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Modelling and sequence analysis of the collagen triple helixCheng, Lung-fung. January 2001 (has links)
Thesis (M.Med.Sc.)--University of Hong Kong, 2001. / Includes bibliographical references (leaves 99-101). Also available in print.
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Regulation of the formation of connective tissue by phagocytizing cells with reference to experimental silicosis /Aalto, Maija. January 1983 (has links)
Thesis (doctoral)--University of Turku.
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The behavior of deaminized collagen ...Foster, Stuart Brooks, January 1925 (has links)
Thesis (Ph. D.)--Columbia University, 1925. / Vita. A contribution to the chemical theory of vegetable tanning. Bibliography: p. 21.
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Studies concerning the mechanism of osteolathyrogenic activity of beta-aminopropionitrileEhrhart, Leo Allen. January 1964 (has links)
Thesis (Ph. D.)--University of Wisconsin, 1964. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliography.
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Tenderness and collagen solubility in relation to chronological age in leghorn fowlWangen, Roger Maurice, January 1968 (has links)
Thesis (M.S.)--University of Wisconsin--Madison, 1968. / eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references.
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Construction of a COL11A1 transgene vector /Beck, Cameron McKell, January 2006 (has links) (PDF)
Thesis (M.S.)--Brigham Young University. Dept. of Physiology and Developmental Biology, 2006. / Includes bibliographical references (p. 37-39).
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Spatial and temporal regulation of three collagen genes during sensory ray morphogenesis of caenorhabditis elegans /Hui, Wing-sze. January 2006 (has links)
Thesis (Ph.D.)--Hong Kong University of Science and Technology, 2006. / Includes bibliographical references (leaves 222-232). Also available in electronic version.
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Characterization of cuticle collagens and their biosynthetic process in C. elegans sensory ray morphogenesis /Lam, Yiu-Man. January 2007 (has links)
Thesis (Ph.D.)--Hong Kong University of Science and Technology, 2007. / Includes bibliographical references (leaves 179-189). Also available in electronic version.
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Interactions between steroidal anti-inflammatory agents and collagenKanfer, Isadore January 1975 (has links)
Much research has been done on the formation of fibrils from solutions of soluble collagen in vitro in order to gain some knowledge of the mechanisms which may occur in vivo. The in vitro formation of fibres from solutions of collagen has been shown to be extremely sensitive to the nature of the solution environment and the presence of added chemical compounds, and thus constitutes an interesting system for the study of collagen-small molecule inter actions. The present study is concerned with the effects of various corticosteroid drugs, used medicinally as anti-inflammatory agents, on collagen in solution. As these corticosteroids are administered to reduce inflammation in conditions such as rheumatoid arthritis and a host of other pathological conditions in which collagen is implicated, this work has been undertaken in order to establish and charac teri ze any binding mechanisms which may be involved. Furthermore, the corticosteroid drugs available commercially in pure form as the free base or as the water-soluble ester salts offer an interesting range of structural and stereochemical variants for the study of their reaction with a complex and biologically important protein molecule such as collagen. A great deal of research on drug- protein interactions (Goldstein, 1949; Meyer and Guttman, 1968a) and more specifically, steroid-protein interactions have been reported over the years (Daughaday, 1959; Sandberg et al., 1966; Villee and Engel, 1961; Westphal , 1971). Comprehensive reports, however, on steroid-collagen interactions in vitro are conspicuously absent from modern scientific literature although relatively superficial accounts have been published (Menczel and Maibach, 1972; Eik-Nes et al., 1954). Although work involving the above has appeared relating specifically to the effects of steroids on collagen biosynthesis both in vivo and in vitro there have been minimal accounts of steroid-collagen interactions tailored to characterize the binding at the molecular level. The effect of corticosteroids on the metabolism of connective tissue has also received special attention (Asboe-Hansen, 1959; Kivirikko, 1953; Nakagawa and Tsurufuji, 1972). Recently, Uitto et al. (1972) reported the effects of several anti-inflammatory corticosteroids on collagen biosynthesis in vitro, whilst Aalto and Kulonen (1972) reported the effects of several antirheumatic drugs on the synthesis of collagen and other proteins in vitro. The interactions between collagen and certain drugs has also been briefly reviewed (Chvapil, 1967). Much data also exists on the binding of a wide range of small molecules and ions with serum albumin (Steinhardt and Reynolds, 1969; Scatchard, 1949; Klotz, 1950). Serum albumin, being specialized for a very general transport function and apparently designed for the purpose of combining with a large range of small molecules, has a proportion of possible reactive sites 'buried' within the molecule itself because of its folded conformation. In addition, serum albumin shows a high degree of cooperative binding in contrast to collagen. The latter molecule, with its larger molecular size and weight is specialized for a biologically structural function and has a higher proportion of possible reactive sites which appear relatively more accessible to ligands. A study of the interactions between corticosteroids and collagen thus provides the opportunity to investigate a protein which is very different from the much studied serum albumin. Because of the limited information available regarding the interaction of steroid drugs and collagen at the molecular level, studies of this nature are relevant to the understanding of the mode of action of steroid compounds which are such an important group of therapeutic substances used in modern medicine.
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Design and Engineering of 3D Collagen-Fibronectin Scaffolds for Wound Healing and Cancer ResearchAsadishekari, Maryam 01 November 2018 (has links)
Despite our understanding of the importance of the 3D environment on the behaviour of virtually every cell, most studies are still performed within 2D engineered cell culture devices. In this project, the main goal was to design and engineer tunable three-dimensional (3D) extracellular matrix (ECM)-mimicking scaffolds made of collagen and fibronectin (namely the two major building blocks of the ECM) that recapitulate the ECM structural and mechanical properties essential for wound healing and cancer research. Two different methods were implemented to fabricate 3D scaffolds.
First, 3D collagen scaffolds with a ‘porous’ structure (fabricated by a previous student via an ice-templating technique) were used. It was shown that, by increasing collagen concentration to 1.25 wt.%, homogenous scaffolds with interconnected pores (needed for cell invasion through the entire scaffold) were obtained. Fibronectin (Fn) was then incorporated using thermal and mechanical gradients to modify protein content and tune scaffolds microarchitecture. The effect of Fn coating of the collagen underlying structure on cell behaviour such as cell adhesion, invasion and matrix deposition was studied. Results showed that overall more cells adhered to Fn-coated scaffolds with respect to pure collagen scaffolds. Furthermore, our findings indicated that cells were also able to sense the conformation of the Fn coating (as assessed by Fluorescence Resonance Energy Transfer, FRET) since they deposited a more compact ECM on compact Fn coating while a more unfolded and stretched ECM was deposited on unfolded Fn coating.
Second, 3D more complex physiologically relevant scaffolds with a ‘fibrillar’ structure were fabricated via a cold/warm casting technique. Pure collagen scaffolds were first generated: in cold-cast scaffolds, clear thin and long collagen fibers were observed while warm-cast scaffolds were denser and comprised shorter collagen fibers. The effect of both collagen concentration and casting temperature on scaffolds’ microstructure was studied. Our results indicate a preponderant effect of temperature. We further engineered dual-protein fibronectin-collagen fibrillar scaffolds by incorporating Fn fibers using thermal gradient. Clear Fn fibers were observed in some conditions. FRET assessment of Fn fibers also showed significant difference of Fn conformation. In this more advanced casting technique, cells were initially embedded into the scaffolds, which provided a more homogeneous cell distribution and a better tissue-mimicking setting. In each case, the effect of resulting ECM properties was tested via cell viability assays. Our data indicate that cells were viable after 72 hours, they could proliferate inside the scaffolds and were able to spread in some conditions.
Collectively, our 3D ECM-mimicking scaffolds represent a new tunable platform for biological and biomaterial research with many potential applications in tissue engineering and regenerative medicine. Investigating cell behaviour in 3D ECM-mimicking environment will provide valuable insights to understand cancer progression and approaches to limit the progression and ultimately prevent metastasis.
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