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The beneficial Effects of Neural Crest Stem Cells on Pancreatic β–cellsNgamjariyawat, Anongnad January 2014 (has links)
Patients with type-1 diabetes lose their β-cells after autoimmune attack. Islet transplantation is a co-option for curing this disease, but survival of transplanted islets is poor. Thus, methods to enhance β-cell viability and function as well as methods to expand β-cell mass are required. The work presented in this thesis aimed to study the roles of neural crest stem cells or their derivatives in supporting β-cell proliferation, function, and survival. In co-culture when mouse boundary cap neural crest stem cells (bNCSCs) and pancreatic islets were in direct contact, differentiating bNCSCs strongly induced β-cell proliferation, and these proliferating β-cells were glucose responsive in terms of insulin secretion. Moreover, co-culture of murine bNCSCs with β-cell lines RIN5AH and β-TC6 showed partial protection of β-cells against cytokine-induced β-cell death. Direct contacts between bNCSCs and β-cells increased β-cell viability, and led to cadherin and β-catenin accumulations at the bNCSC/β-cell junctions. We proposed that cadherin junctions supported signals which promoted β-cell survival. We further revealed that murine neural crest stem cells harvested from hair follicles were unable to induce β-cell proliferation, and did not form cadherin junctions when cultured with pancreatic islets. Finally, we discovered that the presence of bNCSCs in co-culture counteracted cytokine-mediated insulin-producing human EndoC-βH1 cell death. Furthermore, these two cell types formed N-cadherin, but not E-cadherin, junctions when they were in direct contact. In conclusion, the results of these studies illustrate how neural crest stem cells influence β-cell proliferation, function, and survival which may improve islet transplantation outcome.
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Neuroprotection in the Injured Spinal Cord : Novel Strategies using Immunomodulation, Stem cell Transplantation and Hyaluronic acid Hydrogel carriersSchizas, Nikos January 2015 (has links)
The overall aim of this thesis was to establish strategies to minimize secondary damage to the injured spinal cord. Secondary damage that follows spinal cord injury (SCI) involves inflammatory and excitotoxic pathways. Regulation of these pathways using immunomodulatory and neuroprotective substances potentially protects the injured spinal cord from further damage. We also developed and studied resorbable biomaterials to be used as carriers for potential neuroprotectants to the injured spinal cord. We used transversal spinal cord slice cultures (SCSCs) derived from postnatal mice as a model. SCSCs were maintained on different biomaterials and were studied after treatment with immunomodulatory and/or neurotrophic factors. They were further excitotoxically injured and subsequently treated with interleukin-1 receptor antagonist (IL1RA) or by neural crest stem cell (NCSC)-transplantation. The results show that biocompatible and resorbable hydrogels based on hyaluronic acid (HA) preserved neurons in SCSCs to a much higher extent than a conventional collagen-based biomaterial or standard polyethylene terephthalate (PET) membrane inserts. Glial activation was limited in the cultures maintained on HA-based hydrogel. The anti-inflammatory factor IL1RA protected SCSCs from degenerative mechanisms that occur during in vitro incubation, and IL1RA also protected SCSCs from excitotoxic injury induced by N-Methyl-d-Aspartate (NMDA). IL1RA specifically protected neurons that resided in the ventral horn, while other neuronal populations such as dorsal horn neurons and Renshaw cells did not respond to treatment. Finally, transplantation of NCSCs onto excitotoxically injured SCSCs protected from neuronal loss, apoptosis and glial activation, while NCSCs remained undifferentiated. The results presented in this thesis indicate that carriers based on HA seem to be more suitable than conventional collagen-based biomaterials since they enhance neuronal survival per se. The observed neuroprotection is likely due to biomechanical properties of HA. IL1RA protects SCSCs from spontaneous degeneration and from NMDA-induced injury, suggesting that excitotoxic mechanisms can be modulated through anti-inflammatory pathways. Different neuronal populations are affected by IL1RA to various degrees, suggesting that a combination of different neuroprotectants should be used in treatment strategies after SCI. Finally, NCSCs seem to protect SCSCs from excitotoxic injury through paracrine actions, since they remain undifferentiated and do not migrate into the tissue during in vitro incubation. It seems that combinations of neuroprotectants and carrier substances should be considered rather than one single strategy when designing future treatments for SCI. Incorporation of neuroprotectants such as IL1RA combined with stem cells in injectable biocompatible carriers based on HA is the final goal of our group in the treatment of SCI.
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Auxiliary Cells for the Vascularization and Function of Endogenous and Transplanted Islets of LangerhansGrapensparr, Liza January 2017 (has links)
Type 1 diabetes develops through the progressive destruction of the insulin-producing beta-cells. Regeneration or replacement of beta-cells is therefore needed to restore normal glucose homeostasis. Presently, normoglycemia can be achieved by the transplantation of whole pancreas or isolated islets of Langerhans. Islet transplantation can be performed through a simple laparoscopic procedure, but the long-term graft survival is low due to poor revascularization and early cell death. This thesis examined the possibility of using different auxiliary cells (Schwann cells, endothelial progenitor cells, and neural crest stem cells) to improve the engraftment and function of endogenous and transplanted islets. Co-transplantation of Schwann cells with islets improved islet graft function early after transplantation, and caused an increased islet mass at one month posttransplantation. However, the vascular densities of these grafts were decreased, which also related to an impaired graft function. Islet grafts containing endothelial progenitor cells had a superior vascular density, with functional chimeric blood vessels and substantially higher blood perfusion and oxygen tension than control transplants. By culturing and transplanting islets together with neural crest stem cells it was found that islets exposed to these cells had a higher beta-cell proliferation compared with control islets. At one month posttransplantation, the grafts with neural crest stem cells also had a superior vascular- and neural density. The potential of intracardially injected neural crest stem cells to home to the pancreas and ameliorate hyperglycemia in diabetic mice was investigated. During a three-week period after such cell treatment blood glucose concentrations decreased, but were not fully normalized. Neural crest stem cells were present in more than 10% of the pancreatic islets at two days postinjection, at which time the beta-cell proliferation was markedly increased when compared with islets of saline-treated diabetic animals. Three weeks later, a doubled beta-cell mass was observed in animals receiving neural crest stem cells. In summary, islets can easily be transplanted together with different auxiliary cells. Some of these cells provide the possibility of improving vascular- and neural engraftment, as well as beta-cell growth and survival. Systemic administration of neural crest stem cells holds the potential of regenerating the endogenous beta-cells.
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Preparation of Pancreatic EndoCβH1 cells alone and together with Boundary Cap Neural Crest Stem cells for a microgravity experimentRANGASWAMY, SRINIVASAPRASAD January 2022 (has links)
Migrating to Mars is the next exploration of human space missions and adapting to the extreme environment for a long period of time needs to be studied in-prior. Studies on cells in space may promote advancements in our understanding of the human body. The aim of this study is to optimize the protocol for the preparation of EndoCβH1 cells alone in the space chamber and co-culturing EndoCβH1 cells and BCs for microgravity experiments. We analyzed the cell survival and biocompatibility of β- cells with different parameters and the best concentration was used for the co-culture test. A 1:1 ratio of β-cells and BCs were cultured in the space chamber for viability and survival test. Co-culture experiment showed a significant increase in β-cell viability in the space chamber relative to in vitro tests. The effects of mitochondrial health of the cell inside the chamber was evaluated using the mitochondrial membrane test using the fluorescent probe 5,5,6,6’- tetrachloro-1,1’,3,3’ tetraethylbenzimi-dazoylcarbocyanine iodide (JC-1). We determined that the β-cell fitness inside the chamber was two times higher than the 24-well plate. To assess the viability of β-cells in a bioprinted gelatin scaffold we used the Live-dead fluorescence microscopy assay. Scaffolds were stained with Calcein AM (CAM) and propidium iodide (PI) and checked for survival. The result of scaffold staining showed that β- cells in gelatin and BCs in the media had more living cells compared to β-cells without BCs. Thus, space flight (SF) exposure to this culture system can be a platform for further studies in the treatment of diabetes.
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