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Pluripotent stem cells for cardiac regenerationLee, Yee-ki, Carol., 李綺琪. January 2011 (has links)
published_or_final_version / Medicine / Doctoral / Doctor of Philosophy
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A Clonal Analysis of Zebrafish Heart Morphogenesis and RegenerationGupta, Vikas January 2014 (has links)
<p>As vertebrate embryos grow and develop into adults, their organs must acquire mass and mature tissue architecture to maintain proper homeostasis. While juvenile growth encompasses a significant portion of life, relatively little is known about how individual cells proliferate, with respect to one another, to orchestrate this final maturation. For its simplicity and ease of genetic manipulations, the teleost zebrafish (Danio rerio) was used to understand how the proliferative outputs of individual cells generate an organ from embryogenesis into adulthood. </p><p>To define the proliferative outputs of individual cells, a multicolor clonal labeling approach was taken that visualized a large number of cardiomyocyte clones within the zebrafish heart. This Brainbow technique utilizes Cre-loxP mediated recombination to assign cells upwards of ~90 unique genetic tags. These tags are comprised of the differential expression of 3 fluorescent proteins, which combine to give rise to spectrally distinct colors that represent these genetic tags. Tagging of individual cardiomyocytes was induced early in development, when the wall of the cardiac ventricle is a single myocyte thick. Single cell cardiomyocyte clones within this layer expanded laterally in a developmentally plastic manner into patches of variable shapes and sizes as animals grew into juveniles. As maturation continued into adulthood, a new lineage of cortical muscle appeared at the base of the ventricle and enveloped the ventricle in a wave of proliferation that fortified the wall to make it several myocytes thick. This outer cortical layer was formed from a small number (~8) of dominant cortical myocyte clones that originated from trabecular myocytes. These trabecular myocytes were found to gain access to the ventricular surface through rare breaches within the single cell thick ventricular wall, before proliferating over the surface of the ventricle.</p><p> </p><p>These results demonstrated an unappreciated dynamic juvenile remodeling event that generated the adult ventricular wall. During adult zebrafish heart regeneration, the primary source of regenerating cardiomyocytes stems from this outer wall of muscle. Regenerating cardiomyocytes within this outer layer of muscle are specifically marked by the cardiac transcription factor gene gata4, which they continue to express as they proliferate into the wound area.</p><p>Using heart regeneration to guide investigation of juvenile cortical layer formation, we found that both processes shared similar molecular and tissue specific responses including expression and requirement of gata4. Additional markers suggested that juvenile hearts were under stress and that this stress could play a role to initiate cortical morphogenesis. Indeed, experimental injury or a physiologic increase in stress to juvenile hearts caused the ectopic appearance of cortical muscle, demonstrating that injury could trigger premature morphogenesis.</p><p>These studies detail the cardiomyocyte proliferative events that shape the heart and identify molecular parallels that exist between regeneration and cortical layer formation. They show that adult zebrafish heart regeneration utilizes an injury/stress responsive program that was first used to remodel the heart during juvenile growth.</p> / Dissertation
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The spirituality of the regenerate heart in the thought of Jonathan EdwardsInagaki, Noriko. January 1994 (has links)
Thesis (Th. M.)--Regent College, 1994. / Includes abstract. Includes bibliographical references (leaves 127-139).
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The spirituality of the regenerate heart in the thought of Jonathan EdwardsInagaki, Noriko. January 1994 (has links) (PDF)
Thesis (Th. M.)--Regent College, 1994. / Includes abstract. Includes bibliographical references (leaves 127-139).
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The spirituality of the regenerate heart in the thought of Jonathan EdwardsInagaki, Noriko. January 1994 (has links)
Thesis (Th. M.)--Regent College, 1994. / Includes abstract. Includes bibliographical references (leaves 127-139).
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The role of mechanosensitve ion channels during zebrafish heart regeneration / Le rôle des canaux ioniques mécanosensibles dans la régénartion cardiovasculaire chez le poisson zèbreNasr, Nathalie 23 February 2018 (has links)
Chez l'Homme, la plupart des maladies cardio-vasculaires provoquent une destruction du tissu cardiaque. Ce dernier est remplacé par de la fibrose conduisant à une diminution de la fonction contractile et une augmentation de la charge ventriculaire avec des risques d’arythmie. Pour maintenir un débit cardiaque constant, les cardiomyocytes vont alors s’hypertrophier, induisant sur le long terme le développement une insuffisance cardiaque. L’augmentation de la charge ventriculaire pourrait être perçue par des mécanosenseurs tels que les canaux ioniques mecanosensibles TREK-1. Contrairement aux mammifères adultes, le cœur du poisson zèbre se régénère suite à une destruction massive du ventricule. Cette régénération se fait par un mécanisme de dédifférenciation, suivie d'une étape de prolifération des cardiomyocytes. Chez les mammifères adultes, la prolifération des cardiomyocytes pourrait être bloquée / inhibée empêchant ainsi la régénération. L’hypothèse que les gènes responsables de l’hypertrophie pathologique chez les mammifères adultes suite à l’augmentation de la charge ventriculaire, soient également responsables la prolifération des cardiomyocytes au cours de la régénération cardiaque chez le poisson zèbre est ainsi consistante. Cette étude, a montré que les canaux TREK-1a et TREK-1b du poisson zèbre possèdent des propriétés biophysiques et pharmacologiques, similaires à ceux du canal TREK-1 de mammifères, et qu’ils jouent un rôle fondamental dans la régénération cardiaque. / In humans, most cardiovascular disorders lead to the destruction of cardiac tissue which will be replaced by fibrosis, leading to arrhythmia and reduced contractile function, resulting in an increase in ventricular load. In order to maintain an overall cardiac output, cardiomyocytes undergo hypertrophic response, leading to pathological hypertrophy and heart failure. This increase in ventricular load, have to be sensed by mechanosensors such as the mechanosensitive ion channels such as TREK-1. Unlike mammals, adult zebrafish (zf) can fully regenerate their heart after an extensive insult through cardiomyocyte dedifferentiation followed by proliferation. We believe that in adult mammals, cardiomyocyte proliferation has been blocked/inhibited. Therefore it’s likely that genes which respond to increased ventricular load in mammals and trigger pathological hypertrophy will trigger cardiomyocyte proliferation during heart regeneration in zf. In this study we show that zTREK1a and zTREK1b have similar biophysical and pharmacological properties to mammalian TREK1 and they are important for successful zebrafish heart regeneration.
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Cellular and molecular mechanisms of zebrafish heart regenerationSchnabel, Kristin 15 March 2019 (has links)
Humans can, if they survived a cardiac injury such as heart infarction, heal this cardiac injury only by scarring and with minimal regeneration of some cardiac cells. Zebrafish, however, can fully regenerate cardiac tissue after surgical resection of up to 20% of the ventricle. Regenerating tissue includes cells of the three cardiac layers, i.e. myocardium, epicardium and endocardium. Thus, zebrafish, with its ability to regenerate damaged heart and as a model enabling genetic manipulations, provides the possibility to study cellular and molecular mechanisms of heart regeneration. Understanding these mechanisms may help develop new therapeutic approaches to improve the situation after a heart injury in humans. Since molecular mechanisms regulating heart regeneration are so far largely unknown, I aimed to identify and analyze molecular signals that are important for cardiac regeneration in zebrafish.
Molecular signals that are crucial during heart development have been suggested to be reactivated during cardiac regeneration. Since Wnt/β-catenin signaling is crucial for vertebrate heart development, it is likely to be important for zebrafish cardiac regeneration as well.
First, I focused on the functional role of Wnt/β-catenin signaling in cardiac regeneration mainly by using transgenic fish lines that allow inducible activation or inhibition of the pathway. By using in situ hybridization and expression profiling, I tested whether endogenous Wnt/β-catenin target genes are detectable in regenerating hearts and screened for activity of the β-catenin responsive reporter in TOPdGFP transgenic fish (Tg(TOP:GFP)w25) after ventricular resection. I could not identify endogenous Wnt/β-catenin targets during the early phase of regeneration up to 7 days post amputation (dpa) using oligoexpression microarrays or in situ hybridization. An injury specific activation of the β-catenin responsive TOPdGFP reporter was not detectable either, suggesting that Wnt/β-catenin signaling is not active during this early phase of regeneration. The manipulation of Wnt/β-catenin signaling using transgenic fish lines did not influence cell proliferation or the overall extent of zebrafish heart regeneration. These results suggested that Wnt/β-catenin signaling has no functional role during entire zebrafish heart regeneration.
Second, I found the transcription factor Sox9a to be upregulated after ventricular resection during the early phase of heart regeneration. Using transgenic reporter fish lines, I detected Sox9a expression in cardiomyocytes and endothelial cells, part of which were proliferative. Furthermore Sox9a was expressed in some cells of the epicardial layer that activated the expression of developmental genes in the entire heart in response to injury. These results indicated that Sox9a is expressed in cells that were actively involved in the regenerative response.
To gain insight into the functional role of Sox9a, I generated a transgenic fish line where a repressor construct is inducibly expressed, which then interferes with Sox9a target gene transcription. I detected a significant reduction in myocardial and endothelial regeneration after induction of the repressor. These results suggested that Sox9a function is important for regeneration of endothelial and myocardial cells after heart injury.
Third, using oligoexpression microarrays, I performed systematic gene expression profiling of the zebrafish heart regeneration within the first 2 weeks following amputation. I found that known genes, which have previously been shown to be strongly expressed during heart regeneration, as well as novel genes were upregulated after ventricular resection. Some of these genes have been implicated in vertebrate heart development, supporting the idea that cardiac developmental genes are reactivated during heart regeneration. Hence, these results reveal a good starting point for further analysis of the cellular and molecular events occurring within the first days after cardiac injury.
Finally, I developed a cryoinjury method that more closely resembled the injured tissue after human heart infarction. I induced tissue death by exposing the ventricle to dry ice and detected that the zebrafish heart can regenerate upon this cardiac injury similarly as in response to a ventricular resection injury. After cryoinjury, the entire epicardium activated the expression of developmental genes and started to proliferate. I detected also proliferating cardiomyocytes, indicating that similar cellular mechanisms are induced in the epicardium and the myocardium after cryoinjury and ventricular resection. Furthermore, activation of Sox9 expression early after cryoinjury suggested that molecular mechanisms of regeneration are also similar in both injury methods. Thus, cryoinjury provides a useful tool for future studies of zebrafish heart regeneration with more relevance to human cardiac infarction.
I discuss all results with reference to vertebrate heart development and to the response after mammalian heart infarction. Furthermore, the results were put into the context of cellular mechanisms that are present in the process of zebrafish heart regeneration.
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Cardiac Extracellular Matrix: Structure, Biomechanics in Myocardial Infarction, and Heart RegenerationBrazile, Bryn 07 May 2016 (has links)
Myocardial infarction (MI) is the leading cause of death among men and women in the United States. Once a person suffers from a MI, the heart wall will undergo a dynamic and time dependent change, as it goes through the inflammatory phase, proliferative phase, and healing phase. During these phases, the necrotic tissue is removed, and the extracellular matrix (ECM) that holds the cardiomyocytes is altered by an increase in type I collagen, which leads to a scar formation in the infarcted area. The goal of this dissertation is to better understand the role of the cardiac ECM biomechanics in heart physiology, pathophysiology (MI), and regeneration. Three Aims were hence pursued. In Aim 1, we investigated cardiac ECM architecture in intact acellular hearts using diffusion tensor-magnetic resonance imaging (DT-MRI); additionally, we characterized the biomechanical and structural properties of cardiac ECM at different anatomical locations of the left ventricle wall. In Aim 2, we characterized the biomechanical and structural properties of scar ECM during the acute to chronic stages of MI using a rat heart model, in order to better understanding the time course changes in scar ECM biomechanics/microenvironment. In Aim 3, we determined if large mammals (pig heart model) have the capability to fully regenerate a resected piece of the heart apex during the neonatal stage, in which cardiac ECM is still in a developmental phase. The hope is to apply the obtained knowledge in cardiac ECM biomechanics to improve the effectiveness and efficiency of treatments, such as stem cell injection, scar tissue repairing, and regenerative intervention.
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Vývoj materiálu na bázi hydrogelů kyseliny hyaluronové pro regeneraci myokardu / Development of Material Based on Hyaluronic Acid s Hydrogels for Myocardial RegenerationKovářová, Lenka January 2020 (has links)
The thesis is focused on material development based on hyaluronic acid usable in regenerative medicine, especially for heart tissue regeneration after myocardial infarction. The object of the study is the oxidized form of hyaluronic acid (HA-Ox) and hydroxyphenyl derivative of HA (HA-TA). HA-Ox can be crosslinked with a bifunctional alkoxyamine POA and HA-TA undergoes an enzymatic reaction in the presence of hydrogen peroxide catalysed by horseradish peroxidase leading to gel formation. To describe the materials, chemical and physical properties, gelation kinetics and conditions of crosslinking reactions were studied. Hydrogels were characterized by mechanical and viscoelastic properties, degradability or stability in simulated body fluids. These hydrogels serve as scaffolds for the selected cell type. To promote cell adhesion and viability, an RGD sequence has been bonded to the structure of HA-TA. This resulting material is also compatible with selected applicators. Its viscosity and extrusion force are low enough to allow application with a catheter with a very small internal diameter. The applicability of the material through the supply tube to the hydrogel reservoir of the second SPREADS device showed good homogeneity, cell distribution and viability. Finally, the material was applied in vivo using these devices during a preclinical study.
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Mechanisms of cardiomyocyte cell cycle arrest and maturation in postnatal rodents and swineVelayutham, Nivedhitha 23 August 2022 (has links)
No description available.
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