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dc.contributor.author Schreckenberg, R
dc.contributor.author da Costa, Rebelo M
dc.contributor.author Deten, A
dc.contributor.author Weber, M
dc.contributor.author Rohrbach, S
dc.contributor.author Pipicz, Márton
dc.contributor.author Csonka, Csaba
dc.contributor.author Ferdinandy, Péter
dc.contributor.author Schulz, R
dc.contributor.author Schluter, KD
dc.date.accessioned 2019-12-05T07:39:31Z
dc.date.available 2019-12-05T07:39:31Z
dc.date.issued 2015
dc.identifier 84948418726
dc.identifier.citation journalVolume=23;journalIssueNumber=15;journalTitle=ANTIOXIDANTS & REDOX SIGNALING;pagerange=1220-1232;journalAbbreviatedTitle=ANTIOXID REDOX SIGNAL;
dc.identifier.uri http://repo.lib.semmelweis.hu//handle/123456789/8044
dc.identifier.uri doi:10.1089/ars.2014.6139
dc.description.abstract AIMS: Research into right ventricular (RV) physiology and identification of pathomechanisms underlying RV failure have been neglected for many years because function of the RV is often considered to be less important for overall hemodynamics and maintenance of blood circulation. In view of this, the present study focuses on identifying specific adaptive mechanisms of the right and left ventricle (LV) during a state of chronic nitric oxide (NO) deficiency, one of the main causes of cardiac failure. NO deficiency was induced in rats by L-NAME feeding over a four weeks period. The cardiac remodeling was then characterized separately for the RV/LV using qRT-PCR, histology, and functional measurements. RESULTS: Only the RV underwent remodeling that corresponded morphologically and functionally with the pattern of dilated cardiomyopathy. Symptoms in the LV were subtle and consisted primarily of moderate hypertrophy. A massive increase in reactive oxygen species (ROS) (+4.5+/-0.8 fold, vs. control) and a higher degree of oxidized tropomyosin (+46+/-4% vs. control) and peroxynitrite (+32+/-2% vs. control) could be identified as the cause of both RV fibrosis and contractile dysfunction. The expression of superoxide dismutase-2 was specifically increased in the LV by 51+/-3% and prevented the ROS increase and the corresponding structural and functional remodeling. INNOVATION: This study identified the inability of the RV to increase its antioxidant capacity as an important risk factor for developing RV failure. CONCLUSION: Unlike the LV, the RV did not display the necessary adaptive mechanisms to cope with increased oxidative stress during a state of chronic NO deficiency.
dc.format.extent 1220-1232
dc.relation.ispartof urn:issn:1523-0864
dc.title Specific Mechanisms underlying Right Heart Failure
dc.type Journal Article
dc.date.updated 2019-12-04T16:27:23Z
dc.language.rfc3066 en
dc.rights.holder NULL
dc.identifier.mtmt 2893278
dc.identifier.wos 000365517400002
dc.identifier.pubmed 25978844
dc.contributor.department SE/AOK/I/Farmakológiai és Farmakoterápiás Intézet
dc.contributor.institution Semmelweis Egyetem


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