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Mechanisms of joint injury in an animal model of collagen-induced arthritisBakharevski, Olga, 1968- January 2000 (has links)
Abstract not available
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The occurence and `in vivo` activity of tissue collagenase in inflamed human gingivae / Christopher Mark OverallOverall, Christopher Mark January 1984 (has links)
Bibliography: leaves 205-233 / xix, 234 leaves : / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (M.D.S.)--University of Adelaide, 1985
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Functional analyses of type IIA procollagen in embryo development /Leung, Wai-lun, Alan. January 2006 (has links)
Thesis (Ph. D.)--University of Hong Kong, 2006.
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Characterization of candidate genes in English cocker spaniel hereditary nephritisCamacho, Zenaido 17 February 2005 (has links)
Six different isoforms of Type IV collagen (colIVα1-6) have been identified. The individual isoforms of colIV are termed alpha chains and are translated from six different COLIV genes (COLIVA1-A6). Collagen Type IV gene products compose the structural framework of basement membranes. The glomerular basement membrane (GBM) is a specialized basement membrane involved in the ultrafiltration processes of the kidney. The colIVα1-α5 chains are expressed in the human GBM while the colIV α1-α6 chains are expressed in the canine GBM. Many inherited diseases of the kidney have been reported and mutations in genes regulating kidney function have been identified. Alport syndrome (AS) is the most common form of human hereditary nephritis (HN). AS is defined as an inherited progressive kidney disorder associated with sensoneural deafness and is characterized by extensive thickening and multilamminar splitting of the GBM when examined by electron microscopy. AS has both X-linked (XLAS) and autosomal (ARAS) modes of inheritance. Mutations in the COLIVA5 gene are responsible for XLAS. A form of HN with characteristic splitting of the GBM with X-linked inheritance has been described in Samoyed dogs. A specific mutation in the COLIVA5 gene has been identified in Samoyed dogs affected with HN. Mutations in the COLIVA3 and COLIVA4 genes are responsible for ARAS. A form of HN has been identified in English cocker spaniel dogs (ECS) that has been described as autosomal in inheritance and includes GBM abnormalities including extensive lammination characteristic of ARAS. Both ARAS and ECS-HN show loss of the colIVA3 and colIVA4 chains in the GBM when examined with monoclonal anitibodies. ECS-HN has been hypothesized to have the same molecular basis of disease as ARAS. As such, we have isolated and characterized canine COLIVA3 and COLIVA4 sequences from normal dogs and ECS dogs affected with HN and compared the coding regions of these candidate genes.
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The normal basilar artery: structural properties and mechanical behaviorWicker, Bethany Kay 15 May 2009 (has links)
The leading cause of death in patients who survive subarachnoid hemorrhage (SAH) is stroke as a result of cerebral arterial vasospasm1. Such vasospasms involve a vasoactive response, but they remain enigmatic and no clinical treatment has proven effective in prevention or reduction2. Arteries remodel in response to diverse mechanical loads and chemical factors. Following SAH, the surrounding vasculature is exposed to a radically altered chemo-mechanical environment. It is our hypothesis that chemical stimuli associated with the formation of an extravascular blood clot dominates the maladaptive growth and remodeling response early on, thus leading to important structural changes. However, it is not clear which of the many chemical factors are key players in the production of vasospasm. Before an accurate picture of the etiology of vasospasm can be produced, it is imperative to gain a better understanding of the non-pathogenic cerebral vasculature. In particular, the rabbit basilar artery is a well established model for vasospasm. However, surprisingly little is known about the mechanical properties of the rabbit basilar artery. Using an in vitro custom organ culture and mechanical testing device, acute and cultured basilar arteries from male White New Zealand specific pathogen free rabbits underwent cyclic pressurization tests at in vivo conditions and controlled levels of myogenic tone. Sections of basilar arteries were imaged for collagen fiber orientation at 0, 40 and 80 mmHg at in vivo stretch conditions using nonlinear optical microscopy. The nonlinear stress-strain curves provide baseline characteristics for acute and short-term culture basilar arteries. The active and passive testing creates a framework for interpreting the basal tone of arteries in our culture system. Nonlinear optical microscopy second harmonic generation provides unique microstructural information and allows imaging of live, intact arteries while maintaining in vivo geometries and conditions. Collagen fibers were found to be widely distributed about the axial direction in the adventitial layer and narrowly distributed about the circumferential direction in the adventitial layer. The quantified collagen fiber angles within the artery wall further support the development of accurate mathematical models.
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Cellular Response to Ordered Collagen Layers on MicaLeow, Wee Wen 2012 May 1900 (has links)
Extracellular microenvironment, including its components and biophysical parameters such as matrix structure and stiffness, is a crucial determinant of cellular function. There exists interdependency between cellular behaviors and the extracellular matrix (ECM), whereby cells are constantly sensing and modifying their surroundings in response to physical stress or during processes like wound repair, cancer cell invasion, and morphogenesis, to create an environment which supports adaptation. To date, knowledge of the distinct regulatory mechanisms of this complex relationship is little, while the urge is evident as it plays a significant role in understanding tissue remodeling. Cells are observed to align with the parallel arrays of collagen fibrils found in tissues such as bone, tendon, and cornea, suggesting the importance of ordered matrices in defining cell functions. In this study, epitaxial growths of ordered two-dimensional collagen matrices were created, with parallelly aligned fibrils on muscovite mica, and novel triangular pattern matrix on phlogopite mica. Using Fluorescence and Atomic Force Microscopy, we were able to observe cell polarization along with stress fiber formation and matrix deformation at high resolution. Cells were observed to be able to penetrate between collagen fibrils and generate traction anisotropically to polarize. These ordered collagen matrices serve as an excellent model to study cellular remodeling of ECM in vitro, in which this fundamental apprehension of cell-matrix relationship is of crucial importance to manipulate the system and obtain desired cell functions.
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Cardiac Tissue EngineeringDawson, Jennifer Elizabeth 24 June 2011 (has links)
The limited treatment options available for heart disease patients has lead to increased interest in the development of embryonic stem cell (ESC) therapies to replace heart muscle. The challenges of developing usable ESC therapeutic strategies are associated with the limited ability to obtain a pure, defined population of differentiated cardiomyocytes, and the design of in vivo cell delivery platforms to minimize cardiomyocyte loss. These challenges were addressed in Chapter 2 by designing a cardiomyocyte selectable progenitor cell line that permitted evaluation of a collagen-based scaffold for its ability to sustain stem cell-derived cardiomyocyte function (“A P19 Cardiac Cell Line as a Model for Evaluating Cardiac Tissue Engineering Biomaterials”). P19 cells enriched for cardiomyocytes were viable on a transglutaminase cross-linked collagen scaffold, and maintained their cardiomyocyte contractile phenotype in vitro while growing on the scaffold. The potential for a novel cell-surface marker to purify cardiomyocytes within ESC cultures was evaluated in Chapter 3, “Dihydropyridine Receptor (DHP-R) Surface Marker Enrichment of ES-derived Cardiomyocytes”. DHP-R is demonstrated to be upregulated at the protein and RNA transcript level during cardiomyogenesis. DHP-R positive mouse ES cells were fluorescent activated cell sorted, and the DHP-R positive cultured cells were enriched for cardiomyocytes compared to the DHP-R negative population. Finally, in Chapter 4, mouse ESCs were characterized while growing on a clinically approved collagen I/III-based scaffold modified with the RGD integrin-binding motif, (“Collagen (+RGD and –RGD) scaffolds support cardiomyogenesis after aggregation of mouse embryonic stem cells”). The collagen I/III RGD+ and RGD- scaffolds sustained ESC-derived cardiomyocyte growth and function. Notably, no significant differences in cell survival, cardiac phenotype, and cardiomyocyte function were detected with the addition of the RGD domain to the collagen scaffold. Thus, in summary, these three studies have resulted in the identification of a potential cell surface marker for ESC-derived cardiomyocyte purification, and prove that collagen-based scaffolds can sustain ES-cardiomyocyte growth and function. This has set the framework for further studies that will move the field closer to obtaining a safe and effective delivery strategy for transplanting ESCs onto human hearts.
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Endothelial Cells Guided by Immobilized Gradients of Vascular Endothelial Growth Factor on Porous Collagen ScaffoldsOdedra, Devangbhai 25 August 2011 (has links)
A key challenge in tissue engineering is overcoming cell death in the scaffold interior due to the limited diffusion of oxygen and nutrients therein. We hypothesized here that immobilizing a gradient of vascular endothelial growth factor (VEGF-165) would guide endothelial cells into the interior of the scaffold thereby enhancing angiogenesis. The protein was immobilized onto a collagen scaffold through carbodiimide chemistry by one of the three methods experimented: placing 5 µl of the solution at the center of the scaffold to create a ~2 ng/ml/mm gradient in a radial direction. D4T endothelial cells were observed to be guided by this VEGF-165 gradient deep into the center of the scaffold compared to both uniformly immobilized VEGF-165 and VEGF-free controls. We concluded that the VEGF-165 gradient scaffolds promoted the migration, and not proliferation, of cells deep into the scaffold. These gradient scaffolds provide the foundation for future in vivo tissue engineering studies.
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Endothelial Cells Guided by Immobilized Gradients of Vascular Endothelial Growth Factor on Porous Collagen ScaffoldsOdedra, Devangbhai 25 August 2011 (has links)
A key challenge in tissue engineering is overcoming cell death in the scaffold interior due to the limited diffusion of oxygen and nutrients therein. We hypothesized here that immobilizing a gradient of vascular endothelial growth factor (VEGF-165) would guide endothelial cells into the interior of the scaffold thereby enhancing angiogenesis. The protein was immobilized onto a collagen scaffold through carbodiimide chemistry by one of the three methods experimented: placing 5 µl of the solution at the center of the scaffold to create a ~2 ng/ml/mm gradient in a radial direction. D4T endothelial cells were observed to be guided by this VEGF-165 gradient deep into the center of the scaffold compared to both uniformly immobilized VEGF-165 and VEGF-free controls. We concluded that the VEGF-165 gradient scaffolds promoted the migration, and not proliferation, of cells deep into the scaffold. These gradient scaffolds provide the foundation for future in vivo tissue engineering studies.
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The effect of myocardin and Smad3 overexpression in ventricular myofibroblasts: cellular contractility and collagen productionBedosky, Kristen Marie 14 April 2008 (has links)
The incidence of cardiovascular disease has reached epidemic proportions in North America. Specifically, myocardial infarctions (MI) are a major contributor to heart failure which greatly influences morbidity and mortality rates in developed nations. In the post-MI heart, cardiac fibroblasts migrate to the damaged area, convert to myofibroblasts and contribute to infarct scar contraction. As well, cardiac myofibroblasts are hypersynthetic for matrix components eg, collagen, and de novo production of fibrillar collagens lessens the chance for acute scar rupture. TGF-1 is important in the initiation of cardiac healing and fibrosis. Canonical TGF-1 signaling occurs with the activation of receptor-operated Smads (R-Smads) including Smad3. The current study addresses the question of whether Smad3 and/or myocardin influence myofibroblast contractility. We believe that myocardin is a Smad3 binding partner and cofactor and thus contributes to Smad associated healing and fibrotic events in the heart. In mesenchyme-derived cells, myocardin exists as a nuclear protein and is a cardiac and smooth muscle specific transcriptional coactivator of serum response factor (SRF). This transcription factor has been shown to bind to Smad3 in COS-7 cells (a green monkey kidney fibroblast-like cell line) and we suggest that it may contribute to fibroproliferative events. Precisely how Smad3/myocardin facilitates post-MI wound healing and/or contributes to inappropriate post-MI fibrosis is unknown.
Very little work has been done to address myocardin expression in cardiac ventricular myofibroblasts. While a number of previous studies address TGF-β/Smad signaling in cardiac myofibroblasts, none have addressed the effects of overexpressed Smad3 on cellular contractility and collagen secretion. As Smad3 and its endogenous inhibitor Smad eg, I-Smad7, contribute significantly to TGF-β signaling in myofibroblasts, we rationalize that they must be important in the regulation of many fibroproliferative processes. Our goals were first to measure/determine myocardin expression in primary ventricular myofibroblasts; second, to explore a putative interaction between Smad3 and myocardin; third to examine a possible link between TGF-β1 stimulation, myocardin and Smad3. Finally, we sought to examine the effect of overexpressed Smad3, Smad7 and myocardin on contractility and collagen production. These experiments were conducted by using RT-PCR, co-immunoprecipitation, adenoviral overexpression of Smad3, Smad7 and myocardin, Western blot analysis, collagen gel deformation assays (contractility studies) and finally, Pro-collagen 1 N-terminal Peptide (P1NP) secretion as a measure of mature collagen production.
We document the novel expression of myocardin in ventricular myofibroblasts and provide evidence that myocardin may serve as a Smad3 cofactor in cardiac myofibroblasts. Further, myocardin overexpression is linked to increased contractility in myofibroblasts compared to LacZ infected controls, and that TGF-β1 acutely stimulated myocardin expression followed by a dramatic reduction 1 hour thereafter. Overexpressed Smad3 alone led to increased contractility in primary ventricular myofibroblasts. Thus the effect of increasing myocardin expression had a comparable effect to that of increased Smad3 alone with this endpoint. Finally, overexpression of both Smad3 and myocardin in the presence of TGF-β1 led to an additive stimulation of contractility in cells when compared to the effect of TGF-β1 stimulation alone. Overexpressed Smad7 alone was associated with decreased secretion of type I collagen when compared to the control; when cells overexpressing Smad7 are stimulated with TGF-β1, collagen secretion is dramatically reduced when compared to cells treated with TGF-β1.
In an addition series of experiments we addressed reverse mode NCX1 function as a means of Ca2+ entry to the cytosol of myofibroblasts upon their excitation. We have previously shown the stimulatory effect of TGF-β1 on myofibroblast contractility, and we now report that overexpression of Smad3 alone led to increased mRNA expression of NCX1. Thus it is possible that TGF-β1 signaling via Smad3 may influence Ca2+ movements and thus contractile performance in ventricular myofibroblasts. / May 2008
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