UMLS:C0311277 - FACTA Search

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Query: UMLS:C0311277 (abdominal obesity)
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To investigate whether obese subjects with abdominal obesity may be characterized by hyperactivity of the hypothalamic-pituitary-adrenal axis, we examined two groups of obese women with a waist to hip ratio (WHR) lower than 0.80 (n = 13), therefore having peripheral body fat distribution (P-BFD), or a WHR higher than 0.85 (n = 12), thus having abdominal body fat distribution (A-BFD). A group of seven normal weight healthy women served as controls. All subjects underwent the following protocol study that included 1) measurement of daily urinary free cortisol excretion rate; 2) a CRF test (human CRF, 1 microgram/kg BW, as iv bolus), with blood samples taken at regular intervals for ACTH and cortisol determination; and 3) an ACTH test, performed by administering two boli of ACTH (Synacthen, 0.2 microgram/kg BW, iv), at 90-min intervals, with blood samples taken for cortisol determination. Each woman also had a control saline study. Basal levels of both ACTH and cortisol rose significantly after CRF administration in all groups, but this increase was significantly higher in A-BFD than in P-BFD and control women. A significant correlation was found between the incremental area of cortisol and that of ACTH during the CRF test (r = 0.502), but not between these parameters and WHR values. Although the cortisol increase after the ACTH test was higher in A-BFD than in the other groups, these differences were only significant at 60 min during the test and when the analysis for repeated measures was applied. On the contrary, the incremental cortisol area after the ACTH test was not significantly different in the three groups. Moreover, it was not significantly correlated with the incremental cortisol area after CRF test or WHR values. Daily urinary free cortisol excretion rates (per g creatinine), however, were significantly higher in A-BFD than in P-BFD and control women. These results, therefore, suggest that obese women with A-BFD may have hyperactivity of the hypothalamic-pituitary-adrenal axis. This abnormality could be central in origin, due to hypersecretion of CRF or ACTH; alternatively, it could represent an adaptive phenomenon secondary to a state of functional cortisol resistance.
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PMID:The hypothalamic-pituitary-adrenal axis in obese women with different patterns of body fat distribution. 834 38

The structure of a large neural system that responds to and regulates energy balance and that encompasses that PVN and activity of the HPA axis has begun to emerge from these experiments (Fig. 6). Several large loops have been delineated within this context of the maintenance of energy balance. Corticosteroids stimulate both feeding and insulin secretion. The actions of corticosteroids in the periphery are catabolic, causing mobilization of energy stores; their actions in the central nervous system are stimulatory to energy acquisition (food intake). By contrast, the action of insulin in the periphery is anabolic, causing energy storage; its action in the central nervous system is inhibitory to energy acquisition (food intake). At the level of the CNS, insulin inhibits and corticosteroids stimulate expression of NPY mRNA in the arcuate nuclei, and these actions may explain, in part, the reciprocal actions of the hormones on energy acquisition. Thus over the long term, stimulation of insulin secretion by corticosteroids tends to supply an automatic brake on the effects of corticosteroids on feeding. The neural system that controls energy balance and responds to the reciprocal signals of corticosterone and insulin also regulates responsivity to restraint stress in the HPA axis. The low-amplitude ACTH responses to restraint, corticosteroid feedback, and prior stress-induced facilitation that are observed under conditions of relative fasting in the PM can be produced in the AM by a 14-h, overnight fast. By contrast, NPY injected ivt stimulates identical ACTH responses in the AM in fed rats and in rats fasted overnight, suggesting that NPY acts to stimulate CRF secretion at a site closer to the PVN than the stress of restraint, which is filtered through the neural energy balance system. In the periphery, corticosteroids and insulin also have reciprocal effects on energy storage; effects that are opposite those exerted in the CNS on energy acquisition. Thus, together, the two hormones may be construed as a bihormonal system that regulates overall energy balance. Although under normal conditions this system is well designed to accomplish energy balance, and provides a mechanism by which total energy stores may be increased appropriately (e.g., prior to hibernation or migration), it seems probable that under conditions of chronic stress, this regulatory system may be maladaptive. Chronic stress and glucocorticoid treatment cause increases in mean daily concentrations of both corticosteroids and insulin. Increases in the absolute levels of both hormones, with the normal ratio between them maintained, results in remodeling of body energy stores-away from muscle stores and toward fat stores, particularly abdominal fat stores. It seems quite likely that some conditions of abdominal obesity in man may be explained, at least in part, by increased activity in the HPA axis. Because abdominal obesity is associated with cardiovascular diseases, these responses, when they persist, are clearly maladaptive. Exploration of the role and control of the HPA axis in and by the larger neural network that regulates energy balance has to date been instructive. Clearly this work has just begun and is primarily still at the level of phenomenology. However, once the phenomenology is understood, mechanistic work can be performed that will flesh out our understanding of this very large and physiologically essential system.
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PMID:The neural network that regulates energy balance is responsive to glucocorticoids and insulin and also regulates HPA axis responsivity at a site proximal to CRF neurons. 859 46

Certain differences in regional fat distribution might be explicable by subtle hyperactivity of the hypothalamic-pituitary-adrenal (HPA) axis. We examined prospectively PA function relative to abdominal obesity defined by waist-to-hip circumference ratio (WHR) in 71 normotensive men aged 30-55 years. Basal PA activity was assessed by measurements of serum cortisol and plasma corticotropin (ACTH) concentrations during the oral glucose tolerance test (OGTT). Functional activity was examined by dexamethasone suppression and ACTH stimulation tests; responses of 17-hydroxyprogesterone (17-OHP), 11-deoxycortisol (S), cortisol, dehydroepiandrosterone (DHEA), and androstenedione were determined. When the subjects were divided into tertiles for the WHR, the ratio of mean ACTH to mean cortisol during the OGTT was increased (p < 0.05), and the ratio of urinary cortisol to body-mass index was decreased (p < 0.01), whilst the net increments of cortisol (p < 0.05) and 17-OHP (p < 0.05) from 0 to 60 min, as well as the ratio of 17-OHP to S increments (p < 0.05) after ACTH were elevated in the highest vs lowest WHR tertile. The ratio of mean ACTH to mean cortisol (r = 0.495; p < 0.001) during the OGTT, the ratio of net 17-OHP to S increments (r = 0.404; p < 0.001), and the net DHEA (r = 0.276; p = 0.020) and 17-OHP (r = 0.336; p = 0.005) responses to ACTH at 60 min correlated with WHR. In multivariate analyses the ratio of mean ACTH to cortisol, cortisol response to ACTH, and the ratio of net 17-OHP to S increments were all significant predictors of WHR independent of smoking, physical activity, and BMI explaining 49.0% of the variance in WHR. Thus, abdominal obesity may be associated with decreased activity of adrenal 21-hydroxylase. Either obesity-related functional alteration of 21-hydroxylase activity or the high carrier prevalence of genetic defects of this enzyme may explain these findings.
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PMID:Pituitary-adrenocortical function in abdominal obesity of males: evidence for decreased 21-hydroxylase activity. 880 94

To investigate whether obese female subjects with abdominal obesity may have adrenal androgen hypersecretion, we examined two groups of women with abdominal (n = 12) and peripheral (n = 13) obesity (defined by body mass index and waist-to-hip ratio) and a group of seven healthy normal-weight women. All subjects underwent the following protocol study that included a) baseline determination of major adrenal androgens, b) an ACTH test, performed by administering two boli of ACTH (Synacthen, 0.2 microg/Kg BW, e.v.), at 90 min intervals, with blood samples taken for cortisol and androgens, c) an oral glucose tolerance test, performed by administering glucose (75 gr), with blood samples taken for glucose and insulin determination. Each woman also underwent a control saline study. We then investigated the relationships between basal and stimulated androgen levels, body weight and fat distribution and fasting and stimulated insulin levels. Although basal cortisol levels were similar, their increase (as AUC) after the ACTH test was higher in women with abdominal obesity than in the other groups. On the contrary, there were no significant differences in basal and stimulated serum levels of dehydroepiandrosterone, androstenedione and 17-hydroxyprogesterone among the three groups. Fasting and stimulated (as AUC) insulin levels were significantly higher (p < 0.05) in women with abdominal obesity than in those with peripheral obesity and controls. No significant correlation was present between basal and stimulated androgen levels and body mass index, the waist-to-hip ratio or basal and stimulated cortisol values. Therefore, our data indicate that adrenal androgen secretion following low-dose ACTH administration in premenopausal women does not seem to be a function of body fat mass, fat distribution and insulin levels, nor does it correlate with the capacity of the adrenal glands to secrete cortisol in both basal and stimulated conditions.
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PMID:Secretion of major adrenal androgens following ACTH administration in obese women with different body fat distribution. 956 54

Subjects with abdominal obesity are characterized by hyperactivity of the hypothalamic-pituitary-adrenal (HPA) axis, which leads to a condition of 'functional hypercortisolism'. This appears to be the result of two distinct mechanisms. The first, which appears to be central in origin, is characterized by altered ACTH pulsatile secretory dynamics and by hyper-responsiveness of the HPA axis to different neuropeptides and acute or chronic stress events and, possibly, to selected dietary factors. The other appears to be located in the periphery, specifically the liver and visceral adipose tissue, and is characterized by supranormal cortisol production, whose paracrine and systemic effects remain unclear. It is suggested that increased exposure to cortisol of the body may play a fundamental role not only in the development of increased fat in abdominal/visceral depots, but also in determining all metabolic abnormalities closely related to the abdominal obesity phenotype.
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PMID:Activity of the hypothalamic-pituitary-adrenal axis in different obesity phenotypes. 1099 8

We have previously shown that women with abdominal body fat distribution (A-BFD) have a hyperactive hypothalamic-pituitary-adrenal (HPA) axis. However, we did not consider the presence of anxiety and/or depression, common manifestations in obese subjects. Anxiety and depression may be associated with oversecretion of cortisol and could represent a confounding factor in the evaluation of the HPA axis in different obesity phenotypes. In this study nondepressed obese women with abdominal and peripheral (P-BFD) body fat distribution and a control lean group underwent a CRH/AVP stimulation test for ACTH and cortisol determinations. Moreover, all women underwent metabolic evaluation and had their urinary free cortisol (UFC) excretion measured. After the stimuli, ACTH and cortisol responded more in the A-BFD than in the P-BFD and control groups. A positive correlation was found between either ACTH area under the curve (r2 = 0.366; P = 0.003) or cortisol area under the curve (r2 = 0.378; P = 0.043) and the homeostasis insulin resistance index in all obese patients. Unexpectedly, A-BFD had significantly lower UFC per m2 values than P-BFD (P < 0.05). Lowered UFC excretion in the A-BFD group is in keeping with an increased cortisol clearance, which, in turn, may lead to HPA axis hyperactivity as an appropriate compensatory mechanism. On the other hand, other mechanisms, possibly central in origin, such as overdriving of the CRH-ACTH system to chronic environmental stress factors, may be involved in determining HPA overresponsiveness in abdominal obesity. In conclusion, this study suggests that women with the abdominal obesity phenotype are characterized by both central and peripheral alterations of the HPA axis activity.
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PMID:Abnormalities of the hypothalamic-pituitary-adrenal axis in nondepressed women with abdominal obesity and relations with insulin resistance: evidence for a central and a peripheral alteration. 1109 38

There is increasing evidence that the abdominal obesity phenotype may be associated with multiple alterations of the hypothalamic-pituitary-adrenocortical (HPA) axis activity in both sexes. Our hypothesis is that the lack of adequate cortisol suppression after the dexamethasone test may constitute an indirect marker of HPA axis hyperactivity in the presence of the abdominal obesity phenotype. A total of 34 normal-weight (13 men and 21 women) and 87 obese (36 men and 51 women), healthy, nondepressed subjects therefore underwent four different dexamethasone suppression tests randomly performed at varying intervals of at least 1 wk between each test. After a standard overnight 1-mg dexamethasone test, which served as a reference, three other tests were randomly performed at 1-wk intervals by administering 0.0035, 0.0070, and 0.015 mg oral dexamethasone per kilogram of body weight overnight. Blood samples were obtained for cortisol, ACTH, and dexamethasone. Results were analyzed separately in men and women as well as in normal-weight [body mass index (BMI) < or = 25 kg/m(2)] and overweight or obese (BMI > 25 kg/m(2)) subjects. The waist circumference and the waist to hip ratio (WHR) were used as markers of body fat distribution. After the standard 1-mg test, cortisol suppression was greater than 90% in all subjects. However, after each test, obese women had significantly higher values of percent cortisol and percent ACTH suppression than normal-weight women without any difference between obese and normal-weight men. Considering the response to the three variable-dose tests, a clear dose- response pattern (P < 0.001 for trend analysis) in percent cortisol and percent ACTH suppression was found in all subjects. After each test men had significantly higher dexamethasone levels than women, regardless of BMI. However, obese women, but not men, had significantly higher dexamethasone levels after each test than their normal-weight counterpart. Plasma dexamethasone concentrations were dose related (P < 0.001 for trend analysis) in all subjects, but the dose-related increase was significantly higher in normal-weight men than normal-weight women, whereas it was similar in obese subjects of both sexes. Stepwise multiple regression analysis revealed that both percent cortisol and percent ACTH variations were significantly and negatively influenced by dexamethasone levels, as well as by waist circumference values in men, and independently by BMI and waist circumference in women. However, in contrast to what has been found in men, a divergent contribution of BMI and waist circumference was found in women indicating that, with increasing waist values, a smaller suppression of the HPA axis was found with respect to that expected on the basis of BMI values. In conclusion, this study provides data of both physiological and physiopathological relevance. Overall, our data indicated that adjustment of the dexamethasone dose to body weight does not seem to substantially improve the sensitivity of the test, even in obese individuals, particularly when near-maximal doses are administered. However, this study demonstrated a highly significant effect of dexamethasone blood level concentrations on cortisol and ACTH suppression to low-dose dexamethasone tests. In addition, a significant effect of gender on postdexamethasone cortisol concentrations, suppression of the HPA axis, and dexamethasone levels were found, which may be dependent on related differences in both cortisol and dexamethasone metabolism. We showed that pituitary sensitivity to feedback inhibition by dexamethasone is preserved in obesity in both sexes even at low dosages. On the other hand, our data suggest that, at least in women, abdominal fat distribution may partially counteract the progressively greater suppressibility of the HPA axis that would be expected according to increasing BMI.
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PMID:Cortisol and ACTH response to oral dexamethasone in obesity and effects of sex, body fat distribution, and dexamethasone concentrations: a dose-response study. 1178 42

Obesity and starvation have opposing affects on normal physiology and are associated with adaptive changes in hormone secretion. The effects of obesity and starvation on thyroid hormone, GH, and cortisol secretion are summarized in Table 1. Although hypothyroidism is associated with some weight gain, surveys of obese individuals show that less than 10% are hypothyroid. Discrepancies have been reported in some studies, but in untreated obesity, total and free T4, total and free T3, TSH levels, and the TSH response to TRH are normal. Some reports suggest an increase in total T3 and decrease in rT3 induced by overfeeding. Treatment of obesity with hypocaloric diets causes changes in thyroid function that resemble sick euthyroid syndrome. Changes consist of a decrease in total T4 and total and free T3 with a corresponding increase in rT3. untreated obesity is also associated with low GH levels; however, levels of IGF-1 are normal. GH-binding protein levels are increased and the GH response to GHRH is decreased. These changes are reversed by drastic weight reduction. Cortisol levels are abnormal in people with abdominal obesity who exhibit an increase in urinary free cortisol but exhibit normal or decreased serum cortisol and normal ACTH levels. These changes are explained by an increase in cortisol clearance. There is also an increased response to CRH. Treatment of obesity with very low calorie diets causes a decrease in serum cortisol explained by a decrease in cortisol-binding proteins. The increase in cortisol secretion seen in patients with abdominal obesity may contribute to the metabolic syndrome (insulin resistance, glucose intolerance, dyslipidemia, and hypertension). States of chronic starvation such as seen in anorexia nervosa are also associated with changes in thyroid hormone, GH, and cortisol secretion. There is a decrease in total and free T4 and T3, and an increase in rT3 similar to findings in sick euthyroid syndrome. The TSH response to TRH is diminished and, in severe cases, thyroid-binding protein levels are decreased. In regards to GH, there is an increase in GH secretion with a decrease in IGF-1 levels. GH responses to GHRH are increased. The [table: see text] changes in cortisol secretion in patients with anorexia nervosa resemble depression. They present with increased urinary free cortisol and serum cortisol levels but without changes in ACTH levels. In contrast to the findings observed in obesity, the ACTH response to CRH is suppressed, suggesting an increased secretion of CRH. The endocrine changes observed in obesity and starvation may complicate the diagnosis of primary endocrine diseases. The increase in cortisol secretion in obesity needs to be distinguished from Cushing's syndrome, the decrease in thyroid hormone levels in anorexia nervosa needs to be distinguished from secondary hypothyroidism, and the increase in cortisol secretion observed in anorexia nervosa requires a differential diagnosis with primary depressive disorder.
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PMID:Effect of obesity and starvation on thyroid hormone, growth hormone, and cortisol secretion. 1205 88

Reduction in both spontaneous and stimulated GH secretion in obesity has been clearly demonstrated. Mild hyperactivity of hypothalamus-pituitary-adrenal (HPA) axis has been also reported. Glucagon, at least after im administration, induces clear increase in either GH or ACTH and F levels but its effect on somatotroph and corticotroph secretion in obesity has never been studied. In 7 patients with abdominal obesity (OB, aged 24-42 yr, BMI: 29.1-43.9 kg/m2, waist/hip ratio [WHR]: 0.86-1.00) we studied the GH, ACTH and F responses to the im administration of glucagon (0.017 mg/kg at 0 min). The results in OB were compared with those in a group of 6 age-matched controls normal subjects (Ns aged 26-32 yr, BMI 19.7-22.5 kg/m2). In Ns glucagon administration induced clear increase in GH (peak vs baseline, mean+/-SE: 11.6+/-3.4 vs 3.3+/-0.7 microg/l, p<0.02), and ACTH (52.9+/-15.2 vs 19.0+/-1.5 pg/ml, p<0.02) levels which peaked at +150 and +165 min, respectively. Increase in F levels (222.3+/-23.8 vs 158.3+/-7.0 ng/ml, p<0.05) was also recorded but peaked at +180 min. In OB glucagon administration induced GH response (7.4+/-2.3 vs 0.8+/-0.6 microg/l) lower (p<0.05) than that recorded in Ns; when the GH responses were evaluated by co-variance analysis, a significant difference between the 2 groups was recorded in term of peaks but not of AUCs. On the other hand, the ACTH response to glucagon in OB was higher than that in Ns (11452.6+/-2447.7 vs 4892.2+/-719.4 pg/ml x min, p<0.05). The F response to glucagon in OB and Ns was, however, similar (24057.9+/-4109.1 vs 29835.9+/-1566.0 ng/ml x min). In conclusion, this study demonstrates that in obese patients the im administration of glucagon elicits blunted GH response but exaggerated ACTH increase which is uncoupled with the adrenal response. These findings agree with the existence of concomitant GH insufficiency and altered corticotroph function in obesity.
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PMID:Glucagon administration elicits blunted GH but exaggerated ACTH response in obesity. 1210 28

Subjects with abdominal obesity are characterized by hyperactivation of the hypothalamic-pituitary-adrenal (HPA) axis. Food intake, particularly at noon, is a well-known inducer of HPA axis activation. Whether obese subjects present an abnormal response to meals containing different macronutrient proportions is at present unknown. Therefore, this study was carried out to investigate the effect of a high-lipid/protein meal (HLP-meal) and a high-carbohydrate meal (HCHO-meal) on the HPA axis activity in women with different obesity phenotypes. Nondepressed, noncomplicated obese (body mass index greater than 28 kg/m(2)) women with abdominal (A-BFD) (n = 10) and peripheral body fat distribution (P-BFD) (n = 9) and a group of 11 normal-weight controls were investigated in the follicular phase of the menstrual cycle. They were randomly given an 800-kcal HCHO-meal (containing 89% carbohydrates, 11% proteins, 0% lipids), and an 800-kcal HLP-meal (containing 53% lipids, 43% proteins, 4% carbohydrates), which were eaten within 15 min at noon, with an interval of 2 d between each meal. Blood samples for ACTH, cortisol, glucose, and insulin were obtained at 15-min intervals before and after each meal. Baseline hormone and glucose concentrations in the three groups were similar. After the HLP-meal, ACTH tended to similarly but insignificantly increase in all groups, whereas cortisol increased significantly (P < 0.05) in the P-BFD group and insignificantly in the other groups. Conversely, both ACTH and cortisol significantly (P < 0.05) increased only in the A-BFD group, without any significant changes in both controls and P-BFD women. The analysis of the interaction between meals and groups clearly indicated that the cortisol response to the HLP-meal and the HCHO-meal was significantly different (P < 0.025) between the two obese groups, the A-BFD group being characterized by a significantly lower response to the HLP-meal and a significantly higher response to the HCHO-meal, compared with the P-BFD group. Considering all groups together and after adjusting for body mass index, a highly significant relationship was found between cortisol-area under the curve and ACTH-area under the curve after each meal test. However, no relationships were found between changes in ACTH and cortisol and those of glucose, insulin, and the glucose:insulin ratio after each meal. Therefore, our data demonstrate that the response of the HPA axis to meals containing different macronutrient proportions may depend on the pattern of body fat distribution. We also suggest that the activation of the HPA axis following the ingestion of large amounts of carbohydrates may have some pathophysiological relevance, specifically in women with the abdominal obesity phenotype.
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PMID:Comment: response of the hypothalamic-pituitary-adrenocortical axis to high-protein/fat and high-carbohydrate meals in women with different obesity phenotypes. 1216 47

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