A selective, non-ischemic, non-pharmacological left ventricular failure animal model

DOCA-salts induce heart failure in the guinea pig

Heart failure (HF) is a common clinical problem confronting physicians and is often the final manifestation of many cardiovascular disorders. Despite recent advances in the pharmacological management of HF, it remains a highly lethal and disabling disorder. A number of animal models have been developed to study both the pathophysiology of HF and new therapeutic approaches to this complex syndrome. Only through an improved understanding of the basic biology of the early stages of the syndrome can HF be prevented or at least anticipated. With this in view, we have developed an easily realisable and inexpensive model in the guinea pig, which presents numerous structural, metabolic and biochemical similarities compared with the human heart. Thirty guinea pigs, aged 5 weeks and weighing 300 g were used. After anaesthesia, left nephrectomy was performed. After 1 week the guinea pigs were divided into: (a) control group (n=15), which received an injection of vehicle as well as tap water for 10 weeks; (b) DOCA-salts group (n=15), where the animals were treated with an IM injection of 10 mg DOCA 5 days a week for 10 weeks and with drinking water containing 9 g/l(-1) NaCl and 2 g/l(-1) KCl. Our results demonstrate that the administration of DOCA-salts to guinea pigs for 10 weeks caused a significant increase in blood pressure (BP+30%) associated with left ventricular hypertrophy (LVH), evaluated by LV weight (+37%), LV wall (+36%), by the ratio LV weight/Body weight (+23%) and by an increase in LV volume (+51%). Concerning HF, the latter was clinically evident through an increase in body weight, heart rate and dyspnoea. Indeed, guinea pigs presented pleural and/or pericardial effusion often associated with ascite. This model, which combines pressure and volume overload, results in a slow evolution towards HF. This allows a better understanding of the mechanisms in early LV remodelling which has the potential to develop into HF. Some recent studies have emphasised the value of using guinea pigs. The guinea pig heart muscle presents two major regulatory mechanisms of contractility that are closer to those found in humans, the isomyosin pattern which is predominantly V(3) and the phenomenon of Ca(2+)-induced Ca(2+)-release from the sarcoplasmic reticulum. The DOCA-salts model in the guinea pig is an easy surgical procedure with high post-operative survival, which causes an increase in arterial BP, LVH associated with HF. This model is a useful tool for studying some of the basic mechanisms of cardiovascular diseases.

Gross and microscopic pathological changes associated with nonthoracotomy implantable defibrillator leads

BACKGROUND

Although the effects of epicardial implantable cardioverter-defibrillator (ICD) leads on underlying cardiac tissue have been reported, the gross and microscopic changes associated with endocardial ICD leads are less well described. This study describes the gross and microscopic changes associated with endocardial ICD leads in humans.

METHODS AND RESULTS

The hearts from 8 patients were examined. At the time of ICD implantation, the patients' mean age was 47+/-11 years, and the left ventricular ejection fraction was 0.24+/-0.10. Four patients had ischemic heart disease, and 4 had dilated cardiomyopathy. Five hearts were examined after transplantation; 3, after death. The electrode-myocardial interfaces were characterized by intense endocardial fibrosis and were remarkably consistent. Each lead was encased by a ring of fibroelastic tissue, and there was fibrosis of the right ventricular myocardium adjacent to the leads. Fibrosis involved the tricuspid valve in 5 patients, and 1 had perforation of the valve by the lead. Microscopically, interstitial fibrosis was adjacent to each lead in the current path of ICD shocks. Acute cell injury was present only in the hearts that had received recent shocks.

CONCLUSIONS

The ICD electrode-myocardial interface is characterized by intense fibrosis. The fibrosis associated with endocardial ICD leads and the cumulative acute damage produced by defibrillation discharges may explain changes in the defibrillation and pacing thresholds and the difficulty of lead extraction that can be encountered with transvenous ICD systems.

Animal models of heart failure for pharmacological studies

1. Animals for the study of congestive heart failure (HF) should have chronic, stable disease produced by methods which allow controllable damage and hence predictable disease severity. 2. Pressure and volume loading have commonly been used in the past but these methods are limited by the difficulty of controlling the disease severity. 3. HF induced by cardiotoxic agents, particularly doxorubicin, has been widely used for experimental purposes, but again, control of the degree of damage may be difficult. 4. Coronary artery ligation or occlusion produces heart failure in experimental animals, with clear clinical relevance. Disadvantages of such techniques include fatal arrhythmias and collateral vessel growth that prevents or slows the onset of HF. 5. A minimally invasive model of HF which is relatively controllable can be produced by repeated or single DC shocks across the left ventricle. 6. Chronic rapid ventricular pacing produces a technically simple, predictable, stable and controllable preparation of HF with neurohumoral and haemodynamic changes which mimic the clinical pattern. These changes are reversible in the short term but after pacing for 1 year or longer complete recovery does not occur after cessation of pacing. 7. It has recently been suggested that a single DC shock, three to seven times the threshold defibrillating current, administered to the left ventricle, might provide the basis for the development of a model of heart failure which is technically simple and controllable.