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Development of an in vitro assay for MMP cleavageWu, Wing-kei, Ricky., 胡永基. January 2005 (has links)
published_or_final_version / Medical Sciences / Master / Master of Medical Sciences
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A study on the extracellular matrix of mouse fibroblasts used as feeder cells for the culture of embryonic stem cellsHou, Yuen-chi, Denise., 侯元琪. January 2006 (has links)
published_or_final_version / Medical Sciences / Master / Master of Medical Sciences
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Two-photon photochemical crosslinking-based fabrication of protein microstructuresXu, Jinye, 徐金叶 January 2011 (has links)
One of the challenges in tissue engineering is to fabricate scaffolds which can mimic the natural microenvironments of cells. In a cell niche, biophysical and mechanical cues are crucial factors influencing cell functions. Given the complexity of natural extracellular matrix (ECM) engineered ECMs providing controllable biophysical and mechanical cues are appealing both in enhancing the understanding of cell-matrix interaction and in controlling cell fates in vitro.
The ultimate goal of our study is to establish a platform as an engineered ECM by fabricating customized solid protein microstructures from solution using two-photon photochemical crosslinking, a novel laser-based freeform fabrication technique.
In this study, protein structures varying from submicron lines, 2D micropatterns and microporous matrices, to 3D micropillars were successfully fabricated, demonstrating freeform fabrication capability with two-photon photochemical crosslinking.
Two-photon fluorescent imaging and scanning electron microscope (SEM)-based microstructural characterization revealed that power, scan speed, total exposure time and concentrations of protein (bovine serum albumin) and photosensitizer (rose Bengal) in the solution were crucial processing parameters in this fabrication technique. Quantitative imaging analysis showed that porosity of protein matrices was highly dependent on processing parameters including power, scan speed, number of cycles in time series scan and protein concentrations in the solution.
An atomic force microscopy (AFM)-based step change nano-compression test was used to measure the reduced elastic modulus of 3D viscoelastic protein micro-pillars fabricated, as a pilot study.
Microporous protein matrices and 3D micropillar arrays fabricated with two-photon photochemical crosslinking can be used as engineered ECM for future study in cell-ECM interactions. / published_or_final_version / Mechanical Engineering / Master / Master of Philosophy
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The development of bio-mimetic materials for tissue reconstruction through the systematic study of cell-matrix interactionsTong, Wing-yin, Tommy., 湯永賢. January 2013 (has links)
The mission of tissue engineering is to recapitulate the natural process of tissue formation by assembling cells into synthetic scaffold. This relies on the understanding of the functions and properties of the tissue microenvironment (TME), the specific extracellular environment within endogenous tissues. Although existing studies demonstrated the effect of each of the topographical, mechanical and biochemical properties on cell behaviors in isolation, the effect of these properties within the native TME are complicated and ill defined. This thesis aims to investigate how topographical, mechanical and biochemical features of natural TME contribute to the modulation of the biochemistry, morphology and functions of cells, and to translate this knowledge into the fabrication of biomaterials.
Tissue cryosections as a cell culture model system was established. It allowed robust assessment of cell phenotypes in a near-natural TME. Mesenchymal stem cells (MSC) cultured on bone, cartilage and tendon cryosections adopted different morphology, supporting the idea that tissue cryosections forms a robust platform for cell-TME studies. Then, Achilles tendon TME was chosen for proof of concept. This tendon cryosection induced different cell types to adopt different morphologies, indicating that the effect of TME is cell type specific. The proliferation of MSC cultured on cryosection was suppressed, however it was instructed to commit tenogenic differentiation. Then, the necessity of TME topographical properties in forming this instruction was delineated by seeding MSC onto cross-sectional tendon cryosection. Although this surface contained native biomechanical and biochemical cues, it could not promote differentiation. This highlighted the necessity of topographical cues within the TME.
Next, nano-grooved titanium surface that resembles the topographical cues of tendon TME was used to replicate the function of TME. This surface successfully promoted morphogenesis of MSC but not differentiation. This implicated that biomechanical and biochemical cues are both necessary for instructing desired cell phenotypes. The proteomes of MSC cultured on nanogrooved and planar surfaces were then studied using quantitative proteomics. This revealed some expected changes such as up regulation of cytoskeleton and cell-adhesion proteins, suggesting mechanotransduction events might have been induced by nano-grooved surface. However, expressions of RNA-binding proteins were also regulated, representing novel findings. These proteins were also found in the proteome of cellmicroenvironment interface identified through the use of subcellularfractionation and proteomics. This consolidated their involvement in cellmatrix interactions.
The topographical and mechanical properties of cryosection were replicated by using bioimprinting. This imprint induced the morphogenesis of MSC, but tenocytic differentiation was induced only when collagen 1 was coated. However incorrect mechanical properties would abolish such phenotypic guidance. This suggests that topographical, mechanical and biochemical information in a TME are individually indispensable, and it is possible to functionally reconstruct a TME by bioimprinting and ECM protein coating.
In summary, this study investigated the topographical, mechanical and biochemical properties in tendon TME and their combined effect on controlling cell phenotypes. It illustrates that biomimetic approach that mimics these three properties of a tissue can effectively control cell phenotypes. Further investigation on better biomimetic methods and its molecular mechanisms will help establishing strategies for constructing functional tissues. / published_or_final_version / Orthopaedics and Traumatology / Doctoral / Doctor of Philosophy
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The effects of Panax notoginseng extracts and its components on TNF-alpha induced MMP-9 expression and activitySun, Wentao, 孙文韬 January 2014 (has links)
Matrix metalloproteinase (MMP) induced extra cellular matrix (ECM) degradation is a crucial process involved in the development of many chronic inflammatory diseases, including cardiac remodeling and cancer metastasis. In cardiac remodeling, the presence of pathological stimuli leads to elevated MMP-9 expression and impairment of cardiac performance, which subsequently develops into heart failure. While in tumorgenesis, MMP-9 has been found to play key roles in metastasis, as it can break physical barriers for the tumor. Therefore, searching for agents targeting MMP-9 is a new direction for the treatment of cardiac remodeling and cancer metastasis.
Chinese herbal medicine is becoming increasingly used worldwide in recent decades. In the past twenty years, as many highly selective and sensitive bioassays were introduced into the bioactive compounds screening from herbal medicine, more than one hundred new drug candidates have been identified. Therefore, herbal medicine is a potential source of bioactive compounds. Panax notoginseng (PNG) is one of the most common traditional Chinese medicines to treat cardiovascular diseases, and it was also reported to have anti-cancer effect. We hypothesized that it contains bioactive compounds that could inhibit MMP-9 activity in cardiomyocytes and cancer cells.
In order to examine the effect of PNG on cardiac remodeling and cancer metastasis, we employed TNF-α induced MMP-9 in H9c2 cell (a rat cardiomyocyte) and HepG-2 cell (a human hepatoma cell) as an in vitro assay, respectively. PNG was first extracted by four different extraction methods according to the polarity of the solvent. The most effective fraction in suppressing MMP-9 activity in TNF-α induced H9c2 cell was chosen for further separation by silica gel column chromatography and high performance liquid chromatography (HPLC) until a single compound was isolated. According to the result of spectroscopic analysis by NMR, the compound was identified as ginsenoside Rb1. For the bioactivity assays, real-time quantitative polymerase chain reaction (QPCR) and Enzyme-linked immunosorbent assay (ELISA) were used to measure the mRNA and protein expression of MMP-9, respectively. We also examined the MMP-9 activity by gelatin zymography. The results showed that both of the PNG extract obtained from 10% ethanol extraction method (PNG-3) and purified Compound P (ginsenoside Rb1) showed significant inhibitory effect on MMP-9 expression and activity in H9c2 cells and HepG-2 cells.
We further examined the molecular mechanisms of the inhibitory effect of PNG-3. H9c2 and HepG-2 cells were pretreated with different kinase inhibitors followed by the activation by TNF-α. The results showed the protein kinase R (PKR) inhibitor could inhibit TNF-α induced MMP-9 in both of the two cell lines. Furthermore, the results of Western blot showed the PNG-3 suppressed the phosphorylation of eIF-2α which is a down-stream effector of PKR in TNF-α stimulated H9c2 and HepG-2 cells, respectively. Therefore, PNG-3 may act through PKR to regulate TNF-α induced MMP-9 activity.
In summary, bioactivity guided fractionation is an effective way of isolating bioactive compounds from medicinal herbs. In addition, PNG containing ginsenoside Rb1 may be a potential candidate of MMP-9 inhibition for the treatment of cardiac remodeling and cancer metastasis. / published_or_final_version / Paediatrics and Adolescent Medicine / Master / Master of Philosophy
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Multiphoton based biofabrication of 3D protein micro-structures and micro-patterns : voxel and cell matrix niche studiesMa, Jiaoni, 馬姣妮 January 2014 (has links)
abstract / Mechanical Engineering / Doctoral / Doctor of Philosophy
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Mechanism of action of silicon : extracellular matrix synthesis and stabilisationKopanska, Katarzyna January 2012 (has links)
No description available.
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Effect of steady and pulsatile laminar shear stress on extracellular matrix and focal contact-associated proteins of endothelial cellsThoumine, Olivier 05 1900 (has links)
No description available.
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Studies of the 67 kilodalton laminin receptor in retinal vasculatureMcKenna, Declan Joseph January 1999 (has links)
No description available.
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The implications of fibulin-5 on elastin assembly and its role in the elastic fiber /Ferron, Florence Joelle. January 2007 (has links)
The extracellular matrix (ECM) is the material found surrounding the cells in a tissue. One component of the ECM is the elastic fiber, which confers the property of elasticity to its environment. Organs such as the lung, skin and major blood vessels have an abundance of elastic fibers so that they are able to expand and recoil. Elastic fibers are composed of two main components; elastin and microfibrils. Microfibrils are composed primarily of fibrillin-1 and provide a scaffold unto which tropoelastin monomers assemble. Elastic fibers interact with many other proteins in the ECM, one of which is fibulin-5. Based on the severe elastic fiber defects observed in the fibulin-5 null mouse, it was established that fibulin-5 plays an essential role in elastic fiber development. This role may be in the deposition of tropoelastin onto microfibrils and/or in stabilizing the elastic fibers in the extracellular matrix. In the present study, the relationship between fibulin-5 and the elastic fiber was investigated through a number of in vivo and in vitro experiments. To test the hypothesis that fibulin-5 requires the presence of elastin to assemble in the ECM, full-length recombinant fibulin-5 (rF5) was purified from transfected cells and used to make a fibulin-5 antibody. Solid-phase binding assays using rF5 showed that fibulin-5 binds tropoelastin at two sites; the initial portion of the C-terminus and the first calcium-binding epidermal growth factor-like domain at the N-terminus. Immunofluorescence staining of elastin null mouse embryonic fibroblast cultures revealed that fibulin-5 does not require elastin to be present in the ECM in order to assemble. Subsequently, solid-phase binding assays showed that fibulin-5 can bind to the N-terminus of fibrillin-1. To determine if fibulin-5 could exist independent of elastin and/or fibrillin-1 in vivo, an immunohistochemical analysis was conducted on heart, liver, lung, colon, spleen, testis and kidney. All three proteins were co-localized in all organs except in the kidney, where fibrillin-1 was found to independently stain the capillary tufts of the renal corpuscles and renal tubules. Thus, fibulin-5 may be co-regulated with elastin and is not present on elastin-independent microfibrils. Additionally, novel locations of elastic fibers were uncovered in the heart, liver, colon, spleen and testis. Overall, this study provides important insights as to the role of fibulin-5 in elastic fiber structure and assembly and also reveals the complexity in understanding the pathogenesis of diseases involving elastic fiber proteins.
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