RESUMO
The heart contains a collagen network that contributes to the contractility of the heart and provides cardiac strength. In cardiac diseases, an increase in collagen deposition is often observed. This fibrosis formation causes systolic and diastolic dysfunction, and plays a major role in the arrythmogenic substrate. Therefore, accurate detection of cardiac fibrosis and its progression is of clinical importance with regard to diagnostics and therapy for patients with cardiac disease. To evaluate cardiac collagen deposition, both invasive and non-invasive techniques are used. In this review the different techniques that are currently used in clinical and experimental setting are summarised, and the advantages and disadvantages of these techniques are discussed.
RESUMO
INTRODUCTION: Sudden arrhythmogenic cardiac death is a major cause of mortality in patients with congestive heart failure due to adverse electrical remodelling. To establish whether abnormal conduction is responsible for arrhythmogenic remodelling in progressed stages of heart failure, we have monitored functional, structural and electrical remodelling in a murine model of heart failure, induced by longstanding pressure overload. METHODS: Mice were subjected to transverse aortic constriction (TAC; n=18) or sham operated (n=19) and monitored biweekly by echocardiography and electrocardiography. At the 16-week endpoint, electrical mapping was performed to measure epicardial conduction velocity and susceptibility to arrhythmias. Finally, tissue sections were stained for Cx43 and fibrosis. RESULTS: In TAC mice, fractional shortening decreased gradually and was significantly lower compared with sham at 16 weeks. Left ventricular hypertrophy was significant after six weeks. TAC mice developed PQ prolongation after 12 weeks, QT prolongation after 16 weeks and QRS prolongation after two weeks. Right ventricular conduction velocity was slowed parallel to fibre orientation. In 8/18 TAC hearts, polymorphic ventricular tachyarrhythmias were provoked and none in sham hearts. TAC mice had more interstitial fibrosis than sham. Immunohistology showed that Cx43 levels were similar but highly heterogeneous in TAC mice. All parameters were comparable in TAC mice with and without arrhythmias, except for Cx43 heterogeneity, which was significantly higher in arrhythmogenic TAC mice. CONCLUSION.: Chronic pressure overload resulted in rapid structural and electrical remodelling. Arrhythmias were related to heterogeneous expression of Cx43. This may lead to functional block and unstable reentry, giving rise to polymorphic ventricular tachyarrhythmias. (Neth Heart J 2010;18:509-15.).
RESUMO
Mutations that are supposed to affect right (RV) and left ventricular (LV) electrophysiology equally, often reveal dominant conduction slowing and arrhythmia vulnerability in RV. In this study we investigated the mechanism of dominant arrhythmia vulnerability of RV in senescent mice. We performed epicardial ventricular activation mapping on adult and senescent Langendorff perfused hearts. Longitudinal and transversal conduction velocity, as well as arrhythmia inducibility were determined. Subsequently, hearts were processed for immunohisto-chemistry and Picro Sirius Red staining. Senescent mice revealed decreased conduction velocity, increased aniso-tropic ratio and reduced excitation wavelength in RV, but not in LV. Arrhythmias were mainly induced in RV of senescent hearts. No arrhythmias were induced in adult hearts. Immunohistochemistry revealed that the amount of Connexin 43 and cardiac sodium channel Nav1 .5 were equally decreased, and that collagen content was equally increased in senescent RV and LV. However, patches of replacement fibrosis were found throughout the RV wall, but only in the sub-endocardium and mid-myocardium of LV. The study shows that the dominant arrhythmia vulnerability in RV of senescent mice is caused by the distribution of replacement fibrosis which involves the entire RV but only part of the LV. (Neth Heart J 2008;16:356-8.).
RESUMO
During cardiac maturation, increased exposure of the heart to circulating catecholamines correlates with increased conduction velocity and growth of the heart. We used an in vitro approach to study the underlying mechanisms of adrenergic stimulation induced changes in conduction velocity. By combining functional measurements and molecular techniques, we were able to demonstrate that the increased conduction velocity after beta-adrenergic stimulation is probably not caused by changes in intercellular coupling. Instead, RT-PCR experiments and action potential measurements have shown an increased excitability that may well explain the observed increase in conduction velocity. Apart from being relevant to cardiac maturation, our findings are relevant in the context of stem cells and cardiac repair. Preconditioning of stem cell derived cardiomyocytes may help to enhance electrical maturation of de novo generated cardiomyocytes and consequently reduce their proarrhythmogenic potential. (Neth Heart J 2008;16:106-9.).
RESUMO
The gap junction protein Connexin43 (Cx43) is expressed in various cell types during embryonic development and in adult mice. Cx43 null mice (Cx43-/-) die perinatally due to cardiac malformation. In order to define the major functional role of Cx43 gap junction channels in adult mice and to circumvent perinatal death as well as direct or indirect compensation of Cx43 deficiency during development, we established a novel conditional Cx43 mouse mutant. To ablate Cx43 in adult mice in all cells that express Cx43 at a certain time, we targeted the 4-hydroxytamoxifen inducible Cre recombinase, Cre-ER(T), into the endogenous Cx43 locus. This approach left only one Cx43 coding region to be deleted upon induction of Cre-ER(T) activity. Highly efficient inducible ablation of Cx43 was shown in an embryonic stem cell test system and in adult mice. Although Cx43 protein was decreased in different tissues after induction of Cre-ER(T)-mediated recombination, cardiac abnormalities most likely account for death of those mice. Surface and telemetric ECG recordings revealed significant delay of ventricular activation and death during periods of bradyarrhythmia preceded by tachycardias. This novel approach of inducible ablation of Cx43 highlights the functional importance of normal activation of ventricular cardiomyocytes mediated by Cx43 gap junction channels in adult mouse heart to prevent initiation of fatal arrhythmias. The new mouse model should be useful for further analyses of molecular changes initiated by acute loss of Cx43 expression in various cell types.
