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Investigating the Role of Estrogens on the Molecular Mechanisms Modulating Pancreatic Beta Cell Health and Cardiometabolic DiseaseDe Paoli, Monica January 2022 (has links)
Sex-dependent differences in the prevalence of diabetes and cardiovascular diseases are well established. The objective of this project is to investigate the molecular mechanisms by which estrogen modulates chronic disease progression. Our lab, and others, have previously implicated endoplasmic reticulum (ER) stress in the development and progression of diabetes and cardiometabolic disease. We hypothesize that estrogens protect pancreatic beta cell health, and slow the progression of cardiometabolic disease, by modulating the unfolded protein response (UPR) in response to ER stress. Two distinct mouse models were used in these studies. The ApoE-/-Ins2+/Akita mouse model of hyperglycemia-induced atherosclerosis, in which females are significantly protected from hyperglycemia and atherosclerosis relative to males, and the TALLYHO/JngJ mouse model, in which females are protected from chronic hyperglycemia relative to males. We found that ovariectomy of female ApoE-/-Ins2+/Akita or TALLYHO/JngJ mice promoted chronic hyperglycemia. Supplementation with exogenous 17-beta estradiol significantly lowered blood glucose levels in ovariectomized ApoE-/-Ins2+/Akita mice and reduced atherosclerotic lesion development in both male and ovariectomized female mice. Pancreatic islets from sham operated ApoE-/-Ins2+/Akita female mice showed a significant increase in the expression of protective UPR factors and a decrease in pro-apoptotic factors, compared to males or ovariectomized females. To determine if alleviating ER stress could moderate hyperglycemia, male and ovariectomized female TALLYHO/JngJ mice were treated with the chemical chaperone 4-phenylbutryic acid (4-PBA). We showed that 4-PBA treatment significantly lowered fasting blood glucose levels and improved glucose tolerance. The results of this thesis suggest that estrogens play a protective role in the maintenance of beta cell health and blood glucose regulation by activating the adaptive UPR. This mechanism may explain the protection observed in premenopausal women and may lead to the development of targeted therapies to treat diabetes and cardiometabolic diseases. / Thesis / Doctor of Philosophy (PhD) / People who suffer from diabetes mellitus have a higher risk of developing heart attack and stroke compared to those who do not have diabetes. Moreover, the risk of heart attack and stroke is higher in men than in women. We still do not understand the underlying reasons for these differences. This thesis project has used unique mouse models that display many of the same sex differences in disease progression that we see in humans to study the pathways and mechanisms that promote diabetes development. Specifically, we examined the protective effects of estrogen towards the development of diabetes and cardiovascular disease and how this hormone affected specific cells and tissues. The results of these studies are important because they will provide more information regarding the effects of menopause and aging on chronic disease progression in women.
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Glycolytic Metabolism and Pregnancy Parameters in the Murine PlacentaAlbers, Renee Elizabeth January 2017 (has links)
No description available.
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MRI-TRACKABLE MURINE MODEL OF CEREBRAL RADIATION NECROSISAndrew J. Boria (8703303) 17 April 2020 (has links)
<p>Cerebral radiation necrosis as a
consequence of radiation therapy is often observed in patients several months
to years after treatment. Complications include painful headaches, seizures,
and in the worst-case death. Radiation necrosis is an irreversible condition
with the options available to manage it all having noticeable downsides. As
such, there is a critical need for better ways of either preventing the onset
of necrosis and/or managing its symptoms. As radiation necrosis cannot be
induced in humans for ethical reasons, a mouse model that mirrors the features
of radiation necrosis observed in patients would allow for new techniques to be
tested before being used in human clinical trials. This thesis will explain how
our lab designed a murine model of cerebral radiation necrosis that uses a
320 keV cabinet irradiator to produce radiation necrosis and MRI and histology
to evaluate the development of radiation necrosis at multiple time points.</p><p><br></p>
<p> </p>
<p>Our model required the development
of a mouse positioning apparatus that could be used in the cabinet irradiator
used as well as the machining of lead shields so that focal semi-hemispheric
irradiations could be conducted with other critical structures spared. The MRI
scans used as well as the algorithm used to draw radiation necrosis lesions
were based off what has been used in previous Gamma Knife models of radiation
necrosis. Our initial work showed that since the cabinet irradiator has a
relatively flat dose distribution unlike the Gamma Knife, the radiation lesion
volumes produced in the former either plateaued or decreased, unlike in the
case of the latter where lesion volumes tended to decrease over time. Further
work analyzed the effects of fractionation and found minimal sparing using four
different fractionation schemes. The effects of strain and sex on the
development of radiation necrosis were also analyzed, with strain being found
to be a statistically significant parameter while sex was not. Future research
should focus on testing the effects of new drugs and techniques for better
dealing with radiation necrosis.<b></b></p>
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