The mature central nervous system has a very limited capacity for self-renewal and repair following injury. Neural stem cells (NSCs), however, provide a promising new therapeutic option and can be readily expanded in vitro . Towards the development of an effective therapy, greater understanding and control is needed over the mechanisms regulating the differentiation of these cells into function-restoring neurons. In vivo, the neural stem cell niche plays a critical role in directing stem cell self-renewal and differentiation. By understanding and harnessing the power of this niche, a tissue engineered system with encapsulated neural stem cells could be designed to encourage neuronal differentiation and ultimately regeneration of damaged neural tissue. Poly(ethylene glycol)-based hydrogels were used here as a platform for isolating and investigating the response of neural stem cells to various matrix, soluble, and cellular components of the niche. When covalently modified with a cyclic RGD peptide, the synthetic scaffold was demonstrated to support attachment and proliferation of a human NSC line under conditions permissive to cell growth. Under differentiating conditions, the scaffold maintained appropriate lineage potential of the cells by permitting the development of both neuronal and glial populations. Expansion and differentiation of NSCs was also observed in a more biomimetic, three dimensional environment following encapsulation within a degradable hydrogel material. To simulate the soluble signals in the niche, fibroblast growth factor and nerve growth factor were tethered to the hydrogel and shown to direct NSC proliferation and neuronal differentiation respectively. Finally, as an example of the cell-cell interactions in the niche, the pro-angiogenic capacity of encapsulated neural stem cells was evaluated both in vitro and in vivo. Ideally, the optimal scaffold design will be applied to guide NSCs in a therapeutic application. Toward this goal, a novel method was developed for encapsulation of the cells within injectable hydrogel microspheres. This technique was optimized for high cell viability and microsphere yield and was demonstrated with successful microencapsulation and delivery of neural stem cells in rodent model of ischemic stroke.
Identifer | oai:union.ndltd.org:RICE/oai:scholarship.rice.edu:1911/70242 |
Date | January 2012 |
Contributors | West, Jennifer L. |
Source Sets | Rice University |
Language | English |
Detected Language | English |
Type | Thesis, Text |
Format | 167 p., application/pdf |
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