UMLS:C0432222 - FACTA Search

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To determine whether hyperandrogenism caused by an inborn error of adrenal steroidogenesis could produce insulin resistance, we examined insulin sensitivity in females with 21-hydroxylase deficiency. Minimal modelling was used to analyze the results of tolbutamide-modified, frequently sampled, iv glucose tolerance testing. Insulin sensitivity [Si; (min-1) (microU/mL)-1] was plotted against body mass index (BMI; defined as kilograms per m2). Six patients with nonclassical 21-hydroxylase deficiency (mean age, 27 yr; mean BMI, 23.2) underwent testing. None of these patients was in active puberty, nor was any patient being treated with glucocorticoids at the time of the study. Twelve eumenorrheic nonhyperandrogenic young adult female control subjects (mean age, 27 yr; mean BMI, 22.4) were also tested. The basal 17-hydroxyprogesterone concentration, but not the total serum testosterone level, was significantly different in the two groups (mean +/- SEM, 11,987 +/- 2,761 vs. 4,059 +/- 802 pmol/L; P < 0.05). As a group the patients' Si values were significantly lower than those of the controls (mean +/- SEM, 4.1 +/- 0.6 vs. 9.7 +/- 1.2; P < 0.05). There was no correlation between Si and basal serum 17-hydroxyprogesterone, testosterone, delta 4-androstenedione, or dehydroepiandrosterone. We conclude that chronic hypersecretion of androgen precursors due to an inborn error of metabolism can induce a reduction in insulin sensitivity.
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PMID:Insulin insensitivity in adrenal hyperplasia due to nonclassical steroid 21-hydroxylase deficiency. 146 43

To determine whether the adrenal androgen 11 beta-hydroxyandrostenedione is a more sensitive and specific marker than dehydroepiandrosterone sulfate, we compared these serum androgens in 81 women with anovulatory hyperandrogenism before treatment, after corticotropin and corticotropin-releasing-factor stimulation, and after short- and long-term dexamethasone suppression. Of all subjects, 65% and 57% had elevated levels of 11 beta-hydroxyandrostenedione (greater than 2.0 ng/ml) and dehydroepiandrosterone sulfate (greater than 2.8 micrograms/ml), respectively. However, 11 beta-hydroxyandrostenedione and dehydroepiandrosterone sulfate levels did not correlate in either the women with hyperandrogenism (r = 0.12) or the 26 normal women (r = 0.29). After 0.25 mg corticotropin was administered intravenously (n = 16), 11 beta-hydroxyandrostenedione increased by 157% +/- 53% (mean +/- SEM), whereas dehydroepiandrosterone sulfate, androstenedione, dehydroepiandrosterone, and cortisol increased by 6% +/- 2%, 46% +/- 10%, 416% +/- 80%, and 2326% +/- 371%, respectively. After intravenous administration of 100 micrograms corticotropin-releasing factor to eight patients, the percent change from baseline level to peak was 148% +/- 26%, 24% +/- 5%, 61% +/- 15%, 117% +/- 15%, and 116% +/- 18% for 11 beta-hydroxyandrostenedione, dehydroepiandrosterone sulfate, androstenedione, dehydroepiandrosterone, and cortisol, respectively. After 2 mg dexamethasone for 3 days (n = 10), 11 beta-hydroxyandrostenedione, dehydroepiandrosterone sulfate, androstenedione, and testosterone were suppressed by 95% +/- 2%, 74% +/- 3%, 51% +/- 9%, and 32% +/- 9%, respectively. Suppression with 0.5 mg dexamethasone for 3 months lowered 11 beta-hydroxyandrostenedione and dehydroepiandrosterone sulfate levels equally by 50% +/- 14% and 62% +/- 12%, respectively. 11 beta-Hydroxyandrostenedione is a useful marker of adrenal androgen secretion with a calculated sensitivity and specificity greater than that of dehydroepiandrosterone sulfate. The greater sensitivity of 11 beta-hydroxyandrostenedione over dehydroepiandrosterone sulfate to adrenal stimulation and suppression suggests its unique diagnostic use.
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PMID:Is 11 beta-hydroxyandrostenedione a better marker of adrenal androgen excess than dehydroepiandrosterone sulfate? 183 6

Polycystic ovarian disease (PCO) is characterized by hyperandrogenism, ovulatory dysfunction, and altered gonadotropin secretion. Mean plasma FSH concentrations are low, while LH is elevated in a majority of patients. LH pulsatile secretion has been shown to occur at rapid follicular phase frequencies (approximately one pulse per h) in PCO, suggesting persistent rapid frequency GnRH secretion in this disorder. Anovulatory women with PCO were given estradiol (E2; Estraderm skin patches) and progesterone (P; vaginal suppositories) to produce midluteal concentrations for 21 days. The aim was to determine if E2 and P would slow LH (GnRH) pulse frequency and if this would result in augmented FSH secretion and follicular development after withdrawal of E2 and P. Plasma LH was measured every 10 min for 8 h before, during (days 10 and 20), and 7 days after withdrawal of E2 and P (day 28). On each of these study days FSH was measured hourly, and E2 and P were measured every 2 h. After sampling, GnRH (25 and 250 ng/kg, iv) was given to assess pituitary responsiveness. Follicular development was monitored by vaginal ultrasound through day 34 of the study. Basal LH frequency was 8.5 +/- 0.5 pulses/8 h (mean +/- SEM). During E2 and P, LH pulse frequency fell to 3.3 +/- 1.0 (10 days) and 2.3 +/- 0.8 (20 days), 39% and 27% of the basal value, respectively, and subsequently increased to 5.6 +/- 0.7 (66% of basal) 7 days after withdrawal of E2 and P. LH pulse amplitude (basal, 7.2 +/- 1.5 IU/L) was not reduced until day 20, but remained suppressed (3.9 +/- 1.1 IU/L) on day 28. As a result, mean LH (basal, 21.0 +/- 3.5 IU/L) fell progressively during E2 and P, to 3.8 +/- 1.2 IU/L on day 20, and remained low (39% of basal) 7 days after steroid withdrawal. Mean plasma FSH (basal, 7.1 +/- 0.9 IU/L) also fell during steroid administration, but in contrast to LH, had risen to 93% of the basal value by 7 days after E2 and P. LH release in response to exogenous GnRH revealed marked initial responses which did not decrease until day 20, but remained suppressed (8% of basal) after withdrawal of E2 and P. FSH responses were also suppressed on day 20, but had increased to 75% of the basal value by day 28. Initiation of follicular development occurred in all patients, and the lead follicle measured 12.3 +/- 0.8 mm 13 days post-E2 and P. Ovulation occurred in one patient.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Reduction of gonadotropin-releasing hormone pulse frequency is associated with subsequent selective follicle-stimulating hormone secretion in women with polycystic ovarian disease. 190 45

Ten hirsute women with polycystic ovarian syndrome (PCO) and nine with idiopathic hirsutism (IH) underwent selective ovarian suppression with leuprolide for 5-6 months and then were randomized to receive, in addition, dexamethasone or placebo for 4 more months. Serum hormone levels and hair growth rates were determined before and after each treatment period. During the initial treatment period with leuprolide alone, testosterone decreased by 54 +/- 6% (mean +/- SEM) in PCO and by 36 +/- 3% in IH (P = 0.02). Androstenedione decreased by 53 +/- 6% in PCO and by 31 +/- 7% in IH (P = 0.02). Androstanediol glucuronide (Adiol-G) decreased by 14 +/- 6% in PCO and by 7 +/- 3% in IH. There was no change in dehydroepiandrosterone sulfate (DHEAS). While initial serum androgen levels were higher in PCO than in IH, they were similar after ovarian suppression in the two groups. After ovarian suppression, Adiol-G was more consistently correlated with testosterone and androstenedione than was DHEAS, suggesting that Adiol-G may be a better marker than DHEAS of adrenal androgen secretion. Hair growth rates decreased by 37 +/- 6% in PCO and by 14 +/- 10% in IH (P = 0.07). The change in hair growth correlated with the change in androstenedione (r = 0.66; P = 0.002), but not significantly with the change in testosterone (r = 0.29; P = 0.2). After the addition of dexamethasone therapy (0.5 mg daily), testosterone, androstenedione, and DHEAS levels fell to near or below assay detection limits, while Adiol-G decreased by 80 +/- 3%. Hair growth rates decreased slightly more in women during dexamethasone (46 +/- 6%) than during placebo (26 +/- 9%; P = 0.18). In summary, the ovary was the major source of circulating testosterone and androstenedione in PCO. The adrenal contributed a substantial minority of these hormones in PCO and was the major source of androgen secretion in IH. Adrenal hyperandrogenism was common in both IH and PCO. Hair growth rates correlated best with changes in serum androstenedione levels. Adiol-G, which was derived primarily from adrenal precursors, was a better marker of adrenal androgen secretion than was DHEAS in these subjects.
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PMID:Effect of leuprolide and dexamethasone on hair growth and hormone levels in hirsute women: the relative importance of the ovary and the adrenal in the pathogenesis of hirsutism. 215 85

Ovarian hyperandrogenism is a common disorder of women of reproductive age. The therapies that are presently available to treat this disorder are not uniformly effective or free of adverse effects. We conducted a prospective study of eight women receiving ketoconazole for a mean duration of 44 +/- 15 (SEM) weeks, as therapy of ovarian hyperandrogenism. Serum testosterone and hair growth rate declined in patients while on 600 to 1,000 mg ketoconazole daily. Menses normalized in seven of eight subjects during treatment. Ketoconazole therapy was not associated with a change in basal or postgonadotropin-releasing hormone stimulation gonadotropin levels. Basal cortisol levels were also unchanged on ketoconazole though responsiveness of cortisol to adrenocorticotropic hormone stimulation tended to be reduced. We conclude that ketoconazole can effectively reverse the biochemical and clinical abnormalities of ovarian hyperandrogenism. Until the issue of its safety is resolved, ketoconazole therapy is best limited to select individuals who agree to careful monitoring and the use of reliable birth control methods during treatment.
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PMID:Ketoconazole use in the treatment of ovarian hyperandrogenism. 216 44

We have investigated the hypothesis that hyperinsulinemia may cause the polycystic ovary syndrome (PCO) by directly stimulating gonadal steroidogenesis and/or gonadotropin secretion. 10 insulin-resistant women with PCO and 5 age- and weight-matched ovulatory normal women had pulsatile gonadotropin release, gonadotrope sensitivity to gonadotropin-releasing hormone, and sex hormone levels studied on two consecutive study days, basally and during the infusion of insulin (mean +/- SEM steady state insulin levels, 1,254 +/- 63 microU/ml PCO vs. 907 +/- 92 microU/ml normal, P less than or equal to 0.01). Insulin acutely increased mean delta (6 h minus prestudy) levels of androstenedione (A) (P less than or equal to 0.001) and estradiol (E2) (P less than or equal to 0.05) and decreased mean plasma pool (0-6 h) levels of testosterone (T) (P less than 0.05), nonsex hormone binding globulin-bound T (P less than 0.05), and dihydrotestosterone (P less than or equal to 0.01) in the PCO women. Insulin also decreased mean plasma 6 h A to estrone (E1) ratios and increased 6 h E1 levels (both P less than or equal to 0.05) in the PCO women. There were significant sequence effects (insulin + day) in the PCO women on T/E2 ratios, indicating a carryover action of insulin. Insulin had no effects on gonadotropin release in the PCO women. In the normal women, the only significant change was an insulin or study day effect that increased mean 6 h E2 levels (P less than or equal to 0.01). There were significant spontaneous decreases in mean luteinizing hormone (p less than 0.05) and follicle-stimulating hormone levels (p less than or equal to 0.01) in the PCO but not the normal women on the second day of study. This study indicates that insulin can directly alter peripheral sex hormone levels independent of changes in gonadotropin release in insulin-resistent PCO women. Insulin decreased the levels of potent androgens in PCO women and did not increase androgen levels in normal women, arguing against a simple, direct causal relationship between hyperinsulinemia and hyperandrogenism in PCO.
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PMID:Insulin administration alters gonadal steroid metabolism independent of changes in gonadotropin secretion in insulin-resistant women with the polycystic ovary syndrome. 264 19

Insulin may mediate the hyperandrogenism that frequently occurs in patients with insulin-resistant states. To test this hypothesis, we studied five normal women and one woman with hyperandrogenism, insulin resistance, and acanthosis nigricans with the hyperinsulinemic-euglycemic clamp technique. Each woman received a 0.1 U/kg insulin bolus dose, followed by a 10 mU/kg X min insulin infusion for 12-16 h. In the normal women, an average insulin level of 1832 +/- 292 (+/- SEM) microU/ml was achieved; serum glucose was clamped at 116 +/- 5 mg/dl. At this level, insulin may bind to the insulin-like growth factor I receptor as well as to its own receptor. Contrary to our working hypothesis, a rise in serum testosterone did not occur in any women during insulin infusion, and in one women, serum testosterone levels decreased. When analyzed as a percentage of the basal value, serum progesterone levels fell 20% in the normal women within the first 2 h of insulin infusion, but did not change thereafter. Dehydroepiandrosterone sulfate (DHEA-S) levels, however, uniformly and progressively decreased by 39% after 12 h of insulin infusion in the normal women and by 31% at 14 h in the woman with hyperandrogenism, insulin resistance, and acanthosis nigricans. The fall in serum DHEA-S levels was not due to diurnal rhythmicity, as the changes in serum DHEA-S levels did not correlated with those in serum cortisol. Suppression of PRL release also was excluded as a cause of the fall in DHEA-S levels. These results indicate that acute hyperinsulinemia of 12- to 16-h duration does not increase serum testosterone or DHEA-S concentrations and, indeed, can cause a decline in serum DHEA-S levels in both normal women and the single woman studied with hyperandrogenism, insulin resistance, and acanthosis nigricans.
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PMID:The effects of hyperinsulinemia on serum testosterone, progesterone, dehydroepiandrosterone sulfate, and cortisol levels in normal women and in a woman with hyperandrogenism, insulin resistance, and acanthosis nigricans. 294 16

In this study seven normal weight Indian patients with polycystic ovarian disease (PCOD) with no evidence of acanthosis nigricans and 7 age- and weight-matched normal Indian women were studied to determine whether PCOD patients were insulin-resistant. While all 14 women had normal glucose tolerance, the PCOD women had significantly higher mean plasma glucose levels at 30 and 60 min and higher mean incremental glucose areas [incremental areas: PCOD, 9.0 +/- 2.2 (+/- SEM); normal women, 4.0 +/- 0.8 mmol/L; P less than 0.05]. Insulin responses were significantly higher in the PCOD compared to normal women (incremental areas: PCOD, 623.8 +/- 78.3; normal women, 226.2 +/- 30.3 microU/mL; P less than 0.001). Both serum testosterone and androstenedione levels correlated with the insulin areas (r = 0.82; P less than 0.001 and r = 0.86; P less than 0.001, respectively). [125I] Insulin binding to erythrocytes revealed decreased maximum specific binding in the PCOD women (6.9 +/- 0.6%) compared to that in normal women (9.2 +/- 0.7%; P less than 0.02). While Scatchard analysis revealed similar receptor numbers, ID50 values demonstrated decreased receptor affinity in the women with PCOD. In conclusion, in the absence of acanthosis nigricans, nonobese patients with PCOD are insulin resistant, and this insulin resistance correlates with the hyperandrogenism.
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PMID:Evidence for insulin resistance in nonobese patients with polycystic ovarian disease. 295 93

Adolescent girls with a history of precocious pubarche (PP) are known to be at increased risk for ovarian hyperandrogenism, an endocrinopathy related to reduced fetal growth, but the characteristics of their ovulatory function have not been fully documented. We assessed ovulatory function by weekly urinary LH and salivary progesterone measurements over 3 consecutive months in 85 adolescent girls with known weight and gestational age at birth: 49 girls had no history of PP (age, 14.7+/-1.7 yr), and 36 had a history of PP (age, 14.4+/-2.0 yr); 55 girls were in the early postmenarcheal phase (0-3 yr after menarche), and 30 were in the late postmenarcheal phase (> 3 yr after menarche). In girls with PP, the 17-hydroxyprogesterone (17-OHP) response to ACTH was determined at prepubertal diagnosis of PP, and serum androgen and gonadotropin concentrations were measured in adolescence together with insulin responses to an oral glucose load. Early postmenarche, the fraction of girls with ovulations was similar in the non-PP and PP subgroups (61% vs. 62%), as was the fraction of ovulatory cycles (25% vs. 22%). Late postmenarche, however, the fractions of ovulating girls and ovulatory cycles were strikingly higher (P < or = 0.001) in the non-PP than in the PP subgroup (91% vs. 20% and 47% vs. 12%). Within the PP subgroup, anovulatory girls were found to have a lower weight SD score at birth (mean+/-SEM) than ovulatory girls (-1.22+/-0.3 vs. -0.36+/-0.3; P = 0.03), a higher 17-OHP response to ACTH before puberty (333.1+/-31 vs. 203.8+/-26 ng/dL; P < 0.002), and, in adolescence, lower serum sex hormone-binding globulin levels and higher circulating LH, free androgen indexes, and insulin responses. In conclusion, these findings indicate that girls with PP are at increased risk for anovulation from late (not early) adolescence onward, particularly those girls with a low weight at birth and/or a high 17-OHP response to ACTH at prepubertal diagnosis of PP.
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PMID:Anovulation after precocious pubarche: early markers and time course in adolescence. 1044 61

Polycystic ovary syndrome (PCOS) is the most common cause of anovulation in women. Previous studies suggest that the pathogenesis of PCOS may involve interrelated abnormalities of the insulin-like growth factor (IGF) and ovarian steroidogenesis systems. We investigated this hypothesis in fasting serum samples from 140 women with PCOS (age, 27.4 +/- 0.4 yr; body mass index, 26.3 +/- 0.5 kg/m2; mean +/- SEM). IGF-related parameters were also studied in a group of normoovulatory women (n = 26; age, 26 +/- 4 yr; body mass index, 23.6 +/- 4.3 kg/m2). For the PCOS group, the mean testosterone (T) level was 2.5 +/- 0.1 nmol/L, and it was significantly correlated with LH (r = 0.41; P < 10(-6)), estrone (r = 0.33; P = 0.016), estradiol (r = 0.18; P = 0.04), and androstenedione (AD; P < 10(-6)), but not with dehydroepiandrosterone sulfate (P = 0.71), a marker of adrenal steroidogenesis. T and AD were also related to total ovarian follicle number and ovarian size, as previously found with normoovulatory women (1). There were no differences between the PCOS subjects and the normoovulatory group for total IGF-I, IGF-II, or IGF-binding protein-3 (IGFBP-3). However, IGFBP-1 levels were significantly decreased in the PCOS group (1.0 +/- 0.2 vs. 7.3 +/- 1.1 ng/mL; P < 0.001) and were inversely correlated with serum insulin levels (r = -0.50; P < 10(-8)). Serum levels of free IGF-I (fIGF-I) were elevated (5.9 +/- 0.3 vs. 2.7 +/- 0.3 ng/mL; P < 0.001) in inverse relation with IGFBP-1 (r = -0.31; P = 0.046). Serum fIGF-I levels were related to total follicle number (r = - 0.35; P < 10(-4)) and to the ratio of sex hormone-binding globulin to T (r = -0.23; P = 0.009). However, these relationships were not independent of other variables. Despite the more than 2-fold elevation in fIGF-I levels, significant relationships between fIGF-I and markers of ovarian steroidogenesis (T, AD, estradiol, and estrone) could not be demonstrated. In conclusion, although we confirmed correlations between LH and hyperandrogenemia and have found abnormalities in the IGF system in a large cohort of PCOS subjects, a direct relationship between hyperandrogenism and the IGF system could not be shown. Previous studies suggest that elevated LH and hyperinsulinemia lead to excess ovarian androgen synthesis in PCOS and that the intraovarian IGF system is important for normal follicle development and may be important in the arrested state of follicle development in PCOS. However, the data presented in this cross-sectional study suggest that insulin-related changes in circulating IGFBP-1 and subsequent elevation of fIGF-I reflect insulin resistance and have little enhancing effects on ovarian steroidogenesis in this disorder.
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PMID:Elevated serum levels of free insulin-like growth factor I in polycystic ovary syndrome. 1048 60

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