Elevations in myocardial stress initiate structural remodeling of the heart in an attempt to normalize the imposed stress. This remodeling consists of cardiomyocyte hypertrophy and changes in the amount of collagen, collagen phenotype and collagen cross-linking. Since fibrillar collagen is a relatively stiff material, a decrease in collagen can result in a more compliant ventricle while an increase in collagen or collagen cross-linking results in a stiffer ventricle. If continued elevations in wall stress exceed the ability of the heart to compensate, then the ventricular wall thickness is disproportionately reduced compared to chamber volume and diastolic and systolic dysfunction ensues. This review describes the structural organization of collagen within the myocardium, discusses its effect on ventricular function and considers whether therapy aimed at reducing fibrosis is efficacious in heart failure. The evidence indicates that chamber stiffness can clearly be affected by alterations in both collagen quantity and quality, with the effect of changes in collagen concentration being modified by the extent of collagen cross-linking. The limited evidence available regarding the effects of collagen on systolic function indicates that pharmacological attempts to reduce interstitial collagen have a negative impact. Accordingly, a shift in treatment strategies directed more specifically at affecting collagen cross-linking, rather than reducing the concentration of collagen, may be warranted in the prevention of the adverse impact of collagen alterations on myocardial remodeling.
This article outlines evidence that advanced glycation end product (AGE) inhibitors and breakers act primarily as chelators, inhibiting metal-catalyzed oxidation reactions that catalyze AGE formation. We then present evidence that chelation is the most likely mechanism by which ACE inhibitors, angiotensin receptor blockers, and aldose reductase inhibitors inhibit AGE formation in diabetes. Finally, we note several recent studies demonstrating therapeutic benefits of chelators for diabetic cardiovascular and renal disease. We conclude that chronic, low-dose chelation therapy deserves serious consideration as a clinical tool for prevention and treatment of diabetes complications.
Abstract-Correlative data suggest that cardiac mast cells are a component of the inflammatory response that is important to hypertension-induced adverse myocardial remodeling. However, a causal relationship has not been established. We hypothesized that adverse myocardial remodeling would be inhibited by preventing the release of mast cell products that may interact with fibroblasts and other inflammatory cells. Eight-week-old male spontaneously hypertensive rats were treated for 12 weeks with the mast cell stabilizing compound nedocromil (30 mg/kg per day). Age-matched Wistar-Kyoto rats served as controls. Nedocromil prevented left ventricular fibrosis in the spontaneously hypertensive rat independent of hypertrophy and blood pressure, despite cardiac mast cell density being elevated. The mast cell protease tryptase was elevated in the spontaneously hypertensive rat myocardium and was normalized by nedocromil. Treatment of isolated adult spontaneously hypertensive rat cardiac fibroblasts with tryptase induced collagen synthesis and proliferation, suggesting this as a possible mechanism of mast cell-mediated fibrosis. In addition, nedocromil prevented macrophage infiltration into the ventricle. The inflammatory cytokines interferon-␥ and interleukin (IL)-4 were increased in the spontaneously hypertensive rat and normalized by nedocromil, whereas IL-6 and IL-10 were decreased in the spontaneously hypertensive rat, with nedocromil treatment normalizing IL-6 and increasing IL-10 above the control. These results demonstrate for the first time a causal relationship between mast cell activation and fibrosis in the hypertensive heart. Furthermore, these results identify several mechanisms, including tryptase, inflammatory cell recruitment, and cytokine regulation, by which mast cells may mediate hypertension-induced left ventricular fibrosis.
The chronic elevation in ventricular wall stress secondary to ventricular volume or pressure overload leads to structural remodeling of the muscular, vascular and extracellular matrix components of the myocardium. While initially a compensatory response, the progressive hypertrophy and ventricular dilatation induced by this condition ultimately have a detrimental effect on ventricular function, resulting in heart failure. Fibrillar collagen provides the skeletal framework which interconnects the cardiomyocytes, thereby maintaining ventricular shape and size and contributing to tissue stiffness. Accordingly, these myocardial collagen fibers must be disrupted for ventricular dilatation, sphericalization and wall thinning to occur. The presence of an abundant, latent matrix metalloproteinase (MMP) population which coexists with myocardial fibrillar collagen has been documented. Thus, the potential for collagen degradation to exceed synthesis exists should there be significant activation of this latent MMP system. Mast cells are known to store and release a variety of biologically active mediators including TNF-alpha and proteases such as tryptase and chymase, which can induce MMP activation. Increased cardiac mast cell density has been implicated in the pathophysiology of human end-stage cardiomyopathy and experimental myocardial infarction, hypertension and chronic volume overload secondary to mitral regurgitation and aorto-caval fistula. The potential role of cardiac mast cells in activating MMPs, which then results in fibrillar collagen degradation and adverse myocardial remodeling secondary to chronic volume and pressure overload will be the subject of this review.
Abstract-Chronic activation of the sympathetic nervous system is a key component of cardiac hypertrophy and fibrosis.However, previous studies have provided evidence that also implicate inflammatory cells, including mast cells (MCs), in the development of cardiac fibrosis. The current study investigated the potential interaction of cardiac MCs with the sympathetic nervous system. Eight-week-old male spontaneously hypertensive rats were sympathectomized to establish the effect of the sympathetic nervous system on cardiac MC density, myocardial remodeling, and cytokine production in the hypertensive heart. Age-matched Wistar Kyoto rats served as controls. Cardiac fibrosis and hypertension were significantly attenuated and left ventricular mass normalized, whereas cardiac MC density was markedly increased in sympathectomized spontaneously hypertensive rats. Sympathectomy normalized myocardial levels of interferon-␥, interleukin 6, and interleukin 10, but had no effect on interleukin 4. The effects of norepinephrine and substance P on isolated cardiac MC activation were investigated as potential mechanisms of interaction between the two. Only substance P elicited MC degranulation. Substance P was also shown to induce the production of angiotensin II by a mixed population of isolated cardiac inflammatory cells, including MCs, lymphocytes, and macrophages. These results demonstrate the ability of neuropeptides to regulate inflammatory cell function, providing a potential mechanism by which the sympathetic nervous system and afferent nerves may interact with inflammatory cells in the hypertensive heart. (Hypertension. 2010;55:270-276.)
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