The natural history of the metabolic syndrome in young women with the polycystic ovary syndrome and the effect of long-term oestrogen-progestagen treatment.

OBJECTIVE: Little is known about the natural history of polycystic ovary syndrome (PCOS), although preliminary data indicate that affected women are more susceptible than the general population to diabetes and cardiovascular diseases at post-menopausal ages. The aim of this study was to follow-up all main features of the metabolic syndrome in a group of young women with PCOS and to investigate the long-term effects on metabolism and body composition of oestrogen-progestagen (OP) compounds, which are frequently used in these women to treat hyperandrogenism and related clinical features. DESIGN: Long-term follow-up study. SUBJECTS AND METHODS: Thirty-seven women with PCOS were re-evaluated 10.3 +/- 0.8 years (range 6-18 years) after their first assessments (age: before 19.8 +/- 4.9 years; after 29.9 +/- 4.4 years). When first examined, women were instructed to follow a hypocaloric diet if they were obese plus OP, if they agreed to such treatment. Main anthropometric parameters, basal sex hormones and lipids, fasting and glucose-stimulated glucose and insulin levels and several clinical data were recorded before and after follow-up. RESULTS: In the whole group of women with PCOS we found no changes in body weight and fat mass, whereas both the waist-to-hip ratio and the waist-to-thigh ratio were significantly reduced. No significant changes occurred in mean fasting and glucose-stimulated glucose and insulin concentrations, whereas a significant increase in high-density lipoprotein-cholesterol was found. No significant changes occurred in testosterone levels. During the follow-up period 16 women took OP for an average of 97 +/- 18 months (range 12-180 months) (OP-users) whereas 21 women never took OP (non-OP-users). All OP-users were still taking OP when re-evaluated at the follow-up examination. With respect to baseline values, body mass index was higher in non-OP-users than in their counterparts. Waist circumference (P < 0.025), the waist-to-hip (P < 0.05) and the waist-to-thigh (P < 0.01) ratios decreased significantly only in the OP-users. In addition, percentage changes in waist circumference (P < 0.05) and waist-to-hip ratio (P < 0.05) during the follow-up period were significantly different between the groups. Glucose tolerance (as area under the curve (AUC)) improved (P < 0.05) in OP-users but not in non-OP-users. Moreover, compared to baseline values, basal insulin levels were significantly (P < 0.01) reduced in OP-users but not in non-OP-users. On the contrary, no significant change was found in insulinAUC in the former, whereas it significantly increased (P < 0.05) in the latter. Accordingly, fasting C-peptide decreased (P < 0.05) in OP-users, whereas both fasting (P < 0.01) and stimulated (P < 0.01) C-peptide significantly increased in non-OP-users. Changes in fasting or stimulated insulin and C-peptide in non-OP-users were not associated with parallel changes in testosterone levels. Total cholesterol and triglycerides did not change in either group, but HDL-cholesterol increased (P < 0.05) only in OP-users. Sex hormone-binding globulin concentrations increased significantly (P < 0.01) in OP-users, without any significant change in non-OP-users. Testosterone concentrations did not change significantly in either group, but the testosterone: SHBG ratio significantly decreased in OP-users (P < 0.05) but not in the non-OP-users. Among the clinical features, acanthosis nigricans significantly (P < 0.01) worsened in non-OP-users but not in the OP-users, without any significant change in the hirsutism and acne scores. Pregnancy rates during the follow-up were similar in both groups. CONCLUSIONS: These data indicate that hyperinsulinaemia and insulin resistance tended to worsen spontaneously in women with PCOS, without any worsening of the hyperandrogenism. Long-term oestrogen-progestagen treatment countered this tendency, probably because it improved the pattern of body fat distribution, by reducing abdominal fat depots.

ACTH and cortisol response to combined corticotropin releasing hormone-arginine vasopressin stimulation in obese males and its relationship to body weight, fat distribution and parameters of the metabolic syndrome.

OBJECTIVES: To investigate the activity of the hypothalamic-pituitary-adrenal (HPA) axis in male obesity and its relationship with several prominent parameters of the metabolic syndrome. DESIGN: A cross-sectional clinical study of the activity of the HPA axis in groups of obese males and normal-weight controls. SUBJECTS: Seventeen obese non-diabetic males with a body mass index (BMI) >28 and eight normal-weight controls were examined. MEASUREMENTS: Fat free mass (FFM) and fat mass (FM) were measured by bioelectrical impedance, and the waist-to-hip circumference ratio (WHR) was calculated in all subjects. Baseline samples were taken for sex hormone and lipid determination, and an oral glucose tolerance test (OGTT) was performed for glucose and insulin determination. The activity of the HPA axis was determined by the combined administration of human corticotropin releasing hormone (CRH) (100 microg) and arginine vasopressin (AVP) (0.3 IU). RESULTS: As expected, FFM and FM and the WHR were higher in obese men than in controls, as were fasting insulin and stimulated (as area under the curve (AUC)) glucose and insulin concentrations. Baseline adrenocorticotropin (ACTH) and cortisol concentrations were similar in both groups, but stimulated (as AUC), ACTH was higher (P < 0.05) in obese subjects than in controls, whereas no significant difference in cortisolAUC was present. Since the main differences between obese subjects and controls were present during the early 30 min of the test, the correlation coefficients between total and incremental ACTH(AUC 0-30 min) and CortisolAUC 0-30 min and all other variables were analyzed. A significant correlation coefficient was present between them and all anthropometric parameters, fasting insulin and insulinAUC, but not with androgens and gonadotrophins. In addition, a significant correlation was present between total and incremental ACTH(AUC 0-30 min) and triglyceride concentrations. However, after adjusting for BMI or FM values, all correlation coefficients became non-significant, except the one between incremental ACTH(AUC 0-30 min) and insulinAUC (P < 0.05). CONCLUSION: These findings indicate that obese men may also have an altered pituitary response to combined CRH/AVP stimulation, which appears to be predominantly related to body size and total body fat. ACTH hyperresponsiveness after CRH/AVP stimulation also appears to be related to hyperinsulinaemia, but underlying mechanisms of this relationship remain to be elucidated.

Serum leptin in obese women with polycystic ovary syndrome is correlated with body weight and fat distribution but not with androgen and insulin levels.

Leptin is a hormone produced in the adipose tissue and its concentrations in peripheral blood are significantly correlated with the amount of body fat. Whether other factors, including the pattern of body fat distribution and several hormones (such as insulin, sex steroids, and glucocorticoids), may be involved in the regulation of circulating blood leptin levels is controversial. Women with the polycystic ovary syndrome (PCOS) are hyperandrogenic and most of them are characterized by hyperinsulinemia, insulin resistance, and obesity, particularly the visceral phenotype. To assess the potential contribution of anthropometric factors, androgens, and insulin in determining leptin levels, we examined their relationship with body-mass index (BMI), visceral (VAT) and subcutaneous (SAT) adipose tissue areas, basal androgen levels, and fasting and glucose-stimulated (AUC) insulin in different groups of obese women with PCOS (n = 23) and of age-matched obese (n = 16) and non-obese (n = 10) otherwise healthy controls. The VAT/SAT ratio was measured as a parameter of body fat distribution. Serum leptin levels were significantly higher in obese PCOS women than in obese and normal-weight healthy controls and, within the controls, in the obese than in the non-obese group. In all women considered together, and in each group separately, leptin concentrations were highly significantly correlated with BMI. In addition, after adjusting for BMI, both VAT and the VAT/SAT ratio were positively and significantly correlated with leptin. Partial correlations with the VAT/SAT ratio remained significant in both the obese PCOS group and in controls considered separately, whereas the correlation with the SAT value was significant only in the control group. After adjusting for BMI, no correlation between leptin, androgens and fasting or stimulated (like AUC) insulin was found. These findings indicate that leptin levels in obese women with PCOS are higher than those observed in obese and non-obese controls. Moreover, they suggest that, other than BMI, the pattern of body fat distribution may be an independent factor related to circulating leptin levels, which, on the contrary, do not appear to be related to either androgen or insulin concentrations.

Pulsatile secretion of ACTH and cortisol in premenopausal women: effect of obesity and body fat distribution.

OBJECTIVE: There is emerging evidence that women with visceral obesity may have hyper-responsiveness of the hypothalamic-pituitary-adrenal axis. There are no studies on basal daily secretory pattern of ACTH and cortisol in subjects with different obesity phenotypes. DESIGN AND PATIENTS: In this study we examined daytime pulsatile secretion of ACTH and cortisol in two groups of premenopausal obese women with visceral (V-BFD) (BMI 37.1 +/- 1.7) and subcutaneous (S-BFD) (BMI 38.8 +/- 1.5) body fat distribution (measured by CT scan) and in a group of normal weight healthy controls (BMI 21.1 +/- 0.5). After an overnight fast, blood samples were taken at 15-minute intervals for 12 h (49 samples, from 0800 h until 2000 h). All women avoided breakfast but had a normal lunch and dinner, both containing similar food, energy and nutrient composition. ACTH and cortisol responses to mixed meals at noon and in the evening were also investigated. RESULTS: Mean values of ACTH and cortisol did not differ between the groups. However, ACTH pulse frequency was significantly higher in V-BFD (P < 0.06) and S-BFD (P < 0.02) obese women than in controls, without any significant differences between the two obese subgroups. Mean ACTH pulse amplitude was lower in the V-BFD than in S-BFD obese (P < 0.02) and control (P < 0.05) groups. Cortisol episodic characteristics did not differ between V-BFD and S-BFD obese and controls. All differences in ACTH pulsatile parameters between obese and controls and between the two obese subgroups were evident only in the morning, with no further significant differences during the early and late afternoon. There were no significant differences in cortisol parameters during the three periods of the day between the various groups, apart from late afternoon cortisol pulse frequencies, which were significantly lower in V-BFD than in controls. After lunch, ACTH and cortisol levels significantly increased in all groups, but the cortisol increase tended to be more rapid in V-BFD than in the other two groups. After dinner, ACTH significantly increased in V-BFD and controls but not in the S-BFD group, whereas cortisol rose significantly in all groups, but significantly less in S-BFD than in V-BFD and controls. CortisolAUC (but not ACTHAUC) after lunch was significantly higher than after dinner in all groups. ACTH response after each meal was similar in all groups, but cortisolAUC after dinner was significantly lower in S-BFD than in V-BFD women. CONCLUSION: This study demonstrates that in premenopausal women, obesity, particularly the visceral phenotype, is associated with several abnormalities of ACTH pulsatile secretion, particularly in the morning. On the contrary, no major differences were present in either blood concentrations, diurnal rhythm or secretory pattern of cortisol between obese and controls. The responses to meals seem to indicate a much more rapid cortisol response after lunch in women with visceral obesity and a reduced activation of the hypothalamic-pituitary-adrenal axis after dinner in women with subcutaneous obesity.

Secretion of major adrenal androgens following ACTH administration in obese women with different body fat distribution.

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.

Weight control and its beneficial effect on fertility in women with obesity and polycystic ovary syndrome.

Obesity may be an important pathogenetic factor involved in the development of hyper-androgenism in women with polycystic ovary syndrome (PCOS). Among several other mechanisms, hyperinsulinaemia plays a fundamental role, due to its gonadotrophic function, which has been demonstrated both in vitro and in vivo. Therefore, not surprisingly, weight loss may be expected to have several beneficial effects upon clinical, endocrinological and metabolic features of obese women presenting both PCOS. In particular, weight loss appears to be associated with a significant improvement in menses abnormalities, ovulation and fertility rates, and with a reduction of hyperandrogenism, hyperinsulinaemia, and altered gonadotrophin pulsatile secretion. The central role of improved insulin concentrations and insulin-resistant state is emphasized by the fact that similar effects can be achieved by both short- and long-term administration of metformin, an insulin-lowering drug which ameliorates peripheral insulin action in non-diabetic insulin resistant states. We therefore recommend weight loss as a first-line therapeutic option in all women with obesity and PCOS.

Effects of acute hyperinsulinemia on testosterone serum concentrations in adult obese and normal-weight men.

In a previous study performed in adult obese and normal-weight male subjects, we found that suppression of insulin levels by diazoxide reduced testosterone and increased sex hormone-binding globulin (SHBG) blood concentrations. These and other data suggested that insulin may have a regulatory capacity in testosterone secretion and/or metabolism in men, similar to what has already been demonstrated in women. In this study, we investigated the effects of acute hyperinsulinemia on major androgen levels, including testosterone, in two groups of normal-weight in = 11) and obese (n = 9) men. Acute hyperinsulinemia was obtained by the euglycemic-hyperinsulinemic clamp technique. Relationships between the degree of insulin resistance (ie, total glucose disposal [M value]) and testosterone levels were also evaluated. Basal testosterone levels in obese subjects (10.40 +/- 3.02 nmol/L) were significantly lower than in normal-weight controls (15.50 +/- 4.65 nmol/L, P < .01), whereas no difference was present in androstenedione and dehydroepiandrosterone sulfate (DHEA-S) concentrations. During the clamp study, testosterone was significantly increased in the obese group (11.79 +/- 3.64 nmol/L, P < .05) but not in the control group (15.81 +/- 4.54 nmol/L, P = NS). The other two androgens did not significantly change in either the obese or control group. There was a highly significant correlation between baseline testosterone concentrations, with M values suggesting a relationship between impaired peripheral insulin sensitivity and reduced plasma testosterone concentrations. It should be pointed out that there was a certain discrepancy in the testosterone variations, particularly in the control group, in which two thirds of the subjects had no change or some decrease in testosterone levels, whereas in the remainder testosterone increased over the values of the assay variation coefficient. These findings are consistent with the hypothesis that insulin may regulate testosterone blood levels also in male subjects. Whether these effects are primarily due to increased hormone secretion or reduced clearance needs to be investigated.

Influence of menopause on blood cholesterol levels in women: the role of body composition, fat distribution and hormonal milieu. Virgilio Menopause Health Group.

OBJECTIVES: In this study we investigated the relationships between blood lipids and menopausal status. SETTING AND SUBJECTS: All data were obtained from the first cross-sectional examination of the Virgilio Menopause Health Project in a large cohort of middle-aged women in pre, peri-, and postmenopausal age. The data refer to 426 women without metabolic or endocrine diseases, relevant hepatic, renal and cardiovascular abnormalities, none were dieting or taking medications. MAIN OUTCOME MEASURES: A precoded questionnaire including full clinical history, socio-economic and personal information, habitual diet, physical activity, drug use and smoking habits, careful recording of gynaecological events and family history for disease was completed. Several anthropometric parameters and the bioelectrical impedance analysis was used to measure free fatty mass. Blood samples for hormones and biochemistry were also obtained. RESULTS: There were no significant differences on body mass index, fatty mass, free fatty mass and parameters of body fat distribution between the three groups. Again, there were no differences in smoking habits, dietary intake or indices of physical activity amongst the groups. There was a significant increase from pre to postmenopause of LH and FSH and a decrease of oestradiol and testosterone, whereas no difference was found in sex hormone-binding globulin. Age-adjusted values of glucose, triglycerides and high density lipoprotein (HDL-) cholesterol were similar in all groups, whereas postmenopausal women had significantly higher values of total and low density lipoprotein (LDL-) cholesterol. On the contrary, there was a significant fall in insulin levels passing from pre to postmenopause. In multiple regression models, total and LDL-cholesterol correlated positively with body mass index, waist-to-hip ratio and age, and negatively with free fatty mass and oestradiol blood levels. CONCLUSIONS: These results are consistent with the hypothesis that menopausal status may have a significant and independent effect in determining increased total and LDL-cholesterol concentrations in postmenopausal women.

Achievement of near-normal body weight as the prerequisite to normalize sex hormone-binding globulin concentrations in massively obese men.

OBJECTIVE: To investigate the effects of weight loss on sex hormone-binding globulin (SHBG) in massively obese males and whether normal SHBG concentrations could be obtained regardless or not of the achievement of normal body weight values. DESIGN AND SUBJECTS: Sera were collected for SHBG determination from 63 massively obese men, partly before they underwent biliopancreatic diversion (pre-op group = 11) and partly during the post-surgical follow up (post-op group = 52), and twenty normal weight healthy control men. MEASUREMENTS: Serum SHBG was measured using a noncompetitive liquid-phase immunoradiometric assay. RESULTS: Baseline general characteristics were similar in both obese groups. Obese patients in the post-op group had lost 46.4 +/- 2.9 kg since they had undergone operation, namely during a mean period of 14.9 +/- 13.8 (range 1-58) months follow up. Obese groups had significantly lower SHBG than normal weight controls (66.2 +/- 18.6 nmol/l). However, pre-op obese (19.9 +/- 5.5 nmol/l) had significantly lower values than post-op obese subjects (45.5 +/- 24.8 nmol/l; P < 0.001). There were a highly significant correlation between SHBG and individual BMI values (r = -0.629; P < 0.001). Moreover, the post-op obese with BMI values lower or equal to 28 had significantly higher SHBG concentrations than those with BMI greater than 28 (62.8 +/- 22.2 nmol/l vs 32.1 +/- 19.6 nmol/l; P < 0.001), but not significantly different with respect to normal weight controls. CONCLUSIONS: Massively obese men weight loss can completely reverse SHBG abnormalities, which can be restored to the normal range when near-normal body weight is achieved. Since reduced SHBG concentrations can be an independent risk factor for the development of diabetes and cardiovascular disease, this represents an additional benefit of weight loss program in massively obese individuals.

Determinants of sex hormone-binding globulin blood concentrations in premenopausal and postmenopausal women with different estrogen status. Virgilio-Menopause-Health Group.

In women, sex hormone-binding globulin (SHBG) concentrations are the result of a balanced effect of stimulatory and inhibitory factors. Estrogens represent the principal stimulatory hormones, whereas androgens, insulin, excess body fat, and the pattern of body fat distribution have inhibitory effects. Menopause is characterized by major changes in blood sex steroid concentrations, notably a marked reduction of estradiol levels. In this study, we therefore investigated the relationship between hormonal and nonhormonal regulatory factors of SHBG and its blood levels in two groups of premenopausal and postmenopausal women characterized by normal-high or reduced estrogen concentrations. The data were obtained from an analysis of the cross-sectional database obtained during the first survey of the Virgilio-Menopause-Health Project, an epidemiologic longitudinal study aimed at investigating the impact of menopause on body weight, fat distribution, and related major metabolic, hormonal, and cardiovascular risk factors. A total of 329 women, 133 in premenopause and 196 in postmenopause without diabetes, thyroid diseases, or relevant cardiovascular, renal, and hepatic dysfunction, were included in the study. A clinical history (including dietary and physical-activity habits), anthropometry (body mass index [BMI], waist to hip ratio [WHR], and bioelectrical impedance analysis [BIA]), and morning blood samples in the fasting state for sex hormones, insulin, and biochemistry were available for all the women. Premenopausal and postmenopausal women showed no significant difference in SHBG concentrations (38.7 +/- 17.9 v 36.6 +/- 17.5 nmol/L, respectively). On the contrary, postmenopausal women were characterized by a marked reduction of estradiol levels and significantly lower levels of testosterone. After adjusting for age, insulin was lower and the glucose to insulin ratio was higher in postmenopause than in premenopause. Age-adjusted values for all anthropometric parameters were not significantly different in the two groups. In simple correlation models, SHBG was significantly and negatively correlated with BMI, WHR, and insulin and testosterone levels in both premenopausal and postmenopausal women, whereas estradiol levels correlated positively and significantly with SHBG only in the premenopausal group. A significant positive correlation between the glucose to insulin ratio and SHBG was present in both groups. Using multiple regression models, in the premenopausal group, SHBG levels were correlated positively with estradiol and negatively with testosterone and insulin, but not with the WHR. On the contrary, in the postmenopausal group, SHBG values had a significant negative correlation with the WHR, whereas the relationship with estradiol was not significant; moreover, the relationship with testosterone and insulin, although significant, became less marked. In conclusion, this study indicates that (1) there is no significant difference in SHBG blood concentrations between premenopause and postmenopause; (2) SHBG values are correlated positively with estradiol and negatively with insulin and testosterone concentrations, but the predictive value of these variabiles on SHBG appears to be different in premenopause and postmenopause; and (3) SHBG levels decrease with increasing WHRs, particularly in the postmenopausal group. Therefore, determinants of SHBG blood concentrations are likely to change on passing from premenopausal to postmenopausal status. In particular, there seems to be a threshold level for which estradiol is an important determinant of SHBG blood concentrations.

Hypothalamic-pituitary-adrenal axis activity and its relationship to the autonomic nervous system in women with visceral and subcutaneous obesity: effects of the corticotropin-releasing factor/arginine-vasopressin test and of stress.

In a previous study, we demonstrated that premenopausal women with visceral obesity have hyperactivity of the hypothalamic-pituitary-adrenal (HPA) axis, characterized by an exaggerated hormone response to corticotropin-releasing factor (CRF) and corticotropin (ACTH) stimulation. The hypothalamic peptide flow that stimulates the pituitary, particularly after a physiological stress challenge, involves not only CRF, but also arginine-vasopressin (AVP), which synergizes the CRF capacity to stimulate pituitary hormone secretion. Previous studies in humans have demonstrated that combining AVP with CRF permits maximal stimulation of the pituitary, providing a more appropriate method of assessing pituitary hormone reserve. We therefore investigated the response of the HPA axis to combined CRF and AVP stimuli in obese women with different obesity phenotypes. Moreover, we examined hormonal and cardiovascular responses to several mental stress tasks, according to previously standardized procedures. Two groups of age-matched premenopausal eumenorrheic obese women with visceral (V-BFD) or subcutaneous (S-BFD) body fat distribution and a group of normal-weight healthy controls were investigated. All women randomly underwent the following protocol: (1) a combined CRF/AVP test (100 micrograms plus 0.3 IU intravenously [IV], respectively); (2) a standardized stress test, which consisted of completing two puzzles and a mental arithmetic test; and (3) a control saline test. Blood samples for ACTH and cortisol determinations were obtained before and during each test, and measurements of arterial blood pressure and pulse rate were made at regular intervals during the stress test. After combined CRF/AVP administration, ACTH and cortisol were significantly higher in V-BFD than in the other two groups. In contrast, no significant hormonal variation was found in either group during stress tasks. During the stress test, pulse rate (but not arterial blood pressure) significantly increased after 8 and 15 minutes in the V-BFD group, whereas no significant variation was found in S-BFD and control women. A significant correlation was present between the pulse rate and change in cortisol level during the stress test at minutes 8 (r=.54, P<.05) and 15 (r=.57, p<.01) in all women considered together. Subjective emotional involvement during stressful tasks was measured by a two-dimensional short verbal scale, which revealed that the stress section had a more significant impact in obese V-BFD than in S-BFD and control women. These data therefore confirm that women with visceral obesity have hyperactivity of the HPA axis, and that the combined CRF/AVP stimulation may offer a good tool for investigating pituitary reserve in this obesity phenotype. Moreover, the results indicate that these women probably have a hyperreactive sympathetic response to acute stress that seems interrelated to that of the HPA axis.

Nitrendipine treatment in women with polycystic ovarian syndrome: evidence for a lack of effects of calcium channel blockers on insulin, androgens, and sex hormone-binding globulin.

It has been shown that in vitro calcium channel blockers may regulate insulin secretion, and in vivo studies have demonstrated that they can reduce the degree of hyperinsulinemia and ameliorate the insulin-resistant state in subjects (particularly men) with obesity and hypertension. It is also commonly accepted that hyperinsulinemia may be an important factor responsible for the development of hyperandrogenism in obese women with polycystic ovarian syndrome (PCOS). We, therefore, investigated whether the administration of nitrendipine, a widely used calcium channel blocker, may improve both insulin levels and hyperandrogenism in a group of seven insulin-resistant hyperinsulinemic women with obesity and PCOS. They were treated for 7-8 days with oral nitrendipine (10 mg, twice daily) or placebo using a double blind, cross-over design. Before and after treatment, blood samples were obtained for androgen and sex hormone-binding globulin determinations, and an oral glucose tolerance test was performed, measuring glucose and insulin. Both nitrendipine and placebo failed to decrease basal and stimulated insulin levels. Moreover, no significant variations in testosterone, dehydroepiandrosterone sulfate, or sex hormone-binding globulin concentrations were observed after either treatment. Therefore, these data fail to support previous suggestions that calcium channel blockers may play a role in the treatment of hyperandrogenism and hyperinsulinemia in obese women with PCOS.

Insulin regulates testosterone and sex hormone-binding globulin concentrations in adult normal weight and obese men.

There are no studies in vivo on the effects of insulin on androgens and sex hormone-binding globulin (SHBG) in men. We, therefore, investigated the effects of insulin suppression on testosterone and SHBG in two groups of eight nondiabetic adult obese men and six healthy normal weight men who underwent diazoxide treatment (100 mg, three times daily) for 7 days. Blood samples for hormone determination were obtained before the subjects had been selected for the study, immediately before diazoxide administration, and on the last day of treatment. A 24-h oral glucose tolerance test was also performed for glucose, insulin, and C-peptide determinations before and on the last day of treatment. Only one subject experienced significant side-effects, and no significant changes in mean body weight were found during the treatment. Diazoxide administration worsened glucose tolerance in several subjects and reduced fasting and glucose-stimulated insulin levels by approximately 50% in both control and obese subjects. No significant difference was present between historical and pretreatment hormone values in either group. Moreover, there were no differences in pretreatment gonadotropin and SHBG concentrations between the two groups, whereas testosterone (free and total) levels were lower in the obese than in the control subjects. After diazoxide administration, testosterone (free and total) decreased slightly, but significantly, whereas LH and SHBG significantly increased in both groups. Diazoxide treatment increased estradiol levels in controls, but not in obese men. In conclusion, these results indicate that in vivo, insulin is capable of stimulating testosterone production and, simultaneously, of inhibiting SHBG concentrations in both normal weight and obese men.

Body weight, fat distribution and the menopausal status in women. The VMH Collaborative Group.

Since sex hormones are involved in the regulation of body composition and adipose tissue metabolism, in this study we investigated whether menopause may alter body weight and fat distribution in women. Data were obtained from the Virgilio-Menopause-Health Study, which is a longitudinal epidemiological project aimed at investigating the relationship between menopause and related plasma hormonal concentrations, body weight, fat distribution and health. Only data from the first cross-sectional examination are presented. Out of the 952 women living in the town of Virgilio, Mantua (Italy) and born between January 1st, 1932 and December 31st, 1946, 596 (62.6%) participated in the study. Since incomplete data were present in 19 women, 577 was the final sample size available for statistical analysis. The protocol included a collection of blood for hormones and biochemistry, a full clinical history with socioeconomic and personal information, drug use, smoking, dietary and physical activity habits, and several anthropometric measurements. According to the clinical and hormonal status, 160 women were classified as pre-menopausal, 124 as peri-menopausal and 293 as post-menopausal. After adjusting for age, we found that body mass index (BMI) was significantly higher in peri-menopausal than in pre-menopausal women and remained slightly, but again significantly, higher in post-menopausal women. Although waist-to-hip and waist-to-thigh ratios increased significantly and progressively from pre- to post-menopause, any difference was not significant after adjusting for age. Diet, physical activity and smoking habits did not explain the difference in BMI values. No difference was found in the use of estro-progestagen compounds between the groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Body fat distribution has weight-independent effects on clinical, hormonal, and metabolic features of women with polycystic ovary syndrome.

This study was performed to investigate whether different patterns of body fat distribution may have distinct effects on the clinical, hormonal, and metabolic features of women with clinical hyperandrogenism such as polycystic ovary syndrome (PCOS). Ninety-seven consecutive women with PCOS were included in the study after assessment of gynecological and obesity history and careful clinical examination. Women were divided into three tertile groups based on the waist to hip ratio (WHR). Those with peripheral body fat distribution (P-BFD) had a WHR of less than 0.80, those with intermediate body fat distribution (I-BFD) had a WHR of 0.81 to 0.90, and those with abdominal body fat distribution (A-BFD) had a WHR exceeding 0.90. Baseline blood and urine samples were obtained for several hormone and lipid determinations, and the response of glucose, insulin, and C-peptide to a glucose oral challenge (75 g) was investigated. In the PCOS group, WHR values were higher than those used to define P-BFD and A-BFD in the normal female population. As WHR values increased, a significantly greater prevalence of obesity and acanthosis nigricans and a lower prevalence of acne was present. No significant differences were present in any of the other clinical features between the three groups. Ovarian morphology and volumes were similar in all groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Beta-endorphin response to exogenous corticotrophin-releasing hormone in obese women with different patterns of body fat distribution.

Obese individuals may be characterized by higher than normal basal and stimulated beta-endorphin plasma concentrations, which suggests an increased activity of the opioid system. This study was carried out to investigate whether the regulation of beta-endorphin secretion may be different in different phenotypes of obesity. Twenty-two obese women (body mass index greater than 30 kg/m2) without other endocrine and metabolic abnormalities were investigated. A group of seven normal weight healthy women matched for age served as controls. According to the protocol, obese women included in the study had a waist-to-hip ratio higher than 0.85 (n = 9) or lower than 0.80 (n = 13). The former were defined as having abdominal type and the latter peripheral type body fat distribution. Both groups were matched for body mass index. All women randomly underwent a corticotrophin-releasing hormone test (human CRF, 1 microgram/kg body weight) and a control saline study, with blood samples for beta-endorphin determination taken at regular intervals. Basal beta-endorphin levels were not significantly different between the three groups. No significant variation in the hormone levels occurred during the control study in either group. After CRF injection, however, beta-endorphin rose significantly in all women, but the hormone concentrations were significantly higher in obese women with abdominal fat distribution than in those with peripheral fat distribution and in controls. These results indicate that, among obese women, only those with the abdominal phenotype seem to have increased opioid activity.

The hypothalamic-pituitary-adrenal axis in obese women with different patterns of body fat distribution.

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.

Insulin and androgen relationships with abdominal body fat distribution in women with and without hyperandrogenism.

This retrospective study was carried out to investigate, in a large group of hyperandrogenized women with polycystic ovary syndrome (PCOS) and nonhyperandrogenized control women, the interrelationships between sex steroids and indices of body fat distribution. Moreover, we investigated the relationships between these parameters and insulin blood levels, since obese women with abdominal pattern of fat distribution (A-BFD), as well as those with PCOS (either obese and nonobese) are characterized by moderate to severe hyperinsulinemia. A sample of 100 women with PCOS and that of 138 women without clinical signs of hyperandrogenism, who served as a control group, were investigated. The waist to hip circumference ratio (WHR) which was used to define different patterns of fat topography was significantly (p < 0.05) higher in PCOS (0.84 +/- 0.10) than in control women (0.81 +/- 0.08). In both groups, women with WHR values lower than or equal to 0.85 were considered as having a peripheral pattern of body fat distribution (P-BFD) whereas those having WHR values higher than 0.85 had A-BFD. Compared to controls, women with PCOS had higher LH, androgen and estrogen concentrations. In both PCOS and controls there were no differences in sex hormone levels between women with different patterns of fat distribution, except androstenedione, which levels were significantly higher in women with A-BFD than with P-BFD. Women with PCOS showed significantly higher insulin levels than controls. Moreover, in both groups fasting and stimulated insulin were significantly higher in women with A-BFD than in those with P-BFD.(ABSTRACT TRUNCATED AT 250 WORDS)