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Stem Cells of the Neural and Pancreatic LineagesSmukler, Simon 03 March 2010 (has links)
In this thesis, I describe studies identifying and characterizing two putative stem cell populations of the neural and pancreatic lineages. The mechanisms governing the emergence of the earliest mammalian neural cells during development and the ontogeny of neural stem cells remain incompletely characterized. A default mechanism has been suggested to underlie neural fate acquisition, however an instructive process has also been proposed. I utilized mouse ES cells to explore the fundamental issue of how an uncommitted, pluripotent mammalian cell will self-organize in the absence of extrinsic signals, and what cellular fate will result. Individual ES cells were found to rapidly transition directly into neural cells by a default mechanism, a process shown to be independent of suggested instructive factors. Further, I provide evidence that the default neural identity is that of a primitive neural stem cell, the earliest identified stem cell of the neural lineage. The exiguous conditions used to reveal the default state were found to present primitive neural stem cells with a survival challenge, which could be mitigated by survival factors or genetic interference with apoptosis. I also report the clonal identification of multipotent precursor cells, PMPs, from the adult mouse and human pancreas. These cells proliferate in vitro to form clonal colonies and display both pancreatic and neural cell multipotentiality. Importantly, the newly generated beta cells demonstrate glucose-dependent calcium responsiveness and regulated insulin release. PMP colonies do not express markers of embryonic stem cells, nor genes suggestive of mesodermal or neural crest origins. Moreover, genetic lineage-labeling experiments excluded the neural crest, and established the embryonic pancreatic lineage, as the developmental source of PMPs. The PMP cell was further found to express insulin in vivo, and insulin+ stem cells were shown to contribute to multiple pancreatic and neural cell populations in vivo. These findings demonstrate that the adult mammalian pancreas contains a population of insulin+ multipotent stem cells, capable of contributing to the pancreatic and neural lineages. In the final section of this thesis, I consider the relationships between neural and pancreatic tissues, as well as discussing the relevance of these two novel stem cell populations.
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Stem Cells of the Neural and Pancreatic LineagesSmukler, Simon 03 March 2010 (has links)
In this thesis, I describe studies identifying and characterizing two putative stem cell populations of the neural and pancreatic lineages. The mechanisms governing the emergence of the earliest mammalian neural cells during development and the ontogeny of neural stem cells remain incompletely characterized. A default mechanism has been suggested to underlie neural fate acquisition, however an instructive process has also been proposed. I utilized mouse ES cells to explore the fundamental issue of how an uncommitted, pluripotent mammalian cell will self-organize in the absence of extrinsic signals, and what cellular fate will result. Individual ES cells were found to rapidly transition directly into neural cells by a default mechanism, a process shown to be independent of suggested instructive factors. Further, I provide evidence that the default neural identity is that of a primitive neural stem cell, the earliest identified stem cell of the neural lineage. The exiguous conditions used to reveal the default state were found to present primitive neural stem cells with a survival challenge, which could be mitigated by survival factors or genetic interference with apoptosis. I also report the clonal identification of multipotent precursor cells, PMPs, from the adult mouse and human pancreas. These cells proliferate in vitro to form clonal colonies and display both pancreatic and neural cell multipotentiality. Importantly, the newly generated beta cells demonstrate glucose-dependent calcium responsiveness and regulated insulin release. PMP colonies do not express markers of embryonic stem cells, nor genes suggestive of mesodermal or neural crest origins. Moreover, genetic lineage-labeling experiments excluded the neural crest, and established the embryonic pancreatic lineage, as the developmental source of PMPs. The PMP cell was further found to express insulin in vivo, and insulin+ stem cells were shown to contribute to multiple pancreatic and neural cell populations in vivo. These findings demonstrate that the adult mammalian pancreas contains a population of insulin+ multipotent stem cells, capable of contributing to the pancreatic and neural lineages. In the final section of this thesis, I consider the relationships between neural and pancreatic tissues, as well as discussing the relevance of these two novel stem cell populations.
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Glassy dynamics of polymethylphenylsiloxane in one- and two-dimensional nanometric confinementKipnusu, Wykliffe Kiprop, Elsayed, Mohamed, Krause-Rehberg, Reinhard, Kremer, Friedrich 22 May 2018 (has links)
Glassy dynamics of polymethylphenylsiloxane (PMPS) is studied by broadband dielectric spectroscopy in one-dimensional (1D) and two-dimensional (2D) nanometric confinement; the former is realized in thin polymer layers having thicknesses down to 5 nm, and the latter in unidirectional (thickness 50 µm) nanopores with diameters varying between 4 and 8 nm. Based on the dielectric measurements carried out in a broad spectral range at widely varying temperatures, glassy dynamics is analyzed in detail in 1D and in 2D confinements with the following results: (i) the segmental dynamics (dynamic glass transition) of PMPS in 1D confinement down to thicknesses of 5 nm is identical to the bulk in the mean relaxation rate and the width of the relaxation time distribution function; (ii) additionally a well separated surface induced relaxation is observed, being assigned to adsorption and desorption processes of polymer segments with the solid interface; (iii) in 2D confinement with native inner pore walls, the segmental dynamics shows a confinement effect, i.e., the smaller the pores are, the faster the segmental dynamics; on silanization, this dependence on the pore diameter vanishes, but the mean relaxation rate is still faster than in 1D confinement; (iv) in a 2D confinement, a pronounced surface induced relaxation process is found, the strength of which increases with the decreasing pore diameter; it can be fully removed by silanization of the inner pore walls; (v) the surface induced relaxation depends on its spectral position only negligibly on the pore diameter; (vi) comparing 1D and 2D confinements, the segmental dynamics in the latter is by about two orders of magnitude faster. All these findings can be comprehended by considering the density of the polymer; in 1D it is assumed to be the same as in the bulk, hence the dynamic glass transition is not altered; in 2D it is reduced due to a frustration of packaging resulting in a higher free volume, as proven by ortho-positronium annihilation lifetime spectroscopy.
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surface and depth-profiled chemical analysis of insulators after high temperature and/or high pressure treatmentsLu, Hsin-Hsien 19 July 2001 (has links)
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