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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Protein kinase C activity, metabolic, and hemodynamic changes in cerebral ischemia in the adult rat

Crumrine, Ralph Christian January 1990 (has links)
No description available.
2

Compartmentation of the β-adrenergic signal by phosphodiesterases in adult rat ventricular myocytes

Schwartz, Jesse Milo 18 January 2008 (has links)
Previous studies have suggested that phosphodiesterase (PDE) hydrolysis of cyclic adenosine monophosphate (cAMP) is important in the generation of specific and segregated cAMP signals within cells. The purpose of this study was to determine if PDE compartmentation was important in cardiac ventricular myocytes. Therefore, we investigated the effects of β-adrenergic (β-AD) stimulation with isoproterenol in the presence of cilostamide, a PDE3 inhibitor, or Ro 20-1724, a PDE4 inhibitor, on unloaded cell shortening, L-type calcium currents and intracellular calcium levels in freshly dissociated adult rat ventricular myocytes. PDE3 inhibition resulted in a 216 ± 17 % (n=8) increase in unloaded cell shortening after ten minutes of isoproterenol exposure, whereas isoproterenol produced a statistically smaller increase of 155 ± 12 % (n=8) in the presence of PDE4 inhibition. There was a non-significant trend for PDE4 inhibition to produce larger increases in calcium currents (179 ± 17 % (n=4) of controls) than PDE3 inhibition (155 ± 10 % (n=6) of controls). Both PDE3 and PDE4 inhibitors had similar effects on isoproterenol-stimulated increases of calcium transient amplitude with values of 209 ± 14 % (n=8) and 185 ± 12 % (n=8), respectively. Determination of sarcoplasmic reticulum (SR) calcium load using caffeine pulse experiments demonstrated that PDE4 inhibition and isoproterenol superfusion produced a statistically larger increase in SR-calcium loading (139 ± 9 % (n=6)) than PDE3 inhibition and isoproterenol superfusion (113 ± 9 % (n=6)). These results suggest that PDE3 may be active in proximity to the contractile apparatus of cardiac myocytes, whereas PDE4 may be localized in a domain consisting of the L-type calcium channel and junctional SR. Consequently, our study provides functional evidence for differential localization of PDE isoforms in cardiac myocytes. / Thesis (Master, Physiology) -- Queen's University, 2008-01-18 10:14:29.671 / CIHR OGS OGSST
3

Skeletal Response to Simulated Microgravity Exposures and Exercise in the Adult Rat Model

Shirazi-Fard, Yasaman 02 October 2013 (has links)
Mechanical unloading has deleterious effects on the musculoskeletal system and results in significant reductions in bone density, mass, and strength, which do not fully recover even years after returning to weightbearing. For example, the rate of bone loss in microgravity is 10-fold more rapid than the rate of loss seen in elderly Caucasian females, the population group most predisposed to osteoporosis. This raises concern with individuals who are exposed to multiple bed rest periods or crewmembers who make repeated missions. Exercise offers a way to reduce or reverse these effects. Dual-energy X-ray absorptiometry (DXA) densitometry and bone mineral density (BMD) alone are generally insufficient for capturing the complex changes in bone mass, structure, and integrity and not an accurate predictor of fracture risk. Therefore, it is essential to measure the mechanical properties of bone tissue directly using animal models. The hindlimb unloaded (HU) rat model is a well-established ground-based analog for studying bone response to disuse and effects of spaceflight. The current study is one of the very few that has measured longitudinally densitometric and mechanical properties of bone after repeated simulated microgravity and long-term recovery at multiple anatomic sites in skeletally mature rats. The specific aims were to characterize 1) loss and recovery dynamics of bone following a period of unloading, 2) bone response after a second exposure to 28 days of HU, following an initial 28 days of HU and a recovery period equal to twice the duration of initial exposure, and 3) effects of resistance exercise during recovery period following an initial HU exposure and its effects on a subsequent exposure. In general, our data showed that bone response to unloading and recovery is site-specific. More specifically, we found that: 1) the rat proximal tibia metaphysis modeled the loss and discordant recovery dynamics as seen in the International Space Station (ISS) crewmembers proximal femur better than the rat femoral neck; 2) the initial exposure to HU has minimal effect on the subsequent HU exposure, and detrimental effects of the second HU exposure were milder than the initial due to reduced mechanosensitivity of the bone; 3) exercise significantly enhanced recovery following the initial HU exposure, and losses during the second exposure were not affected by exercise in most cases.
4

The role of vascular endothelial growth factor in heart failure with preserved ejection fraction

Glazyrine, Vassili 08 April 2016 (has links)
To this day heart failure with preserved ejection fraction (HFpEF) remains a poorly understood malady. Half of all heart failure (HF) cases are HFpEF, and the prevalence of HF is on the rise. Unlike HF with reduced ejection fraction, HFpEF has no treatment options and is often times difficult to diagnose because victims of HFpEF often have pre-existing conditions. Vascular endothelial growth factor (VEGF) has been implicated in maintaining myocardial health and is thought to play a role in HFpEF. We sought to test the hypothesis that VEGF-A plays a role in HFpEF in a hypertensive murine model of HFpEF. Using Western blot analysis we found that there was an up regulation of VEGF-A in the homogenized left ventricle (LV) of our HFpEF mice. Unexpectedly, there was a down regulation of VEGF-A in the homogenized tissue from the aorta in those mice. To study the circulating levels of VEGF in our HFpEF mice we used an ELISA. We found that our HFpEF mice had similar levels of circulating VEGF as our control. This suggests that VEGF has paracrine/autocrine role in our HFpEF model rather than endocrine, like our human data suggested. To identify the cells responsible for the expression profile we saw in the homogenized tissue data we looked at the response of adult rat ventricular myocytes (ARVM) and vascular smooth muscle cells (VSMC) to aldosterone stimulation at short (1hr) and long (24hr) time points at both physiological (50nm) and pathological (1μm) concentrations. To do this analysis we recruited the help of Western blot, ELISA and RT-PCR techniques to construct a consistent VEGF expression profile. The Western blot ARVM data showed statistically significant (P<0.05) increase in VEGF-A to pathological doses of aldosterone, especially at the longer time point. When we tested the VSMC using Western blot analysis, we found that the trend of our n=1 sample suggested a strong response to the physiological dose of aldosterone in the short term. Using the more sensitive ELISA technique to measure the VEGF content of our VCMS we increasing our sample size to n=4 and found no statistically significant (p=NS) response to aldosterone stimulation from the VSMC. However, looking at the trends in the data it is clear that VSMC increases VEGF in response to long-term physiological doses of aldosterone. This is contrary to what we found using Western blot analysis, so we queried the VEGF mRNA from the VSMC to settle the score. Unfortunately, this too proved fruitless. The RT-PCR data was not significant and the trend was that of the ARVM expression profile. We initially turned to VSMC because we hypothesized that they could contribute to the paracrine/autocrine activity similar to what we saw in the LV from the ARVM. It is unclear if VSMC play a role in HFpEF progression, but their lack of consistent response to aldosterone could potential explain the down regulation of VEGF-A we observed in the aorta of our HFpEF mice. We initially sough to test the hypothesis that VEGF-A plays a role in our HFpEF mouse model, what we found was that ARVM contribute to localized VEGF-A increased production in the LV while in the aorta there is a down regulation of VEGF-A in our HFpEF model, we are unable to make any conclusion about VSMC response to aldosterone because of insufficient sample size. Thus in conclusion, it appears that VEGF-A does play a role in our HFpEF model specifically in a paracrine/autocrine manner in the LV where the ARVM contributes to the increased production of the cytokine.
5

Epigenetic effects of adolescent nicotine exposure on rat serial pattern learning

Renaud, Samantha Marie 18 July 2013 (has links)
No description available.
6

Assessment of Cognitive Deficits and Sex Differences in Adult Rats after Adolescent Methylphenidate Exposure

Thalluri, Rajaa 12 May 2016 (has links)
No description available.
7

Identifying appropriate attachment factors for isolated adult rat cardiomyocyte culture and experimentation

Lumkwana, Dumisile 04 1900 (has links)
Thesis (MScMedSc)--Stellenbosch University, 2014. / ENGLISH ABSTRACT: Introduction: Primary culture of isolated adult rat cardiomyocytes (ARCMs) is an important model for cardiovascular research, but successful maintenance of these cells in culture for their use in experiments remains challenging (Xu et al, 2009; Louch et al, 2011). Most studies are done on acutely isolated cardiomyocytes immediately after isolation, which is due to low survival of these cells in culture. Obstacles in culture are due to the type of medium and attachment factors (tissue culture adhesives) used to culture and grow these cells. Although we previously identified an optimum medium and adhesive for culture, an adhesive that permits cells to remain attached to the culture surface until after an ischemia/reperfusion insult was elusive. Aims: We therefore aimed to identify the best attachment factor and concentration that will allow adult rat cardiomyocytes to remain attached to the culture surfaces after ischemia/reperfusion experiments. Methods: Cardiomyocytes were isolated from adult Wistar rat hearts and cultured overnight on different concentrations (25 -200 μg/ml) of collagen 1, collagen 4, extracellular matrix (ECM), laminin/entactin (L/E) and laminin. Following overnight cultures, experiments were done in PBS and in PBS versus MMXCB to compare ARCM attachment and viability. Cardiomyocytes cultured on ECM, L/E and L (25−200μg/ml) were subjected to 1 hour of simulated ischemia using MMXCB that contained 3mM SDT and 10mM 2DG, followed by 15 minutes reperfusion. Cell viability was determined by staining cells with JC-1 and images of cells in a field view of 1.17μm/mm2 were captured using fluorescence microscopy. The cells were analysed according to morphology and fluorescence intensity. Results: Total and rod-shaped ARCMs attachment was improved when MMXCB was used as an experimental buffer instead of PBS. Regardless of the buffer used, morphological viability was poor on substrates of Col 1 and Col 4. In contrast to collagens, ARCMs attached efficiently and morphological viability was high on substrates of ECM, L/E and L in MMXCB, but this was greatly reduced in PBS. Mitochondrial viability was high in MMXCB compared to PBS on Col 1 and Col 4 at 75−175μg/ml and on ECM, L/E and L at all concentrations, except at 50 and 150μg/ml ECM, 175μg/ml L/E and 25μg/ml L. When cardiomyocytes cultured on ECM, L/E and L were subjected to simulated ischemia, total ARCMs, rod-shaped and R/G fluorescence (mitochondrial viability) was reduced at all concentrations compared to the control group. Hypercontracted cells were higher in the ischemic treated cells compared to the controls on ECM at 75−150μg/ml and 200μg/ml, L/E at 50,100μg/ml and 175μg/ml and on L at 125μg/ml. Total numbers of ARCMs attached on ECM, L/E and L in the ischemic group consisted of similar numbers of non-viable hypercontracted and viable rod-shaped cells. Conclusion: Cardiomyocytes should be cultured on ECM or L/E or L at concentrations from 25−200μg/ml in MMXCB. PBS is harmful to cultured ARCMs and should thus not be used as an experimental buffer. Ischemia/reperfusion can be simulated on ARCMs cultured on ECM, L/E or L from 25−200μg/ml, provided that a modified culture buffer is used as experimental buffer. / AFRIKAANSE OPSOMMING: Inleiding: Primêre selkulture van geïsoleerde volwasse rot kardiomiosiete (VRKMe) is ‘n belangrike model vir kardiovaskulêre navorsing, maar om hierdie selle suksesvol in kultuur te onderhou is ‘n groot uitdaging (Xu et al, 2009; Louch et al, 2011). Die meeste navorsingstudies maak gebruik van akuut geïsoleerde kardiomiosiete onmiddelik na isolasie omdat oorlewing van hierdie selle in kultuur baie laag is. Die struikelblokke in kultuur is as gevolg van die tipe medium en weefselkultuurgom wat gebruik word. Ons het voorheen 'n optimale medium en weefselkultuurgom geïdentifiseer vir VRKM kultuur oorlewing, maar die weefselkultuurgom was nie effektief genoeg om die selle aan die kultuuroppervlak te laat bly vaskleef, tot na die einde van 'n isgemie/herperfusie eksperiment nie. Doel: Die doel was dus om die beste weefselkultuurgom en konsentrasie te identifiseer, wat sal toelaat dat VRKMe verbonde bly aan die kultuuroppervlaktes tot na die einde van isgemie/herperfusie eksperimente. Metodes: Kardiomiosiete was geïsoleer vanaf volwasse Wistar rotharte en oornag in kultuur op verskillende konsentrasies (25 -200 μg/ml) van kollageen 1, kollageen 4, ekstrasellulêre matriks (ESM), laminin/entactin (L/E) en laminin onderhou. Die volgende dag was die VRKMe vir eksperimentasie in PBS en in PBS teenoor MMXCB gebruik, om selbehoud en oorlewing te vergelyk. Kardiomiosiete op ESM, L/E en L (25−200μg/ml) was aan 1 uur van gesimuleerde isgemie blootgestel, in MMXCB wat 3mM SDT en 10mM 2DG bevat het, gevolg deur 15 minute herperfusie. Sel oorlewing was bepaal deur selle te kleur met JC-1 en daarna was fluoressensiebeelde van die selle in ‘n veldgebied van 1.17μm/mm2 geneem. Die selle was volgens selmorfologie en fluoressensie intensiteit ontleed. Resultate: Met die gebruik van MMXCB as eksperimentele buffer in plaas van PBS, het die aantal totale en staafvormige VRKMe verbinding verbeter. Morfologiese onderhoud was sleg op kollageen 1 en 4, ongeag van watter buffer gebruik was. In kontras met die kollagene was die VRKM verbinding en morfologiese onderhoud op ESM, L/E en L in MMXCB effektief verbeter, maar in PBS aansienlik verminder. Mitochondriale lewensvatbaarheid in MMXCB teenoor PBS op kollageen 1 en 4 by 75−175μg/ml, sowel as op ECM, L/E en L by alle konsentrasies, was hoog, behalwe by 50 en 150μg/ml ESM, 175μg/ml L/E en 25μg/ml L. Isgemie blootstelling van kardiomiosiete gekultuur op alle konsentrasies van ESM, L/E en L, het ‘n afname in die totale, staafvormige en R/G fluoressensie (mitochondriale lewensvatbaarheid) teweeggebring. Meer hiperkontrakteerde kardiomiosiete was in die isgemie behandelde groepe as in die kontrole groepe teenwoordig, spesifiek op ESM by 75−150μg/ml en 200μg/ml, op L/E by 50,100μg/ml en 175μg/ml asook op L by 125μg/ml. In die isgemie groepe het die totale aantal VRKMe op ESM, L/E en L meestal uit ‘n gelyke hoeveelheid hiperkontrakteerde en staafvormige selle bestaan. Gevolgtrekking: Kardiomiosiete moet op ESM of L/E of L by konsentrasises van 25−200μg/ml in MMXCB gekultuur word. PBS is nadelig vir VRKMe in kultuur en moet dus nie gebruik word as eksperimentele buffer nie. Isgemie/herperfusie eksperimente kan gesimuleer word op VRKMe wat op 25−200μg/ml ESM, L/E of L gekultuur is, mits ‘n gemodifiseerde kultuur buffer gebruik word as eksperimentele buffer.
8

Influence des processus inflammatoires sur la neuroplasticité et sur les récupérations fonctionnelles après lésion spinale chez le rat adulte / Influence of inflammatory processes on neuroplasticity and functional recovery after spinal cord injury in the adult rat

Thomaty, Sandie 09 December 2015 (has links)
Les lésions spinales conduisent à des altérations majeures des fonctions sensorimotrices. Les récupérations fonctionnelles consécutives à ces atteintes sont très limitées, notamment en raison des capacités réduites de réparation des tissus endommagés dans le SNC. En outre, ces récupérations dépendent notamment de plusieurs processus cellulaires tels que l'activation astrogliale qui conduit à la formation de la cicatrice gliale, ou encore l'inflammation dont les cellules microgliales et les mastocytes sont les effecteurs les plus précoces. Cette inflammation est connue pour exacerber les dommages tissulaires et restreindre les possibilités de récupération. Cependant, des études récentes chez l'animal et chez l'Homme montrent que l'inflammation pourrait également avoir des effets favorisant les processus de récupération. Le but de cette thèse était de mieux comprendre les liens qui existent entre neuroinflammation, neuroplasticité et récupérations fonctionnelles après lésion spinale. L’objectif expérimental visait à examiner les réactivités microgliales, mastocytaires et astrocytaires post-lésionnelles, en parallèle avec des restaurations fonctionnelles. Dans ce contexte nous nous sommes plus particulièrement intéressés à l'influence d'une cytokine pro-inflammatoire, le Granulocyte-Macrophage Colony Stimulating Factor (GM-CSF) sur ces processus inflammatoires et la plasticité fonctionnelle après une hémisection C4-C5 chez le rat adulte. L’ensemble de nos travaux suggère que le GM-CSF pourrait agir par l’intermédiaire de plusieurs événements cellulaires et moléculaires, en favorisant des phénomènes de plasticité adaptatifs et la récupération partielle de fonctions altérées. / Spinal cord injuries are mostly of traumatic origin and result in major sensorimotor deficits. Postlesion functional recovery is limited, especially because of the reduced capacity of repairing damaged tissues. Moreover, this recovery depends specifically on several cellular processes such as astroglial activation conducting to glial scar formation, or inflammation for which microglial and mast cells are the earliest effectors. This inflammation is known to exacerbate tissue damages and restrain the capacity to recover. However, recent studies in animals and humans show that inflammation may also have beneficial aeffects on recovery processes. The studies conducted during my doctoral research were intended to better understand the links between neuroinflammation, neuroplasticity and functional recovery following spinal cord injury. We aimed at examining microglial, mast cells and astroglial reactivities after the injury, in relation with functional recovery of somatosensory and motor functions. In this context, we were particularly interested in the influence of Granulocyte Macrophage-Colony Stimulating Factor (GM-CSF) on inflammatory and plasticity mechanisms after a C4-C5 hemisection in the adult rat. Our doctoral research suggests that GM-CSF could act through several cellular and molecular events promoting adaptive plasticity phenomena underlying partial recovery of impaired functions.

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