Global ETD Search

51	Remise diabetu 2. typu u pacientů na různých dietních režimech / Remission of type 2 diabetes in patients on various dietary regimens Kábelová, Adéla January 2020 (has links) Type 2 diabetes mellitus (T2D) is a highly prevalent metabolic disorder linked with the development of specific complications and comorbidities that negatively affect life quality and greatly increase the risk of an early death. The main goal of T2D treatment, which in common clinical practice comprises lifestyle changes and pharmacotherapy, is to delay onset of these complications. Evidence from many recent studies shows the ability of some interventional methods to induce remission of T2D, meaning a major improvement or complete disappearance of T2D symptoms. Besides bariatric surgery procedures, some dietary regimens such as low-energy diet, low-carbohydrate diet and intermittent fasting, can also lead to T2D remission. Attributes of these dietary regimens, especially their effect in T2D treatment, is summarized in the theoretical part of this theses. The aim of the practical part of this thesis was to assess the effect of the dietary regimens mentioned above on morphometric and biochemical parameters associated with T2D by clinical and survey research. In most of the subjects with T2D, the individual dietary regimens, more precisely low-energy diet and low-carbohydrate diet, decreased body weight, where the weight loss induced by low-carbohydrate diet was caused by major decrease in the amount...
52	Brain Hypometabolism and Seizures: The Dynamics of Hypoxia and Hypoglycemia in Brain Energy Homeostasis Dwyer, Trisha A. 28 December 2011 (has links) No description available. Biomedical Research Neurosciences Ischemia Hypoxia Hypoglycemia Seizures Glyceraldehyde 3-phosphate dehydrogenase GABA receptor Glycolysis Ketogenic diet 2-deoxyglucose Pentose phosphate pathway
53	Étude du métabolisme cérébral au cours du vieillissement sain chez le rat : impact de la diète cétogène et de la restriction calorique / The study of brain metabolism during aging in rats: the effect of the ketogenic diet and calorie restriction Roy, Maggie January 2014 (has links) Résumé : Les personnes atteintes de la maladie d’Alzheimer présentent une diminution de la capture cérébrale du glucose, qui semble être impliquée dans le développement des problèmes cognitifs associés à la maladie. Toutefois, il n’y a encore aucun consensus quant à savoir si la capture cérébrale du glucose est diminuée chez les personnes âgées cognitivement saines. En condition de déficit de glucose, les cétones sont le substrat énergétique alternatif pour le cerveau. La diète cétogène, induisant une cétose légère, améliore les fonctions cognitives chez les modèles animaux et chez l’homme. Notre premier objectif était d’évaluer l’effet du vieillissement sain et de la diète cétogène sur la capture cérébrale du glucose et des cétones chez le rat. Pour cela, la capture cérébrale de radiotraceurs analogues au glucose et aux cétones a été mesurée par tomographie par émission de positons. Nos résultats montrent que la capture des deux principaux substrats énergétiques du cerveau est globalement similaire chez des rats sains jeunes et âgés, mais est plus élevée suite à la diète cétogène. L’induction d’une cétose légère pourrait corriger la diminution de capture cérébrale du glucose subvenant au cours de la maladie d’Alzheimer. Le second objectif était de déterminer l’effet d’une diète cétogène sur le métabolisme cérébral du glucose et des cétones chez le rat. Pour cela, les différents intermédiaires des voies métaboliques du glucose et des cétones ont été mesurés par spectroscopie par résonance magnétique nucléaire. Les résultats démontrent que le métabolisme du glucose et des cétones dans les cellules du cerveau est plus élevé suite à la diète cétogène. Le contenu en acide [gamma]-aminobutyrique, le principal neurotransmetteur inhibiteur, est aussi plus élevé suite à la diète cétogène, ce qui pourrait contribuer à l’effet antiépileptique de la diète cétogène. Le troisième objectif était d’évaluer l’impact d’une restriction calorique à long terme, pouvant induire une cétose légère, sur le métabolisme cérébral chez des rats âgés sains. Nos résultats montrent que, couplée à une diète à haute teneur en sucrose et faible en acides gras oméga-3, la restriction calorique à long terme chez les rats âgés ne modifie pas le profil des métabolites et des acides gras du cerveau. La déficience en acides gras oméga-3 et la surcharge de sucrose pourraient empêcher une grande partie des effets bénéfiques de la restriction calorique au cerveau.//Abstract : Alzheimer’s disease is associated with a reduction of brain glucose uptake, which may be involved in the development of the cognitive problems associated with the disease. It is however unclear whether brain glucose uptake is decreased in the cognitively healthy elderly. Under conditions of glucose deficit, ketones are the alternative brain energy substrate. A mild ketosis, induced by the ketogenic diet, improves cognitive functions in animal models and humans. Our first objective was to evaluate the effect of healthy aging and of a ketogenic diet on brain glucose and ketone uptake in the rat. Brain uptake of radiotracers analogous to glucose and ketones was measured by positron emission tomography. Our results show that the uptake of the brains two main energy substrates is generally similar in healthy young and aged rats, but is higher under the ketogenic diet. The induction of a mild ketosis may compensate the reduction of brain glucose uptake occurring in Alzheimer’s disease. The second objective was to assess the effect of a ketogenic diet on brain glucose and ketone metabolism in the rat. Metabolic pathway intermediates of glucose and ketones were measured by nuclear magnetic resonance spectroscopy. Results show that glucose and ketone metabolism in brain cells is higher under the ketogenic diet. Content of [gamma]-aminobutyric acid, the main inhibitory neurotransmitter, is also higher under the ketogenic diet, which could contribute to the antiepileptic effect of the ketogenic diet. The third objective was to evaluate the effect of a long-term calorie restriction, which may induce a mild ketosis, on brain metabolism in healthy aged rats. Our results show that, in conjunction with a diet enriched in sucrose and low in omega-3 fatty acids, long-term calorie restriction in aged rats does not change brain metabolite and fatty acid profiles. Omega-3 fatty acid deficiency and an overload of sucrose may prevent the beneficial effects associated with calorie restriction in the brain. Métabolisme cérébral Glucose Cétones Vieillissement Diète cétogène Restriction calorique Tomographie par émission de positons Brain metabolism Glucose Ketones Aging Ketogenic diet Calorie restriction Positron emission tomography Nuclear magnetic resonance spectroscopy
54	Etude de la dysfonction cellulaire et moléculaire du syndrome mitochondrial MELAS. / Study of cellular and molecular dysfunction of mitochondrial MELAS syndrom Geffroy, Guillaume 29 September 2017 (has links) Chaque mitochondrie contient son propre génome en de multiples copies d’ADN. Les mutations de l'ADN mitochondriales (ADNmt) sont responsables de sévères dysfonctions de la chaîne respiratoire. Le ratio entre la proportion de copies sauvages et mutantes, qualifiée d'hétéroplasmie, détermine la sévérité de la pathologie. Une des mutations les plus répandues de l'ADNmt est la mutation m.3243A>G, affectant l'ARN de transfert de la leucine. Ce variant est à l'origine du syndrome mitochondrial MELAS. Il n’existe à l’heure actuelle aucun traitement curatif pour ce syndrome. Nous avons développé une série de cybrides neuronaux porteurs de la mutation m.3243A>G a différents taux d’hétéroplasmie. Nous avons mis en évidence que de fort taux de mutations sont responsables de sévères dysfonctions de la chaîne respiratoire, d’un défaut d’assemblage précoce du complexe I ainsi qu’une réduction du renouvellement mitochondrial. Différentes stratégies métaboliques ont été employées pour compenser ces déficits. L’exposition des cellules a une restriction glucidique ou à la diète cétogène associant réduction glucidique et ajout de corps cétoniques, améliore significativement les fonctions mitochondriales après 4 semaines. Ces effets passent notamment par une restauration de l’assemblage et de l’activité du complexe I médiée ces interventions métaboliques. Par ailleurs, l’administration de la diète cétogène à un patient atteint du syndrome MELAS a déjà montré des résultats encourageants. De telles approches pourraient alors, constituées des stratégies thérapeutiques futures dans le traitement du syndrome MELAS et des maladies mitochondriales. / Each mitochondrion contains its own genome in multiple copies. Mitochondrial DNA (mtDNA) mutations are responsible for respiratory chain defects. The ratio of mutant to normal mtDNA, a condition known as heteroplasmy, may determine the disease severity. The m.3243A>G mutation, which affects the leucine tRNA, is one of the most common mtDNA mutation. This variant is responsible for the MELAS syndrome, a neurodegenerative disease, characterized by pseudostrokes. Unfortunately there are no curative treatments for MELAS syndrome. We have developed series of cybrid neuronal cells lines carrying the m.3243A>G mutation with different mutant loads, within the same nuclear background. High mutation load is associated to severe respiratory chain dysfunction, an early complex I assembly defect and a mitochondrial turn-over deficit. Different strategies were used to compensate the defects in the mutant cells. Cell exposure to low glucose or ketogenic diet, combining glucose reduction and the addition of ketone bodies, greatly improves mitochondrial functions after 4 weeks. Those effects are linked to a significant increase of complex I assembly and activity mediated by those metabolic interventions. In addition, a MELAS patient treated with ketogenic diet showed significant clinical improvement. Thus, metabolic approaches may constitute promising therapeutic strategies against MELAS syndrome and mitochondrial disorders. Syndrome MELAS Hétéroplasmie Dysfonctions oxydatives Régime cétogène Réduction glucidique Assemblage du Complexe I Renouvellement mitochondrial MtRosella MELAS syndrome Heteroplasmy Oxidative dysfunctions Ketogenic diet Low glucose Complex I assembly Mitochondrial turnover MtRosella 611.018
55	Effects of Nicotinamide Riboside and Beta-hydroxybutyrate on C. elegans Lifespan Peters, Jeffery 01 May 2020 (has links) The nicotinamide riboside (NR) form of vitamin B3and the ketone body ß-hydroxybutyrate (BHB) are two of the most promising natural compounds yet identified for the treatment of aging and aging-related diseases. Forms of vitamin B3are precursors for the synthesis of the coenzymes nicotinamide adenine dinucleotide (NAD(H)) and nicotinamide adenine dinucleotide phosphate (NADP(H)). In aged cells levels of NAD+decline, decreasing metabolism and decreasing activity of protective sirtuin protein deacetylases. In aged cells NR, but not more common forms of vitamin B3, boost NAD+levels. BHB is naturally produced by the body when individuals fast or consume a ketogenic (KD) or calorically restricted (CR) diet. These diets have been shown to extend lifespan in mice, while they are also protective in many disease models. Caenorhabditis elegans, a roundworm with a short mean lifespan of roughly 2 to 3 weeks depending upon the temperature, is used as a model system to study aging. BHB has been previously shown to increase lifespan by roughly 20% when administered to C. elegans.We administered NR and BHB individually and together to C. elegans starting at two different developmental stages (larval stages 1 and 4) and measured lifespan. We found that administration of 20 mM DL-BHB decreased lifespan when first given at the L1 stage, while it robustly increased lifespan when first given at the L4 stage. Administration of 0.5 mM NR increased lifespan when first given at L1, with only a very slight increase when first given at L4. When initiating administration at L1, NR greatly mitigated the BHB-mediated decline in longevity, however, NR did not increase BHB-mediated lifespan extension when first administered at L4. Lifespan C. elegans Nicotinamide Riboside Beta-hydroxybutyrate Ketogenic Diet Nicotinamide Adenine Dinucleotide Biochemistry Chemical Actions and Uses Genetic Phenomena Medical Biochemistry Medical Cell Biology Medical Physiology Organic Chemicals
56	The role of pyruvate dehydrogenase kinase in glucose and ketone body metabolism Rahimi, Yasmeen 03 January 2014 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The expression of pyruvate dehydrogenase kinase (PDK) 2 and 4 are increased in the fasted state to inactivate the pyruvate dehydrogenase complex (PDC) by phosphorylation to conserve substrates for glucose production. To assess the importance of PDK2 and PDK4 in regulation of the PDC to maintain glucose homeostasis, PDK2 knockout (KO), PDK4 KO, and PDK2/PDK4 double knockout (DKO) mice were generated. PDK2 deficiency caused higher PDC activity and lower blood glucose levels in the fed state while PDK4 deficiency caused similar effects in the fasting state. DKO intensified these effects in both states. PDK2 deficiency had no effect on glucose tolerance, PDK4 deficiency produced a modest effect, but DKO caused a marked improvement, lowered insulin levels, and increased insulin sensitivity. However, the DKO mice were more sensitive than wild-type mice to long term fasting, succumbing to hypoglycemia, ketoacidosis, and hypothermia. Stable isotope flux analysis indicated that hypoglycemia was due to a reduced rate of gluconeogenesis. We hypothesized that hyperglycemia would be prevented in DKO mice fed a high saturated fat diet for 30 weeks. As expected, DKO mice fed a high fat diet had improved glucose tolerance, decreased adiposity, and were euglycemic due to reduction in the rate of gluconeogenesis. Like chow fed DKO mice, high fat fed DKO mice were unusually sensitive to fasting because of ketoacidosis and hypothermia. PDK deficiency resulted in greater PDC activity which limited the availability of pyruvate for oxaloacetate synthesis. Low oxaloacetate resulted in overproduction of ketone bodies by the liver and inhibition of ketone body and fatty acid oxidation by peripheral tissues, culminating in ketoacidosis and hypothermia. Furthermore, when fed a ketogenic diet consisting of low carbohydrate and high fat, DKO mice also exhibited hypothermia, ketoacidosis, and hypoglycemia. The findings establish that PDK2 is more important in the fed state, PDK4 is more important in the fasted state, survival during long term fasting depends upon regulation of the PDC by both PDK2 and PDK4, and that the PDKs are important for the regulation of glucose and ketone body metabolism. Ketone body metabolism -- Research Pyruvate kinase -- Research Blood sugar -- Regulation Sugar in the body Hypoglycemia Ketoacidosis Hypothermia Gluconeogenesis -- Research Fatty acids -- Synthesis Pyruvate carboxylase Ketogenic diet Mice as laboratory animals -- Research

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