Global ETD Search

261	Modulation of arterial stiffness by angiotensin receptors and nitric oxide in the insulin resistance syndrome Brillante, Divina Graciela, Clinical School - St George Hospital, Faculty of Medicine, UNSW January 2008 (has links) The insulin resistance syndrome [INSR] is associated with increased cardiovascular risk and affects up to 25% of the Australian population. The mechanism underlying the relationship between the INSR and increased cardiovascular risk is controversial. We postulated that perturbations in the renin-angiotensin system [RAS] and endothelium-derived NO may be implicated in the development of early vascular changes in the INSR. Repeated measurements of arterial stiffness [using digital photoplethysmography] and haemodynamic parameters in response to vasoactive medications were used to demonstrate the functional expression of angiotensin II [Ang II] receptors and NO synthase [NOS]. Ang II acts via two main receptor sub-types: the Ang II type 1 [AT1] and Ang II type 2 [AT2] receptors. The AT1 receptor is central to the development of arterial stiffness and endothelial dysfunction. The role of AT2 receptors in humans is controversial but is postulated to counter-act AT1 receptor mediated effects in diseased vascular beds. We demonstrated increased AT1 and AT2 receptor-mediated effects in small to medium-sized arteries of subjects with early INSR [Chapter 6]. In addition, functional expression of AT2 receptors in adult insulin resistant humans [Chapter 5], but not in healthy volunteers [Chapter 4] was demonstrated. AT1 receptor blockade in subjects with early INSR resulted in improvements in vascular function, with a consequent functional down-regulation of AT2 receptors [Chapter 7]. Functional NOS expression was demonstrated to be increased in subjects with early INSR compared with healthy controls [Chapter 6]. This was postulated to be a homeostatic response to counteract early vascular changes in subjects with early INSR. AT1 receptor blockade in these subjects reduced functional NOS expression [Chapter 8]. In conclusion, patients with early INSR represent a model of early disease where early intervention may be able to reverse the process incited by the initial exposure to multiple cardiovascular risk factors. Early vascular changes in these individuals are mediated at least in part, by increased AT1 receptor activity and/or expression, and may be detected by changes in arterial stiffness indices and non-invasive vascular reactivity studies. There is a compensatory increase in AT2 receptor and NOS expression/activity to counter-act these vascular changes. Arterial stiffness. Insulin resistance syndrome. Metabolic syndrome. Nitric oxide. Angiotensin receptors. AT1 receptor. AT2 receptor.
262	Therapeutic interventions for lipidinduced insulin resistance in skeletal muscle: mechanisms of action Lessard, Sarah, not supplied January 2006 (has links) It has long been known that in addition to disruptions in glucose homeostasis, individuals with insulin resistance have a breakdown in lipid dynamics, often manifested by elevated levels of circulating fatty acids (FA) together with accumulation of lipids in insulin-sensitive tissues, including skeletal muscle. However, little is known about how common therapies used to treat insulin resistant individuals (such as Rosiglitazone and exercise training) improve skeletal muscle lipid and glucose metabolism. Thus, the primary aim of the studies undertaken for this thesis was to enhance our understanding of the mechanisms by which Rosiglitazone and exercise training improve skeletal muscle lipid metabolism and insulin sensitivity in two distinct models of insulin resistance. The first investigation determined the effect of chronic Rosiglitazone treatment on the accumulation of lipid metabolites and enzymatic regulators of lipid metabolism in the skeletal muscle of obese Zucker rats. The observation that Rosiglitazone treatment exacerbated the accumulation of muscle ceramide and diacylglycerol in skeletal muscle, while improving glucose tolerance led to the conclusion that this insulin sensitising drug improves insulin sensitivity by mechanisms other than reduction of fatty acid metabolites in this tissue. Accordingly, the second investigation sought to identify an alternative mechanism by which Rosiglitazone treatment may improve skeletal muscle insulin sensitivity. It was found that Rosiglitazone restored AMP-activated protein kinase (AMPK) á2 activity in the skeletal muscle of obese Zucker rats, providing a potential peroxisome proliferator activated receptor (PPAR) ã-independent mechanism by which this drug may mediate its insulinsensitising actions. The final experiment undertaken for this thesis determined the independent and interactive effects on Rosiglitazone and exercise training on various aspects of skeletal muscle glucose and lipid metabolism in a model of diet-induced insulin resistance, the high-fat fed rat. Exercise training, but not Rosiglitazone treatment restored skeletal muscle insulin sensitivity in high-fat fed rats. Improvements in insulin sensitivity with exercise training were associated with increased FA oxidation, increased AMPK activity and a normalisation of the expression of the Akt substrate, AS160. In contrast, Rosiglitazone treatment was associated with increased FA uptake and decreased insulin-stimulated glucose uptake in skeletal muscle. Exercise prevented the accumulation of skeletal muscle lipids in Rosiglitazone-treated animals when the two treatments were combined. In summary, the results from the studies undertaken for this thesis provide novel information regarding the mechanisms by which two insulinsensitising therapies, exercise training and Rosiglitazone treatment, act to improve glucose and lipid metabolism in skeletal muscle.It has long been known that in addition to disruptions in glucose homeostasis, individuals with insulin resistance have a breakdown in lipid dynamics, often manifested by elevated levels of circulating fatty acids (FA) together with accumulation of lipids in insulin-sensitive tissues, including skeletal muscle. However, little is known about how common therapies used to treat insulin resistant individuals (such as Rosiglitazone and exercise training) improve skeletal muscle lipid and glucose metabolism. Thus, the primary aim of the studies undertaken for this thesis was to enhance our understanding of the mechanisms by which Rosiglitazone and exercise training improve skeletal muscle lipid metabolism and insulin sensitivity in two distinct models of insulin resistance. The first investigation determined the effect of chronic Rosiglitazone treatment on the accumulation of lipid metabolites and enzymatic regulators of lipid metabolism in the skeletal muscle of obese Zucker rats. The observation that Rosiglitazone treatment exacerbated the accumulation of muscle ceramide and diacylglycerol in skeletal muscle, while improving glucose tolerance led to the conclusion that this insulin sensitising drug improves insulin sensitivity by mechanisms other than reduction of fatty acid metabolites in this tissue. Accordingly, the second investigation sought to identify an alternative mechanism by which Rosiglitazone treatment may improve skeletal muscle insulin sensitivity. It was found that Rosiglitazone restored AMP-activated protein kinase (AMPK) á2 activity in the skeletal muscle of obese Zucker rats, providing a potential peroxisome proliferator activated receptor (PPAR) ã-independent mechanism by which this drug may mediate its insulinsensitising actions. The final experiment undertaken for this thesis determined the independent and interactive effects on Rosiglitazone and exercise training on various aspects of skeletal muscle glucose and lipid metabolism in a model of diet-induced insulin resistance, the high-fat fed rat. Exercise training, but not Rosiglitazone treatment restored skeletal muscle insulin sensitivity in high-fat fed rats. Improvements in insulin sensitivity with exercise training were associated with increased FA oxidation, increased AMPK activity and a normalisation of the expression of the Akt substrate, AS160. In contrast, Rosiglitazone treatment was associated with increased FA uptake and decreased insulin-stimulated glucose uptake in skeletal muscle. Exercise prevented the accumulation of skeletal muscle lipids in Rosiglitazone-treated animals when the two treatments were combined. In summary, the results from the studies undertaken for this thesis provide novel information regarding the mechanisms by which two insulinsensitising therapies, exercise training and Rosiglitazone treatment, act to improve glucose and lipid metabolism in skeletal muscle. Rosiglitazone exercise training therapy type 2 diabetes insulin resistance skeletal muscle
263	Regulation of insulin signalling by exercise in skeletal muscle Wadley, Glenn, mikewood@deakin.edu.au January 2003 (has links) Regular physical activity improves insulin action and is an effective therapy for the treatment and prevention of type 2 diabetes. However, little is known of the mechanisms by which exercise improves insulin action in muscle. These studies investigate the actions of a single bout of exercise and short-term endurance training on insulin signalling. Twenty-four hours following the completion of a single bout of endurance exercise insulin action improved, although greater enhancement of insulin action was demonstrated following the completion of endurance training, implying that cumulative bouts of exercise substantially increase insulin action above that seen from the residual effects of an acute bout of prior exercise. No alteration in the abundance and phosphorylation of proximal members of the insulin-signalling cascade in skeletal muscle, including the insulin receptor and IRS-1 were found. A major finding however, was the significant increase in the serine phosphorylation of a known downstream signalling protein, Akt (1.5 fold, p ≤0.05) following an acute bout of exercise and exercise training. This was matched by the observed increase in protein abundance of SHPTP2 (1.6 fold, p ≤0.05) a protein tyrosine phosphatase, in the cytosolic fraction of skeletal muscle following endurance exercise. These data suggest a small positive role for SHPTP2 on insulin stimulated glucose transport consistent with transgenic mice models. Further studies were aimed at examining the gene expression following a single bout of either resistance or endurance exercise. There were significant transient increases in IRS-2 mRNA concentration in the few hours following a single bout of both endurance and resistance exercise. IRS-2 protein abundance was also observed to significantly increase 24-hours following a single bout of endurance exercise indicating transcriptional regulation of IRS-2 following muscular contraction. One final component of this PhD project was to examine a second novel insulin-signalling pathway via c-Cbl tyrosine phosphorylation that has recently been shown to be essential for insulin stimulated glucose uptake in adipocytes. No evidence was found for the tyrosine phosphorylation of c-Cbl in the skeletal muscle of Zucker rats despite demonstrating significant phosphorylation of the insulin receptor and Akt by insulin treatment and successfully immunoprecipitating c-Cbl protein. Surprisingly, there was a small but significant increase in c-Cbl protein expression following insulin-stimulation, however c-Cbl tyrosine phosphorylation does not appear to be associated with insulin or exercise-mediated glucose transport in skeletal muscle. non-insulin-dependent diabetes pathophysiology exercise physiological effect strained muscle metabolism insulin resistance insulin diabetes
264	Structure and function of AMPK: subunit interactions of the AMPK heterotrimeric complex Iseli, Tristan J. Unknown Date (has links) (PDF) AMP-activated protein kinase (AMPK) is an important metabolic stress-sensing protein kinase responsible for regulating metabolism in response to changing energy demand and nutrient supply. Mammalian AMPK is a stable aß? heterotrimer comprising a catalytic a subunit and two non-catalytic subunits, ß and ?. The ß subunit targets AMPK to membranes via an N-terminal myristoyl group and to glycogen via a mid-molecule glycogen-binding domain. Here I show that the conserved C-terminal 85-residue sequence of the ß subunit, ß1(186-270), is sufficient to form an active AMP-dependent heterotrimer a1ß1(186-270)?1, whereas the 25-residue ß1 C-terminal (246-270) sequence is sufficient to bind ?1, ?2, or ?3 but not the a subunit. Within this sequence (246-270), two residues were essential for ß? association based on Ala scanning mutagenesis. / Substitution of ß1 Tyr-267 for Ala precludes ß? but not aß association suggesting independent binding requirements. Substitution of Tyr-267 for Phe or His but not Ala or Ser can rescue ß? binding. Substitution of Thr-263 for Ala also resulted in decreased ß? but not aß association. Truncation of the a subunit reveals that ß1 binding requires the a1(313-473) sequence while the remainder of the a C-terminus is required for ? binding. The conserved C-terminal 85-residue sequence of the ß subunit (90% between ß1 and ß2) is the primary a? binding sequence responsible for the formation of the AMPK aß? heterotrimer. The ? subunits contain four repeat CBS sequences with variable N-terminal extensions and the ?1 isoform is N-terminally acetylated. The ?2 subunit can be multiply phosphorylated by protein kinase C (PKC) in vitro, with Ser-32 identified as a minor site. A detailed understanding of the structure and regulation of AMPK will enable rational drug design for treatment of such linked diseases as obesity, insulin resistance and type 2 diabetes.
265	Modulation of arterial stiffness by angiotensin receptors and nitric oxide in the insulin resistance syndrome Brillante, Divina Graciela, Clinical School - St George Hospital, Faculty of Medicine, UNSW January 2008 (has links) The insulin resistance syndrome [INSR] is associated with increased cardiovascular risk and affects up to 25% of the Australian population. The mechanism underlying the relationship between the INSR and increased cardiovascular risk is controversial. We postulated that perturbations in the renin-angiotensin system [RAS] and endothelium-derived NO may be implicated in the development of early vascular changes in the INSR. Repeated measurements of arterial stiffness [using digital photoplethysmography] and haemodynamic parameters in response to vasoactive medications were used to demonstrate the functional expression of angiotensin II [Ang II] receptors and NO synthase [NOS]. Ang II acts via two main receptor sub-types: the Ang II type 1 [AT1] and Ang II type 2 [AT2] receptors. The AT1 receptor is central to the development of arterial stiffness and endothelial dysfunction. The role of AT2 receptors in humans is controversial but is postulated to counter-act AT1 receptor mediated effects in diseased vascular beds. We demonstrated increased AT1 and AT2 receptor-mediated effects in small to medium-sized arteries of subjects with early INSR [Chapter 6]. In addition, functional expression of AT2 receptors in adult insulin resistant humans [Chapter 5], but not in healthy volunteers [Chapter 4] was demonstrated. AT1 receptor blockade in subjects with early INSR resulted in improvements in vascular function, with a consequent functional down-regulation of AT2 receptors [Chapter 7]. Functional NOS expression was demonstrated to be increased in subjects with early INSR compared with healthy controls [Chapter 6]. This was postulated to be a homeostatic response to counteract early vascular changes in subjects with early INSR. AT1 receptor blockade in these subjects reduced functional NOS expression [Chapter 8]. In conclusion, patients with early INSR represent a model of early disease where early intervention may be able to reverse the process incited by the initial exposure to multiple cardiovascular risk factors. Early vascular changes in these individuals are mediated at least in part, by increased AT1 receptor activity and/or expression, and may be detected by changes in arterial stiffness indices and non-invasive vascular reactivity studies. There is a compensatory increase in AT2 receptor and NOS expression/activity to counter-act these vascular changes. Arterial stiffness. Insulin resistance syndrome. Metabolic syndrome. Nitric oxide. Angiotensin receptors. AT1 receptor. AT2 receptor.
266	Modulation of arterial stiffness by angiotensin receptors and nitric oxide in the insulin resistance syndrome Brillante, Divina Graciela, Clinical School - St George Hospital, Faculty of Medicine, UNSW January 2008 (has links) The insulin resistance syndrome [INSR] is associated with increased cardiovascular risk and affects up to 25% of the Australian population. The mechanism underlying the relationship between the INSR and increased cardiovascular risk is controversial. We postulated that perturbations in the renin-angiotensin system [RAS] and endothelium-derived NO may be implicated in the development of early vascular changes in the INSR. Repeated measurements of arterial stiffness [using digital photoplethysmography] and haemodynamic parameters in response to vasoactive medications were used to demonstrate the functional expression of angiotensin II [Ang II] receptors and NO synthase [NOS]. Ang II acts via two main receptor sub-types: the Ang II type 1 [AT1] and Ang II type 2 [AT2] receptors. The AT1 receptor is central to the development of arterial stiffness and endothelial dysfunction. The role of AT2 receptors in humans is controversial but is postulated to counter-act AT1 receptor mediated effects in diseased vascular beds. We demonstrated increased AT1 and AT2 receptor-mediated effects in small to medium-sized arteries of subjects with early INSR [Chapter 6]. In addition, functional expression of AT2 receptors in adult insulin resistant humans [Chapter 5], but not in healthy volunteers [Chapter 4] was demonstrated. AT1 receptor blockade in subjects with early INSR resulted in improvements in vascular function, with a consequent functional down-regulation of AT2 receptors [Chapter 7]. Functional NOS expression was demonstrated to be increased in subjects with early INSR compared with healthy controls [Chapter 6]. This was postulated to be a homeostatic response to counteract early vascular changes in subjects with early INSR. AT1 receptor blockade in these subjects reduced functional NOS expression [Chapter 8]. In conclusion, patients with early INSR represent a model of early disease where early intervention may be able to reverse the process incited by the initial exposure to multiple cardiovascular risk factors. Early vascular changes in these individuals are mediated at least in part, by increased AT1 receptor activity and/or expression, and may be detected by changes in arterial stiffness indices and non-invasive vascular reactivity studies. There is a compensatory increase in AT2 receptor and NOS expression/activity to counter-act these vascular changes. Arterial stiffness. Insulin resistance syndrome. Metabolic syndrome. Nitric oxide. Angiotensin receptors. AT1 receptor. AT2 receptor.
267	Relationships among Cynical Hostility, Metabolic Syndrome, and Cardiac Structure and Function in Multi-Ethnic Post-Myocardial Infarction Patients: A Structural Modeling Approach Wachowiak, Paul Stephen 10 August 2009 (has links) BACKGROUND: Risk factors associated with Metabolic Syndrome (MetS) have been implicated in cardiovascular disease (CVD) development and outcomes. Few studies have investigated relationships between psychological variables, MetS factors, and indices of cardiac structure and function (CSF) among healthy individuals in a single conceptual model. No studies to date have analyzed such relationships in patients with CVD. METHODS: The present study examined associations between cynical hostility (CynHo), MetS factors, and CSF in 186 multi-ethnic post-myocardial infarction (MI) patients. Structural equation modeling was used to test a theory driven model of MetS that had good statistical fit. Primary MetS variables included waist circumference (WC), the homeostatic model of insulin resistance (HOMA-IR), glucose area under the curve (G-AUC), triglycerides (TRIG), high-density lipoprotein cholesterol (HDL-C), and diastolic blood pressures (DBP). Secondary MetS variables included plasminogen activator inhibitor-1 (PAI-1) and a latent inflammation variable comprised of CRP and IL-6. Cardiac function variables were fractional shortening (FS), E/A ratio, and rate-pressure product (RPP). A latent cardiac mass (CM) variable was also created. RESULTS: The final structural model had good model fit (Chi-Square(102)=100.65, p=0.52, CFI=1.00, RMSEA=0.00, and SRMR=0.04). Direct paths were supported between WC and CM and all MetS factors except TRIG and G-AUC. WC was indirectly associated with DBP via CM. The model supported positive direct paths between HOMA-IR and G-AUC, TRIG, and PAI-1, but not inflammation or HDL-C. HOMA-IR demonstrated a direct positive association with RPP and direct inverse associations with FS and E/A ratio. No direct paths were supported between other MetS variables except one between TRIG and HDL-C. CynHo demonstrated a direct positive relationship with HOMA-IR. CONCLUSIONS: Similar to findings in healthy individuals, central adiposity and IR play primary roles in CSF impairment in post-MI patients. Findings suggest that CynHo could promote the progression of metabolic dysfunction and cardiac disease via factors that influence the efficiency of glucose metabolism. Interventions for post-MI patients should take into account both direct and indirect effects of CynHo, central adiposity, and IR on the progression of CVD in this population to reduce adverse outcomes and improve quality of life.
268	Do Metabolic and Psychosocial Responses To Exercise Explain Ethnic/Racial Disparities in Insulin Resistance? Hasson, Rebecca Elizabeth 01 February 2009 (has links) Introduction . Non-Hispanic blacks (blacks) are more insulin resistant compared to non-Hispanic whites (whites), increasing their risk for Type 2 diabetes. The role played by ethnic/racial disparities in the response to physical activity in mediating those higher rates of insulin resistance in blacks is unknown. Because the beneficial effects of exercise are transient and require subsequent doses of exercise to maintain the effect; the metabolic and psychosocial responses to single exercise bouts have strong implications for both opposing insulin resistance and raising the probability that an individual will continue to exercise. Purpose . To compare the metabolic and psychosocial responses to individual bouts of exercise, at the intensity and duration corresponding to the current Institute of Medicine guidelines, in blacks and age/gender/BMI-matched whites. Methods . Insulin sensitivity (hyperinsulinemic-euglycemic clamp) and metabolic flexibility (suppression of resting fat oxidation) along with exercise task self-efficacy, mood, and state-anxiety were assessed before and after a bout of exercise in black and white men and women (metabolic n = 21; psychosocial n = 31). Participants walked on a treadmill at 75% of maximum heart rate for 75 minutes. Exercise sessions were repeated on three separate occasions to assess the cumulative change in psychosocial responses to exercise. Results . There were no ethnic/racial differences in baseline measures of whole-body insulin sensitivity (p = 0.95). Black participants demonstrated larger improvements in the insulin sensitivity response to individual bouts of exercise compared to their white counterparts (+18% vs. -1.8%), which was primarily the result of enhanced non-oxidative glucose disposal during the clamp. Additionally, blacks demonstrated a greater capacity to switch from primarily fat oxidation at rest to primarily carbohydrate oxidation during the clamp (p <0.003). There were no ethnic/racial differences in the psychosocial response to individual bouts of exercise; individual bouts of exercise improved exercise task self-efficacy and reduced psychological distress in both black and white participants (p = 0.006). Black participants reported higher positive in-task mood during all three bouts of exercise (p = 0.003) and lower RPE scores (p = 0.04) during the third exercise bout compared to white participants, despite similar heart rates in both groups. Conclusions . These data demonstrate that metabolic and psychosocial responses to individual bouts of exercise do not help to explain the increased insulin resistance and lower adherence rates to exercise programs reported in blacks compared to whites. If these results are confirmed in a larger, more diverse, free-living population, future research should focus on social determinants of insulin resistance and physical inactivity to obtain a better understanding of the root causes of increased risk of Type 2 diabetes in black populations. Exercise Health disparities Insulin resistance Metabolic flexibility Physical activity Self-efficacy Kinesiology
269	Högfettskost till obesa barn : Pilotstudie Lidgren, Agnetha January 2010 (has links) Syftet med denna pilotstudie var att studera om man hos pediatriska patienter som lider av sjuklig fetma kan se förändringar i metabolismen genom att ersätta den traditionella kosten med en kost bestående av hög andel fett och låg andel kolhydrater. De frågeställningar som används är om den förändrade kosten leder till en gynnsam förändring av metabola markörer samt hur patientupplevelsen av de nya kostråden är. Studien har både en kvantitativ och kvalitativ design. Totalt ingår 4 barn i åldern 4-17 år. Två av dessa har under fyra veckor ätit en kost bestående av hög andel fett (50-60E%) och låg andel kolhydrater (15-20E%). Efter avslutad intervention undersöktes hur metabola parametrar förändrats (blodprov) samt hur patienterna upplevt kosten (frågeformulär). Resultatet visar på att kostråden leder till en sänkning av triglycerider, glukos, HDL, total kolesterol och ASAT. Bland kontrollpatienterna ser man en ökning av triglycerider, HDL och total kolesterol. Upplevelsen av kostråden beskrivs som positiva, trots att nackdelar finns. Det finns en positiv attityd till att fortsätta med kostråden. Child obesity high-fat diet low-carbohydrate diet insulin resistance Barnfetma högfetts diet lågkolhydrat diet insulinresistens
270	Oral nutrition or water loading before hip replacement surgery; a randomized clinical trial Ljunggren, Stefan, Hahn, Robert G January 2012 (has links) Background Surgery induces insulin resistance that might be alleviated by a nutritional drink given preoperatively. The authors hypothesized that some of the beneficial effects of the drink could be attributed to the volume component (approximately 1 L) rather than to the nutrients. Methods Sixty patients scheduled for elective total hip replacement under spinal anesthesia were recruited to a clinical trial, and randomly allocated to preoperative fasting, to oral ingestion of tap water, or to oral ingestion of a carbohydrate drink. An intravenous glucose tolerance test calculated glucose clearance and insulin sensitivity on the day before surgery, in the postoperative ward, and on the day after surgery. Other parameters were stress (cortisol in plasma and urine), muscle catabolism (urinary 3-methylhistidine), and wellbeing. Results Fifty-seven patients completed the study. In the postoperative ward, the glucose clearance and the insulin response had decreased from the previous day by 23% and 36%, respectively. Insulin sensitivity did not decrease until the next morning (−48%) and was due to an increased insulin response (+51%). Cortisol excretion was highest on the day of surgery, while 3-methylhistidine increased 1 day later. Follow-up on the third postoperative day showed an average of 1.5 complications per patient. Wellbeing was better 2 weeks after than before the surgery. None of the measured parameters differed significantly between the study groups. Conclusions Preoperative ingestion of tap water or a nutritional drink had no statistically significant effect on glucose clearance, insulin sensitivity, postoperative complications, or wellbeing in patients undergoing elective hip surgery. / <p>Funding Agencies\|Olle Engkvist Byggmastare Foundation\|\|Stockholm County Council\|2009-0433\|</p> Glucose tolerance test Glucose clearance Insulin resistance Cortisol complications W-BQ12 Health index MEDICINE MEDICIN

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