at the level of the papillary muscles. Methods The animals were sacrificed 2 weeks after the last injections. The hearts were weighted and fixed in formalin for 2 h. Then they were embedded in paraffin, cut in an axial plane (from basis to apex) and stained with hematoxylin and eosin and alcian blue for glycosaminoglycans. Additional step sections, ranging from 1 to 3 (approximately 100 mm between sections) were carried out for those heart sections without valves. Extreme care was taken in sectioning the heart so that the valves were mainly cut transversely (with the attachment sides of the leaflets visible on both ends of the valve). Morphometry was performed by digital image analysis using a PC digital image camera (Digital Sight DS-5M, Nikon Corp, Japan) mounted on an Axiolab Zeiss light microscope (Carl Zeiss Corp, Germany) with a 10 objective (Acroplan, Zeiss). We used the NIH Image program (Image-J 1.35 d, Nation Institutes of Health, Bethesda, USA). The program was calibrated with a graduated slide. Microscopic images were used to evaluate blindly the cardiac valves and cardiomyocytes. The maximum thickness of every valve present was measured. The width of at least ten cardiomyocytes was measured on the left ventricle of each section. Study design Animals handling During the whole study, the animals were housed in stainless steel cages with sawdust bedding. They were kept at an average room temperature of 248C, a relative humidity of 50%, and a 12 h day/ night cycle. Food (rat maintenance diet, SAFE, France) and water were provided at libidum. Drugs preparation and administration Serotonin (5-HT Creatinin Sulphate Complex, Sigma-Aldrich) was dissolved in physiological saline at a concentration of 20 mg/mL. In order to avoid skin lesions like subcutaneous bleedings and traumatic wounds, the injection side was changed daily. An equal volume of physiological saline (1 mL/kg) was given to the placebo rats. Pergolide mesylate (Sigma-Aldrich) was prepared in a 10% alcoholic solution at a concentration of 0.5 mg/mL. An equal volume of a 10% ethanol solution (1 mL/kg) was given to the placebo rats. The treatment identity of the rats was hidden during echocardiography and pathological evaluation. Echocardiography Ten minutes before imaging, the rat was anesthetized with 50 mg/kg sodium pentobarbital intraperitoneally. Subsequently the anterior chest wall was shaved and the rat was placed in left lateral decubitus on a wooden bench in order to obtain optimal image quality and views. ECG electrodes were fixed on the paws. A Vivid 7 Pro system (GE Medical Systems, Milwaukee, WI, USA) with a 10 MHz neonatal probe (10S) was used. Images and loops were stored digitally for post-test analysis. The image sector was kept narrow in order to get a maximal frame rate. When necessary, cineloop speed was reduced for optimal jet evaluation. Regurgitant jets were assessed visually with 2D colour Doppler and continuouswave Doppler in the parasternal short and long axis, apical three and four chamber views. If no retrograde flow was detectable Statistical analysis Data are expressed as median with range or interquartile range. Comparison between groups were performed by using the Mann– Whitney U-test and Fisher’s exact test. A cut-off value for valvular thickness and correlation between valvular thickness and regurgitation was calculated using receiver operating characteristic (ROC) analysis. Data were not corrected for multiple comparisons. All P-values were calculated two-tailed. A value of P , 0.05 was considered significant. Statistical analysis was done with GraphPad Prism (version 4.03, San Diego, CA, USA). Results There were no differences between the two placebo groups for all measurements. In the following part, the placebo data were pooled for further analysis. Clinical signs The serotonin injections induced flushing, loose stools, drowsiness, and tachypnea persisting for several hours after the injections. The clinical signs of the pergolide injections were most pronounced in the first 2 weeks of the study and included hyperactivity, poor grooming, aggressive behaviour, and increased gnawing activity. Three treated animals died during follow-up (one serotonin at 10 weeks immediately after anaesthesia and two pergolide rats were found dead at 14 and 19 weeks without identifiable cause at necropsy). Downloaded from by guest on October 28, 2014 Thirty male Wistar Unilever rats (Harlan, the Netherlands) (350+3 g; 11 weeks) were randomized into two placebo-controlled arms. In the first arm, eight rats received daily one injection of serotonin (20 mg/kg) subcutaneously and seven rats received the vehicle only. In the second arm, eight rats received daily one injection of pergolide (0.5 mg/kg) intraperitoneally and seven rats the vehicle only. An echocardiographic evaluation was performed at baseline and at 10 and 20 weeks, followed by necropsy and histological examination of the heart. This study protocol was approved by the Ethics Committee of the Vrije Universiteit, Brussel. Histopathology 2158 S. Droogmans et al. Table 1 Evolution of the valvular regurgitations of the placebo, serotonin- and pergolide-treated animals at 10 and 20 weeks 10 weeks N Tricuspid regurgitation (%) Pulmonary regurgitation (%) Mitral regurgitation (%) Aortic regurgitation (%) 20 weeks Placebo Serotonin Pergolide Placebo Serotonin Pergolide 14 36 7 0 0 7 71 57* 29 0 8 63 13 25 0 14 57 36 0 0 7 100 71 57** 86*** 6 83 100* 67** 67** Percentage of rats with valvular regurgitation. *P , 0.05, **P , 0.01, and ***P , 0.001, compared with placebo of the same age. Echocardiography M-mode measurements A significant increase in LVEDD and a decrease in FS were observed at 20 weeks in the pergolide but not the serotonin treated animals (Table 2). Both groups had a diminished left ventricular wall thickness compared with placebo. Pathology Post-mortem measurements At sacrifice, serotonin- and pergolide-treated animals had a lower body weight [400 (362–468) g; P ¼ 0.0003] and [467 (435–517) g; P ¼ 0.001], respectively, compared with the placebo group [571 (483–626) g]. The heart to body weight ratio was higher in the serotonin group [3.63 (3.12–3.89) mg/g; P ¼ 0.0007] and in the pergolide group [3.17 (2.78– 3.50) mg/g; P ¼ 0.07] compared with the placebo group [2.79 (2.57–3.56) mg/g]. Figure 1 (A) Apical three chamber view in a pergolide rat at 20 weeks with aortic regurgitation (green arrow). (B) Parasternal long-axis view in a pergolide rat at 20 weeks with mitral regurgitation (green arrow). LA, left atrium; LV, left ventricle; AR, aortic root. Valvular pathology Histological examination revealed the presence of thickened aortic, mitral, and tricuspid cusps in the serotonin- and pergolide-treated animals (Figure 2). Moreover, regurgitant valves were thicker on histology [192 (69–405) mm; P ¼ 0.0003] compared with non-regurgitant valves [106 (61– 278) mm]. Using ROC analysis, a good correlation was found between echocardiography and pathology (AUC 0.76; P ¼ 0.0003) with 161 mm as cut-off for a thickened pathological valve. Valvular thickening was because of myxoid change in the sponge layer of the leaflet (Figure 3). These Downloaded from by guest on October 28, 2014 Valvular analysis Every valve was visualized in all animals during the study. A baseline echocardiography was performed before the start of the injections. There were no valvular abnormalities. The occurrence of valvular regurgitation in the different groups during follow-up is shown in Table 1. At 20 weeks, aortic regurgitation (AR) was present in six (86%; P ¼ 0.0001) animals of the serotonin group and in four (67%; P ¼ 0.003) of the pergolide group (Figure 1). The median colour-Doppler ratio of regurgitant jet width to the left ventricular outflow tract diameter was 35.5 (24–43) and 25 (21–50), respectively. AR was not found in the placebo group. Mitral regurgitation (MR) was also not found in the placebo group. At 20 weeks, MR was present in four (57%; P ¼ 0.006) serotonin and four (67%; P ¼ 0.003) pergolide-treated animals (Figure 1B). The median regurgitant area ratio were 16.5 (8–36) and 25 (14–31)%, respectively. Tricuspid regurgitation (TR) and pulmonary regurgitation (PR) were found in both the placebo and treated animals. However, TR was found in 57% of placebos, in all serotonins (P ¼ 0.06), and in 83% pergolide rats (P ¼ 0.35). PR was present in 36% of placebos, in 71% of serotonins (P ¼ 0.19), and in all pergolide rats (P ¼ 0.014). In addition, the TR was more severe in the serotonin group [regurgitant area ratio 26.5 (17–42)%; P ¼ 0.02] and in the pergolide group [regurgitant area ratio 32 (17–39)%; P ¼ 0.03] compared with the placebo group [regurgitant area ratio 12.5 (5–33)%]. Drug-induced valvular heart disease in rats 2159 Table 2 M-mode parameters of the left ventricle (LV) (parasternal short-axis view) of the placebo animals and the treated animals at 10 and 20 weeks 10 Weeks N Anterior wall diastole (cm) Inferior wall diastole (cm) LV enddiastolic diameter (cm) LV endsystolic diameter (cm) Fractional shortening (%) 20 Weeks N Anterior wall diastole (cm) Inferior wall diastole (cm) LV enddiastolic diameter (cm) LV endsystolic diameter (cm) Fractional shortening (%) Placebo IQR Serotonin IQR P-value Pergolide IQR P-value 14 0.20 0.18 0.71 0.45 40 0.17–0.23 0.17–0.22 0.68–0.76 0.39–0.47 38–45 7 0.21 0.17 0.73 0.42 42 0.17–0.24 0.16–0.19 0.65–0.76 0.38–0.45 36–44 0.79 0.26 0.91 0.68 0.48 8 0.19 0.17 0.73 0.45 38 0.17–0.20 0.16–0.18 0.69–0.75 0.41–0.48 34–40 0.39 0.09 0.89 0.56 0.19 14 0.20 0.20 0.72 0.43 41 0.18–0.22 0.19–0.23 0.69–0.79 0.39–0.47 37–44 7 0.17 0.16 0.75 0.44 40 0.16–0.18 0.15–0.18 0.72–0.80 0.40–0.48 36–52 0.01 0.004 0.26 0.65 0.91 6 0.17 0.16 0.80 0.52 35 0.15–0.19 0.15–0.17 0.73–0.85 0.48–0.55 32–39 0.01 0.008 0.03 0.009 0.02 Values are expressed as median and interquartile range (IQR). P-values are compared with placebo of the same age. Left ventricular pathology The left ventricular cardiomyocytes were hypertrophic in both serotonin- [width 15.4 (12.4–17.4) mm; P ¼ 0.01] and pergolide-treated animals [16.1 (13.7–18.1) mm; P ¼ 0.003] compared with placebo-treated animals [12.4 (10.5–14.5) mm]. Macroscopically, left ventricular cavities were more dilated in both the serotonin and pergolide groups. Discussion In this study, we presented and characterized for the first time an in vivo animal model of pergolide-induced valvulopathy. We showed that long-term pergolide administration led to VHD in these rats. This was demonstrated by serial in vivo echocardiographic assessment of valvular changes during the course of the experiment. Moreover, there was an excellent correlation between these echocardiographic findings and histological analysis. We finally describe the pathological lesions in this model of drug-induced valvulopathy. Drug-induced valvulopathy was demonstrated by means of echocardiographic illustration of valvular regurgitations. AR and MR were found only in the pergolide- and serotonininjected animals, whereas PR and TR were also present in the placebo group. This illustrates that regurgitations are also present in normal rats and one should take this fact into account when studying VHD in rodents. Right-sided valvular regurgitations could be a physiological manifestation of the natural aging process of rats and might be Figure 2 Scale bar represents the median of the maximum thickness of each valve (measured on the digital microscopic images) of the placebo, serotonin, and pergolide groups at 20 weeks. Thickness of the values is in micrometre, with interquartile range. N, number of valves analysed, *P , 0.05. Downloaded from by guest on October 28, 2014 glycosaminoglycans deposits were also observed in the placebo group, but were smaller and localized at the distal free edge of the valve leaflet. In contrast, the serotoninand pergolide-treated animals showed diffuse thick myxoid changes throughout the valves reaching the base of the cusps. Several areas of chondroid metaplasia were noted at the basal septum between the attachment sites of the aortic and mitral leaflets in the serotonin- (50%; P ¼ 0.28), pergolide- (60%; P ¼ 0.24), and placebo-treated animals (18%). True valvular fibrosis with dense collagen was not observed. 2160 S. Droogmans et al. Downloaded from by guest on October 28, 2014 Figure 3 Photomicrographs of the aortic valve. Placebo rat (A) with limited myxoid change of the distal free end of both leaflets (black arrow). Diffuse myxoid thickening of the spongy layer reaching the base of the cusps (black arrows) of a (B) serotonin-treated animal and (C and D) pergolide-treated animal. Chondroid metaplasia is present at the attachment sides of the aortic valve (white arrows, insert) in both treated animals. Scale bar is 250 mm, original magnification 40, insert 200, HES (A–C) and Alcian blue (D). more pronounced under anaesthesia. More research is needed to clarify this observation. On the other hand, this can explain the absence of significant difference regarding TR in the pergolide-treated animals compared with controls by echocardiography. However, the severity of TR was more pronounced in both pergolide- and serotonin-treated animals compared with placebo. This might be because of the higher pulmonary resistance in these rodents.18 Moreover, histological analysis confirmed the tricuspid involvement in both pergolide- and serotonin-treated animals. This was not the case for the pulmonary valves. Although speculative, this can be explained by the more difficult imaging of the pulmonary valves by echocardiography and pathology in clinical and preclinical research in rodents.11,19 On the other hand, the pulmonary valve might present a different density of the 5-HT2b receptor. This needs to be addressed in future research. As in our clinical study with pergolide, left- and right-sided heart valves were affected.3 Carcinoid heart disease is mainly limited to the right side since serotonin is broken down by monoaminooxidase in the lungs, but the left side can also be affected.20 In our study, left-side involvement was also found in the serotonin-treated animals and is probably because of the relatively high dosage injected. Similar findings were observed in the study of Gustaffson.11 Our study also demonstrated an excellent correlation between echocardiographic valvular regurgitation and valvular thickness as measured by histological examination. With exception of the pulmonary valve, all valves were significantly thicker in the pergolide and serotonin groups. Since no data exist about normal values of valvular thickness in rats, we calculated 161 mm as a best cut-off for a pathologically thickened valve in this study. The histological lesions consisted of myxoid thickening of the valvular sponge layer in this animal model as observed by others.11,21,22 These endocardial myxoid changes have been described in normal aging rats, but the deposits are smaller and mainly situated at the distal free edges of the valvular leaflets.19 On the other hand, 5 HT2B receptor agonists such as pergolide14 could lead to an increased biosynthesis of collagen and glycoaminoglycans which accumulate in the valvular sponge layer in a diffuse pattern.10 Drug-induced valvular heart disease in rats Conclusions We described the first pergolide-induced valvulopathy animal model and proved also that in vivo ultrasound imaging of VHD is feasible and correlates well with pathology. This opens the door towards research in the field of drug-induced VHD for answering important remaining questions such as dose-dependency, reversibility and influence of inhibitory drugs. Acknowledgements The authors wish to thank Nicole Buelens and Ce ´line Degaillier for their technical support and assistance in preparing the histological sections. Steven Droogmans has received a scholarship from the ‘Fonds voor Wetenschappelijk Onderzoek Vlaanderen (FWO)’ for this work. Conflict of interest: none declared. References 1. Redfield MM, Nicholson WJ, Edwards WD, Tajik AJ. Valve disease associated with ergot alkaloid use: echocardiographic and pathologic correlations. Ann Intern Med 1992;117:50–52. 2. Connolly HM, Crary JL, McGoon MD, Hensrud DD, Edwards BS, Edwards WD, Schaff HV. Valvular heart disease associated with fenfluramine-phentermine. N Engl J Med 1997;337:581–588. 3. Van Camp G, Flamez A, Cosyns B, Weytjens C, Muyldermans L, Van Zandijcke M, De Sutter J, Santens P, Decoodt P, Moerman C, Schoors D. Treatment of Parkinson’s disease with pergolide and relation to restrictive valvular heart disease. Lancet 2004;363:1179–1183. 4. Schade R, Andersohn F, Suissa S, Haverkamp W, Garbe E. Dopamine agonists and the risk of cardiac-valve regurgitation. N Engl J Med 2007; 356:29–38. 5. Zanettini R, Antonini A, Gatto G, Gentile R, Tesei S, Pezzoli G. Valvular heart disease and the use of dopamine agonists for Parkinson’s disease. N Engl J Med 2007;356:39–46. 6. Ferrans VJ, Roberts WC. The carcinoid endocardial plaque; an ultrastructural study. Hum Pathol 1976;7:387–409. 7. Seuwen K, Magnaldo I, Pouyssegur J. Serotonin stimulates DNA synthesis in fibroblasts acting through 5-HT1B receptors coupled to a Gi-protein. Nature 1988;335:254–256. 8. Xu J, Jian B, Chu R, Lu Z, Li Q, Dunlop J, Rosenzweig-Lipson S, McGonigle P, Levy RJ, Liang B. Serotonin mechanisms in heart valve disease II: the 5-HT2 receptor and its signaling pathway in aortic valve interstitial cells. Am J Pathol 2002;161:2209–2218. 9. Nemecek GM, Coughlin SR, Handley DA, Moskowitz MA. Stimulation of aortic smooth muscle cell mitogenesis by serotonin. Proc Natl Acad Sci USA 1986;83:674–678. 10. Jian B, Xu J, Connolly J, Savani RC, Narula N, Liang B, Levy RJ. Serotonin mechanisms in heart valve disease I: serotonin-induced up-regulation of transforming growth factor-beta1 via G-protein signal transduction in aortic valve interstitial cells. Am J Pathol 2002;161: 2111–2121. 11. Gustafsson BI, Tommeras K, Nordrum I, Loennechen JP, Brunsvik A, Solligard E, Fossmark R, Bakke I, Syversen U, Waldum H. Long-term serotonin administration induces heart valve disease in rats. Circulation 2005;111:1517–1522. 12. Mekontso-Dessap A, Brouri F, Pascal O, Lechat P, Hanoun N, Lanfumey L, Seif I, Benhaiem-Sigaux N, Kirsch M, Hamon M, Adnot S, Eddahibi S. Deficiency of the 5-hydroxytryptamine transporter gene leads to cardiac fibrosis and valvulopathy in mice. Circulation 2006;113:81–89. 13. Rothman RB, Baumann MH, Savage JE, Rauser L, McBride A, Hufeisen SJ, Roth BL. Evidence for possible involvement of 5-HT(2B) receptors in the cardiac valvulopathy associated with fenfluramine and other serotonergic medications. Circulation 2000;102:2836–2841. 14. Setola V, Hufeisen SJ, Grande-Allen KJ, Vesely I, Glennon RA, Blough B, Rothman RB, Roth BL. 3,4-Methylenedioxymethamphetamine (MDMA, ‘Ecstasy’) induces fenfluramine-like proliferative actions on human cardiac valvular interstitial cells in vitro. Mol Pharmacol 2003;63: 1223–1229. 15. Fitzgerald LW, Burn TC, Brown BS, Patterson JP, Corjay MH, Valentine PA, Sun JH, Link JR, Abbaszade I, Hollis JM, Largent BL, Hartig PR, Hollis GF, Meunier PC, Robichaud AJ, Robertson DW. Possible role of valvular serotonin 5-HT(2B) receptors in the cardiopathy associated with fenfluramine. Mol Pharmacol 2000;57:75–81. 16. Millan MJ, Maiofiss L, Cussac D, Audinot V, Boutin JA, Newman-Tancredi A. Differential actions of antiparkinson agents at multiple classes of monoaminergic receptor. I. A multivariate analysis of the binding profiles of 14 drugs at 21 native and cloned human receptor subtypes. J Pharmacol Exp Ther 2002;303:791–804. 17. Jahnichen S, Horowski R, Pertz HH. Agonism at 5-HT2B receptors is not a class effect of the ergolines. Eur J Pharmacol 2005;513:225–228. 18. Hong Z, Smith AJ, Archer SL, Wu XC, Nelson DP, Peterson D, Johnson G, Weir EK. Pergolide is an inhibitor of voltage-gated potassium channels, including Kv1. 5, and causes pulmonary vasoconstriction. Circulation 2005;112:1494–1499. 19. Elangbam CS, Colman KA, Lightfoot RM, Tyler RD, Wall HG. Endocardial myxomatous change in Harlan Sprague–Dawley rats (Hsd:S-D) and CD-1 mice: its microscopic resemblance to drug-induced valvulopathy in humans. Toxicol Pathol 2002;30:483–491. Downloaded from by guest on October 28, 2014 Besides these typical histological findings, we also describe the presence of chondroı¨d metaplasia at the attachment sides of the aortic and mitral valves. This could be an age-related manifestation aggravated by overstimulation of the 5-HT receptor as reported in studies of human calcified valves.23,24 This phenomenon was also described in 5-HT transmembrane transporter knockout mice.12 In these mice, fibrotic lesions were found in the valves and in the heart with left ventricular dilatation and decreased fractional shortening. Although we did not observe valvular and myocardial fibrosis, the pergolide group also developed a pronounced, dilated cardiomyopathy with thinning of the left ventricular wall and decreased fractional shortening. Chronic AR and MR might lead to volume overload and eventually to the development of a dilated cardiomyopathy, but this might also be because of a direct toxic effect on the cardiomyocytes although we did not find necrosis of the cardiomyocytes. In the serotonin group, the left chamber dilatation was not so marked. In addition, histological examination showed hypertrophy of the cardiomyocytes in both groups, possibly reflecting the 5-HT receptor overstimulation, as described by others.25,26 Medications interacting with the serotonergic system are becoming increasingly common in clinical practice, i.e. in the treatment of migraine (5-HT1A receptor agonists), chemotherapy-induced emesis (5-HT3 receptor antagonists), irritable bowel syndrome (serotonin agonists and antagonists), depression (selective serotonin reuptake inhibitors), and Parkinson’s disease (pergolide and cabergoline).4,5 With the development of this model of pergolide-induced valvulopathy, it may also be possible to study other specific drug-induced diseases for preclinical research, including drugs with a low affinity for the 5-HT receptor. This in vivo animal model permits to answer urgent questions in the field of drug-induced valvulopathies. Exposure to higher cumulative doses of serotonergic drugs could lead to more pronounced valvular lesions, whereas recovery of valvular function might occur after cessation of these drugs. Furthermore, the addition of 5-HT receptor antagonists could reduce or inhibit the development of valvular lesions. These issues will require further investigation. Because echocardiography showed to be a very useful tool to study in vivo drug-induced valvulopathy in this study, it will be the method of choice for the serial assessment of cardiac valves during these interventions. 2161 2162 20. Simula DV, Edwards WD, Tazelaar HD, Connolly HM, Schaff HV. Surgical pathology of carcinoid heart disease: a study of 139 valves from 75 patients spanning 20 years. Mayo Clin Proc 2002;77:139–147. 21. Van Camp G, Flamez A, Cosyns B, Goldstein J, Perdaens C, Schoors D. Heart valvular disease in patients with Parkinson’s disease treated with high-dose pergolide. Neurology 2003;61:859–861. 22. Horvath J, Fross RD, Kleiner-Fisman G, Lerch R, Stalder H, Liaudat S, Raskoff WJ, Flachsbart KD, Rakowski H, Pache JC, Burkhard PR, Lang AE. Severe multivalvular heart disease: a new complication of the ergot derivative dopamine agonists. Mov Disord 2004;19:656–662. 23. Mohler ER III, Gannon F, Reynolds C, Zimmerman R, Keane MG, Kaplan FS. Bone formation and inflammation in cardiac valves. Circulation 2001; 103:1522–1528. S. Droogmans et al. 24. Levy RJ. Serotonin transporter mechanisms and cardiac disease. Circulation 2006;113:2–4. 25. Jaffre F, Callebert J, Sarre A, Etienne N, Nebigil CG, Launay JM, Maroteaux L, Monassier L. Involvement of the serotonin 5-HT2B receptor in cardiac hypertrophy linked to sympathetic stimulation: control of interleukin-6, interleukin-1beta, and tumor necrosis factor-alpha cytokine production by ventricular fibroblasts. Circulation 2004;110: 969–974. 26. Nebigil CG, Jaffre F, Messaddeq N, Hickel P, Monassier L, Launay JM, Maroteaux L. Overexpression of the serotonin 5-HT2B receptor in heart leads to abnormal mitochondrial function and cardiac hypertrophy. Circulation 2003;107:3223–3229. Downloaded from by guest on October 28, 2014