Statins Protect Against Early Stages of Doxorubicin-induced Cardiotoxicity Through the Regulation of Akt Signaling and SERCA2.

Background: Doxorubicin-induced cardiomyopathy (DICM) is one of the complications that can limit treatment for a significant number of cancer patients. In animal models, the administration of statins can prevent the development of DICM. Therefore, the use of statins with anthracyclines potentially could enable cancer patients to complete their chemotherapy without added cardiotoxicity. The precise mechanism mediating the cardioprotection is not well understood. The purpose of this study is to determine the molecular mechanism by which rosuvastatin confers cardioprotection in a mouse model of DICM. Methods: Rosuvastatin was intraperitoneally administered into adult male mice at 100 µg/kg daily for 7 days, followed by a single intraperitoneal doxorubicin injection at 10 mg/kg. Animals continued to receive rosuvastatin daily for an additional 14 days. Cardiac function was assessed by echocardiography. Optical calcium mapping was performed on retrograde Langendorff perfused isolated hearts. Ventricular tissue samples were analyzed by immunofluorescence microscopy, Western blotting, and quantitative polymerase chain reaction. Results: Exposure to doxorubicin resulted in significantly reduced fractional shortening (27.4% ± 1.11% vs 40% ± 5.8% in controls; P < 0.001) and re-expression of the fetal gene program. However, we found no evidence of maladaptive cardiac hypertrophy or adverse ventricular remodeling in mice exposed to this dose of doxorubicin. In contrast, rosuvastatin-doxorubicin-treated mice maintained their cardiac function (39% ± 1.26%; P < 0.001). Mechanistically, the effect of rosuvastatin was associated with activation of Akt and phosphorylation of phospholamban with preserved sarcoplasmic/endoplasmic reticulum Ca2+ transporting 2 (SERCA2)-mediated Ca2+ reuptake. These effects occurred independently of perturbations in ryanodine receptor 2 function. Conclusions: Rosuvastatin counteracts the cardiotoxic effects of doxorubicin by directly targeting sarcoplasmic calcium cycling.

Contexte: La cardiomyopathie induite par la doxorubicine (CMID) est l'une des complications pouvant limiter le traitement d'un nombre considérable de patients atteints de cancer. Dans des modèles animaux, l'administration de statines peut prévenir l'apparition d'une CMID. Ainsi, l'utilisation de statines avec les anthracyclines pourrait vraisemblablement permettre aux patients de compléter leur chimiothérapie en évitant une cardiotoxicité supplémentaire. Le mécanisme précis qui sous-tend cet effet cardioprotecteur n'est pas entièrement élucidé. Cette étude a pour objectif de déterminer dans un modèle murin de CMID le mécanisme moléculaire par lequel la rosuvastatine confère une cardioprotection. Méthodologie: La rosuvastatine a été administrée par voie intrapéritonéale à des souris adultes mâles à une dose de 100 µg/kg par jour pendant sept jours, suivie d'une dose unique de doxorubicine de 10 mg/kg administrée par injection intrapéritonéale. Les animaux poursuivaient ensuite le traitement par la rosuvastatine une fois par jour pendant 14 jours supplémentaires. La fonction cardiaque a été mesurée par échocardiographie. Une cartographie optique du calcium a été réalisée sur des cœurs isolés soumis à une perfusion rétrograde selon la méthode de Langendorff. Des échantillons de tissu ventriculaire ont été analysés par microscopie en immunofluorescence, par buvardage de western et par mesure quantitative de l'amplification en chaîne par polymérase. Résultats: L'exposition à la doxorubicine a entraîné une diminution significative de la fraction de raccourcissement (27,4 % ± 1,11 % vs 40 % ± 5,8 % dans le groupe témoin; p < 0,001) et la réexpression du programme génique fœtal. Toutefois, aucune hypertrophie cardiaque inadaptée ni aucun remodelage ventriculaire indésirable n'ont été observés chez les souris ayant été exposées à la dose de doxorubicine étudiée. En revanche, la fonction cardiaque a été préservée chez les souris traitées par l'association rosuvastatine-doxorubicine (39 % ± 1,26 %; p < 0,001). Sur le plan du mode d'action, l'effet de la rosuvastatine a été associé à une activation de l'Akt et à une phosphorylation du phospholambane, avec préservation du recaptage de Ca2+ médié par la pompe SERCA2 (sarcoplasmic/endoplasmic reticulum Ca 2+ transporting 2). Ces effets sont survenus indépendamment des perturbations de la fonction du récepteur RyR2 (ryanodine receptor 2). Conclusions: La rosuvastatine neutralise les effets cardiotoxiques de la doxorubicine en ciblant directement la circulation sarcoplasmique du calcium.

Omnipolarity applied to equi-spaced electrode array for ventricular tachycardia substrate mapping.

AIMS: Bipolar electrogram (BiEGM)-based substrate maps are heavily influenced by direction of a wavefront to the mapping bipole. In this study, we evaluate high-resolution, orientation-independent peak-to-peak voltage (Vpp) maps obtained with an equi-spaced electrode array and omnipolar EGMs (OTEGMs), measure its beat-to-beat consistency, and assess its ability to delineate diseased areas within the myocardium compared against traditional BiEGMs on two orientations: along (AL) and across (AC) array splines. METHODS AND RESULTS: The endocardium of the left ventricle of 10 pigs (three healthy and seven infarcted) were each mapped using an Advisor™ HD grid with a research EnSite Precision™ system. Cardiac magnetic resonance images with late gadolinium enhancement were registered with electroanatomical maps and were used for gross scar delineation. Over healthy areas, OTEGM Vpp values are larger than AL bipoles by 27% and AC bipoles by 26%, and over infarcted areas OTEGM Vpp values are 23% larger than AL bipoles and 27% larger than AC bipoles (P < 0.05). Omnipolar EGM voltage maps were 37% denser than BiEGM maps. In addition, OTEGM Vpp values are more consistent than bipolar Vpps showing less beat-by-beat variation than BiEGM by 39% and 47% over both infarcted and healthy areas, respectively (P < 0.01). Omnipolar EGM better delineate infarcted areas than traditional BiEGMs from both orientations. CONCLUSION: An equi-spaced electrode grid when combined with omnipolar methodology yielded the largest detectable bipolar-like voltage and is void of directional influences, providing reliable voltage assessment within infarcted and non-infarcted regions of the heart.

Physiological Assessment of Ventricular Myocardial Voltage Using Omnipolar Electrograms.

BACKGROUND: Characterization of myocardial health by bipolar electrograms are critical for ventricular tachycardia therapy. Dependence of bipolar electrograms on electrode orientation may reduce reliability of voltage assessment along the plane of arrhythmic myocardial substrate. Hence, we sought to evaluate voltage assessment from orientation-independent omnipolar electrograms. METHODS AND RESULTS: We mapped the ventricular epicardium of 5 isolated hearts from each species-healthy rabbits, healthy pigs, and diseased humans-under paced conditions. We derived bipolar electrograms and voltage peak-to-peak (Vpps) along 2 bipolar electrode orientations (horizontal and vertical). We derived omnipolar electrograms and Vpps using omnipolar electrogram methodology. Voltage maps were created for both bipoles and omnipole. Electrode orientation affects the bipolar voltage map with an average absolute difference between horizontal and vertical of 0.25±0.18 mV in humans. Vpps provide larger absolute values than horizontal and vertical bipolar Vpps by 1.6 and 1.4 mV, respectively, in humans. Bipolar electrograms with the largest Vpps from either along horizontal or vertical orientation are highly correlated with omnipolar electrograms and with Vpps values (0.97±0.08 and 0.94±0.08, respectively). Vpps values are more consistent than bipoles, in both beat-by-beat (CoV, 0.28±0.19 versus 0.08±0.13 in human hearts) and rhythm changes (0.55±0.21 versus 0.40±0.20 in porcine hearts). CONCLUSIONS: Omnipoles provide physiologically relevant and consistent voltages that are along the maximal bipolar direction on the plane of the myocardium.

Effects of Late Sodium Current Blockade on Ventricular Refibrillation in a Rabbit Model.

BACKGROUND: After defibrillation of initial ventricular fibrillation (VF), it is crucial to prevent refibrillation to ensure successful resuscitation outcomes. Inability of the late Na+ current to inactivate leads to intracellular Ca2+ dysregulation and arrhythmias. Our aim was to determine the effects of ranolazine and GS-967, inhibitors of the late Na+ current, on ventricular refibrillation. METHODS AND RESULTS: Long-duration VF was induced electrically in Langendorff-perfused rabbit hearts (n=22) and terminated with a defibrillator after 6 minutes. Fibrillating hearts were randomized into 3 groups: treatment with ranolazine, GS-967, or nontreated controls. In the treated groups, hearts were perfused with ranolazine or GS-967 at 2 minutes of VF. In control experiments, perfusion solution was supplemented with isotonic saline in lieu of a drug. Inducibility of refibrillation was assessed after initial long-duration VF by attempting to reinduce VF. Sustained refibrillation was successful in fewer ranolazine-treated (29.17%; P=0.005) or GS-967-treated (45.83%, P=0.035) hearts compared with that in nontreated control hearts (84.85%). In GS-967-treated hearts, significantly more spontaneous termination of initial long-duration VF was observed (66.67%; P=0.01). Ca2+ transient duration was reduced in ranolazine-treated hearts compared with that in controls (P=0.05) and also Ca2+ alternans (P=0.03). CONCLUSIONS: Late Na+ current inhibition during long-duration VF reduces the susceptibility to subsequent refibrillation, partially by mitigating dysregulation of intracellular Ca2+. These results suggest the potential therapeutic use of ranolazine and GS-967 and call for further testing in cardiac arrest models.