{"@context":"http://iiif.io/api/presentation/2/context.json","@id":"https://repo.library.stonybrook.edu/cantaloupe/iiif/2/manifest.json","@type":"sc:Manifest","label":"The use of biomaterials for cell function enhancement: acceleration of fibroblast migration and promotion of stem cell proliferation","metadata":[{"label":"dc.description.sponsorship","value":"This work is sponsored by the Stony Brook University Graduate School in compliance with the requirements for completion of degree."},{"label":"dc.format","value":"Monograph"},{"label":"dc.format.medium","value":"Electronic Resource"},{"label":"dc.identifier.uri","value":"http://hdl.handle.net/11401/76340"},{"label":"dc.language.iso","value":"en_US"},{"label":"dc.publisher","value":"The Graduate School, Stony Brook University: Stony Brook, NY."},{"label":"dcterms.abstract","value":"Wound healing and tissue regeneration proceed via fibroblast migration along three dimensional scaffolds composed of fibers with different diameters, spacing, and junction angles.  In order to understand how each of these factors influences fibroblast migration, a technique for preparation of three dimensional fibrillar scaffolds was developed where the fiber diameters and the angles between adjacent fiber layers could be precisely controlled. In order to study the en-mass migration process, the agarose droplet method was chosen since it enabled accurate determinations of the dependence of the migration speed, focal adhesion distribution, and nuclear deformation on the fiber structures. Results showed that on oriented single fiber layers, if the fiber diameters exceeded 1\u00b5m, large focal adhesion complexes formed in a linear arrangement along the fiber axis and cell motion was highly correlated.  For fibers 1\u00b5m or less, some cell alignment along the fiber direction was measured, but no correlation between the distribution of focal adhesion points and fiber orientation was found.  On multi layered scaffolds the focal adhesion sites were found to concentrate at the junction points and the migration speed followed a parabolic function with a distinct minimum at 35\u00b0. When compared to fibroblasts plated on 90\u00b0 fibers, fibroblasts plated on 30\u00b0 fibers showed a decrease of 25% in the degree of nuclear deformation and an increase of 25% in the number of focal adhesion sites, indicating that cell migration speed was correlated to the angle and distance of approach to the junction point.  The time dependence of the migration velocity on oriented fibers was measured for four days and compared to the value measured on flat surfaces. After the initial 24 hour incubation period, the cells on both the 8\u00b5m fibers and flat surfaces migrated with a similar speed. During the next three days the migration speed for the cells on the fibrillar surfaces doubled in magnitude, while remained constant for the cells on the flat surfaces. The increased speed on the 8\u00b5m fiber surfaces could be correlated with a 20% increase in the nuclear deformation, and a decrease around 30% in the number of focal adhesion during the same observation period. RNA expression of Myosin IIA, a protein which complexes to the actin and is responsible for exertion of traction forces during migration was not upregulated during this process. On the other hand, histochemical staining of Myosin IIA showed that the protein had re-organized into large fibers which spanned the length of the cells. Observation of the cell morphology indicated that a new mode of motion had been established. Rather than the classical retraction of the cytoplasm followed by center of mass translation, which was observed on the flat surfaces, the cells were now moving by a contractile motion around the nucleus similar to that found in muscular motion. This mode was found to be more efficient when undergoing oriented motion.  In addition to orientation, surface mechanics are also important in the tissue regeneration process. This study demonstrated that mechanical factors are important for the maintenance of pluripotency and control of proliferation rates. CD34+ hematopoietic stem cells (HSCs) were transduced with ICD (intracellular domain)-Notch and plated on gelatin hydrogels, whose moduli were controlled by the crosslinking ratio. On the softer hydrogel,  a synergy was achieved which resulted in more than a five-fold increase in proliferation and a four-fold increase in the preservation of stemness, while HSCs maintained their ability to differentiate into multiple blood cell lineages. These results point the way for achieving clinically significant expansion of human HSCs."},{"label":"dcterms.available","value":"2017-09-20T16:50:03Z"},{"label":"dcterms.contributor","value":"Rafailovich, Miriam H"},{"label":"dcterms.creator","value":"Qin, Sisi"},{"label":"dcterms.dateAccepted","value":"2017-09-20T16:50:03Z"},{"label":"dcterms.dateSubmitted","value":"2017-09-20T16:50:03Z"},{"label":"dcterms.description","value":"Department of Materials Science and Engineering."},{"label":"dcterms.extent","value":"121 pg."},{"label":"dcterms.format","value":"Monograph"},{"label":"dcterms.identifier","value":"http://hdl.handle.net/11401/76340"},{"label":"dcterms.issued","value":"2014-12-01"},{"label":"dcterms.language","value":"en_US"},{"label":"dcterms.provenance","value":"Made available in DSpace on 2017-09-20T16:50:03Z (GMT). No. of bitstreams: 1\nQin_grad.sunysb_0771E_12185.pdf: 3122689 bytes, checksum: 950e8094ba213997254393653a9da4ad (MD5)\n  Previous issue date:    1"},{"label":"dcterms.publisher","value":"The Graduate School, Stony Brook University: Stony Brook, NY."},{"label":"dcterms.subject","value":"Cell differentiation, Cell migration, Electrospinning, Fibroblast, Hematopoietic Stem Cell, Oriented fiber"},{"label":"dcterms.title","value":"The use of biomaterials for cell function enhancement: acceleration of fibroblast migration and promotion of stem cell proliferation"},{"label":"dcterms.type","value":"Dissertation"},{"label":"dc.type","value":"Dissertation"}],"description":"This manifest was generated dynamically","viewingDirection":"left-to-right","sequences":[{"@type":"sc:Sequence","canvases":[{"@id":"https://repo.library.stonybrook.edu/cantaloupe/iiif/2/canvas/page-1.json","@type":"sc:Canvas","label":"Page 1","height":1650,"width":1275,"images":[{"@type":"oa:Annotation","motivation":"sc:painting","resource":{"@id":"https://repo.library.stonybrook.edu/cantaloupe/iiif/2/12%2F49%2F09%2F124909041285499560763214573182462648357/full/full/0/default.jpg","@type":"dctypes:Image","format":"image/jpeg","height":1650,"width":1275,"service":{"@context":"http://iiif.io/api/image/2/context.json","@id":"https://repo.library.stonybrook.edu/cantaloupe/iiif/2/12%2F49%2F09%2F124909041285499560763214573182462648357","profile":"http://iiif.io/api/image/2/level2.json"}},"on":"https://repo.library.stonybrook.edu/cantaloupe/iiif/2/canvas/page-1.json"}]}]}]}