ABSTRACT
Medical therapy is but one of a multiarm, multispecialty approach that is needed in order to successfully treat adrenocortical tumors. The role of surgery, radiation therapy, radiofrequency ablation, and the need for a team approach for the care of the patient cannot be over-emphasized. In this article current and potential future medical therapies for adrenocortical tumors are reviewed.
Subject(s)
Adrenal Cortex Neoplasms/drug therapy , Adrenocortical Carcinoma/drug therapy , Antineoplastic Agents, Hormonal/therapeutic use , Antineoplastic Combined Chemotherapy Protocols/therapeutic use , Adrenal Cortex Neoplasms/complications , Adrenocortical Carcinoma/complications , Androgen Antagonists/administration & dosage , Chemotherapy, Adjuvant , Dopamine Antagonists/administration & dosage , Glucocorticoids/administration & dosage , Humans , Hyperaldosteronism/drug therapy , Hyperaldosteronism/etiology , Mineralocorticoid Receptor Antagonists/administration & dosage , Octreotide/administration & dosage , Patient Care Team , Treatment OutcomeABSTRACT
BACKGROUND: Children with type 1 diabetes living in rural areas may have limited access to specialty diabetes care compared to children living in urban areas. To address this issue, providers have developed outreach services in which specialists travel periodically to rural communities. OBJECTIVE: To determine whether the care of children with type 1 diabetes treated by pediatric endocrinologists in a rural outpatient clinic is comparable to the care of children treated in an urban medical center by the same diabetes team. METHODS: We carried out a retrospective cohort study comparing the number of patient visits with physicians, behavioral specialists, and dietitians and the frequency of hemoglobin A1c (HbA1c) measurements over a 12-month period treated in a rural clinic with a matched group treated in an urban children's hospital clinic. RESULTS: We found that urban patients (n = 38) were more likely to complete four visits per year compared to a matched group (n = 19) at the rural clinic (55.3% vs. 15.8%; p < 0.004), were significantly more likely than those in the rural clinic to have had four HbA1c measurements per year (55.3% vs. 21.1%; p < 0.014), and more likely to have had an assessment by a behavioral specialist (31.6% vs. 0%). Children at the rural clinic site were more likely to have had a visit with a nutritionist during the year (89.5% vs. 36.8%; p < 0.005). CONCLUSION: We conclude that diabetes care provided using a rural outreach model closely approximates, but does not entirely duplicate, care provided in the urban setting.
Subject(s)
Child Health Services/organization & administration , Diabetes Mellitus, Type 1/therapy , Rural Health Services/organization & administration , Child , Cohort Studies , Glycated Hemoglobin/analysis , Humans , Office Visits/statistics & numerical data , Retrospective Studies , Urban Health Services/organization & administration , WashingtonABSTRACT
Estradiol (E2) negative feedback on LH secretion was examined in 10 pubertal girls, testing the hypothesis that E2 suppresses LH pulse frequency and amplitude through opioid pathways. At 1000 h, a 32-h saline infusion was given, followed 1 week later by an E2 infusion at 13.8 nmol/m2 x h. During both infusions, four iv boluses of saline were given hourly beginning at 1200 h, and four naloxone iv boluses (0.1 mg/kg each) were given hourly beginning at 1200 h on the following day. Blood was obtained every 15 min for LH determination and every 60 min for E2 determination from 1200 h to the end of the infusion. E2 infusion increased the mean serum E2 concentration from 44+/-17 to 112+/-26 pmol/L (P < 0.01). The mean LH concentration between 2200-1200 h decreased from 3.19+/-0.89 to 1.99+/-0.65 IU/L (P = 0.014), and LH pulse amplitude decreased from 3.4+/-0.6 to 2.6+/-0.5 IU/L (P = 0.0076). Although there were 1.2 fewer pulses during E2 infusion compared to saline infusion, differences did not reach significance (P = 0.1; 95% confidence interval for the difference, -3.5, 1.1). Pituitary responsiveness to GnRH, assessed at the end of the infusion by administering 250 ng/kg GnRH iv, did not change during E2 infusion. The effect of naloxone blockade of opioid activity on LH secretion was determined by assessing the area under the curve (AUC) from 1200-1600 h. During saline infusion, the LH AUC was 1122+/-375 IU/L during saline boluses and 1575+/-403 IU/L during naloxone boluses (P = 0.39). When E2 was infused, the LH AUCs during saline and naloxone boluses were 865+/-249 and 866+/-250 IU/L, respectively. Thus, in pubertal girls: 1) E2 decreases the LH concentration and LH pulse amplitude; 2) the main site of negative feedback effect of E2 appears to be at the level of the hypothalamus; 3) an increase in LH secretion after naloxone administration could not be demonstrated in these girls and may depend on the maturity of the hypothalamic-pituitary-gonadal axis; and 4) opioid receptor blockade does not reverse the E2 inhibition of LH secretion even in the most mature girls. Thus, E2 suppression of LH secretion in pubertal girls appears to be mediated by a decrease in hypothalamic GnRH secretion that is independent of opioid pathways.
Subject(s)
Estradiol/pharmacology , Luteinizing Hormone/antagonists & inhibitors , Naloxone/pharmacology , Narcotic Antagonists/pharmacology , Puberty/physiology , Adolescent , Child , Female , Gonadotropin-Releasing Hormone/pharmacology , Humans , Luteinizing Hormone/metabolism , Pituitary Gland/drug effectsSubject(s)
Abdominal Muscles/drug effects , Adipose Tissue/drug effects , Dwarfism, Pituitary/therapy , Growth Hormone/adverse effects , Human Growth Hormone/deficiency , Abdominal Muscles/pathology , Adipose Tissue/pathology , Child , Growth Hormone/administration & dosage , Humans , Hypertrophy , Injections, Subcutaneous , MaleABSTRACT
We have shown previously in pubertal boys that testosterone (T) suppresses the nocturnal augmentation of luteinizing hormone (LH) secretion principally by decreasing LH pulse frequency. As T can be aromatised to estradiol (E2), and E2 effects on LH secretory dynamics may be separate from those of T, we examined the effects of acute E2 infusion on LH secretion in pubertal boys. Opioid receptor blockade has been reported to increase LH secretion after estradiol suppression in adult men, so we also examined whether naloxone might augment LH secretion during E2 treatment in pubertal boys. Starting at 1000 h, eight pubertal boys were given a 33 h saline infusion, followed 1 week later by an E2 infusion at 4.6 nmol/m2/h. During both infusions, four iv boluses of saline were given hourly beginning at 1200 h on the first day, and four naloxone iv boluses, 0.1 mg/kg each, were given hourly beginning at 1200 h on the second day. Blood was obtained every 15 min for LH, and every 60 min for T and E2, from 1200 h until the end of the infusion. Pituitary responsiveness to gonadotropin-releasing hormone (GnRH) was assessed after both infusions by iv administration of 250 ng/kg synthetic GnRH. Estradiol infusion increased the mean plasma E2 concentration from 23 +/- 4 to 46 +/- 6 pmol/L (P < 0.01) and suppressed mean plasma T from 4.9 +/- 1.4 to 3.0 +/- 3.5 nmol/L (saline vs. E2 infusion, P < 0.05). The overall mean LH was suppressed by E2 infusion from 3.7 +/- 0.5 to 2.2 +/- 0.4 IU/L (saline vs. E2 infusion, P < 0.01). LH pulse frequency was suppressed by 50%, whereas mean LH pulse amplitude was not different between saline and E2 infusions. Administration of naloxone did not alter the mean LH, LH pulse frequency, or amplitude during either saline or E2 infusions. Pituitary responsiveness to exogenous GnRH was similar during both infusions. These studies indicate that E2 produces its negative feedback in pubertal boys principally by suppression of LH pulse frequency, and naloxone does not reverse these suppressive effects. Thus E2 suppression of LH secretion is mediated by a decrease of hypothalamic GnRH secretion that is independent of endogenous opioid pathways.
Subject(s)
Estradiol/pharmacology , Luteinizing Hormone/metabolism , Naloxone/pharmacology , Narcotic Antagonists/pharmacology , Puberty/physiology , Adolescent , Gonadotropin-Releasing Hormone/pharmacology , Humans , Infusions, Intravenous , Male , Pituitary Gland/drug effects , Pulsatile Flow , Sodium Chloride/pharmacologyABSTRACT
Acceleration of linear growth during puberty is associated with increased GH secretion, although the relationship between growth and GH is complex. As GH exists as a family of isoforms, some of which may not be identified by immunoassay, there may be alterations in isoform secretion during pubertal maturation that result in increased growth. The changes in serum immunoreactive and bioactive GH concentrations across pubertal maturation were determined in 30 boys, aged 6.5-19.3 yr, with idiopathic short stature or constitutional delay of adolescence. Data were grouped as follows: 1) 6 prepubertal boys with bone age 7 yr or less; 2) 5 prepubertal boys with bone age of more than 7 yr, 3) 10 boys in early puberty; 4) 9 boys with mid- to late puberty. Blood was obtained every 20 min from 2000-0800 h. An equal aliquot of each serum sample was pooled for determination of GH by bio- and immunoassays. The mean serum immunoreactive GH concentration increased from 2.1 +/- 0.3, 1.8 +/- 0.3, and 2.9 +/- 0.5 micrograms/L in groups 1, 2, and 3, respectively, to a peak of 4.6 +/- 0.7 micrograms/L in group 4 (P < 0.05 vs. groups 1-3). The mean serum GH bioactivity was 48 +/- 13 micrograms/L in group 1 and declined to 39 +/- 8 and 31 +/- 3 micrograms/L in groups 2 and 3, increasing to a maximum of 64 +/- 15 micrograms/L in group 4 (P < 0.05 vs. group 3). The ratio of bioactive to immunoreactive GH suggests that the biopotencies of secreted isoforms do not increase during pubertal maturation. The role of E2 in increasing GH secretion was characterized in 8 additional early pubertal boys. Each boy received a saline infusion from 1000-0800 h, followed 1 week later by an infusion of E2 at 4.6 nmol/m2.h. Blood was obtained every 15 min from 2200-0800 h for GH and LH and every 60 min for E2 and testosterone. An equal aliquot of each overnight serum sample was pooled for insulin-like growth factor I (IGF-I) and GH by immuno- and bioassays. The mean serum LH concentration decreased from 5.0 +/- 0.9 to 2.3 +/- 0.6 IU/L (P < 0.01), and the E2 concentration increased from 22 +/- 4 to 81 +/- 26 pmol/L (P < 0.01) during saline and E2 infusions, respectively. Mean serum GH concentrations as measured by immunoassay were similar during both infusions (6.6 +/- 1.4 vs. 9.7 +/- 2.1 micrograms/L; saline vs. E2 infusion, respectively). In contrast, the mean serum GH concentration, as measured by bioassay, decreased from 48 +/- 10 micrograms/L during saline infusion to 16 +/- 3 micrograms/L during E2 infusion (P < 0.05). The mean serum IGF-I concentration also decreased significantly from 116 +/- 17 to 93 +/- 15 micrograms/L (saline vs. E2 infusion, respectively; P < 0.05). Thus, although mean overnight serum GH concentrations increase in late puberty, whether measured by immuno- or bioassay, an acute increase in E2 produces an acute decline in serum GH bioactivity and a lesser decline in the serum IGF-I concentration. These unexpected changes indicate that E2 may affect pubertal growth and GH secretion in a complex or biphasic manner depending on the context in which it is administered.
Subject(s)
Estradiol/pharmacology , Growth Hormone/blood , Puberty/blood , Adolescent , Adult , Child , Estradiol/administration & dosage , Estradiol/blood , Follicle Stimulating Hormone/blood , Growth Hormone/immunology , Humans , Insulin-Like Growth Factor Binding Protein 3/blood , Insulin-Like Growth Factor I/analysis , Luteinizing Hormone/blood , Male , Testosterone/bloodABSTRACT
Puberty in boys is characterized by a nocturnal increase in mean LH concentration and LH pulse frequency. To determine whether similar mechanisms exist in girls, nocturnal serum LH concentrations were determined in 16 girls with constitutional delay of adolescence or idiopathic short stature who had or have subsequently been shown to have spontaneous puberty. Mean LH and LH pulse frequency and amplitude were analyzed in 3-h blocks and compared to those in 20 pubertal boys. Girls had an increase in mean LH concentration from 3.6 +/- 0.7 IU/L at 2000-2250 h to 4.8 +/- 0.9 IU/L at 0200-0450 h. LH pulse frequency increased from 0.27 +/- 0.11 pulses/girl.h at 2000-2250 h to 0.54 +/- 0.10 pulses/girl.h at 0200-0450 h. The increase in LH pulse amplitude, from 2.0 +/- 0.8 IU/L at 2000-2250 h to 4.1 +/- 1.1 IU/L at 2300-0150 h, did not achieve statistical significance because many girls had no pulses from 2000-2250 h. With advancing age, the day/night differences in LH concentration and LH pulse frequency disappeared in girls, but were preserved in boys of same pubertal stage. The effect of lack of estrogen on LH pulse characteristics was inferred by analyzing the LH profiles of 15 girls with gonadal dysgenesis who were age-matched to girls with spontaneous puberty. The girls with gonadal dysgenesis had an increase in mean LH concentration after 0200 h, but LH pulse frequency was rapid in all time blocks; the nocturnal increase in LH concentration was secondary to a significant increase in LH pulse amplitude. Older girls with gonadal dysgenesis had a loss of nighttime augmentation of LH secretion similar to that seen in girls with spontaneous puberty. These data suggest that the apparent slower LH pulse frequency encountered in girls with spontaneous puberty during waking hours may be related to estrogen suppression of LH pulse amplitude, which masks the true daytime LH pulse frequency. With or without pubertal estrogen exposure, developmental progression of LH secretion occurs more rapidly in girls than in boys. Thus, intrinsic sex differences exist in the timing and tempo of endocrine control of pubertal maturation between boys and girls.
Subject(s)
Hypogonadism/blood , Luteinizing Hormone/blood , Puberty/blood , Adolescent , Child , Estradiol/blood , Female , Humans , Male , Testosterone/bloodABSTRACT
To determine the usefulness of a GnRH agonist analog as a diagnostic test to distinguish between constitutional delay of growth (CGD) in boys with Tanner stage I of sexual development and patients with hypogonadotropic hypogonadism (HH), we evaluated six boys (mean age 15 yr 4 m) and five HH patients (mean age 20 yr 4 m). In addition, 20 normal healthy men aged 21 yr to 50 yr received either nafarelin or GnRH followed two weeks later by the other test in order to compare the efficacy of each of these tests and to evaluate the optimal sampling times for the nafarelin test. All subjects were healthy, and had not received hormonal replacement for at least 2 months prior to enrollment in the study. Each man had four baseline blood samples before and at timed intervals following the administration of either GnRH or nafarelin. Each of the patients had blood withdrawn every 15 min during 12 h overnight followed by a single s.c. injection of nafarelin (1 microgram(s)/kg up to 100 microgram(s)), except two HH patients who did not have an overnight study. Blood samples were obtained at timed intervals for 24 h. LH, FSH, T and E2 were measured by RIA. Baseline concentrations of plasma LH, FSH and T were similar before the administration of either GnRH or nafarelin in the group of normal men. Peak stimulation of plasma LH, FSH and T released by nafarelin was significantly higher, and it took a longer time to reach the peak maximum, than after GnRH (p < 0.001). Mean nocturnal LH was 5.5 +/- 0.9 IU/I for the CGD group, and 2.7 +/- 0.7 IU/I for HH (p < 0.02). Mean nocturnal FSH was 5.1 +/- 1.0 and 2.5 +/- 0.2 IU/I whereas mean nocturnal T concentrations were 4.2 +/- 0.8 and 0.7 +/- 0.2 nmol/I (CGD vs HH, respectively, p < 0.02). Peak LH responses to nafarelin were 36.9 +/- 8.9 IU/I for the CGD group, and 7.0 +/- 2.0 IU/I for the HH group (p < 0.001). Peak FSH released by nafarelin was 14.2 +/- 2.4 IU/I for the CGD group and 4.8 +/- 2.0 IU/I for the HH group (p < 0.02). Peak T was reached 24 h following nafarelin injection and was 5.7 +/- 1.7 nmol/I for the CGD group and 0.3 +/- 0.2 nmol/I for the HH group (p < 0.001). The results obtained indicate that in early stages of puberty (before detectable changes of sexual maturation) the nafarelin test, with measurements of LH, FSH and T in blood or in urine, is superior to and more practical than overnight hormonal estimates to clearly distinguish CGD from HH.
Subject(s)
Gonadotropin-Releasing Hormone , Growth Disorders/diagnosis , Hypogonadism/diagnosis , Nafarelin , Adult , Circadian Rhythm , Diagnosis, Differential , Estradiol/blood , Follicle Stimulating Hormone/blood , Follicle Stimulating Hormone/urine , Humans , Luteinizing Hormone/blood , Luteinizing Hormone/urine , Male , Middle Aged , Puberty, Delayed , Testosterone/bloodABSTRACT
A family of male limited gonadotrophin independent precocious puberty was examined for activating mutation of the LH receptor. A transition of A to G in nucleotide 1733 of the human LH receptor gene was identified in all affected males and in an unaffected carrier female. The mutation was shown by identifying a new restriction site created by the mutation. This mutation appears to be a common feature of the disorder, as it has been reported previously in unrelated families. Therefore, the presence of this new restriction site can serve as a diagnostic tool in males at risk before the onset of symptoms, as well as identifying carrier females.
Subject(s)
Point Mutation , Puberty, Precocious/genetics , Receptors, LH/genetics , Adenylyl Cyclases/metabolism , Base Sequence , Child, Preschool , DNA Mutational Analysis , Enzyme Activation , Female , Heterozygote , Humans , Male , Molecular Sequence Data , Pedigree , Polymerase Chain Reaction , Receptors, LH/metabolismABSTRACT
LH secretion is maximal during the night in pubertal boys, and testosterone (T) administration blunts this nocturnal rise of LH. We have previously shown that in pubertal boys, the acute negative feedback effects of T infusion on LH secretion during the daytime cannot be reversed by opioid receptor blockade. To determine whether the nocturnal secretion of LH in early puberty is regulated by endogenous opioid pathways, we determined whether naloxone during the night affected LH secretion or T-mediated suppression of LH secretion. Seven pubertal boys (bone age, 11-13.5 yr) were given a control infusion of saline, followed 1 week later by an infusion of T at 960 nmol/m2.h for 41 h starting at 2000 h. During both saline and T infusions, six iv boluses of saline were given hourly beginning at 2400 h on the first day, and six iv boluses of naloxone (0.1 mg/kg each) were given hourly beginning at 2400 h on the second day. Starting at 2200 h, blood was obtained every 15 min for LH and every 30 min for T determinations for 14 h each night. Pituitary responsiveness was assessed at the end of each study night by i.v. bolus administration of 250 ng/kg synthetic GnRH. T infusion increased the mean T concentration 6-fold (P < 0.0001) and suppressed the mean plasma LH concentrations from 5.6 +/- 0.6 to 3.8 +/- 0.6 IU/L (P < 0.01). The nocturnal augmentation of LH secretion was suppressed by the infusion of T, and this suppression was not reversed by naloxone. The mean nighttime plasma LH (2400-0600 h) was 8.1 +/- 1.1 IU/L during the control saline infusion and 5.1 +/- 0.6 IU/L during the T infusion (P < 0.01). The mean LH level was 4.0 +/- 0.7 IU/L during the administration of naloxone boluses concomitantly with the T infusion, not significantly different from that during the T infusion. Likewise, LH pulse frequency during the same time period was decreased by T infusion from 0.6 +/- 0.1 to 0.36 +/- 0.04 pulses/boy.h (P < 0.05), and it was unaltered by coadministration of naloxone (0.38 +/- 0.12 pulses/boy.h). Naloxone administration during the saline infusion did not increase either the mean plasma LH concentration (7.5 +/- 0.7 IU/L; P = NS vs. saline control) or the LH pulse frequency (0.69 +/- 0.1 pulses/boy.h; P = NS vs. saline control). Pituitary responsiveness to GnRH was similar on each of the 4 nights during either saline or T infusions.(ABSTRACT TRUNCATED AT 400 WORDS)
Subject(s)
Luteinizing Hormone/antagonists & inhibitors , Naloxone/administration & dosage , Puberty/physiology , Testosterone/pharmacology , Adolescent , Circadian Rhythm , Drug Administration Schedule , Growth Hormone-Releasing Hormone/pharmacology , Humans , Luteinizing Hormone/metabolism , Male , Naloxone/pharmacology , Pituitary Gland/drug effects , Pituitary Gland/metabolism , Pulsatile Flow , Sodium Chloride/pharmacologyABSTRACT
We have recently developed a new bioassay for growth hormone (GH) in serum, which is based on the ability of GH to suppress glucose use in cultured murine adipocytes. We tested the hypothesis that bioactive GH (B-GH) concentrations would correlate better with the GH-dependent peptides, IGF-I, and IGF-binding protein-3 (IGFBP-3) than would GH determined by conventional RIA (RIA-GH). Twenty-five girls with Turner's syndrome were studied. The subjects had ages ranging from 4.8 to 15.9 y and height SD from the mean (SD score) ranging from -0.77 to -5.67. Blood samples were obtained every 15 or 20 min for 12 h overnight. For each girl, an equal aliquot of each overnight sample was pooled for determination of B-GH, RIA-GH, IGF-I, IGFBP-3, LH, FSH, and estradiol. Measurable estradiol concentrations were present in six girls and were sufficient to suppress gonadotropin concentrations in two girls, but they did not alter B-GH, RIA-GH, IGF-I, and IGFBP-3 concentrations compared with the age-matched girls without measurable estradiol concentrations. Hence, data for all girls were combined for subsequent regression analyses. RIA-GH did not correlate significantly with B-GH, IGF-I, or IGFBP-3. B-GH exhibited a significant correlation with IGF-I (r = 0.407, p < 0.05), and the correlation with IGFBP-3 was better than that for RIA-GH (r = 0.355 versus 0.064, B-GH and RIA-GH, respectively). None of the B-GH, RIA-GH, IGF-I, or IGFBP-3 concentrations had a significant correlation with height SD score or height velocity SD score.(ABSTRACT TRUNCATED AT 250 WORDS)
Subject(s)
Growth Hormone/blood , Insulin-Like Growth Factor I/metabolism , Turner Syndrome/blood , Adipose Tissue/drug effects , Adipose Tissue/metabolism , Adolescent , Animals , Biological Assay/methods , Body Height , Carrier Proteins/blood , Child , Child, Preschool , Evaluation Studies as Topic , Female , Follicle Stimulating Hormone/blood , Glucose/metabolism , Growth Hormone/analysis , Growth Hormone/pharmacology , Humans , Insulin-Like Growth Factor Binding Proteins , Luteinizing Hormone/blood , Mice , Radioimmunoassay , Turner Syndrome/pathologyABSTRACT
We describe a 9-year-old boy and his 34-year-old father with the Pallister-Hall syndrome. The proband had precocious puberty, imperforate anus, postaxial polydactyly, hypospadias, a hypothalamic mass, and a displaced pituitary gland. The father had polydactyly, a hypothalamic mass, and a flattened pituitary gland. We conclude that the most likely cause of the Pallister-Hall syndrome is a mutation in a gene inherited in an autosomal dominant manner.
Subject(s)
Abnormalities, Multiple/genetics , Anus, Imperforate/genetics , Chromosome Aberrations , Chromosome Disorders , Hypospadias/genetics , Polydactyly/genetics , Child , Humans , Male , Phenotype , SyndromeABSTRACT
FSH plays an essential role in folliculogenesis and ovarian growth. However, cross-sectional studies have not shown an increase in bioactive FSH (B-FSH) during puberty. To eliminate intersubject variability, we used a longitudinal design and tested the hypothesis that B-FSH increases during puberty. Thirty normal, healthy girls were enrolled in a longitudinal study from pubertal stages I to IV. The subjects were evaluated at 6-mo intervals; each visit consisted of pubertal staging, bone age determination by x-ray, measurements of serum immunoreactive FSH (I-FSH) and B-FSH (n = 14) or immunoreactive LH (I-LH) and bioactive LH (B-LH) (n = 18), and adrenal and ovarian steroids. All girls had clinical and hormonal characteristics of puberty. Both I-FSH and B-FSH levels were relatively elevated before puberty, whereas serum I-LH and B-LH were low. From pubertal stages I to III, there was a modest yet significant rise in serum I-FSH (p < 0.001) and serum B-FSH (p < 0.01). Serum I-LH and B-LH concentrations showed the expected increases with puberty (p < 0.001), with serum B-LH concentrations exhibiting a greater rise than I-LH (p < 0.001). Our results demonstrate that serum B-FSH and I-FSH increase during puberty. Relatively elevated B-FSH concentrations from early to midpuberty may be an important factor for ovarian growth while circulating LH and estrogen are still low. As puberty progresses, the continued and selective increase in LH induces a rise in estradiol and ultimately leads to ovulation.
Subject(s)
Follicle Stimulating Hormone/blood , Luteinizing Hormone/blood , Puberty/blood , Adolescent , Biological Assay/methods , Child , Estradiol/blood , Female , Humans , Insulin-Like Growth Factor I/metabolism , Radioimmunoassay , Time FactorsABSTRACT
To assess the relative roles of growth hormone-releasing hormone (GHRH) pulse and somatostatin withdrawal as potential generators of pulsatile growth hormone (GH) release in humans, we studied GH responses to iv bolus GHRH (1 microgram/kg) and to termination of a 4 h iv somatostatin infusion (7.2 micrograms.kg-1.h-1) in five normal young men, and in five men with previously diagnosed isolated GH deficiency. The patients were diagnosed 8-15 years previously on the basis of typical auxological and hormonal criteria, were treated with exogenous GH and were off GH therapy for 1.5-8.9 years prior to this study. Growth hormone rises to a bolus GHRH were similar between the controls and the patients (maximum GH 27.3 +/- 15.3 vs 8.0 +/- 4.0 micrograms/l). The controls exhibited only a small GH rise to somatostatin withdrawal (maximum GH 2.9 +/- 1.2 micrograms/l), while the patients did not (maximum GH 0.7 +/- 0.1 micrograms/l; p < 0.05). We conclude that somatostatin withdrawal by itself is an ineffective promoter of GH pulsatility. Periodic quiescence of somatostatinergic neurons must be associated with a concomitant GHRH pulse in order to result in a robust GH pulse.
Subject(s)
Growth Hormone/metabolism , Pituitary Gland/metabolism , Somatostatin/physiology , Adult , Cluster Analysis , Growth Hormone/deficiency , Growth Hormone-Releasing Hormone/administration & dosage , Growth Hormone-Releasing Hormone/pharmacology , Humans , Infusions, Intravenous , Insulin-Like Growth Factor I/biosynthesis , Male , Radioimmunoassay , Somatostatin/administration & dosage , Somatostatin/blood , Time FactorsABSTRACT
Puberty is the last phase of the complex process of sexual maturation, a process by which an individual acquires reproductive competency. This article reviews the physiologic and physical changes of normal puberty and the causes of either delayed or precocious sexual development of boys.
Subject(s)
Puberty, Delayed/physiopathology , Puberty, Precocious/physiopathology , Adolescent , Humans , Male , Puberty, Delayed/drug therapy , Puberty, Precocious/drug therapyABSTRACT
We tested the hypothesis that the improved sensitivity of immunofluorometric (IFMA) assays will lead to an increase in the number of detectable LH pulses compared to RIA in early pubertal boys, in whom LH secretion is low. To test this hypothesis we determined plasma LH concentrations in six pubertal boys (bone age, 12-16 yr) by IFMA and compared the results to RIA data reported previously. Each boy was given an infusion of saline, followed 1 week later by an infusion of testosterone (T; 960 nmol/h) for 33 h starting at 1000 h. Starting at 1200 h, blood was obtained every 15 min for LH determinations (RIA and IFMA) and every 30 min for T measurements. At the end of both studies, responses to GnRH (250 ng/kg) were assessed. The assay sensitivities for LH by RIA and IFMA (Delfia hLH Spec Pharmacia Diagnostics ENI, Columbia, MA) were 1.0 and 0.05 IU/L, respectively. LH pulses were identified by three independent pulse detection programs: Detect, Cluster, and Kushler-Brown. The correlation for LH values as measured by RIA and IFMA was highly significant (r = 0.81). There was a poor correlation between LH values determined by IFMA and RIA when LH values within 4 times the SD of each assay sensitivity were compared (r = 0.08; P = NS). T infusion suppressed LH pulse frequency by 40% and 66%, as determined by RIA and IFMA, respectively (P = NS). Using the Detect program, during the complete study in all 6 boys, 117 pulses of LH were identified by RIA and 93 by IFMA (79% ratio of detection IFMA/RIA). During saline infusion there were 73 vs. 69 LH pulses (94%), while during T infusion there were 24 vs. 44 LH pulses (55%), as detected by IFMA vs. RIA, respectively. Administration of naloxone did not accelerate LH pulse frequency during T infusion, as determined by either method. Changes in pituitary responses to exogenous GnRH also showed similar trends of augmentation by T infusion by both methods. We conclude that the use of IFMA does not lead to the anticipated increase in the detectability of LH pulsatility. Actually, fewer LH pulses were identified by IFMA in this group of boys. We speculate that this is due to the increased specificity of the IFMA assay. More significant was the finding that the physiological interpretation of the effects of T and naloxone on LH pulse frequency and responses to GnRH did not change whether LH was measured by RIA or IFMA.
Subject(s)
Fluoroimmunoassay , Luteinizing Hormone/blood , Puberty, Precocious/blood , Radioimmunoassay , Adolescent , Adult , Gonadotropin-Releasing Hormone/pharmacology , Humans , Male , Naloxone/pharmacology , Pulsatile Flow , Sensitivity and SpecificityABSTRACT
GH, in clinical practice, is determined by RIA, but RIA estimates may not accurately reflect serum GH bioactivity. The available measures of GH bioactivity lack either sensitivity, specificity, or a physiologically relevant end point. The objective of this research was to develop a physiologically relevant GH bioassay which would not only measure the bioactivity of purified GH preparations, but would also have sufficient sensitivity to measure GH bioactivity in human serum. The method consisted of incubating murine 3T3-F442A adipocytes in serum-free medium containing BSA, 14C-glucose, and increasing concentrations of GH or test materials for 24 h, followed by measurement of conversion of glucose to lipid. Interference by nonspecific serum factors was reduced by the addition of 10 micrograms/liter insulin, 25 nM dexamethasone, and 37 nM estradiol to the medium. In the presence of 10 micrograms/liter insulin, 50 micrograms/liter insulin-like growth factor-1 did not alter the ability of GH to suppress lipid accumulation. Epinephrine and glucagon could suppress lipid accumulation but only at concentrations greatly in excess of the physiological range in serum. Twenty two thousand dalton hGH produced dose-dependent suppression of lipid accumulation which was linear between 0.625 and 10 micrograms/liter (r = 0.926; P = 0.0001) with a half-maximal response of 3.0 +/- 0.2 micrograms/liter (n = six experiments). The intra- and interassay coefficients of variation were 7% and 19%, respectively. The assay was specific for GH since addition of human PRL produced suppression of lipid accumulation only at concentrations where contamination of the preparation by GH became a significant factor. ACTH also suppressed lipid accumulation but only at doses of 1000 micrograms/liter or greater. Human placental lactogen and hLH, hFSH, and hTSH did not cross-react with GH in this assay. Addition of human serum did not alter the slope of ED50 of the GH dose-response curve. Pools of serum from prepubertal and pubertal boys and girls, subjects treated with arginine or insulin, a diabetic girl, and a boy with gigantism who had a serum GH content of 80 micrograms/liter by RIA and 40 micrograms/liter by bioassay, produced dose response curves parallel to that of the GH standard curve. Serum from patients with hypopituitarism did not produce significant suppression of lipid accumulation in any assay. Recovery of 5 micrograms/liter GH added to human serum was 94%. Twenty thousand dalton GH also suppressed lipid accumulation in this assay, but was 2-fold less potent than 22,000 dalton GH.(ABSTRACT TRUNCATED AT 400 WORDS)
Subject(s)
Adipose Tissue/drug effects , Biological Assay , Growth Hormone/blood , Adipose Tissue/metabolism , Adolescent , Animals , Blood , Cell Line , Dexamethasone/pharmacology , Diabetes Mellitus/blood , Estradiol/pharmacology , Female , Glucose/metabolism , Growth Disorders/blood , Growth Hormone/pharmacology , Humans , Insulin/pharmacology , Lipid Metabolism , Male , Mice , Quality Control , Radioimmunoassay , Turner Syndrome/bloodABSTRACT
The experimental induction of puberty by GnRH administration to prepubertal lambs increases serum bioactive FSH (B-FSH) as measured in the rat Sertoli cell aromatase induction bioassay. Serum immunoreactive FSH (I-FSH) levels are unchanged. The increase in serum B-FSH is associated with an increase in the proportion of less acidic and more biopotent FSH serum isoforms. However, it is unknown if this effect of GnRH on serum FSH microheterogeneity is direct or mediated by gonadal factors. We have used the nutritionally growth-restricted ovariectomized lamb as a model of the neuroendocrine regulation of FSH isoform microheterogeneity. With this model, the hypothalamic-pituitary component of the neuroendocrine axis may be isolated from gonadal factors. In the present study, using the nutritionally growth-restricted ovariectomized lamb as a model, we investigated the role of GnRH on the regulation of FSH microheterogeneity. Specifically, we tested the hypothesis that GnRH increases the proportion of the less acidic (more biopotent) serum FSH isoforms. As an in vitro correlate, we investigated the effect of GnRH on gonadotropin secretion and FSH isoform distribution in ovine pituitary explant cultures. Seven ovariectomized nutritionally restricted lambs were administered GnRH (i.v., 2 ng/kg) for 36 h (at 2-h intervals for 24 h, then hourly for the final 12 h). Six others served as controls. Blood samples were withdrawn at 12-min intervals during the last 4 h for the measurement of serum immunoactive LH (I-LH) and I-FSH. Pituitary homogenates and serum from four animals from each group were individually chromatofocused, and the FSH isoform distribution patterns were determined. Pulsatile administration of GnRH to nutritionally growth-restricted lambs increased circulating I-LH concentrations from 0.6 +/- 1.0 to 5.9 +/- 3.1 ng/ml (P < 0.01), but did not significantly change circulating I-FSH (4.9 +/- 1.8 vs. 11.5 +/- 4.2 ng/ml) nor B-FSH concentrations (3.9 +/- 1.2 vs. 5.7 +/- 1.5 ng/ml). The pituitary content of I-FSH, B-FSH, and I-LH were unchanged. Neither serum nor pituitary FSH isoform distribution patterns were altered by pulsatile GnRH administration. However, compared to the pituitary FSH isoforms, a higher percentage of circulating FSH isoforms eluted in the salt peak of both groups of lambs. Similar to the in vivo studies, in vitro, GnRH increased the release of I-LH, as well as I-FSH, from pituitary explants, but did not significantly change the FSH isoform distribution in either the pituitary explant or media.(ABSTRACT TRUNCATED AT 400 WORDS)
Subject(s)
Follicle Stimulating Hormone/metabolism , Gonadotropin-Releasing Hormone/pharmacology , Growth Disorders/metabolism , Isoenzymes/metabolism , Ovariectomy , Pituitary Gland/metabolism , Animal Nutritional Physiological Phenomena , Animals , Female , Follicle Stimulating Hormone/blood , Growth Disorders/blood , Growth Disorders/etiology , Luteinizing Hormone/blood , Pulsatile Flow , Sheep , Tissue DistributionABSTRACT
To evaluate the relative changes in serum bioactive (B) and immunoreactive (I) plasma gonadotropin concentrations during pubertal maturation, 28 healthy boys were enrolled at Tanner stage I and followed at 6-month intervals until achievement of Tanner stage V of pubertal maturation. At each visit, a careful interview, complete physical examination, sexual maturation staging, and bone age x-ray study were done, and a blood sample was obtained. Serum concentrations of PRL, dehydroepiandrosterone, and its sulfate, delta 4-androstenedione, estrone, estradiol, and testosterone (T) were determined by RIA. Samples from 20 boys were assayed for I-LH by RIA and for B-LH by the rat interstitial cell testosterone production assay, using 2 standards [Second International Reference Preparation-Human Menopausal Gonadotropin (2nd IRP-hMG) and LER 960]. Samples from 11 boys (3 from LH group and 8 others) were assayed for I-FSH by RIA and B-FSH by the rat Sertoli cell aromatase induction assay. The results were analyzed by regression analysis for B and I LH and FSH by Tanner stages of puberty, and by correlation of B to I LH and FSH as well as B and I LH and FSH to T. The results from both LH standards correlated well to each other (r = 0.967 and 0.882 for B- and I-LH, respectively), and the data are presented for 2nd IRP-hMG standard. In both groups of boys serum T concentrations increased progressively with pubertal development (P < 0.001). The boys bone age, testicular volume, serum T, dehydroepiandrosterone sulfate, dehydroepiandrosterone, delta 4-androstenedione, estrone concentrations correlated well with pubertal maturation, similar to previously published data and indicate that this group of boys had progressed through puberty in the expected normal manner. Mean serum I-LH concentrations increased progressively from Tanner stage I to V of puberty (P < 0.001), and serum B-LH exceeded the increase in serum I-LH levels. Mean serum I-LH concentrations were 2.0 +/- 0.1, 2.9 +/- 0.2, 4.7 +/- 0.4, 6.7 +/- 0.7, and 10.4 +/- 2.0 IU/L 2nd IRP-hMG whereas mean serum B-LH concentrations were 0.8 +/- 0.1, 2.2 +/- 0.2, 5.9 +/- 0.2, 10.3 +/- 1.2, and 22.3 +/- 3.8 IU/L 2nd IRP-hMG for Tanner stages I-V of puberty, respectively. This resulted in a progressive increase of LH B/I ratio with advancing pubertal maturation (P < 0.001).(ABSTRACT TRUNCATED AT 400 WORDS)
