The relationship between myocardial extracellular matrix remodeling and ventricular function☆ (original) (raw)

Journal Article

Department of Cell and Developmental Biology and Anatomy, School of Medicine, University of South Carolina, Columbia, SC 29208, United States

Search for other works by this author on:

Department of Cell and Developmental Biology and Anatomy, School of Medicine, University of South Carolina, Columbia, SC 29208, United States

Search for other works by this author on:

Department of Cell and Developmental Biology and Anatomy, School of Medicine, University of South Carolina, Columbia, SC 29208, United States

Search for other works by this author on:

Department of Cell and Developmental Biology and Anatomy, School of Medicine, University of South Carolina, Columbia, SC 29208, United States

Search for other works by this author on:

Department of Cell and Developmental Biology and Anatomy, School of Medicine, University of South Carolina, Columbia, SC 29208, United States

Search for other works by this author on:

Department of Cell and Developmental Biology and Anatomy, School of Medicine, University of South Carolina, Columbia, SC 29208, United States

Search for other works by this author on:

Department of Cell and Developmental Biology and Anatomy, School of Medicine, University of South Carolina, Columbia, SC 29208, United States

Search for other works by this author on:

Revision received:

10 July 2006

Published:

01 October 2006

Cite

Gregory L. Brower, Jason D. Gardner, Mary F. Forman, David B. Murray, Tetyana Voloshenyuk, Scott P. Levick, Joseph S. Janicki, The relationship between myocardial extracellular matrix remodeling and ventricular function, European Journal of Cardio-Thoracic Surgery, Volume 30, Issue 4, October 2006, Pages 604–610, https://doi.org/10.1016/j.ejcts.2006.07.006
Close

Navbar Search Filter Mobile Enter search term Search

Summary

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.

1 Introduction

The elevation in myocardial stress that results from cardiac injury and/or persistent elevations in ventricular developed pressure or volume initiates a structural remodeling of the myocardium in an attempt to return the tissue stress to its normal value. This process consists of progressive remodeling of the muscular, vascular and extracellular matrix (ECM) components of the heart that manifests as changes in ventricular wall and chamber dimensions. Depending on the cause, duration and magnitude of the increase in myocardial stress, the surviving myocytes undergo hypertrophy through in-series and/or parallel addition of sarcomeres and the ECM undergoes alterations in its interstitial collagen properties (e.g., fibrillar collagen concentration, types and cross-linking). In general, the stressed ventricle is considered to be compensated if the remodeling process results in near normal diastolic and systolic function reflected by attainment of an above normal ventricular mass-to-volume ratio sufficient to normalize myocardial wall stress. However, the heart will eventually fail if the sustained increase in wall stress exceeds the compensatory ability of the heart, exhausting the hypertrophic reserve without normalizing myocardial stress. At this stage of dysfunction, ventricular wall thickness is disproportionately reduced relative to an increase in chamber volume, ventricular geometry is becoming spherical, and there is significant myocardial fibrosis.

As fibrillar collagen is a relatively stiff material that is in intimate contact with all other components of the myocardium, it plays a crucial role in the maintenance of ventricular shape, size and function [1,2]. Degradation of myocardial collagen typically results in ventricular dilatation and a decrease in ventricular stiffness, while an increase in interstitial collagen concentration and/or cross-linking results in a stiffer myocardium and ventricular diastolic dysfunction. While the effects of changes in myocardial collagen on stiffness have been investigated extensively over the past 25 years, the influence of specific alterations in collagen properties on diastolic, systolic and lusitropic function have not been clearly delineated. This review will begin with a brief description of the organization and mechanical properties of myocardial collagen, continue with a synopsis of what is known regarding ECM remodeling and myocardial function, and conclude with a consideration of whether targeted therapy directed at reducing fibrosis in the failing heart would be efficacious.

2 Myocardial fibrillar collagen structural organization and mechanical properties

Interspersed between cardiomyocytes, nerves and blood vessels, the cardiac interstitium is comprised of ground substance and connective tissue which is predominantly collagen with relatively small amounts of fibronectin, laminin and elastin. The fibrillar collagens found in the myocardium include types I, III and V. These fibrillar collagens are comprised of three peptide chains intertwined to form a right-handed super-helix. Once interstitial collagen is deposited in mature form and subsequently cross-linked, it is extremely stable and resistant to degradation. However, interstitial collagen in the myocardium is not a static protein, and changes in the balance between synthesis and degradation may lead to alterations in the composition of the collagen network in the heart [3]. While the relative proportions of these collagens in the myocardium are dependent on both species and the type of digestion utilized to characterize solubility (i.e., pepsin or cyanogen bromide), type I collagen is the predominant type (normally >50%), followed by type III (between 10 and 45%) and type V (≪5%) [4–9]. The organization of the fibrillar collagen matrix has been described in terms of three major subdivisions, consisting of (1) the endomysial component which forms intricate networks of fibers that surround and interconnect individual myocytes, including the collagen struts that connect myocytes to neighboring myocytes and capillaries; (2) perimysial fibers that arborize to form weaves of collagen surrounding groups of myocytes and collagen fibers referred to as strands which join adjacent groups of myocytes to one another, as well as tendinous extensions spanning interconnections with the epimysium; and (3) the epimysium which is a sheath of collagenous connective tissue that encompasses muscle bundles [9–12].

In the normal adult heart, morphometric assessments indicate that approximately 2–4% of the myocardium is collagen. However, because collagen is a relatively stiff material with a high tensile strength, small changes in its concentration have been shown to exert marked effects on the passive mechanical properties of the heart [13]. In addition to the concentration of collagen, the passive behavior of the myocardium may also be dependent on the relative proportions of the types of collagen, the diameter of the collagen fibers and their spatial alignment, and the degree of cross-linking. Accordingly, tissue containing predominantly type I collagen, large diameter collagen fibers, and/or a high degree of cross-linking will be stiffer than tissue composed of greater concentrations of type III fibers, relatively small diameter collagen fibers and essentially no cross-linked collagen [14]. Examples of both extremes would be tendinous tissue which is highly resistant to elongation versus relatively compliant skin tissue. Another characteristic of fibrillar collagen which influences passive tissue properties is related to the coiled, spring-like nature or crimp of the collagen fibers [13,15]. Initially as the tissue is stretched, collagen fibers uncoil with minimal resistance, but once uncoiled, the stress required to produce further elongation increases exponentially, effectively restricting further stretch of the tissue.

3 Alterations in ECM fibrillar collagen properties and left ventricular diastolic function

3.1 Increased collagen concentration

An interest in the effects of increased collagen on left ventricular (LV) diastolic function was sparked in the late 1970s and early 1980s by the following seminal studies: Bing et al. [16] reported an increase in myocardial hydroxyproline in hypertrophied LV; Caulfield and Borg [17] reported the first description of the cardiac ECM ultrastructure; and Pearlman et al. [14] documented an increase in myocardial collagen concentration in hypertrophied human hearts from postmortem patients with and without heart failure. Since then there have been numerous studies with experimental (i.e., Goldblatt and abdominal aortic coarctation induced renovascular hypertension, aortic arch constriction, and perinephritic hypertension) or genetic (i.e., spontaneously hypertensive and Dahl salt-sensitive rats) hypertension to indicate a strong relationship between increased LV collagen concentration and chamber stiffness [2,18]. While these models of chronic pressure overload also result in significant myocyte hypertrophy, it has been shown that myocyte enlargement is not the cause of the increased myocardial stiffness. For example, Narayan et al. [19] were able to prevent myocyte hypertrophy with hydralazine but not the abnormal accumulation of collagen in spontaneously hypertensive rats (SHR). A comparison between hydralazine treated and untreated, hypertrophied SHR indicated that the passive myocardial stiffness was similar in both and significantly greater than the corresponding stiffness obtained in the genetic control. Others found no change in myocardial collagen concentration and LV diastolic chamber compliance in dogs with experimental hypertension despite significant hypertrophy [20,21]. Finally, in the athlete with a significant increase in LV mass and presumably physiologic hypertrophy, diastolic function is normal at rest and enhanced during exercise [22,23]. This physiologic hypertrophy is in contrast to hypertensive patients who typically have significant diastolic dysfunction despite an increase in LV mass that is less than that occurring in athletes [24]. In view of the fact that collagen concentration is increased in humans with systemic hypertension [14] and that diastolic abnormalities in hypertensive patients are not related to increases in LV mass [25], it is reasonable to assume that hypertension-related diastolic dysfunction is the result of excessive myocardial collagen.

3.2 Decreased collagen concentration

As stated earlier, collagen is extremely stable and highly resistant to degradation by all proteinases except specific collagenases [26]. While copious amounts of collagenase were first demonstrated in the heart by Monfort and Pérez-Tamayo [27], fortunately only 1–2% of this total myocardial collagenase is normally present in its active form [28,29]. However, most of the latent collagenase is closely associated with the collagen matrix, such that a sudden activation of this ECM-bound enzyme would result in rapid and extensive collagen degradation. Indeed studies have demonstrated significant collagen breakdown occurring within 24 h following an experimentally induced myocardial infarction. Specifically, Takahashi et al. [30] reported degradation of approximately 50% of myocardial collagen in the infarcted area within 3 h of infarction coinciding with a two- to three-fold increase in tissue collagenase activity. A similar increase in collagenase activity and rapid collagen degradation was observed in ischemic reperfused, stunned myocardium [31,32].

Matrix metalloproteinase (MMP) activation and consequent collagen degradation have also been reported in the cardiomyopathic and failing heart. Gunja-Smith et al. [33] reported a 30-fold increase in collagenase activity in explanted hearts from patients with documented dilated cardiomyopathy. Subsequently, others have reported similar increases in MMP activity in patients with heart failure secondary to dilated cardiomyopathy [34–36]. While these findings suggest an association between increased MMP activity and ventricular remodeling (i.e., ventricular dilatation, sphericalization and increased compliance), they are ‘after-the-fact’ findings in that dilatation had already occurred, and did not necessarily reflect a cause and effect relationship. However, a direct cause and effect relationship between increased MMP activity and ventricular remodeling was evident from the findings in a temporal study comparing cardiomyopathic and golden Syrian hamsters between the ages of 150 and 300 days [37]. In contrast to control hearts, in which the collagen volume fraction (CVF) and MMP activity were age-invariant, there was a continual increase in MMP activity in the cardiomyopathic Syrian hamster, such that collagen degradation eventually exceeded synthesis, producing a decrease in CVF which coincided with the occurrence of significant ventricular dilatation and wall thinning.

Further insight into the relation between MMP activity, collagen degradation and adverse ventricular remodeling was demonstrated in a rat aorto-caval (AV) fistula model of chronic biventricular volume overload [38]. Within 12 h of creating the fistula, a significant increase in MMP activity occurred which was sustained for approximately the first week. As a consequence of this mast cell-mediated MMP activation, CVF was significantly decreased by the third day [39]. The onset of progressive ventricular dilatation and hypertrophy was apparent at one week post-fistula [38], and this myocardial remodeling in the initial phase of volume overload was considered to be deleterious in that it resulted in a significant depression in chamber contractility and the ventricle was clearly more compliant. As further evidence of a cause and effect relation between collagen degradation and ventricular dilatation, there are several reports indicating the ability of MMP inhibitors to attenuate ventricular dilatation using this and other experimental models of heart failure [40–43]. From these findings, one could conclude that elevations in MMP activity during the early stages of injury or elevated wall stress and the consequent degradation of fibrillar collagen are responsible for the initiation of a progressive remodeling process that eventually leads to heart failure.

3.3 Altered ratio of collagen types

The ratio of collagen types I/III has been reported to increase in the following disease states: experimentally induced or genetic hypertension [6,8,44]; in patients with dilated cardiomyopathy [45]; and in experimental myocardial infarction [46]. Whereas, in experimental animals and patients with diabetes the type I/III ratio was reported to be below that of a non-diabetic control group [47,48]. However, the functional consequences of altered amounts of type I and/or type III collagens, if any, have not been rigorously determined. Burgess et al. [44] reported a correlation (i.e., r = 0.91) between an index of LV relaxation (i.e., maximal rate of fall of LV pressure divided by mean arterial pressure) and the type I/III ratio indicating a slower relaxation rate as the amount of collagen type I increased relative to type III. Weber et al. [9] reported an early but transient increase in type III collagen relative to type I in hypertensive primates, which corresponded to an increase in myocardial stiffness. An increase in type III collagen, but not type I, was also documented in the myocardium of diabetic patients [47]. However, in addition to alterations in the ratio of collagen types in these studies there were also significant increases in total collagen concentration, which could have influenced the LV relaxation rate, myocardial stiffness or both. This was supported by a study myocardial biopsy specimens and LV function in patients with hypertension, where a significant increase in the collagen type I/III ratio was not associated with an increase in diastolic stiffness when overall collagen content was unchanged [49]. Given the variable relationship between the ratio of collagen types and myocardial stiffness, no definitive conclusions can be drawn regarding the functional consequences of such alterations.

3.4 Altered collagen cross-linking

Cross-linking is a process whereby collagen fibers are covalently linked to one another resulting in increased material stiffness and greater resistance to degradation. The formation of these cross-links occurs naturally with aging [50] and is also exacerbated in chronic diseases such as hypertension [51,52], chronic ventricular volume overload [53,54] and diabetes [48,55]. While there are several types of cross-linking, the most extensively characterized and predominant type is thought to be associated with advanced glycation end (AGE) products [56]. In most studies, the degree of cross-linking has been determined by the amount of insoluble collagen relative to soluble collagen content in the heart. Pertinent to this review, several studies have investigated the influence of collagen cross-linking on diastolic function. Norton et al. [51] concluded that increased myocardial stiffness secondary to hypertension in SHR is the result of enhanced myocardial collagen cross-linking rather than increased collagen concentration. Similarly, Woodiwiss et al. [52] demonstrated that a reduction in collagen cross-linking results in reduced myocardial stiffness and ventricular dilatation, irrespective of collagen concentration or type, in two rat models of pressure-overload induced heart failure (i.e., suprarenal abdominal aortic banding and chronic isoproterenol administration). Finally, Avendano et al. [55] reported aminoguanidine was able to prevent collagen cross-linking and the increase in LV chamber stiffness in diabetic dogs, without preventing diabetes-induced fibrosis. From these studies, it is obvious that the degree of collagen cross-linking has a strong impact on diastolic function, which is independent of myocardial collagen concentration. However, this should not be interpreted as suggesting myocardial stiffness is not influenced by alterations in myocardial collagen concentration. Rather, as Badenhorst et al. [57] elegantly demonstrated using experimental models of pressure overload, myocardial and LV chamber stiffness is affected by changes in both collagen quantity and quality (i.e., cross-linking), with the effect of changes in collagen concentration being modified by collagen quality.

4 Alterations in ECM fibrillar collagen and left ventricular systolic function

In contrast to the preponderance of myocardial ECM studies focused on diastolic function, there have been relatively few which have attempted to assess the effects of ECM alterations on myocardial systolic function. Baicu et al. [1] studied isolated papillary muscle from normal rat and feline hearts, as well as from felines with pressure overload induced hypertrophy and fibrosis, that were treated with plasmin to produce an acute activation of MMPs and disruption of the ECM. This decrease in collagen in the papillary muscles was accompanied by a marked decrease in systolic function (i.e., reduced amount and rate of shortening, reflected by developed tension (T) and +d_T_/d_t_) without affecting isolated cardiomyocyte contractility, leading the authors to conclude that myocardial fibrillar collagen is a major contributor to normal myocardial systolic performance. In contrast to these findings, Lamberts et al. [58] reported myocardial function was improved following specific degradation of collagen type I (i.e., an increase in developed tension and the rate of relaxation). Unfortunately, relaxation rates were not reported in the Baicu study, precluding comparison of this parameter. When considering this disparity, however, it should be noted that the preparation used by the Lamberts group was perfused, and consequently significant edema, evident by a significant increase in the diastolic tension-length curve, accompanied the disruption of collagen. In their discussion the authors concluded that an edema-induced Starling response may have masked the functional effects of collagen removal. Recent studies in our laboratory using an isolated, beating rat heart preparation, resulted in significant decreases in the peak isovolumetric pressure (25%) and in the maximal rates of LV pressure development (80%) and relaxation (90%) following an acute decrease of approximately 50% in collagen concentration (unpublished results). While edema also occurred in these studies, collagen degradation resulted in significant dilatation without a change in the overall compliance of the myocardium [59,60]. Thus, our findings are in agreement with the conclusion of Biacu et al. [1] that normal amounts of interstitial collagen contribute to the maintenance of systolic function.

Significant fibrosis is known to occur in human hypertensive, hypertrophied hearts and in the dilated failing heart regardless of etiology [14,61–63]. This has led to the notion that this fibrosis is at least partially responsible for the diminished ventricular function. Accordingly, one could hypothesize that reducing the amount of fibrosis would be beneficial to the failing heart. Thus far, the impact of ECM alterations on functional deterioration in heart failure has been primarily derived from studies of left ventricular assist device (LVAD) performance as a bridge to recovery/transplantation. There is currently intensive interest in identifying those patients who can be successfully weaned from LVAD support [64–66]. The supposition has been that reversal of the deleterious remodeling in heart failure is responsible for the observed clinical improvement in LVAD patients. Some findings appear to corroborate this expectation, with several studies reporting reverse remodeling characterized by significant reductions in the extent of myocardial fibrosis and cardiomyocyte size [67–71]. However, an equivalent number of studies have found improvement in functional parameters despite significant increases in myocardial collagen [72–75]. The improvement in systolic function observed in both cases suggests that the benefit of LVAD support was independent of effects on myocardial fibrosis. This was a possibility raised by Li et al. [76], who found minimal differences in total collagen, but significant increases in collagen cross-linking in LVAD supported hearts. Thus, a definitive cause and effect relationship between fibrosis and depressed systolic function has not been established.

Furthermore, there is evidence to indicate that a reduction in the myocardial collagen matrix could further exacerbate the severity of heart failure. As mentioned above, Baicu et al. [1] reported a decrease in systolic function in papillary muscles from pressure overloaded right ventricles following ECM disruption. Another study indicating that inducing collagen degradation may be contraindicated utilized the spontaneously hypertensive heart failure (SHHF) rat [41]. In the SHHF model, significant elevations in myocardial MMP activity occur between 9 and 13 months of age. During this interval, clinical signs of congestive heart failure become evident and the heart becomes functionally depressed, markedly enlarged and abnormally compliant, such that it can no longer maintain the elevated pressures. However, treatment with a broad-spectrum MMP inhibitor starting at 9 months of age, which presumably prevented collagen degradation, was cardioprotective in that the transition to a decompensated state did not occur [41]. The disconnect between fibrosis and impaired systolic function is also reflected by our findings in the AV fistula model, where LV contractility progressively declined despite myocardial collagen concentration remaining at normal levels prior to the development of heart failure [39]. Finally, if myocardial fibrosis is primarily due to cardiomyocyte necrosis (i.e., reparative or replacement fibrosis), then it is doubtful that collagen degradation would be beneficial. In this case, the heavily cross-linked scar tissue is less vulnerable to degradation than the normal endomysial collagen responsible for maintaining integrity of the myocardial tissue. Significant degradation of this ultrastructural collagen coinciding with the development of ventricular dilatation was noted in the cardiomyopathic hamster even though total collagen remained above normal due to the extensive scarring resulting from myocyte necrosis [77].

While therapy to reduce fibrosis may be contraindicated, the use of pharmacological agents to reduce the degree of cross-linking warrants further clinical investigation. Studies in older animals with and without experimental diabetes using such agents have reported marked improvement in both diastolic and systolic function [48,50,55,56]. The cross-link breaker, alagebrium chloride (ALT-711) has been tested in a clinical study using 21 aged patients with diastolic dysfunction. In this 16-week, open-label study, LV diastolic filling, peak oxygen consumption, aortic distensibility and LV ejection fraction and mass before and after treatment was non-invasively assessed. The results indicated a small but significant reduction in mass and a slight improvement in some of the early filling parameters with no change in the remaining variables. Despite the limited improvement during this relatively short study, these clinical results together with the encouraging animal findings justify additional larger clinical trials of longer duration.

In summary, the properties of the interstitial collagen matrix influence the stiffness of the myocardium, thereby contributing to the development of diastolic dysfunction. While changes in the relative distribution of collagen types occur during the course of myocardial remodeling secondary to sustained elevations in pressure or volume, the functional consequences remain to be determined. In contrast, 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. Therefore, a shift in treatment strategies for heart failure directed more specifically at affecting collagen cross-linking, rather than reducing the concentration of collagen, may be warranted in the attenuation of the adverse impact of collagen alterations on myocardial remodeling.

☆

Presented at Cardiodynamics: Ventricular Wall Structure and Cardiac Function, Institute of Biomedical Engineering, University and ETH Zurich, Switzerland, November 4–5 2005.

Acknowledgements

This work was supported in part by grants from: NHLBI (RO1-HL-59981, HL-62228, HL-73990 and F32 HL072566) and from the American Heart Association (0435298N).

References

[1]

Changes in extracellular collagen matrix alter myocardial systolic performance

Am J Physiol Heart Circ Physiol

2003

, vol.

284

(pg.

H122

H132

)

[2]

Myocardial collagen and left ventricular diastolic dysfunction

Left ventricular diastolic dysfunction

1993

Philadelphia

Lea Febiger

(pg.

125

140

)

[3]

Collagen turnover and its regulation in the normal and hypertrophying heart

Eur Heart J

1995

, vol.

Suppl. C

(pg.

)

[4]

Age-related changes in the proportion of types I and III collagen

Mech Ageing Dev

1988

, vol.

(pg.

203

212

)

[5]

Characterization of intramuscular collagen in the mammalian left ventricle

Basic Res Cardiol

1982

, vol.

(pg.

589

598

)

[6]

Collagen phenotypes during development and regression of myocardial hypertrophy in spontaneously hypertensive rats

Circ Res

1990

, vol.

(pg.

1474

1480

)

[7]

Alteration of collagen phenotypes in ischemic cardiomyopathy

J Clin Invest

1991

, vol.

(pg.

1141

1146

)

[8]

Alteration of cardiac collagen phenotypes in hypertensive hypertrophy: role of blood pressure

J Mol Cell Cardiol

1993

, vol.

(pg.

185

196

)

[9]

Collagen remodeling of the pressure-overloaded, hypertrophied nonhuman primate myocardium

Circ Res

1988

, vol.

(pg.

757

765

)

[10]

The collagen matrix of the heart

Fed Proc

1981

, vol.

(pg.

2037

2041

)

[11]

Skeletal framework of mammalian heart muscle. Arrangement of inter- and pericellular connective tissue structures

Lab Invest

1983

, vol.

(pg.

482

498

)

[12]

The heart as a suction pump

Sci Am

1986

, vol.

254

(pg.

)

[13]

Coiled perimysial fibers of papillary muscle in rat heart: morphology, distribution, and changes in configuration

Circ Res

1988

, vol.

(pg.

577

592

)

[14]

Muscle fiber orientation and connective tissue content in the hypertrophied human heart

Lab Invest

1982

, vol.

(pg.

158

164

)

[15]

Left ventricular perimysial collagen fibers uncoil rather than stretch during diastolic filling

Basic Res Cardiol

1996

, vol.

(pg.

111

122

)

[16]

Mechanical properties of rat cardiac muscle during experimental hypertrophy

Circ Res

1971

, vol.

(pg.

234

245

)

[17]

The collagen network of the heart

Lab Invest

1979

, vol.

(pg.

364

372

)

[18]

Extracellular matrix and cardiac remodeling

Interstitial fibrosis in heart failure

2005

New York

Springer

(pg.

)

[19]

Myocardial collagen and mechanics after preventing hypertrophy in hypertensive rats

Am J Hypertens

1989

, vol.

(pg.

675

682

)

[20]

Changes in diastolic cardiac function in developing and stable perinephritic hypertension in conscious dogs

Circ Res

1991

, vol.

(pg.

555

567

)

[21]

Hypertrophy, fibrosis and diastolic dysfunction in early canine experimental hypertension

J Am Coll Cardiol

1991

, vol.

(pg.

530

536

)

[22]

A comparative study of left ventricular structure and function in elite athletes

Br J Sports Med

1991

, vol.

(pg.

)

[23]

Effects of exercise on left ventricular diastolic performance in trained athletes

Am J Cardiol

1991

, vol.

(pg.

945

949

)

[24]

Left ventricular hypertrophy. Relation of structure to diastolic function in hypertension

Br Heart J

1984

, vol.

(pg.

637

642

)

[25]

Correlates of diastolic filling abnormalities in hypertension: a doppler echocardiographic study

Am Heart J

1991

, vol.

120

(pg.

386

391

)

[26]

Mammalian collagenases

Extracellular matrix biochemistry

1984

New York

Elsevier

(pg.

119

158

)

[27]

The distribution of collagenase in normal rat tissues

J Histochem Cytochem

1975

, vol.

(pg.

910

920

)

[28]

Direct extraction and estimation of collagenase(s) activity by zymography in microquantities of rat myocardium and uterus

Clin Biochem

1993

, vol.

(pg.

191

198

)

[29]

Collagenase immunolocalization studies of rheumatoid and malignant tissues

Collagenase in normal and pathological tissues

1978

New York

John Wiley & Sons

(pg.

105

125

)

[30]

Collagen degradation in ischaemic rat hearts

Biochem J

1990

, vol.

265

(pg.

233

241

)

[31]

Collagen loss in the stunned myocardium

Circulation

1992

, vol.

(pg.

1483

1490

)

[32]

Collagenase degrades collagen in vivo in the ischemic heart

Biochim Biophys Acta

1999

, vol.

1428

(pg.

251

259

)

[33]

Remodeling of human myocardial collagen in idiopathic dilated cardiomyopathy—role of metalloproteinases and pyridinoline cross-links

Am J Pathol

1996

, vol.

148

(pg.

1639

1648

)

[34]

Differential expression of tissue inhibitors of metalloproteinases in the failing human heart

Circulation

1998

, vol.

(pg.

1728

1734

)

[35]

Expression of matrix metalloproteinase activity in idiopathic dilated cardiomyopathy: a marker of cardiac dilatation

Mol Cell Biochem

2004

, vol.

264

(pg.

183

191

)

[36]

Increased matrix metalloproteinase activity and selective upregulation in LV myocardium from patients with end-stage dilated cardiomyopathy

Circulation

1998

, vol.

(pg.

1708

1715

)

[37]

Collagen degradation in the heart

Molecular biology of collagen matrix in the heart

1995

Austin

R.G. Landes Company

(pg.

)

[38]

Temporal evaluation of left ventricular remodeling and function in rats with chronic volume overload

Am J Physiol Heart Circ Physiol

1996

, vol.

271

(pg.

H2071

H2078

)

[39]

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

Am J Physiol Heart Circ Physiol

2002

, vol.

283

(pg.

H518

H525

)

[40]

Effects of matrix metalloproteinase inhibition on ventricular remodeling due to volume overload

Circulation

2002

, vol.

105

(pg.

1983

1988

)

[41]

Matrix metalloproteinase inhibition attenuates left ventricular remodeling and dysfunction in a rat model of progressive heart failure

Circulation

2001

, vol.

103

(pg.

2303

2309

)

[42]

Matrix metalloproteinase inhibition attenuates early left ventricular enlargement after experimental myocardial infarction in mice

Circulation

1999

, vol.

(pg.

3063

3070

)

[43]

Matrix metalloproteinase inhibition during the development of congestive heart failure: effects on left ventricular dimensions and function

Circ Res

1999

, vol.

(pg.

364

376

)

[44]

Exercise- and hypertension-induced collagen changes are related to left ventricular function in rat hearts

Am J Physiol Heart Circ Physiol

1996

, vol.

270

(pg.

H151

H159

)

[45]

Dilated cardiomyopathy is associated with an increase in the type I/type III collagen ratio: a quantitative assessment

J Am Coll Cardiol

1995

, vol.

(pg.

1263

1272

)

[46]

Left and right ventricular collagen type I/III ratios and remodeling post-myocardial infarction

J Card Fail

1999

, vol.

(pg.

117

126

)

[47]

Collagen remodelling in myocardia of patients with diabetes

J Clin Pathol

1993

, vol.

(pg.

)

[48]

Glycation end-product cross-link breaker reduces collagen and improves cardiac function in aging diabetic heart

Am J Physiol Heart Circ Physiol

2003

, vol.

285

(pg.

H2587

H2591

)

[49]

Semiquantitative analysis of collagen types in the hypertrophied left ventricle

J Anat

1998

, vol.

198

(pg.

)

[50]

An advanced glycation endproduct cross-link breaker can reverse age-related increases in myocardial stiffness

Proc Natl Acad Sci

2000

, vol.

(pg.

2809

2813

)

[51]

Myocardial stiffness is attributed to alterations in cross-linked collagen rather than total collagen or phenotypes in spontaneously hypertensive rats

Circulation

1997

, vol.

(pg.

1991

1998

)

[52]

Reduction in myocardial collagen cross-linking parallels left ventricular dilatation in rat models of systolic chamber dysfunction

Circulation

2001

, vol.

103

(pg.

155

160

)

[53]

Increase in cross-linking of type I and type III collagens associated with volume-overload hypertrophy

Circ Res

1988

, vol.

(pg.

399

408

)

[54]

Glycated collagen cross-linking alters cardiac mechanics in volume-overload hypertrophy

Am J Physiol Heart Circ Physiol

2003

, vol.

284

(pg.

H1277

H1284

)

[55]

Effects of glucose intolerance on myocardial function and collagen-linked glycation

Diabetes

1999

, vol.

(pg.

1443

1447

)

[56]

Crosslink breakers: a new approach to cardiovascular therapy

Curr Opin Cardiol

2004

, vol.

(pg.

336

340

)

[57]

Cross-linking influences the impact of quantitative changes in myocardial collagen on cardiac stiffness and remodelling in hypertension in rats

Cardiovasc Res

2003

, vol.

(pg.

632

641

)

[58]

Acute and specific collagen type I degradation increases diastolic and developed tension in perfused rat papillary muscle

Am J Physiol Heart Circ Physiol

2004

, vol.

286

(pg.

H889

H894

)

[59]

Endothelin-1 mediates cardiac mast cell degranulation, matrix metalloproteinase activation and myocardial remodeling in rats

Am J Physiol Heart Circ Physiol

2004

, vol.

287

(pg.

H2295

H2299

)

[60]

Cardiac mast cell-mediated activation of gelatinase and alteration of ventricular diastolic function

Am J Physiol Heart Circ Physiol

2002

, vol.

282

(pg.

H2152

H2158

)

[61]

Myocardial collagen network in dilated cardiomyopathy. Morphometry and scanning electron microscopy study

Ir J Med Sci

1991

, vol.

160

(pg.

399

401

)

[62]

Patterns of myocardial fibrosis in idiopathic cardiomyopathies and chronic chagasic cardiopathy

Can J Cardiol

1991

, vol.

(pg.

287

294

)

[63]

Impairment of the myocardial ultrastructural and changes of the cytoskeleton in dialted cardiomyopathy

Circulation

1991

, vol.

(pg.

504

514

)

[64]

LVAD-induced reverse remodeling: basic and clinical implications for myocardial recovery

J Card Fail

2006

, vol.

(pg.

227

239

)

[65]

Reverse remodeling following insertion of left ventricular assist devices (LVAD): a review of the morphological and molecular changes

Cardiovasc Res

2005

, vol.

(pg.

376

386

)

[66]

Left ventricular assist devices and the failing heart: a bridge to recovery, a permanent assist device, or a bridge too far?

Circulation

1998

, vol.

(pg.

2367

2369

)

[67]

Plasma neurohormone levels correlate with left ventricular functional and morphological improvement in LVAD patients

J Surg Res

2005

, vol.

123

(pg.

)

[68]

Evidence of improved right ventricular structure after LVAD support in patients with end-stage cardiomyopathy

J Heart Lung Transplant

2004

, vol.

(pg.

)

[69]

Regression of fibrosis and hypertrophy in failing myocardium following mechanical circulatory support

J Heart Lung Transplant

2001

, vol.

(pg.

457

464

)

[70]

The implications for cardiac recovery of left ventricular assist device support on myocardial collagen content

Am J Surg

2000

, vol.

180

(pg.

498

501

)

[71]

Cellular and hemodynamics responses of failing myocardium to continuous flow mechanical circulatory support using the DeBakey-Noon left ventricular assist device: a comparative analysis with pulsatile-type devices

J Heart Lung Transplant

2005

, vol.

(pg.

566

575

)

[72]

Mechanical unloading during left ventricular assist device support increases left ventricular collagen cross-linking and myocardial stiffness

Circulation

2005

, vol.

112

(pg.

364

374

)

[73]

Comparison of right and left ventricular responses to left ventricular assist device support in patients with severe heart failure: a primary role of mechanical unloading underlying reverse remodeling

Circulation

2001

, vol.

104

(pg.

670

675

)

[74]

Time course of reverse remodeling of the left ventricle during support with a left ventricular assist device

J Thorac Cardiovasc Surg

2001

, vol.

121

(pg.

902

908

)

[75]

Structural and left ventricular histologic changes after implantable LVAD insertion

Ann Thorac Surg

1995

, vol.

(pg.

609

613

)

[76]

Downregulation of matrix metalloproteinases and reduction in collagen damage in the failing human heart after support with left ventricular assist devices

Circulation

2001

, vol.

104

(pg.

1147

1152

)

[77]

Interstitial collagen remodeling in chronic heart failure

Basic Appl. Myology

1995

, vol.

(pg.

339

348

)

Topic:

Advertisement intended for healthcare professionals

Citations

Views

Altmetric

Metrics

Total Views 2,675

1,756 Pageviews

919 PDF Downloads

Since 1/1/2017

Month:	Total Views:
January 2017	2
February 2017	7
March 2017	3
April 2017	7
May 2017	13
June 2017	10
July 2017	8
August 2017	19
September 2017	8
October 2017	6
November 2017	6
December 2017	20
January 2018	17
February 2018	32
March 2018	43
April 2018	35
May 2018	42
June 2018	43
July 2018	38
August 2018	44
September 2018	36
October 2018	38
November 2018	48
December 2018	32
January 2019	44
February 2019	42
March 2019	52
April 2019	57
May 2019	47
June 2019	37
July 2019	26
August 2019	51
September 2019	32
October 2019	27
November 2019	22
December 2019	27
January 2020	17
February 2020	16
March 2020	26
April 2020	27
May 2020	23
June 2020	20
July 2020	24
August 2020	19
September 2020	26
October 2020	9
November 2020	15
December 2020	22
January 2021	19
February 2021	19
March 2021	24
April 2021	30
May 2021	12
June 2021	17
July 2021	21
August 2021	20
September 2021	38
October 2021	23
November 2021	17
December 2021	20
January 2022	40
February 2022	28
March 2022	49
April 2022	27
May 2022	47
June 2022	27
July 2022	29
August 2022	34
September 2022	25
October 2022	46
November 2022	41
December 2022	32
January 2023	51
February 2023	25
March 2023	28
April 2023	28
May 2023	36
June 2023	38
July 2023	23
August 2023	34
September 2023	21
October 2023	32
November 2023	37
December 2023	32
January 2024	37
February 2024	41
March 2024	31
April 2024	30
May 2024	40
June 2024	31
July 2024	42
August 2024	32
September 2024	29
October 2024	27

Citations

223 Web of Science

The relationship between myocardial extracellular matrix remodeling and ventricular function☆ (original) (raw)

Cite

Summary

1 Introduction

2 Myocardial fibrillar collagen structural organization and mechanical properties

3 Alterations in ECM fibrillar collagen properties and left ventricular diastolic function

3.1 Increased collagen concentration

3.2 Decreased collagen concentration

3.3 Altered ratio of collagen types

3.4 Altered collagen cross-linking

4 Alterations in ECM fibrillar collagen and left ventricular systolic function

Acknowledgements

References

Citations

Views

Altmetric

Email alerts

Citing articles via

Most Cited

The relationship between myocardial extracellular matrix remodeling and ventricular function☆ (original) (raw)

Cite

Summary

1 Introduction

2 Myocardial fibrillar collagen structural organization and mechanical properties

3 Alterations in ECM fibrillar collagen properties and left ventricular diastolic function

3.1 Increased collagen concentration

3.2 Decreased collagen concentration

3.3 Altered ratio of collagen types

3.4 Altered collagen cross-linking

4 Alterations in ECM fibrillar collagen and left ventricular systolic function

Acknowledgements

References

Citations

Views

Altmetric

Email alerts

Citing articles via

Most Read

Most Cited