Global ETD Search

141	The Development of Elastomeric Biodegradable Polyurethane Scaffolds for Cardiac Tissue Engineering Parrag, Ian 01 September 2010 (has links) In this work, a new polyurethane (PU) chain extender was developed to incorporate a Glycine-Leucine (Gly-Leu) dipeptide, the cleavage site of several matrix metalloproteinases. PUs were synthesized with either the Gly-Leu-based chain extender (Gly-Leu PU) or a phenylalanine-based chain extender (Phe PU). Both PUs had high molecular weight averages (Mw > 125,000 g/mol) and were phase segregated, semi-crystalline polymers (Tm ~ 42°C) with a low soft segment glass transition temperature (Tg < -50°C). Uniaxial tensile testing of PU films revealed that the polymers could withstand high ultimate tensile strengths (~ 8-13 MPa) and were flexible with breaking strains of ~ 870-910% but the two PUs exhibited a significant difference in mechanical properties. The Phe and Gly-Leu PUs were electrospun into porous scaffolds for degradation and cell-based studies. Fibrous Phe and Gly-Leu PU scaffolds were formed with randomly organized fibers and an average fiber diameter of approximately 3.6 µm. In addition, the Phe PU was electrospun into scaffolds of varying architecture to investigate how fiber alignment affects the orientation response of cardiac cells. To achieve this, the Phe PU was electrospun into aligned and unaligned scaffolds and the physical, thermal, and mechanical properties of the scaffolds were investigated. The degradation of the Phe and Gly-Leu PU scaffolds was investigated in the presence of active MMP-1, active MMP-9, and a buffer solution over 28 days to test MMP-mediated and passive hydrolysis of the PUs. Mass loss and structural assessment suggested that neither PU experienced significant hydrolysis to observe degradation over the course of the experiment. In cell-based studies, Phe and Gly-Leu PU scaffolds successfully supported a high density of viable and adherent mouse embryonic fibroblasts (MEFs) out to at least 28 days. Culturing murine embryonic stem cell-derived cardiomyocytes (mESCDCs) alone and with MEFs on aligned and unaligned Phe PU scaffolds revealed both architectures supported adherent and functionally contractile cells. Importantly, fiber alignment and coculture with MEFs improved the organization and differentiation of mESCDCs suggesting these two parameters are important for developing engineered myocardial constructs using mESCDCs and PU scaffolds. Biodegradable Polyurethanes Cardiac Tissue Engineering Matrix Metalloproteinases Electrospinning Embryonic Stem Cells Cardiomyocytes Fibroblasts Fibrous Scaffolds 0541 0542
142	Tumor necrosis factor triggers the expression and activation of matrix metalloproteinases through NADPH-dependent superoxide production Awad, Ahmed Unknown Date No description available. tumor necrosis factor matrix metalloproteinases reactive oxygen species reactive nitrogen species pressure overload cardiac disease
143	The Development of Elastomeric Biodegradable Polyurethane Scaffolds for Cardiac Tissue Engineering Parrag, Ian 01 September 2010 (has links) In this work, a new polyurethane (PU) chain extender was developed to incorporate a Glycine-Leucine (Gly-Leu) dipeptide, the cleavage site of several matrix metalloproteinases. PUs were synthesized with either the Gly-Leu-based chain extender (Gly-Leu PU) or a phenylalanine-based chain extender (Phe PU). Both PUs had high molecular weight averages (Mw > 125,000 g/mol) and were phase segregated, semi-crystalline polymers (Tm ~ 42°C) with a low soft segment glass transition temperature (Tg < -50°C). Uniaxial tensile testing of PU films revealed that the polymers could withstand high ultimate tensile strengths (~ 8-13 MPa) and were flexible with breaking strains of ~ 870-910% but the two PUs exhibited a significant difference in mechanical properties. The Phe and Gly-Leu PUs were electrospun into porous scaffolds for degradation and cell-based studies. Fibrous Phe and Gly-Leu PU scaffolds were formed with randomly organized fibers and an average fiber diameter of approximately 3.6 µm. In addition, the Phe PU was electrospun into scaffolds of varying architecture to investigate how fiber alignment affects the orientation response of cardiac cells. To achieve this, the Phe PU was electrospun into aligned and unaligned scaffolds and the physical, thermal, and mechanical properties of the scaffolds were investigated. The degradation of the Phe and Gly-Leu PU scaffolds was investigated in the presence of active MMP-1, active MMP-9, and a buffer solution over 28 days to test MMP-mediated and passive hydrolysis of the PUs. Mass loss and structural assessment suggested that neither PU experienced significant hydrolysis to observe degradation over the course of the experiment. In cell-based studies, Phe and Gly-Leu PU scaffolds successfully supported a high density of viable and adherent mouse embryonic fibroblasts (MEFs) out to at least 28 days. Culturing murine embryonic stem cell-derived cardiomyocytes (mESCDCs) alone and with MEFs on aligned and unaligned Phe PU scaffolds revealed both architectures supported adherent and functionally contractile cells. Importantly, fiber alignment and coculture with MEFs improved the organization and differentiation of mESCDCs suggesting these two parameters are important for developing engineered myocardial constructs using mESCDCs and PU scaffolds. Biodegradable Polyurethanes Cardiac Tissue Engineering Matrix Metalloproteinases Electrospinning Embryonic Stem Cells Cardiomyocytes Fibroblasts Fibrous Scaffolds 0541 0542
144	Der Einfluss adulter Stammzellen auf die Aktivierung von Kardiomyozyten im in-vitro Modell Röske, Fabian 03 November 2014 (has links) (PDF) Während der letzten Jahre zeigten einige Studien, dass die Behandlung mit Knochenmark- Stammzellen (KMSZ) eine vielversprechende neue Therapieoption für den geschädigten Herzmuskel darstellen könnte. In dieser Arbeit wurde untersucht, ob es unter Behandlung mit Stammzellen zu einer zellulären Antwort in angezüchteten Kardiomyozyten (KMZ) kommt. Dafür wurden subkonfluente Kulturen aus Herzmuskelzellen von neonatalen Ratten für drei Tage mit Vybrant CM-DiI-markierten, sternalen humanen Knochenmarkstammzellen co-kultiviert. Im Anschluss wurden immunohistochemische Färbungen sowie eine quantitative Analyse mittels Western Blot für das Protoonkogen c-Myc durchgeführt. Des Weiteren wurde die Dichte der Beta-Adrenozeptoren unter Anwendung einer Histoautoradiographie mittels [125I]- iodocyanopindolol-Bindung analysiert. Die Auswertung der Immunohistochemie und der Western Blots zeigte eine signifikante Erhöhung der Expression von c-Myc in den Kardiomyozyten, welche in naher Umgebung der Stammzellen lagen. Dieser Effekt war direkt abhängig von der Entfernung der KMZ zur SZ. Die Histoautoradiographie zeigte eine signifikant höhere Beta-Rezeptor-Dichte in Kardiomyozyten in direkter Nähe zur Stammzelle. Mit steigender Entfernung von der Stammzelle verringerte sich die Rezeptordichte. Somit konnte gezeigt werden, dass eine kleine Anzahl von Knochenmark-Stammzellen ausreicht, um eine große Zahl von Kardiomyozyten zu beeinflussen, indem eine intrazelluläre Signalkaskade über c-Myc aktiviert und die Anzahl der Beta-Adrenozeptoren erhöht wird. Stammzellen Kardiomyozyten kardiale Myoplastie Betarezeptoren c-Myc stem cells cardiomyocytes regenerative medicine c-Myc beta adrenoceptors ddc:610
145	Reprogrammation nucléaire de cardiomyocytes vers un stade progéniteur par fusion partielle avec des cellules souches adultes Acquistapace, Adrien, Acquistapace, Adrien 26 October 2011 (has links) (PDF) La thérapie cellulaire régénératrice offre des perspectives d'applications dans de nombreuses pathologies entraînant une perte cellulaire. Cependant, suite à un infarctus du myocarde et donc une diminution importante du nombre de cardiomyocytes, l'injection de cellules souches n'a permis de mettre en évidence qu'une amélioration légère et transitoire de la fonction cardiaque. Ces résultats suggèrent qu'il est nécessaire d'améliorer l'efficacité des protocoles de thérapie cellulaire cardiaque. Cette amélioration passe par une meilleure compréhension des mécanismes mis en jeu par les cellules souches dans la régénération myocardique. Parmi les hypothèses soulevées, la fusion entre les cellules souches et les cardiomyocytes a été décrite dans plusieurs études mais le rôle physiologique de ce phénomène reste inconnu. Mon travail de thèse a consisté à étudier ce mécanisme in vitro au sein de cocultures entres des cellules souches adultes humaines (cellules hMADS pour human multipotent adipose derived stem cells) et des cardiomyocytes murins adultes. Nous avons pu mettre en évidence un processus de fusion hétérologue entre ces deux types cellulaires, aboutissant à la reprogrammation du cardiomyocyte vers un stade de progéniteur. Les cellules hybrides résultant de cette fusion ont exprimé des marqueurs cardiomyogéniques précoces et de prolifération et ont été montrées comme ayant un génotype exclusivement murin. Ces cellules hybrides ou progéniteurs cardiaques se sont formés préférentiellement par un mécanisme de fusion partielle par l'intermédiaire de structures intercellulaires appelées nanotubes composés de f-actine et de microtubules. En outre, nous avons montré que le transfert de mitochondries des cellules souches vers les cardiomyocytes était indispensable pour la reprogrammation des cardiomyocytes. En conclusion, nos résultats apportent de nouveaux éléments dans la compréhension des mécanismes de régénération médiés par les cellules souches qui est un pré-requis pour optimiser les protocoles de thérapie cellulaire cardiaque Reprogrammation nucléaire Cellules souches adultes Fusion partielle Cardiomyocytes Nanotubes Mitochondries
146	Phosphodiesterases as Crucial Regulators of Cardiomyocyte cAMP in Health and Disease Perera, Ruwan K. 09 September 2014 (has links) No description available. 610 Phosphodiesterases FRET pmEpac1 Localized cAMP Cardiac Hypertrophy PDE2 PDE3 PDE4 cAMP ANP PDE Cardiomyocytes Atropine Medizin (PPN619874732)
147	Efeitos da hiperaceleração de histonas na diferenciação in vitro de células tronco embrionárias murinas Oliveira, Clara Slade [UNESP] 19 February 2009 (has links) (PDF) Made available in DSpace on 2014-06-11T19:29:16Z (GMT). No. of bitstreams: 0 Previous issue date: 2009-02-19Bitstream added on 2014-06-13T20:59:34Z : No. of bitstreams: 1 oliveira_cs_me_jabo.pdf: 1799127 bytes, checksum: 5a858a3a6eed3c27cf1b8f8968db5a50 (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / O estudo dos processos de diferenciação em células tronco embrionárias (CTE) representa uma importante ferramenta para o entendimento das vias moleculares que os regem, apresentando grande aplicação tanto na ciência básica quanto na engenharia de tecidos e medicina regenerativa. Pouco é conhecido sobre as marcas epigenéticas existentes na cromatina destas células, e de que forma a regulação da expressão gênica ocorre no momento da diferenciação. O presente trabalho teve como objetivo o estudo dos efeitos da hiperacetilação das histonas causada pela droga tricostatina A (TSA), uma inibidora das enzimas histona desacetilases, sobre a diferenciação destas células em estádios iniciais e avançados. Para tanto, a hiperacetilação induzida pela droga foi estimada por reações de imunocitoquímica para AcLys9H3. Os efeitos anti-proliferativos da TSA foram mensurados pelo teste de TUNEL e contagem de células. Ainda, foram conduzidos experimentos de diferenciação in vitro de CTE e análise da expressão de proteínas características de linhagens celulares diferenciadas por reações de imunocitoquímica (Oct3/4, nestina, âIII tubulina, desmina e troponina I), em cultivos tratados com TSA em diferentes concentrações e em diferentes momentos. Desta forma, foi estimada a população de tipos celulares oriundos dos folhetos embrionários ectodérmico e mesodérmico, como neurônios, e células musculares, quando foi promovida a hiperacetilação das histonas nas CTE, em diferentes momentos da diferenciação celular in vitro. A TSA induziu apoptose em níveis superiores aos do grupo controle, e retardou/inibiu a divisão celular. Promoveu hiperacetilação dose-dependente nos períodos estudados, e estimulou a diferenciação de precursores mesodérmicos (50nM d5) e ectodérmicos (15nMd0-5 e 50nMd5), cardiomiócitos (50nMd5 e 100nMd13) e neurônios (15nMd0-5, 50nMd5, 100nMd5, 100nMd13). / Studies on embryonic stem cells (ESC) differentiation represents an important tool leading to understanding of its molecular pathways, with many applications both on basic research and tissue engineering / regenerative medicine. Little is known about epigenetic marks on ESC chromatin, and how gene expression occurs at differentiation time. The aim of this work was to study effects of histone hiperacetylation, induced by cell treatment with trichostatin A (TSA), an histone deacetylase inhibitor, on both initial and late differentiation. For that, drug-induced hyperacetylation was studied by AcLys9H3 immunocitochemistry. TSA anti-proliferative effects were analysed by TUNEL test and cell counts. Experiments on ESC in vitro differentiation and immunocitochemistry for specific cell types proteins (Oct3/4, nestin, âIII tubulin, desmin and troponin I) were performed, in treated and control groups, at different moments. This analysis showed specific cell types populations derived from embryonic ectodermal and mesodermal, such as neurons and cardiomyocytes, when histone hyperacetylation were induced, on both initial and late diferentiation. Our results showed that TSA induces apoptosis and inhibits cellular proliferation. Also, TSA promoted dose-dependent histone hyperacetylation at studied moments, and stimulated mesodermal (50nM d5) and ectodermal (15nMd0-5 e 50nMd5) precursors, cardiomyocytes (50nMd5 e 100nMd13) and neurons (15nMd0-5, 50nMd5, 100nMd5, 100nMd13) differentiation. Neuronios Células tronco embrionárias Diferenciação Hiperacetilação de histonas Cardiomiócitos Embryonic stem cells Differentiation Histone hyperacetylation trichostatin A Cardiomyocytes. eng Neurons. eng
148	Estudo do envolvimento da molécula MyD88 na infecção de cardiomiócitos pelo Trypanosoma cruzi. / Study of the involvement of MyD88 molecule in infected cardiomyocytes Trypanosoma cruzi. Danni Yohani Santana Rosero 07 November 2016 (has links) A cardiomiopatia chagásica crônica é a consequência mais grave da Doença de Chagas, quadro infeccioso humano causado pelo protozoário Trypanosoma cruzi. Uma vez que os cardiomiocitos podem ser invadidos pelo T. cruzi, é nosso interesse averiguar se esta população estrutural reconhece o parasita in vivo através dos TLRs (Toll Like receptors). Visto que a maioria dos TLRs sinaliza através da molécula adaptadora MyD88, no presente trabalho temos estudado a participação deste elemento transdutor. Para isto fomos examinar a infecção pelo T. cruzi em camundongos F2 (Mer / MyD88flox+/+), modelo animal no qual o tratamento com a droga Tamoxifeno deve eliminar a molécula MyD88 exclusivamente nos cardiomiócitos. Resultados: em um estudo prévio, constatamos que cardiomiócitos tumorais murinos HL-1, em repouso ou após infecção pelo T. cruzi, transcrevem a molécula MyD88. A seguir, validamos o modelo experimental in vivo, ao mostrar que o tratamento com tamoxifeno dos animais F2 resulta na diminuição de MyD88 no coração, mas não no baço. Ainda, constatamos que a transcrição de MyD88 é mais intensa na aurícula do que no ventrículo, sendo igualmente abolida dos animais F2 pelo tratamento com tamoxifeno. Por outro lado, verificamos que o tamoxifeno determina um aumento da parasitemia em ambos os animais F2 e controle (MerCreMer+/+), não se observando diferenças significativamente entre estes. Finalmente, estudos preliminares mostraram que a eliminação de MyD88 nos cardiomiócitos dos animais F2 não altera significativamente o quadro de patologia (parasitismo e infiltração leucocitária) aos 10 ou 28 dias de infecção pelo T. cruzi, quando comparado ao de animais controle (MerCreMer+/+) igualmente tratados com tamoxifeno e infectados. / Chronic Chagas cardiomyopathy is the most serious consequence of Chagas Disease, caused by Trypanosoma cruzi. Cardiomyocytes are invaded by T. cruzi, it is our interest to see if this structural population in vivo recognizes the parasite through TLRs. Since most TLRs signal through MyD88, we studied in vivo participation of Myd88 in cardiomyocyte response. Treatment with tamoxifen (Tam) eliminate the MyD88 molecule exclusively from cardiomyocytes in F2 mice, which we used to understand its role on T. cruzi infection. Results: HL-1 cells, a murine cardiomyocyte tumor line, in infection with T. cruzi, transcribe the MyD88 molecule. Transcription of MyD88 is more intense in the atria than in ventricle. Tam treatment of F2 mice eliminates the MyD88 at the heart completely, but not at spleen. Tam caused increased parasitaemia, no differences were observed in the parasitaemia curve of infected F2 and MerCreMer+/+ (control) mice. Finally, MyD88 elimination in cardiomyocytes of F2 mice does not alters the pathology frame at days 10 and 28 post infection. Trypanosoma cruzi Adaptador MyD88 Cardiomiócitos Cardiomiopatia Doença de Chagas Receptor de estrógeno Trypanosoma cruzi Adapter MyD88 Cardiomyocytes Cardiomyopathy Chagas disease Estrogen receptor
149	Régulation de l'expression membranaire et dynamique du canal potassique KV1.5 dans les cardiomyocytes atriaux / Regulation of KV1.5 channel surface expression and dynamics in atrial cardiomyocytes Barbier, Camille 08 June 2016 (has links) Les canaux ioniques sont des déterminants majeurs de la forme et de la durée du potentiel d'action (PA) cardiaque. Leur expression fonctionnelle à la membrane plasmique résulte d'une balance entre les voies antérograde et rétrograde du trafic intracellulaire, ainsi que de leur prise en charge par des compartiments endosomaux afin d'être recyclés ou dégradés. Le canal KV1.5 porte le courant principal de repolarisation atriale chez l'homme, IKur, et est impliqué dans la physiopathologie de la fibrillation atriale (FA). La FA est caractérisée par un raccourcissement de la durée du PA lié à un courant IKur augmenté et un courant ICaL diminué et est favorisée par l'augmentation des contraintes mécaniques. Ainsi, le canal KV1.5 constitue une cible majeure pour le développement d'anti-arythmiques spécifiques de l'oreillette. Ce projet avait pour but de mieux comprendre comment est régulée l'expression fonctionnelle des canaux KV1.5 dans les myocytes atriaux. Dans un premier temps, nous avons montré que le shear stress entraîne une augmentation du courant IKur impliquant la voie de mécanotransduction intégrine?1/FAK et l'endosome de recyclage lent. Dans les cellules hypertrophiées, cette voie de mécanotransduction est hyperactivée et le courant IKur est ainsi augmenté. Dans un second temps, nous avons montré que la voie d'endocytose des canaux KV1.5 est dépendante de la clathrine et que les microtubules sont principalement impliqués dans l'internalisation et la dynamique du canal à la surface des cellules. Ainsi, ce travail a permis de mieux caractériser les acteurs du trafic impliqués dans la régulation de l'expression fonctionnelle du canal KV1.5 dans les cardiomyocytes atriaux. / Ion channels are major determinants of shape and duration of the cardiac action potential (AP). Their functional expression at the sarcolemma is a dynamic process resulting from a balance between anterograde (exocytosis) and retrograde (endocytosis) pathways, and the involvement of the endosomal compartments which direct ion channels towards recycling or degradation. KV1.5 channel carries IKur current which constitutes the main atrial repolarizing current in human and which is involved in atrial fibrillation (AF). Mechanical forces and shortening of the AP duration are linked to an increased in IKur current and decreased ICaL current. Therefore, KV1.5 channel constitutes a major target for the development of atria-selective antiarrhythmic drugs. The aim on this project was to better understand how functional expression of KV1.5 channels in atrial myocytes is regulated. Firstly, we showed that shear stress triggers an increase in IKur current implying the integrinβ1/FAK mecanotransduction pathway. This process requires an intact microtubule network and involves the Rab11-associated recycling endosome. In hypertrophied cells, the mecanotransduction pathway is overactivated. Consequently, IKur is increased. Secondly, we demonstrated that KV1.5 channel endocytosis is mediated by the clathrin pathway. We showed that microtubules are involved in the internalization and dynamics of KV1.5 channel in the membrane. Therefore, this work provides a better understanding of the different players involved in the trafficking of KV1.5 channel and shed new lights on the functional regulation of this atria-specific channel. Canal potassique KV1.5 Cardiomyocytes atriaux Clathrine Dynamique membranaire Cytosquelette Contraintes mécaniques KV1.5 potassium channel Surface dynamics Clathrin 571.9
150	Explorative bioinformatic analysis of cardiomyocytes in 2D &3D in vitro culture system Janardanan, Sruthy January 2021 (has links) The in vitro cell culture models of human pluripotent stem cells (hPSC)-derived cardiomyocytes (CMs) have gained a predominant value in the field of drug discovery and is considered an attractive tool for cardiovascular disease modellings. However, despite several reports of different protocols for the hPSC-differentiation into CMs, the development of an efficient, controlled and reproducible 3D differentiation remains challenging. The main aim of this research study was to understand the changes in the gene expression as an impact of spatial orientation ofhPSC-derived CMs in 2D(two-dimensional) and 3D(three-dimensional) culture conditions and to identify the topologically important Hub and Hub-Bottleneck proteins using centrality measures to gain new knowledge for standardizing the pre-clinical models for the regeneration of CMs. The above-mentioned aim was achieved through an extensive bioinformatic analysis on the list of differentially expressed genes (DEGs) identified from RNA-sequencing (RNA-Seq). Functional annotation analysis of the DEGs from both 2D and 3D was performed using Cytoscape plug-in ClueGO. Followed by the topological analysis of the protein-protein interaction network (PPIN) using two centrality parameters; Degree and Betweeness in Cytoscape plug-in CenTiScaPe. The results obtained revealed that compared to 2D, DEGs in 3D are primarily associated with cell signalling suggesting the interaction between cells as an impact of the 3D microenvironment and topological analysis revealed 32 and 39 proteins as Hub and Hub-Bottleneck proteins, respectively in 3D indicating the possibility of utilizing those identified genes and their corresponding proteins as cardiac disease biomarkers in future by further research. Cardiomyocytes Pluripotent stem cells 2D 3D differentially expressed genes Hub nodes Hub-Bottleneck nodes Medical Bioscience Medicinsk biovetenskap

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