Mechanical Unloading During Left Ventricular Assist Device Support Increases Left Ventricular Collagen Cross-Linking and Myocardial Stiffness

Klotz, Stefan; Foronjy, Robert; Dickstein, Marc L.; Gu, Anguo; Garrelds, Ingrid M.; Danser, A.H. Jan; Öz, Mehmet C.; DʼArmiento, Jeanine; Burkhoff, Daniel

doi:10.1161/circulationaha.104.515106

Cited by 174 publications

(149 citation statements)

References 63 publications

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“…The differences in this association between the BM and collagen fibers may be due to alterations of the BM but may also be caused by the changes in the ECM. 15,36,37 With IHC, we showed a significant reduction of type IV collagen immunoreactivity in the BM after LVAD support. However, laminin was still present in the BM after unloading of the heart.…”

Section: Basement Membrane Degradation After Lvad Ah Bruggink Et Almentioning

confidence: 78%

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Type IV collagen degradation in the myocardial basement membrane after unloading of the failing heart by a left ventricular assist device

Bruggink

Oosterhout

Jonge

et al. 2007

Laboratory Investigation

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After left ventricular assist device (LVAD) support in patients with end-stage cardiomyopathy, cardiomyocytes decrease in size. We hypothesized that during this process, known as reverse remodeling, the basement membrane (BM), which is closely connected to, and forms the interface between the cardiomyocytes and the extracellular matrix, will be severely affected. Therefore, the changes in the myocardial BM in patients with end-stage heart failure before and after LVAD support were studied. The role of MMP-2 in this process was also investigated. Transmission electron microscopy showed that the BM thickness decreased post-LVAD compared to pre-LVAD. Immunohistochemistry indicated a reduced immunoreactivity for type IV collagen in the BM after LVAD support. Quantitative PCR showed a similar mRNA expression for type IV collagen pre-and post-LVAD. MMP-2 mRNA almost doubled post-LVAD (Po0.01). In addition, active MMP-2 protein as identified by gelatin zymography and confirmed by Western blot analysis was detected after LVAD support and in controls, but not before LVAD support. Active MMP was localized in the BM of the cardiomyocyte, as detected by type IV collagen in situ zymography. Furthermore, in situ hybridization/immunohistochemical double staining showed that MMP-2 mRNA was expressed in cardiomyocytes, macrophages, T-cells and endothelial cells. Taken together, these findings show reduced type IV collagen content in the BM of cardiomyocytes after LVAD support. This reduction is at least in part the result of increased MMP-2 activity and not due to reduced synthesis of type IV collagen. Left ventricular assist devices (LVADs) are commonly used in patients with heart failure as a bridge to heart transplantation (HTx). In most cases, LVAD support extends the patient's lifespan and improves the quality of life. 1,2 In addition, pressure and volume unloading of the left ventricle (LV) by LVAD can reverse left ventricular dilatation and leads to regression of left ventricular hypertrophy and neurohormonal changes. [3][4][5][6] The understanding of this process, referred to as 'reverse remodeling,' 7 is important for a better insight into both myocardial events during LVAD support and the processes leading to heart failure. Additionally, several institutions described the possibility of LVAD explantation without the need for HTx (weaning). 4,[8][9][10][11] This requires a profound knowledge of the process of reverse remodeling.In previous studies with cardiac unloading, we demonstrated partial recovery of the contractile myofilaments in the cardiomyocytes 12 and decreased natriuretic peptide levels both in the plasma of the patients and in the heart. 5,6 Since reverse remodeling not only involves the cardiomyocytes but also the extracellular matrix (ECM), we have focused on the changes in ECM before and after LVAD support. The ECM, which consists of the fibrillar collagens, type I and III collagen, and comprises a basement membrane (BM) surrounding cardiomyocytes, forms a continuum between different cell types within t...

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Section: Basement Membrane Degradation After Lvad Ah Bruggink Et Almentioning

confidence: 78%

“…[35][36][37] In a previous study of our group, 15 we have shown that reverse remodeling of type I and III collagen in the ECM follows a biphasic pattern. Initially, an increase of type I and III collagen turnover takes place, which is paralleled by an increase of the ECM volume.…”

Section: Basement Membrane Degradation After Lvad Ah Bruggink Et Almentioning

confidence: 81%

Type IV collagen degradation in the myocardial basement membrane after unloading of the failing heart by a left ventricular assist device

Bruggink

Oosterhout

Jonge

et al. 2007

Laboratory Investigation

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“…54 Secondly, myocardial fibrosis (antecedent scarring or localized injury induced by cannula placement) increases the propensity for arrhythmias. 59 Use of angiotensin-converting enzyme inhibitors may reduce levels of fibrosis and collagen deposition. The third aspect is the electrophysiological adaptation to LVAD support.…”

Section: Atrial Arrhythmiasmentioning

confidence: 99%

Ventricular assist devices for heart failure: a focus on patient selection and complications

Cipriani¹,

Simone²,

D’Angelo³

et al. 2014

RRCC

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Heart transplantation represents the "gold standard" for the treatment of patients with end-stage heart failure, but remains challenged by inadequate donor supply, finite graft survival, and long-term complications arising from immunosuppressive therapy. In addition, a lot of patients waiting for a heart transplant experience clinical deterioration, and other patients become ineligible to undergo this treatment due to their age or relevant comorbidities. Left ventricular assist devices have emerged as a valid therapeutic option for advanced heart failure. In recent years, we have seen significant advances not only in the technologies available, but also in patient selection, indications for use, and management after implantation. Consequently, there has been an increase in the number of implants and an improvement in the survival rate and quality of life for these patients. At the same time, there are new challenges on the horizon. Patient selection is a difficult process, based on clinical and imaging parameters and risk scores, and more data are needed to refine patient selection criteria and the timing of the implant. Left ventricular assist device-related complications are still a serious problem, causing adverse events and hospital readmissions. Continuous progress in the development of these implantable devices, such as a further reduction in size and hopefully the abolition of the external driveline, will probably make ventricular assist devices an option also for less advanced stages of heart failure. Here, we discuss the current indications for left ventricular assist device implantation, patient selection criteria, and the most frequent complications associated with these devices.

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“…The changes in ECM during this process of reverse remodeling resulted not only in a time-dependent change of type I and type III collagen protein (Goldsmith and Borg, 2002;Stamenkovic, 2003), but also in considerable changes in composition of the basal membrane. These included amongst others reduced collagen type IV content in the cardiomyocyte basal membrane, as a result of increased matrix metalloproteinase activity (Bruggink et al, 2007;Spinale, 2002;Li et al, 2001;Klotz et al, 2005). So, during LVAD support myocardial architecture and composition change at the level of both the cardiomyocytes and the ECM.…”

Section: Introductionmentioning

confidence: 99%

Altered Expression of mRNA and miRNA during Mechanical Support of the Failing Human Heart

Schipper¹,

Lok²,

Dullens³

et al. 2011

Ventricular Assist Devices

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Mechanical Unloading During Left Ventricular Assist Device Support Increases Left Ventricular Collagen Cross-Linking and Myocardial Stiffness

Cited by 174 publications

References 63 publications

Type IV collagen degradation in the myocardial basement membrane after unloading of the failing heart by a left ventricular assist device

Type IV collagen degradation in the myocardial basement membrane after unloading of the failing heart by a left ventricular assist device

Ventricular assist devices for heart failure: a focus on patient selection and complications

Altered Expression of mRNA and miRNA during Mechanical Support of the Failing Human Heart

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