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381	Tissue Engineering of a Differentiated Skeletal Muscle Construct with Controllable Structure and Function Bian, Weining January 2011 (has links) <p>Transplantation of a functional engineered skeletal muscle substitute is a promising therapeutic option to repair irreversible muscle damage, and, on the other hand, functional muscle tissue constructs can serve as in vitro 3D tissue models that complement the conventional 2D cell cultures and animal models to advance our limited understanding of intrinsic myogenesis and muscle regeneration process. However, the engineering of skeletal muscle constructs with comparable contractile function to the native muscle is hampered by the lack of 1) effective and reproducible methods to form relatively large muscle constructs composed of viable, dense, aligned and matured myofibers, and 2) beneficial microenvironmental cues as well as physiological stimulations that favor the growth, differentiation and maturation of myogenic cells. Thus, in this thesis, I have developed a mesoscopic hydrogel molding approach to fabricate relatively large engineered muscle tissue networks with controllable thickness, pore dimensions, overall myofiber alignment and regional myofiber orientation. I then investigated the effect of variation in pore length on the force generation and passive properties of engineered muscle networks and the potential to improve the contractile function of engineered muscle networks with the treatment of a soluble neurotrophic factor, agrin.</p><p>Specifically, high aspect-ratio soft lithography was utilized to precisely fabricate elastomeric molds containing an array of staggered hexagonal posts which created elliptical pores in muscle tissue sheets made from a mixture of primary skeletal myoblasts, fibrin and Matrigel. The improved oxygen and nutrient access through the pores increased the viability of the embedded muscle cells and prevented the formation of an acellular core. The differentiated myofibers were locally aligned in tissue bundles surrounding the elliptical pores. The length and direction of the microfabricate posts arbitrarily determined the length of elliptical pores and the mean orientation of myofibers formed around the pores, which enables the control of pore dimensions and regional myofiber orientation. Contractile force analysis revealed that engineered muscle networks with more elongated pores generated larger contractile force due to the increased myonuclear density and degree of overall myofiber alignment, despite the larger porosity and reduced tissue volume. Furthermore, the introduction of elliptical pores resulted in distinct deformational changes in tissue bundles and node regions that connect the ends of bundles with the applied unaxial macroscopic stretch, but such spatial alteration of local strain field resulted in no significant change in macroscopic length- tension relationships among engineered muscle networks with different pore length. </p><p>In addition, supplementing culture medium with soluble recombinant agrin significantly increased contractile force production of engineered muscle networks in the absence of nerve-muscle interaction, primarily or partially due to the agrin-induced upregulation of dystrophin. As expected, alteration in the levels endogenous ACh or ACh-like compound affected the agrin-induced AChR aggregation. Furthermore, increased autocrine AChR stimulation, a novel mechanism underlying survival and maturation of aneural myotubes, attenuated the agrin-induced force increase, while suppressed autocrine AChR stimulation severely comproised the overall force production of engineered muscle networks, of which the underlying mechanisms remains to be elucidated in the future studies. </p><p>In summary, a novel tissue engineering methodology that enables the fabrication of relative large muscle tissue constructs with controllable structure and function has been developed in this thesis. Future studies, such as optimizing cell-matrix interaction, incorporating beneficial regulatory proteins in the fibrin-based matrix, and applying specific patterns of electro-mechanical stimulations are expected to further augment the contractile function of engineered muscle networks. The potential application of this versatile tissue fabrication approach to engineer different types of soft tissue might further advance the development of tissue regeneration therapies as well as deepen our understanding of intrinsic tissue morphogenesis and regeneration process.</p> / Dissertation Biomedical Engineering agrin contractile force fibrin hydrogel molding skeletal muscle tissue engineering
382	Mechanical Stretch and Electrical Stimulation in Mouse Skeletal Muscle in Vivo: Initiation of Hypertrophic Signaling Brathwaite, Ricky Christopher 12 July 2004 (has links) Skeletal muscle has an integral role in many activities. Although mechanical stretch and active force generation are known to be required for the maintenance of healthy muscle function, the mechanism by which those signals mediate muscle growth is unknown. This project was based on the hypothesis that stretch and force generation activate the Calcineurin/NFAT pathway and induce Cox-2 expression and initiate muscle hypertrophy. The specific aims of this study were to 1) develop a minimally invasive system capable of initiating hypertrophic signaling in mice, 2) characterize the effects of isometric activation, passive lengthening, and active lengthening on signaling cascades, and 3) determine the involvement of the Calcineurin/NFAT pathway and activation of COX-2 gene expression. We propose a pathway in which stimuli increase intracellular calcium, which activates the phosphatase calcineurin. Calcineurin dephosphorylates NFAT, which is translocated into the nucleus and initiates transcription of the COX-2 gene. COX-2 mediated synthesis of PGG2 is the rate-limiting step in bioactive prostaglandin synthesis. Prostaglandins then stimulate known hypertrophic signals including the PI-3 Kinase and MAP Kinase signaling cascades. PI3 Kinase MAP Kinases NFAT Skeletal muscle COX-2 Exercise Stimulation Stretch Mouse
383	Role Of Tnf-alpha In Skeletal Muscle Atrophy In Ovariectomized Rats: An Experimental Functional, Histological And Molecular Biology Study Dagdeviren, Sezin 01 June 2010 (has links) (PDF) Skeletal muscle is defined to be atrophic in osteoporosis models and therefore is a potential target tissue for osteoporosis research. The aim of this longitudinal randomized controlled interdisciplinary study was to analyze the functional, histological, ultra-structral and molecular changes and the role of cachectic muscle atrophy inducer TNF-alpha in the skeletal muscles of the ovariectomized (OVX) rat model which mimics postmenopausal osteoporosis. Female Sprague-Dawley rats were randomly assigned to the control, the OVX and the OVX+10&amp / #956 / g/g/week TNF-alpha antagonist (Remicade) treated OVX-TNF groups. Maximum isometric and tetanic-twitch amplitudes were lower than the control group in the OVX group. Maximum isometric twitch amplitudes recovered in the fast-twitch extensor digitorum longus (EDL) muscles but not in the slow-twitch soleus muscles in the OVX-TNF group. The decrease in tetanic-twitch amplitudes recovered in the OVX-TNF group in both muscle types. Splitting and size variations of fibers, central nuclei and well-preserved overall ultrastructure were noted in the OVX and the OVX-TNF groups. Slow-twitch Type I fiber percentage, areas and diameters increased in EDL muscles of the OVX and the OVX-TNF group comparing to the control group. p65 and MyoD immune-labeling increased in OVX group whereas MyoD and C-Rel increased and p50 decreased in OVX-TNF group. Expressions of 61 genes and 42 unidentified transcripts were significantly different between the control, the OVX and the OVX-TNF groups. To sum up TNF-alpha has a role in skeletal muscle dysfunction in OVX rats and TNF-alpha antagonist administration recovered it. But this modulation was not sufficient for total structural recovery.
384	Contribution of sarcoplasmic reticulum calcium pumping to resting mouse muscle metabolism Norris, Sarah January 2009 (has links) Few studies have quantified resting mouse muscle metabolism and even fewer studies have separated the contribution of sarcoplasmic reticulum (SR) Ca2+ pumping to resting metabolic rate. Furthermore, the studies that have attempted to quantify the contribution of Ca2+ pumping have used indirect methods to inhibit SR Ca2+ ATPase activity. The purpose of this study is to directly quantify resting muscle oxygen consumption and the contribution of SR Ca2+ pumping to resting oxygen consumption in mouse hindlimb muscles by using CPA to specifically inhibit Ca2+ pump activity in intact muscles at rest. The TIOX system was used to measure resting muscle VO2 of extensor digitorum longus (EDL) and soleus (SOL) muscles at 30oC and 20oC. C57BL mice aged 8-12 weeks were used with an average whole body mass of 23.8 g and EDL and SOL dry weights averaging 1.88 mg and 1.8 mg, respectively. All muscle VO2 measurements are expressed per gram dry weight. There were no differences (P>0.1) in resting muscle VO2 between EDL and SOL muscles at either 30oC (EDL, 2.05 µL/g/s; SOL, 2.27 µL/g/s) or 20oC (EDL, 0.62 µL/g/s; SOL, 0.71 µL/g/s). The average Q10 (3.1) was determined from EDL and SOL VO2 measures at 20oC and 30oC. The contribution of Ca2+ pumping by the sarco(endo)plasmic reticulum Ca2+ ATPase (SERCA) was measured at 30oC using a range of CPA concentrations (1-15 µM) . There was a concentration-dependent effect of CPA on oxygen consumption with increasing CPA concentrations up to 10 µM resulting in progressively greater reductions in muscle oxygen consumption. Specifically, 1, 5, 10, and 15 µM CPA caused an 11, 35.4, 49.5, and 50.3% reduction in VO2. There were no differences (P>0.1) between 10 and 15 µM CPA indicating that 10 µM CPA induces maximal inhibition of SERCA in isolated muscle preparations. The results indicate that the Ca2+ pumping by SERCA is responsible for ~50% of oxygen consumption in resting mouse EDL and SOL muscle. This is the first study to use a direct inhibitor of SERCA to quantify the contribution of Ca2+ cycling to resting oxygen consumption and therefore is a more accurate reflection of the actual contribution of SERCA to resting muscle oxygen consumption compared to previous findings. These results suggest that SERCA energy consumption accounts for a large portion of resting muscle metabolism and may represent a potential therapeutic target for metabolic alterations to oppose obesity. sarco(endo)plasmic reticulum Ca2+ ATPase skeletal muscle oxygen consumption Kinesiology
385	Faserverteilung und Muskelfaserspezifische glykolytische und oxidative Enzymaktivität im Skelettmuskel von Patienten mit Typ 2 Diabetes Oberbach, Andreas 26 January 2011 (has links) (PDF) Mittels immunhistochemischer- und zyto-fotometrischer Verfahren wurden die Änderungen der glykolytischen und der oxidativen Enzymkapazität im Skelettmuskel von Patienten mit T2DM mit der Muskelfasercharakteristik untersucht. Weiterführende Analysen klären den Zusammenhang zwischen der Änderung der Muskelfaserverteilung und der Enzymkapazität. Durch eine perkutane Biopsie des M. vastus lateralis wurden 10 Patienten mit T2DM und 15 Gesunden Probanden Muskelgewebe extrahiert. In der anschließenden Zytophotometrie erfolgte die Bestimmung der glykolytischen und oxidativen Enzymaktivität in Abhängigkeit der Fasercharakteristik nach SO, FOG und FT-Fasern. Die Untersuchung verdeutlichte eine Verminderung der oxidativen Enzymaktivität des M. vastus lateralis im Homogenat bei bestehenden T2DM mit gleichzeitiger Verringerung der SO- Muskelfasern um 16 Prozent und Erhöhung der FT- Muskelfasern um 49 Prozent im Vergleich zur Kontrollpopulation. Bei T2DM ist sowohl die oxidative als auch die glykolytische Enzymaktivität in den FG-Fasern als auch in den FOGMischfasern signifikant erhöht. Zusammenfassend weisen unsere Ergebnisse darauf hin, dass die geringere oxidative Enzymaktivität im Homogenat des Skelettmuskel von Patienten mit T2DM vielmehr durch einen verminderten Anteil von SO-Fasern als durch verminderte oxidative Aktivität in einzelnen Fasern verursacht ist. Die erhöhte glykolytische und oxidative Enzymaktivität in einzelnen Muskelfasern korreliert mit dem Maß langfristiger BZHomöostase und der Insulinempfindlichkeit. Diese Adaptation der Skelettmuskulatur könnte einen kompensatorischen Mechanismus bezüglich des pathologischen Glukosestoffwechsels des T2DM darstellen. Enzymkapazität Skelettmuskel Typ 2 Diabetes Enzyme activity skeletal muscle Typ 2 Diabetes ddc:610
386	Membrane cholesterol balance in exercise and insulin resistance Habegger, Kirk M. January 2009 (has links) Thesis (Ph.D.)--Indiana University, 2009. / Title from screen (viewed on December 9, 2009). Department of Biochemistry and Molecular Biology, Indiana University-Purdue University Indianapolis (IUPUI). Advisor(s): Jeffrey S. Elmendorf, Peter J. Roach, Joseph T. Brozinick, Michael S. Sturek, Robert V. Considine. Includes vitae. Includes bibliographical references (leaves 97-124).
387	Inorganic phosphate uptake in rat skeletal muscle Abraham, Kirk A., January 2003 (has links) Thesis (Ph. D.)--University of Missouri--Columbia, 2003. / Typescript. Vita. Includes bibliographical references (leaves 63-74). Also available on the Internet.
388	Aging differences in mechanisms of human skeletal muscle hypertrophy Kosek, David J. January 2007 (has links) (PDF) Thesis (Ph.D.)--University of Alabama at Birmingham, 2007. / Title from PDF title page (viewed on Feb. 18, 2010). Includes bibliographical references.
389	Examining the role of the adenosine monophosphate-activated protein kinase α2 (AMPKα2) subunit on sarcoplasmic reticulum calcium-ATPase (SERCA) expression and function in sedentary and exercise-trained mice. Morissette, Marc 03 April 2013 (has links) This thesis determined whether changes in adenosine monophosphate-activated protein kinase (AMPK) activity would influence sarcoplasmic reticulum Ca2+-ATPase (SERCA) content and function in left ventricle (LV) and skeletal muscle isolated from sedentary or exercise trained mice. The data indicate that AMPKα2 kinase dead transgenic (KD) mice, as compared to wild-type (WT) mice, were characterized by reduced SERCA1a, SERCA2a and higher phospholamban (PLN) protein levels in both cardiac and skeletal muscle. Notably, exercise-training up-regulated myocardial SERCA2a protein content by 43%, as compared to sedentary WT mice. In contrast, exercise-training did not alter myocardial SERCA2a protein content in KD mice. Even so, exercise-training up-regulated SERCA1a protein content in skeletal muscle in both WT and KD mice. Based on these data, it appears that an AMPKα2-mediated mechanism influences SERCA2a content and function in the heart and skeletal muscle, which may contribute to the pathophysiology of models characterized by impaired AMPK activity and impaired calcium-cycling. physiology kinesiology AMPK AMPKα2 SERCA SERCA1a SERCA2a exercise exercise-training skeletal muscle cardiac muscle fiber-type
390	Die histomorphometrischen Effekte von Cimicifuga racemosa CR BNO 1055 und ihren Fraktionen auf Haut und Skelettmuskulatur der ovarektomierten Sprague-Dawley-Ratte / The histomorphometric effects of Cimicifuga racemosa CR BNO 1055 and fractions on skin and skeletal muscle of ovariectomized Sprague-Dawley rats Scharf, Manuel 17 June 2015 (has links) No description available. 610 cimicifuga racemosa skin skeletal muscle elastic fibres subcutaneous fat saponine Medizin (PPN619874732)

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