Amanda L. Chancey scite author profile

The objectives of this study were to investigate the temporal response of left ventricular (LV) matrix metalloproteinase (MMP) activity and collagen volume fraction (CVF) induced by an aortocaval fistula and the role of cardiac mast cells in regulating MMP activity. LV tissue was analyzed for MMP activity, CVF, and mast cell number in rats euthanized at 0.5, 1, 2, 3, 5, 14, 21, 35, and 56 days. Additional rats treated with the mast cell membrane-stabilizing drug cromolyn sodium were euthanized 1, 2, and 3 days postfistula. Marked increases in MMP activity occurred rapidly and remained significantly elevated for 5 days before returning toward normal. A significant decrease in CVF occurred by day 5, but thereafter CVF rebounded to normal or above normal values. The number of myocardial mast cells also significantly increased postfistula, and there was a close association between mast cell density and MMP activity. Cromolyn treatment prevented the increase in mast cell number and MMP activity. Thus it is concluded that cardiac mast cells play a major role in the regulation of MMP activity.

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Effects of Matrix Metalloproteinase Inhibition on Ventricular Remodeling Due to Volume Overload

Chancey

et al. 2002

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Background-Left ventricular (LV) hypertrophy and dilatation are important compensatory responses to chronic volume overload. Although LV function is initially preserved by these responses, the continued structural remodeling of the myocardium ultimately becomes maladaptive, leading to the development of heart failure. We have shown previously that increased myocardial matrix metalloproteinase (MMP) activity precedes LV dilatation induced by a chronic volume overload. Accordingly, this study focused on the effects of MMP inhibition therapy (PD 166793, 1 mg · kg Ϫ1 · d

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Cardiac mast cell regulation of matrix metalloproteinase-related ventricular remodeling in chronic pressure or volume overload

Janicki

Brower

Gardner

et al. 2006

Cardiovascular Research

102

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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.

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The Dynamic Interaction Between Matrix Metalloproteinase Activity and Adverse Myocardial Remodeling

et al. 2004

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The process of cardiac remodeling in response to cardiac injury and/or persistent elevations in wall stress generally relates to the progressive changes that occur in ventricular chamber dimensions and the various components of the myocardium, in particular the cardiomyocytes and the extracellular matrix. Volume overload, pressure overload or myocardial injury produces a sustained abnormal elevation in myocardial wall stress which initiates cardiac remodeling that frequently results in ventricular decompensation and heart failure. Regardless of the inciting cause, there appear to be three distinct phases to this process. In the initial phase, fibrillar collagen is partially degraded secondary to increased matrix metalloproteinase (MMP) activity. Following this, there is a chronic compensatory phase during which MMP activity and collagen concentration return to normal while cardiomyocyte size continues to progressively increase. The final phase is attained once the compensatory hypertrophic mechanisms are exhausted and is characterized by elevated MMP activity, marked ventricular dilatation and prominent fibrosis. Details of this progressive, dynamic remodeling process and its effect on ventricular function during chronic volume overload, chronic pressure overload and following myocardial infarction will be the focus of this article.

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Amanda L. Chancey

Cause and effect relationship between myocardial mast cell number and matrix metalloproteinase activity

Effects of Matrix Metalloproteinase Inhibition on Ventricular Remodeling Due to Volume Overload

Cardiac mast cell regulation of matrix metalloproteinase-related ventricular remodeling in chronic pressure or volume overload

The Dynamic Interaction Between Matrix Metalloproteinase Activity and Adverse Myocardial Remodeling

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