Coronary Microvascular Disease in Chronic Chagas Cardiomyopathy Including an Overview on History, Pathology, and Other Proposed Pathogenic Mechanisms

To investigate pathologic fibrosis and connective tissue matrix in left ventricular hypertrophy due to chronic arterial hypertension in humans. Seventeen human hearts were studied. Group 1 consisted of control hearts (four hearts, weighing 280 +/- 40 g each), from subjects who had had no evidence of heart disease and for whom the diagnoses of death were noncardiac. Groups 2 (five hearts, weighing 440 +/- 50 g each), 3 (five hearts, weighing 560 +/- 50 g each), and 4 (three hearts, weighing 680 +/- 60 g each) consisted of hearts from subjects who had had a history of systemic hypertension. All hearts had no valvular deformities and no evidence of ischemic disease at the postmortem examination. A cell-maceration method was employed to evaluate the myocardial connective matrix after removal of the nonfibrous elements of myocardial tissue, leaving behind a noncollapsed matrix, thus allowing a better three-dimensional view. Myocardial tissue was also processed for conventional light microscopic and morphometric studies. The minor transverse diameter of myocytes from hearts in groups 1-4 hearts were 13.7 +/- 7.8, 23.7 +/- 3.4, 26.6 +/- 3.7, and 32.8 +/- 5.8 microm, respectively. The volume fraction of fibrosis of the controls was 6.5%, whereas the volume fractions in hypertensive hearts increased progressively according to heart weight: 15.4, 22.9, and 31.1% for hearts in groups 2, 3, and 4, respectively. The most striking feature was the diffuse marked increase in amount of pericellular collagen weave fibers (endomysial matrix), parallel to the increase of heart weight. The hypertrophied myocytes were encased in a dense weave of collagen fibrils continuous with those of adjacent myocytes. The muscle fibers in hypertrophied hearts were markedly larger than normal, although this was extremely variable from an area to another. Besides, a diffuse increase in the number of thick collagen fibers constituting broad bands and sheets of collagen surrounding disorganized muscle bundles (perimysial matrix) was observed. Scattered dense scar-like foci, apparently replacing areas of myocyte loss, could be seen, mainly on the periphery of muscle bundles. This latter finding was more commonly observed among hypertrophied hearts from group 3 and, mainly, among hypertrophied hearts of group 4. Importantly, a progressive disarray of the connective tissue skeleton of the myocardium could be seen in parallel to the progressive increase of cardiac hypertrophy. The progressive accumulation of interstitial collagen fibers in left ventricular hypertrophy, in parallel to an increase in heart weight, can be expected to contribute to a spectrum of ventricular dysfunction involving either the diastolic or systolic phase of the cardiac cycle, or both, that is associated with the greater than normal arrhythmogenic risk for a hypertensive heart. Moreover, the methodology used is useful for studying the spatial organization of the collagen fibrils of the myocardium under normal and pathologic conditions.

A collagen network, composed largely of type I and III fibrillar collagens, is found in the extracellular space of the myocardium. This network has multiple functions which includes a preservation of tissue architecture and chamber geometry. Given its tensile strength, collagen is a major determinant of tissue stiffness. Its disproportionate accumulation, in the form of either a reactive or a reparative fibrosis, further increases stiffness. A degradation of collagen tethers, on the other hand, is an anatomic requisite for a distortion in tissue architecture and a reduction in stiffness that can lead to chamber dilatation, wall thinning, and even rupture of the myocardium. Collagen turnover in the myocardium is dynamic. When synthesis exceeds degradation, an adverse accumulation of collagen appears to distort tissue structure. This is true for either the hypertrophied and/or nonhypertrophied ventricle. Factors that contribute to the appearance of myocardial fibrosis are largely different from those that promote cardiac myocyte growth. Included amongst these fibrogenic factors are effector hormones of the reinin-angiotensin-aldosterone system (RAAS). Studies conducted both in intact animals (relative to dietary sodium intake) and in cultured adult cardiac fibroblasts have pointed toward the association between collagen accumulation and chronic elevations in circulating angiotensin II and aldosterone. A tissue hormonal system involving angiotensin II, endothelins and bradykinin, may likewise regulate fibrogenesis. In this regard, angiotensin converting enzyme is found in connective tissue of the normal heart, including the matrix of heart valves and the adventitia of the intramural coronary arteries, and fibrous tissue that forms following infarction or with chronic RAAS activation. The importance of ACE in the regulation of local angiotensin II and bradykinin levels and their contribution to collagen turnover is a fruitful area of research with important clinical implications. The myocardium also contains a proteolytic system, including collagenase. The characteristics and regulation of matrix metalloproteinases and their tissue inhibitors in various cardiovascular disease states requires further investigation.