Global ETD Search

191	Cardiogenic differentiation of induced pluripotent stem cells for regeneration of the ischemic heart Buccini, Stephanie M. January 2013 (has links) No description available. Physiological Psychology iPS cells myocardial infarction cardiomyocyte differentiation angiogenesis mesenchymal stem cells cardiac regeneration
192	Development of Osteochondral Tissue Constructs using a Gradient Generating Bioreactor Rivera, Alexander Lee 03 June 2015 (has links) No description available. Biomedical Engineering Tissue Engineering Osteochondral Constructs Bioreactor Mesenchymal Stem Cells Chondrogenesis Osteogenesis Biomolecular Gradients
193	Effects of RhoA/ROCK Signaling Inhibition on Human Mesenchymal Stem Cell-Based Chondrogenic Development Wang, Kuo-Chen 04 June 2018 (has links) No description available. Biomedical Research tissue engineering chondrogenesis mass transport mesenchymal stem cells RhoA, ROCK signaling
194	THE USE OF FUNCTIONAL TISSUE ENGINEERING AND MESENCHYMAL STEM CELL SEEDED CONSTRUCTS FOR PATELLAR TENDON REPAIR JUNCOSA-MELVIN, LAURA NATALIA 27 September 2005 (has links) No description available. Engineering, Biomedical tissue engineering patellar tendon repair mesenchymal stem cells rabbit model collagen scaffolds
195	Osteogenic-Peptide Functionalized Polymeric Materials for Bone Regeneration Applications Policastro, Gina 07 June 2016 (has links) No description available. Polymer Chemistry Polymers Biology Osteogenic Growth Peptide Tissue Engineering Human Mesenchymal Stem Cells MC3T3s Osteogenesis Biomaterials
196	Stem Cell Therapy for Myocardial Infarction: Overcoming the Hypoxic Impediment to Enhance Cell-survival and Engraftment Chacko, Simi M. 08 September 2009 (has links) No description available. Biophysics Myocardial infarction oximetry electron paramagnetic resonance (EPR) cell therapy mesenchymal stem cells preconditioning
197	Isolation and Characterization of Mesenchymal Stem Cells from the Periodontal Ligament of Healthy Teeth Lagerholm, Sara January 2019 (has links) ABSTRAKT:Isolering och karaktärisering av mesenkymala stamceller från periodontalligamentet hos friskatänderSYFTE: Att isolera och odla celler från periodontalligamentet samt karaktärisera dem sommesenkymala stamceller.MATERIAL OCH METOD: Friska premolarer gjordes tillgängliga vid ortodontiskaextraktioner. Den mellersta 1/3 av periodontalligamentet skrapades varpå en enzymatiskmetod användes för isolering av individuella celler. Resulterande celler odlades understandardiserade metoder. Karaktärisering av celler skedde genom flödescymetri med 2 olikapaneler av cellyta markörer; en för etablerat positiva uttryck och en för kända negativauttryck hos mesenkymala stamceller. Möjlighet av celler att differentieras in vitro tilladipocyter och osteocyter testades genom tillförsel av specifika substanser till odlingsmediet.RESULTAT: Celler från 11 av 13 tänder isolerades och odlades framgångsrikt adherenta tillodlingsytan i upp till 8 generationer. Celluttryck av de positiva markörerna CD73, CD90 samtCD44 bekräftades genom flödescymetri. Inget uttryck observerades för den negativa panelenCD45, CD34, CD11b, CD19 eller HLA class II. Uttrycket av CD105 kunde inte fastställas pgaofullständigt data. Försök till differentiering av celler till adipocyter och osteocyter visade påfenotypiska förändringar efter 21 dagar.SLUTSATS: Den här studien har bidragit till framgångsrik isolering och delvis karaktäriseringav mesenkymala stamceller från periodontalligamentet hos friska tänder. En icke-invasivmetod av detta slag, resulterande i tillgång till denna cellpopulation utgör ett lovande verktygför framtida studier med goda möjligheter till ytterligare kunskap applicerbart till kliniskasituationer inom tandvården. / ABSTRACT:Isolation and Characterization of Mesenchymal Stem Cells from the Periodontal Ligament ofHealthy TeethAIM: To isolate and culture viable cells from the periodontal ligament and confirming theiridentity as mesenchymal stem cells.METHODS AND MATERIALS: Healthy premolars were collected at the time oforthodontic extractions. The middle 1/3 of the periodontal ligament was scraped andsubsequent cell isolation was performed using an enzymatic method; yielding single cellisolates. Cells were cultured and maintained under standard culture conditions. Cellcharacterization was performed by flow cytometry using two sets of cell surface markers; oneknown to be present and one known to be absent in mesenchymal stem cells. Ability of thecells for in vitro differentiation into adipogenic and osteogenic lineages was tested usingspecifically formulated media supplements.RESULTS: Cells were successfully isolated from 11 of 13 teeth and were maintained asadherent cultures for up to 8 generations. Cellular expression of positive markers; CD73, CD90and CD44 were confirmed by flow cytometry. For the negative marker panel, expression ofCD45, CD34, CD11b, CD19 and HLA class II were not detectable. The expression of CD105was inconclusive. As determined by phenotypic changes, cells appeared to have undergoneadipogenic and osteocytic differentiation at 21 days.CONCLUSION: This study has resulted in successful isolation and partial characterization ofmesenchymal stem cells from the periodontal ligament of healthy teeth. Non-invasive accessto these cells, provides an excellent tool for future studies, potentially leading to beneficialknowledge transferable to the dental clinical situation. Mesenchymal stem cells Osteogenic differentiation Adipogenic differentiation Extracted teeth Periodontal ligament Medical and Health Sciences Medicin och hälsovetenskap
198	ENCAPSULATION OF FACTOR IX-ENGINEERED MESENCHYMAL STEM CELLS IN ALGINATE-BASED MICROCAPSULES FOR ENHANCED VIABILITY AND FUNCTIONALITY Sayyar, Bahareh 04 1900 (has links) <p>The work presented in this thesis was focused on design and construction of novel cell-loaded microcapsules by incorporation of bioactive molecules (proteins or peptides) for potential application in hemophilia B treatment. The objective of this study was to improve the viability and functionality of the encapsulated cells by creating biomimetic microenvironments for cells that more closely mimic their physiological extracellular matrix (ECM) environment.</p> <p>Three cell-adhesive molecules were used in this work: fibrinogen and fibronectin, two abundant proteins present in ECM, and arginine-glycine-aspartic acid (RGD) tri-peptide, the minimal essential cell adhesion peptide sequence and the most widely studied peptide for cell adhesion. Alginate, the most commonly used biomaterial used for cell encapsulation, was combined with either of these molecules to create biomimetic microcapsules. Non-modified alginate (control) and modified alginate matrices were used to encapsulate the factor IX (FIX) secreting cells for protein delivery. In this work, FIX-engineered cord blood-derived human mesenchymal stem cells CB MSCs were used as a cell source for FIX delivery.</p> <p>Our data suggested that fibrinogen-alginate, fibronectin-alginate and RGD-alginate microcapsules improved the viability of encapsulated MSC and are applicable in cell therapy technologies. However, fibrinogen-alginate and fibronectin-alginate microcapsules more significantly enhanced the proliferation and protein secretion from the encapsulated cells and may have potential for FIX delivery for hemophilia B and other inherited or acquired protein deficiencies. RGD-alginate microcapsules can v potentially be used for other tissue engineering applications with the aim of enhanced viability and attachment of the enclosed cells. Differentiation studies showed the osteogenic (but not chondrogenic or adipogenic) differentiation capability of FIX-engineered CB MSCs and their efficient FIX secretion while encapsulated in fibrinogen-alginate and fibronectin-alginate microcapsules.</p> / Doctor of Philosophy (PhD) cell encapsulation alginate biomimetic microcapsules mesenchymal stem cells hemophilia B Biomaterials Biomaterials
199	Mesenchymal Stem Cells Encapsulated and Aligned in Self-Assembling Peptide Hydrogels Kasani, Yashesh Varun 12 1900 (has links) This study presents a viable strategy using fmoc-protected peptides hydrogels, to encapsulate and stretch mesenchymal stem cells (MSC). To explore the peptide hydrogel potential, a custom mechanical stretching device with polydimethylsiloxane (PDMS) chambers were used to stretch MSCs encapsulated in Fmoc hydrogels. We investigated the impact of fmoc- FF prepared in dimethyl sulfoxide (DMSO), 1,1,1,3,3,3-hexafluoro-2-propanol (HFP) and deionizied water in the self-assembly, and mechanical properties of the gels. The peptide hydrogel is formed through molecular self-assembly of peptide sequence into β-sheets that are connected with the π-π aromatic stacking of F-F groups. The hydrogels provided a stiff, hydrated gel with round nanofiber morphology representing an elastic modulus of 174-266 KPa. MSCs cultured on peptide hydrogels undergo viability, morphology, and alignment evaluations using MTT, live/dead, and phalloidin (F-actin) staining. The F-actins of 3D- cultured MSCs in Fmoc-FF/HFP, and Fmoc-FF/DMSO followed by mechanical stretching showed elongated morphology with defined microfilament fibers compared to the round and spherical F-actin shape of the control cells. Peptide gels with 5mM concentration preserved 100% viability of MSC. Results reveals the feasibility and conditions for successful cell encapsulation and alignment within peptide hydrogels. Encapsulation of MSC in peptide nanofiber followed by a stretching process present a promising tissue engineering platform. By enhancing our understanding of MSC-peptide hydrogel interactions, this research con- tributes to the development of biomaterials tailored for regenerative medicine. Peptide Self-assembly Mesenchymal STEM cells 3D cell culture Hydrogels. Engineering, Biomedical
200	Osteogenic Scaffolds for Enhanced Graft-Bone Integration in Ligament Tissue Engineering Gadalla, Dina Mohamed Adly 22 June 2020 (has links) Among the most common knee ligament injuries are those to the anterior cruciate ligament (ACL). Annually, approximately 350,000 people require surgical ACL reconstruction, accounting for more than $6 billion of health-care costs in the United States alone. An injured ACL loses its functions as it cannot heal with larger injuries and heals slowly with smaller ones. This may introduce complications, such as abnormal joint kinematics and deterioration, prior to complete rupture. Although the use of an autologous graft is the current gold standard for ACL reconstruction surgery, it is associated with donor site morbidity and a decrease in mechanical strength at the donor site. The use of allogenic grafts instead of autografts introduces the risk of disease transmission. Furthermore, integration of soft tissue grafts (e.g., hamstring tendon) to native bone is slow and risks graft pullout. To circumvent these limitations, tissue engineering seeks to fabricate suitable biomaterials that could replace the entire ACL, stimulate regeneration of the ligament tissue, and integrate with host bone tissue. Numerous efforts have led to the development of complex, multi-phased biomaterial scaffold designs that are intended to deliver an array of cell types and biological cues. Particularly, scaffolds that possess bone-regenerating biomaterials at the ends are envisioned to facilitate rapid integration with the femur and tibia. Electrospun fiber scaffolds continue to be regularly utilized for their high tensile strength, flexibility, and ability to bend. Nevertheless, fibrous scaffolds are inert and require the incorporation of trophic factors to guide tissue regeneration. Additionally, electrospun fibers are often densely packed, which can hinder cell infiltration and subsequent tissue formation. The objective of this work was to guide bone remodeling through the incorporation of trophic factors with 1) electrospun fiber scaffolds or 2) nanoparticles that could be combined with electrospun fiber scaffolds, and 3) to develop model three-dimensional fiber-hydrogel composites that support cell viability and proliferation. Two approaches were utilized to present the trophic factor bone morphogenic protein (BMP)-2 to stimulate bone formation. In the first approach, electrospun fibers were modified through the adsorption or covalent conjugation of BMP-2. These fibers exhibited increased BMP-2 concentrations with covalent conjugation over adsorption, and the incorporation of heparin into the fibers improved both adsorption and conjugation. Mesenchymal stem cells (MSCs) – that have the capacity to differentiate into osteoblastic cells – were able to attach and proliferate on all films yet appeared to do so to a greater extent on surfaces with higher heparin contents. Additionally, markers of osteoblastic differentiation were significantly higher on surfaces with covalently conjugated BMP-2 than on those with adsorbed BMP-2. In the second approach, a nanoparticle system was produced to control BMP-2 delivery and release. Importantly, this flexible system can be fabricated separately, and then combined with a scaffold for tissue regeneration. In this approach, BMP-2 was combined with chitosan nanoparticles through adsorption, encapsulation, or covalent conjugation. The particular BMP-2 incorporation technique had no significant effect on BMP-2 incorporation efficiencies, but affected particle size and BMP-2 release kinetics. Specifically, covalent conjugation method caused the aggregation of particles while adsorption method allowed the most sustainable release. MSCs cultured in the presence of the different particles survived and proliferated, but only particles with adsorbed BMP-2 stimulated osteoblastic differentiation. Finally, three-dimensional fiber-hydrogel composites of various models were fabricated to mimic the complexity of full-sized scaffolds for ACL regeneration, and to study cell infiltration, differentiation, and tissue formation. A collagen hydrogel phase was introduced to electrospun fiber scaffolds using different approaches. MSCs seeded within a thin collagen layer were able to proliferate, sense underlying substrate and spread according to fiber orientation, while those within thicker layers were not. Additionally, cells initially present in only the collagen phase infiltrated to the fiber phase. These results demonstrate that minor changes in fabrication steps to combine the two phases could significantly alter cell function during the formation of three-dimensional fiber-hydrogel composites for tissue regeneration. / Doctor of Philosophy / The anterior cruciate ligament (ACL) is one of four ligaments that connect the thigh bone to the shin bone and stabilize the knee. Injuries to the ACL often occur during high impact sports, and ruptures can necessitate surgical intervention. ACL reconstruction surgery involves drilling tunnels through the ends of leg bones, deploying the tissue graft through the knee joint and bone tunnels, and anchoring it within the bone tunnels. The most common grafts are autografts that use tendons of the patient's own body or allografts that are obtained from cadavers. The complications associated with autografts include pain at the site of tissue harvest, while allografts risk disease transmission. Additionally, directly affixing a soft tissue graft (e.g., the hamstring tendon) to bone within the bone tunnel suffers from slow tissue integration and risk of pull-out. Tissue engineering is a field that seeks to develop devices to direct the regeneration of damaged tissues and organs. In the context of ACL repair, it seeks to achieve a biomaterial device with the properties of ACL, that can both guide the regeneration of ligament tissue and facilitate integration with bone tunnels, eliminating the need for autografts and allografts and their associated risks. Toward the development of an engineered ACL, this work focuses on improving graft-to-bone integration. In the first project, fibrous materials are surface-modified with bone morphogenetic protein (BMP)-2 (a bone-forming protein), and then tested for their ability to stimulate formation of a bone-like tissue in cell culture. In the second project, the deployment of BMP-2 either on the surface of or within nanoparticle delivery vehicles is evaluated as an alternative strategy to stimulate bone-like tissue formation. The third project explores the inclusion of a hydrogel phase to facilitate cell infiltration and bone-like tissue formation within fibrous materials. Together these studies provide insights into how the architecture of the engineered tissue and the deployment of bone-forming proteins can be used to enhance ACL regeneration. tissue engineering graft-bone integration osteoblastic differentiation nanoparticles electrospinning mesenchymal stem cells

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