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161	Caracterização e mecanismos do desequilíbrio redox na fisiopatologia da estenose valvar aórtica degenerativa / Characterization and mechanisms of redox imbalance in pathophysiology of degenerative aortic valve stenosis Marcel Liberman 20 August 2007 (has links) Para investigar se estresse oxidativo contribui para a progressão da calcificação/estenose valvar aórtica (VA), avaliamos a produção de espécies reativas de oxigênio (ERO) e efeitos dos antioxidantes tempol e ác. lipóico em modelo de calcificação VA em coelhos. Superóxido, H2O2 e 3-nitrotirosina aumentaram em células inflamatórias e principalmente nos núcleos de calcificação, juntamente com as subunidades p22phox, Nox2 da NADPH oxidase e da proteína dissulfeto isomerase, que co-localizam. PCR mostrou aumento da Nox4 em relação a Nox1. A calcificação foi menor com ác.lipóico e maior com tempol, coicidindo com resultados de modelo in vitro em células musculares lisas. VA humanas estenóticas tiveram aumento semelhante de ERO e da expressão protéica em torno da calcificação. Estresse oxidativo pode contribuir para a progressão da estenose aórtica. / To invetigate whether oxidative stress contributes to aortic valve (AV) calcification/stenosis progression, we assessed reactive oxygen species (ROS) production and effects of antioxidants tempol and lipoic acid in a rabbit AV calcification model. Superoxide, H2O2 and 3-nitrotyrosine increased in inflammatory cells and mainly in calcifying nuclei, coincident with NADPH oxidase subunits p22phox, Nox2 and protein disulfide isomerase, which co-localized. PCR showed switch from Nox1 to Nox4. Calcification was smaller with lipoic acid and greater with tempol, similar to an in vitro smooth muscle cell calcification model results. Human stenotic AV had analogous increase in ROS and protein expression around calcifying nuclei. Oxidative stress can contribute to AV stenosis progression. Antioxidantes Calcificação fisiológica Coelhos Estenose da valva aórtica Estresse oxidativo Antioxidants Aortic valve stenosis Oxidative stress Physiologic calcification Rabbits
162	Exploring Heart Valve Homeostasis and Repair Nordquist, Emily M. 01 October 2021 (has links) No description available. Cellular Biology Molecular Biology Biomedical Research aortic valve AoV regeneration endothelial cell VIC VEC cardiac valve injury
163	Effekte körperlichen Trainings auf eine präexistente Aortenklappensklerose im Tiermodell Schlotter, Florian 31 May 2012 (has links) Bisher existiert keine nicht-invasive/ nicht-operative Therapie der Aortenklappenstenose. Als wichtiger Zeitpunkt für eine präventive Maßnahme, zur Verhinderung der Ausbildung einer hömodynamisch relevanten Aortenklappenstenose, kann das Stadium der Aortenklappensklerose angesehen werden. Dieses frühe Erkrankungsstadium verfügt über zahlreiche pathophysiologische Parallelen zur Atherosklerose, für die eine positive Rolle der Prävention durch körperliche Aktivität erwiesen ist. Ziel dieser Arbeit war die Durchführung der Sekundärprävention der kalzifizierenden Aortenklappenerkrankung durch körperliches Training. Um mögliche Effekte dieser Intervention zu eruieren, wurden LDLR-/--Mäuse mit bereits bestehenden pathologischen Aortenklappenveränderungen über einen Zeitraum von 16 Wochen körperlichem Training unterzogen. Durch morphologische, serumanalytische, immunhistochemische und Genexpressionsanalysen konnte abschließend eine Quantifizierung der Effekte körperlichen Trainings - in der Zielsetzung der Sekundärprävention - realisiert werden. info:eu-repo/classification/ddc/610 ddc:610
164	4D optical coherence tomography of aortic valve dynamics in a murine mouse model ex vivo Schnabel, Christian, Jannasch, Anett, Faak, Saskia, Waldow, Thomas, Koch, Edmund 29 August 2019 (has links) The heart and its mechanical components, especially the heart valves and leaflets, are under enormous strain during lifetime. Like all highly stressed materials, also these biological components undergo fatigue and signs of wear, which impinge upon cardiac output and in the end on health and living comfort of affected patients. Thereby pathophysiological changes of the aortic valve leading to calcific aortic valve stenosis (AVS) as most frequent heart valve disease in humans are of particular interest. The knowledge about changes of the dynamic behavior during the course of this disease and the possibility of early stage diagnosis could lead to the development of new treatment strategies and drug-based options of prevention or therapy. ApoE-/- mice as established model of AVS versus wildtype mice were introduced in an ex vivo artificially stimulated heart model. 4D optical coherence tomography (OCT) in combination with high-speed video microscopy were applied to characterize dynamic behavior of the murine aortic valve and to characterize dynamic properties during artificial stimulation. OCT and high-speed video microscopy with high spatial and temporal resolution represent promising tools for the investigation of dynamic behavior and their changes in calcific aortic stenosis disease models in mice. info:eu-repo/classification/ddc/620 ddc:620
165	Computational Assessment of Aortic Valve Function and Mechanics under Hypertension Kadel, Saurav 04 August 2020 (has links) No description available. Mechanical Engineering Biomedical Engineering Biomedical Research Biomechanics CAVD Hypertension Fluid-structure interaction Aortic valve Computational Study Wall shear stress
166	Treatment-Specific Approaches for Analysis and Control of Left Ventricular Assist Devices Faragallah, George 01 January 2014 (has links) A Left Ventricular Assist Device (LVAD) is a mechanical pump that helps patients with heart failure conditions. This rotary pump works in parallel to the ailing heart and provides an alternative path for blood flow from the weak left ventricle to the aorta. The LVAD is controlled by the power supplied to the pump motor. An increase in the pump motor power increases the pump speed and the pump flow. The LVAD is typically controlled at a fixed setting of pump power. This basically means that the controller does not react to any change in the activity level of the patient. An important engineering challenge is to develop an LVAD feedback controller that can automatically adjusts its pump motor power so that the resulting pump flow matches the physiological demand of the patient. To this end, the development of a mathematical model that can be used to accurately simulate the interaction between the cardiovascular system of the patient and the LVAD is essential for the controller design. The use of such a dynamic model helps engineers and physicians in testing their theories, assessing the effectiveness of prescribed treatments, and understanding in depth the characteristics of this coupled bio-mechanical system. The first contribution of this dissertation is the development of a pump power-based model for the cardiovascular-LVAD system. Previously, the mathematical models in the literature assume availability of the pump speed as an independent control variable. In reality, however, the device is controlled by pump motor power which, in turn, produces the rotational pump speed. The nonlinear relationship between the supplied power and the speed is derived, and interesting observations about the pump speed signal are documented. The second contribution is the development of a feedback controller for patients using an LVAD as either a destination therapy or a bridge to transplant device. The main objective of designing this controller is to provide a physiological demand of the patient equivalent of that of a healthy individual. Since the device is implanted for a long period of time, this objective is chosen to allow the patient to live a life as close to normal as possible. The third contribution is an analysis of the aortic valve dynamics under the support of an LVAD. The aortic valve may experiences a permanent closure when the LVAD pump power is increased too much. The permanent closure of the aortic valve can be very harmful to the patients using the device as a bridge to recovery treatments. The analysis illustrates the various changes in the hemodynamic variables of the patient as a result of aortic valve closing. The results establish the relationship between the activity level and the heart failure severity with respect to the duration of the aortic valve opening. Feedback controller Left ventricular assist device bio mechanical modeling aortic valve dynamics Electrical and Computer Engineering Electrical and Electronics Engineering
167	Native Valve Candida Metapsilosis Endocarditis Following a Ruptured Appendix: A Case Report Sanku, Koushik, Youssef, Dima 01 January 2022 (has links) complex has been further divided into , , and . is considered to be the least virulent fungi of the complex. Candida endocarditis is uncommon but is associated with a very high mortality rate. Prosthetic or previously damaged valves act as common targets, but native, structurally normal valves are seldom affected. We hereby present a case of endocarditis involving a native aortic valve in an immunocompetent 55-year-old male who was successfully treated with surgical valve replacement and antifungal therapy. aortic valve replacement appendix rupture candida endocarditis echocardiography immunocompetent infective endocarditis invasive fungal disease metapsilosis native valve parapsilosis Internal Medicine
168	Hemodynamic Follow-Up after Valve-in-Valve TAVR for Failed Aortic Bioprosthesis Wilbring, Manuel, Kappert, Utz, Haussig, Stephan, Winata, Johan, Matschke, Klaus, Mangner, Norman, Arzt, Sebastian, Alexiou, Konstantin 01 March 2024 (has links) Background “valve-in-valve” TAVR (VIV-TAVR) is established and provides good initial clinical and hemodynamic outcomes. Lacking long-term durability data baffle the expand to lower risk patients. For those purposes, the present study adds a hemodynamic 3-years follow-up. Methods A total of 77 patients underwent VIV-TAVR for failing aortic bioprosthesis during a 7-years period. Predominant mode of failure was stenosis in 87.0%. Patients had a mean age of 79.4 ± 5.8 years and a logistic EuroSCORE of 30.8 ± 15.7%. The Society of Thoracic Surgeons-PROM averaged 5.79 ± 2.63%. Clinical results and hemodynamic outcomes are reported for 30-days, 1-, 2-, and 3-years. Completeness of follow-up was 100% with 44 patients at risk after 3-years. Follow-up ranged up to 7.1 years. Results Majority of the surgical valves were stented (94.8%) with a mean labeled size of 23.1 ± 2.3 mm and true-ID of 20.4 ± 2.6 mm. A true-ID ≤21 mm had 58.4% of the patients. Self-expanding valves were implanted in 68.8% (mean labeled size 24.1 ± 1.8 mm) and balloon-expanded in 31.2% (mean size 24.1 ± 1.8 mm). No patient died intraoperatively. Hospital mortality was 1.3% and three-years survival 57.1%. All patients experienced an initial significant dPmean-reduction to 16.8 ± 7.1 mmHg. After 3-years mean dPmean raised to 26.0 ± 12.2 mmHg. This observation was independent from true-ID or type of transcatheter aortic valve replacement (TAVR)-prosthesis. Patients with a true-ID ≤21 mm had a higher initial (18.3 ± 5.3 vs. 14.9 ± 7.1 mmHg; p = .005) and dPmean after 1-year (29.2 ± 8.2 vs. 13.0 ± 6.7 mmHg; p = .004). There were no significant differences in survival. Conclusions VIV-TAVR is safe and effective in the early period. In surgical valves with a true-ID ≤21 mm inferior hemodynamic and survival outcomes must be expected. Nonetheless, also patients with larger true-IDs showed steadily increasing transvalvular gradients. This raises concern about durability. info:eu-repo/classification/ddc/610 ddc:610
169	In vitro assessment of the effects of valvular stenosis on aorta hemodynamics and left ventricular function Madan, Ashish 07 June 2018 (has links) No description available. Mechanical Engineering Fluid Dynamics Biomechanics Physiology Calcific aortic stenosis aortic valve ascending aorta aortic dilation left ventricle particle image velocimetry
170	BMP Signaling and Intersecting Molecular Mechanisms in Calcific Aortic Valve Disease Gomez Stallons, Maria V. January 2016 (has links) No description available. Molecular Biology Calcific Aortic Valve Disease Bone Morphogenetic Proteins Smads1 5 8 Klotho-deficient mice Porcine aortic VICs

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