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Pathogenesis of the Metabolic Syndrome: influence of lipid depots and effect of physical activity

Abstract Metabolic Syndrome (MetSyn) is a medical condition prevalent in Australia. MetSyn is diagnosed with a varying combination of visceral obesity, insulin resistance/ impaired glucose tolerance/ Type 2 diabetes, dyslipidaemia and hypertension. Obesity is a central feature of this syndrome that is characterised by abnormalities in glucose and lipid metabolism. An understanding of the cause of the metabolic derangement that occurs in obesity, and that contributes to MetSyn, would allow effective treatment and prevention strategies to be formulated. This is a priority in the current environment of highly prevalent overweight and obesity in Australian children and adults. Lipotoxicity of insulin-dependent tissues and ectopic fat depots are emerging as fundamental processes in the pathogenesis of MetSyn. Lifestyle intervention, such as increased physical activity, show great promise as agents for disrupting the disease progression and may act via direct or indirect mechanisms on the underlying pathology of MetSyn. This study aimed to determine if diagnostic markers of MetSyn exist in obese, prepubertal, Australian children and to assess the contribution of lifestyle factors on components of MetSyn. Further, this study sought to investigate the relationship between body fat patterning (total body fat, abdominal adipose depots, skeletal intramyocellular lipids, intrahepatocellular lipids) and markers of MetSyn. An experimental intervention was then employed to examine the effect of physical activity on body fat distribution, insulin sensitivity, and haemodynamic and biochemical markers of MetSyn, and additionally to determine if the effect of exercise on parameters of MetSyn was mediated by a change in body fat patterning. Data were collected in a group of 15 obese (mean BMI Z-score 2.51 ± 0.49), prepubertal children (6 male, 9 female) aged 5.1 – 11.4 years (mean age 7.82 yrs ± 1.83). Measures included insulin sensitivity, blood biochemistry (lipid, haemostatic and adipocyte activity markers), blood pressure, two-compartment body composition by hydrometry, and nuclear magnetic resonance scanning for abdominal adipose depots, intrahepatic lipids and skeletal intramyocellular lipids. Each child’s habitual nutrition and physical activity were also ascertained using multiple-pass 24-hr diet recalls and accelerometry respectively. Data collection was conducted pre and post a 12-week physical activity intervention which consisted of cardiorespiratory activity during instructor led sessions (60 mins, twice weekly) and family led sessions (>10 mins, 4 days/wk). There is no universally accepted definition of MetSyn in childhood. The International Diabetes Federation suggests that MetSyn should not be diagnosed in children aged 6 to < 10 years. Children can be identified to be at risk of MetSyn, however, based on waist circumference ≥90th percentile and family history1,2; all subjects in this study were at risk according to these criteria. Four definitions of paediatric MetSyn previously applied to a group of young, overweight Australian children3 were used to calculate the prevalence of MetSyn in the current sample and it was found to be 27-89% at baseline and 13-80% after the experimental intervention depending upon the definition used. Acanthosis nigricans and impaired glucose tolerance (IGT) were present in one female child. Post-intervention, IGT had resolved and the child was glucose tolerant. Habitual dietary intake (energy intake and macronutrients) measured over a 3-day period pre-intervention displayed a significant positive association between fasting glucose and energy intake, as well as a significant negative association between fasting glucose and the protein component of the diet. Following the physical activity programme, energy intake was significantly positively correlated with body fat percentage (% BF). There was no difference found in dietary intake assessed prior to and following cessation of the physical activity intervention, in terms of energy or % energy from macronutrients. Habitual physical activity was not related to MetSyn diagnostic indicators. A higher level of physical fitness, estimated by predicted O2max (ml•kg-1•min-1), was significantly correlated with a lower level of diastolic blood pressure at baseline. A greater fitness level ( O2max) was moderately correlated with a lower BMI Z-score following the 12-week intervention. There was no difference between pre- and post-intervention habitual physical activity. A trend towards less sedentary time and increased light intensity activity was found, but these did not reach significance. Physical fitness level showed a trend for improvement following the intervention (P = 0.060). Anthropometrically determined body composition and body fat distribution did not change following the intervention. Radiologically determined abdominal adipose tissue depots were not significantly different post-intervention. % BF was not different when assessed with bioelectrical impedance analysis. However, % BF did reduce significantly over the 12-week intervention period when quantified by hydrometry (42.3% ± 5.0 vs 36.9% ± 8.6, P = 0.022). Adipokines, the secretory products of adipocytes displaying pleiotropic metabolic action, were investigated for their relation to lipid depots and additionally for change post-intervention. Cardiovascular (CV) disease risk was investigated by proatherogenic and protective blood lipids. When examined at baseline, fasting blood triacylglycerols (TAG) were inversely associated with basal and stimulated insulin sensitivity. Post-intervention, a higher level of HDL-C was found to be associated with greater insulin sensitivity, although this was not apparent at baseline. The relation between TAG and insulin sensitivity discovered pre-intervention was no longer evident. All other biomarkers of CV risk were not associated with body composition, glucose homeostasis, and lifestyle factors pre- and post-intervention. The effect of the physical activity intervention on indicators of haemostasis, physical fitness, blood lipids and lipoproteins, systemic inflammation, and fibrinolytic activity were analysed for change. Both systolic and diastolic blood pressure were significantly reduced following the physical activity programme. There was no significant difference found in any other measured parameter of CV risk. Log[HOMA], a surrogate index of insulin resistance, was significantly decreased post-intervention indicating reduced insulin resistance. QUICKI, a surrogate index of insulin sensitivity, was significantly improved post-intervention. The remaining indicators of insulin resistance, insulin sensitivity and β-cell function based on fasting surrogates did not significantly change over the 12-week experimental period. Dynamic insulin sensitivity and β-cell function were investigated pre- and post-intervention using paired samples t-tests. Glucose and insulin area under the curve of the OGTT were significantly reduced and whole-body insulin sensitivity index (WBISI) was significantly increased hence showing an improvement in stimulated insulin sensitivity. AUCCP/AUCglu significantly declined also indicating an improved response to oral glucose stimulation. IGI and ΔCP30/ΔG30, as markers of β-cell insulin secretion, did not change. Disposition index, the interrelationship of insulin secretion (IGI) and insulin sensitivity (WBISI), was not changed pre- and post-intervention. Hepatic insulin extraction was increased post-intervention (4.3 ± 1.2 vs 4.8 ± 1.1, P = 0.022) possibly due to greater hepatic and/or peripheral insulin sensitivity. General linear modeling (GLM) showed the improvement in whole-body insulin sensitivity discovered following the intervention was independent of % BF, abdominal adipose tissue depots, and ectopic lipid depots. Intrahepatocellular lipids (IHCL) significantly decreased after the 12-week intervention (6.99% ± 9.41 vs 5.83% ± 8.54) whilst there was no significant change in the serum markers of liver inflammation. IHCL was positively and strongly associated with total abdominal adipose tissue, intra-abdominal adipose tissue and subcutaneous abdominal adipose tissue both before and after the intervention. IHCL was positively associated with %BF measured post-intervention; this relationship almost reached significance when measured pre-intervention (P = 0.060). IHCL was not associated with insulin sensitivity either pre- or post-intervention nor with circulating lipids at either timepoint. The change in IHCL was independent of % BF and abdominal adipose tissue tested by GLM. However, there was no significant difference found in IHCL post-intervention after adjustment for insulin sensitivity (WBISI) by GLM. Prior to intervention, 10 of 15 subjects had hepatic steatosis diagnostic of non-alcoholic fatty liver disease. Eight of the 10 subjects with clinically significant hepatic steatosis had reduction of fatty infiltrate following the exercise intervention. In the whole group it was demonstrated that physical activity attenuates lipid infiltration of the liver independent of body fat. To further investigate the pathophysiology of ectopic lipid depots, biomarkers of oxidative stress and anti-oxidant status were examined in relation to IHCL. Pre-intervention, there was no association found between pro-oxidative or anti-oxidative activity and IHCL. Post-intervention, an inverse association of plasma carotenoid:cholesterol ratio with IHCL was found. Skeletal intramyocellular lipids (IMCL) measured in the right soleus were significantly increased post-intervention (2.4 ± 1.1 vs 2.6 ± 1.2, P = 0.035). There was no association between IMCL and % BF when measured pre- or post-intervention. Abdominal adipose depots were associated with IMCL at baseline and following the intervention. IMCL was not related to IHCL at either timepoint. Pre-intervention, there was a trend for a relationship between IMCL and insulin. Post-intervention, IMCL was tightly and inversely correlated with insulin sensitivity (r = -0.85 P = 0.000). Linear regression between IMCL and WBISI run pre-intervention and post-intervention found the slopes were not significantly different whereas the intercepts were highly significantly different (P = 0.001), thus, as IMCL increased there was a corresponding decrease in insulin sensitivity. GLM found the increase in IMCL was independent of % BF and abdominal adipose tissue, but was not independent of WBISI. These data indicate the greater IMCL level found post-intervention was a non-pathologic training adaptation. To further investigate the pathophysiology of ectopic lipid depots, biomarkers of oxidative stress and anti-oxidant status were examined in relation to IMCL. Pre-intervention, there was a positive association between malondialdehyde and IMCL. Post-intervention, an inverse association was found between IMCL and both plasma total carotenoids and total carotenoid:free cholesterol ratio. In summation, this study found improved metabolic health in obese, prepubertal children following a 12-week physical activity intervention without dietary intervention or intentional weight loss. Body fat and fat distribution were not prime mediators for the effect of the intervention on parameters of the Metabolic Syndrome; whereas insulin sensitivity was discovered to be a mediator of the change shown in ectopic fat depots. Causality and directionality of these fascinating relationships cannot be determined from the present study, and further research is encouraged. This thesis offers an insight into the pathogenesis of MetSyn and the use of physical activity to improve MetSyn in the setting of paediatric obesity.

Identiferoai:union.ndltd.org:ADTP/279118
CreatorsLisa-Marie Atkin
Source SetsAustraliasian Digital Theses Program
Detected LanguageEnglish

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