Parathyroid incidentaloma discovered during thyroid ultrasound imaging.

We report two patients with incidentally discovered enlarged parathyroid glands while performing neck ultrasonography (US) for thyroid nodules. The parathyroid masses were seen as hypoechoic, homogeneous, oval nodules, separated from the thyroid gland. Both patients were completely asymptomatic, although subclinical evidence of hyperparathyroidism (serum PTH and calcium levels in the upper limit of the normal range, increased ionized serum calcium, osteocalcin, urinary calcium and hydroxyproline) was subsequently found in one patient. An enhanced uptake on sesta-MIBI scinti scan was concordant with the US finding in the two cases. PTH levels in the wash-out from the US-guided fine needle aspiration biopsy, confirmed the parathyroid origin of the lesions. Cytology and immunocytochemistry were, in our cases, unreliable diagnostic procedures. The extensive use of US imaging in thyroid pathology may increase the finding of US incidentally discovered parathyroid adenomas. The early detection of silent parathyroid pathologic findings may extend the natural history of these masses to a preclinical stage. Further investigations are necessary to evaluate the evolution of parathyroid incidentalomas and therefore their clinical significance.

Detection and diagnosis of parathyroid incidentalomas during thyroid sonography.

PURPOSE: The aim of our study was to evaluate the incidence of incidentally found parathyroid adenomas (incidentalomas) in patients undergoing sonography of the neck for thyroid disease. METHODS: A total of 1,686 patients (305 men and 1,381 women) underwent sonography of the neck; the mean age was 49.6 +/- 21.7 years. In 38 patients (2.3%; 7 men and 31 women) with a mean age of 48.7 +/- 14.7 years, hypoechoic, homogeneous, oval nodules (mean volume, 1.0 +/- 0. 9 cm(3)) adjacent to the thyroid parenchyma were observed. All these lesions, compatible with the shape of an enlarged parathyroid gland, underwent ultrasound-guided fine-needle aspiration biopsy (FNAB), with measurement of parathyroid hormone (PTH) and thyroglobulin (Tg) levels in the needle washings (FNAB-PTH and FNAB-Tg). Biochemical screening for hyperparathyroidism was also performed. RESULTS: Cytologic examination plus FNAB-PTH/FNAB-Tg measurements revealed the presence of cellular material consistent with parathyroid tissue in 9 patients (24%), thyroid tissue in 22 patients (58%), and lymphoid tissue in 4 patients (11%). A tissue diagnosis was not established in 3 patients (8%). Five of 9 patients with parathyroid enlargement had high serum PTH and calcium levels. CONCLUSIONS: Enlarged parathyroid glands may be incidentally discovered during sonography of the thyroid. In patients with thyroid disease, the positive-predictive value of sonography in the identification of parathyroid tissue was low. Ultrasound-guided FNAB-PTH determination should be carried out when parathyroid adenoma is suspected. The incidental finding of an enlarged parathyroid may or may not be associated with yet undiagnosed hyperparathyroidism.

Testicular function in hypercholesterolemic male patients during prolonged simvastatin treatment.

Simvastatin is a very effective hypocholesterolemic drug which, reducing cholesterol biosynthesis, can affect normal steroid hormone production. Testes require a continuous cholesterol supply for testosterone synthesis and this can be derived from low density lipoprotein receptor-mediated uptake or from de novo local synthesis. The aim of the study was to see if prolonged simvastatin treatment compromised endocrine testicular function both in basal conditions and after stimulation by human Chorionic Gonadotropin (hCG) (Profasi 5,000 Ul, i.m. at 8 a.m.). Free testosterone (FT) levels were determined at baseline and after 3, 6 and 12 months of simvastatin treatment (20 mg/day) in eight hypercholesterolemic patients. At the same time we performed a hCG stimulation test to evaluate testicular reserve. A significant reduction of FT, both basal and hCG-stimulated, was observed in the 6th and the 12th month of the study. However, FT levels remained in the normal range and no patient complained of gonadal function related symptoms. No significant change was observed in estradiol response to hCG test. Lastly, there was no variation in LH, FSH, progesterone, 17-OH-progesterone, androstenedione or dehydroepiandrosterone-sulphate levels. Our study concluded that the drug causes a mild decline in FT secretion without any clinical sign of testicular dysfunction.

Effects of oral glucose administration on spontaneous and growth hormone (GH)-releasing hormone-stimulated GH release in children and adults.

It has been suggested that hypothalamic regulation of GH secretion in children may differ from that in adults. On the other hand, there is evidence that oral glucose administration affects GH secretion through hypothalamic mechanisms. Therefore, we investigated spontaneous and GHRH-stimulated (1 microgram/kg BW) GH responses after oral glucose administration (children, 1.75 g/kg BW; adults, 75 g) in peripubertal normal children (13 girls and 13 boys, aged 11.7 +/- 0.4 yr; range, 8-13) and healthy adults (12 males and 14 females, aged 25.7 +/- 1.2 yr; range, 18-39). Three studies were carried out. In study 1, serum GH levels in 8 children were suppressed (< 1 microgram/L) for 135 min after oral glucose administration. Afterward, there was a rise in serum GH levels. In 8 adults, the suppressive effect of glucose persisted throughout the 210-min study period, and no GH rebound appeared. In study 2, the GH responses to iv GHRH boli in 10 adults and 10 children were, respectively, inhibited, unchanged, or augmented by an oral glucose load administered 30, 60, or 120 min before GHRH challenge. In study 3, oral glucose administration to 8 adults greatly enhanced the GH response to GHRH given 180 min after the glucose, whereas in 8 children, the GH response to GHRH was unchanged. In conclusion, glucose affects basal and GHRH-stimulated GH release in a similar manner in adults and children, indicating that neuroregulatory influences of glucose on the GH axis may not differ in the two age groups. In children, however, the duration of both the initial inhibitory and subsequent stimulatory effects of glucose administration on GH secretion is shorter.

Short and long-term effects of growth hormone treatment on lipid, lipoprotein, and apolipoprotein levels in short normal children.

Since recombinant growth hormone (GH) has been available, its use has been extended to treating not only children with growth hormone deficiency, but also short-statured children without GH deficiency. It is interesting, therefore, to determine whether GH therapy given in conventional doses causes metabolic side effects in these patients. In the present study we have examined the effect of recombinant human GH on eleven short normal children. Patients received 12 U/m2/week for 1 year. Before beginning treatment, the children had a mean annual growth velocity of 5.1 +/- 0.9 cm/yr; during the year of treatment, the therapy was effective and improved the mean growth velocity to 7.1 +/- 1.7 cm/yr, p < 0.05. We evaluated the subacute short-term effects during the first 15 days of treatment and the long-term effects for one year of GH treatment on lipid and lipoprotein levels. We found a significant increase in total cholesterol (TC) and low density lipoprotein cholesterol (LDL-C) at the 6th month. Triglycerides (TG) increased significantly at the 3rd and 6th month. Both TC and TG returned to baseline at the 12th month. In no case however did the levels of TC, LDL-C and TG go above normal nor were there any changes in the following tests: high density lipoprotein cholesterol (HDL-C), apolipoprotein (Apo) A-I, Apo B, Apo C-II, Apo C-III and Apo E. In conclusion, conventional doses of GH given to short normal children are effective in ameliorating growth velocity and do not cause serious metabolic side effects.

Long-term therapy with high-dose simvastatin does not affect adrenocortical and gonadal hormones in hypercholesterolemic patients.

Simvastatin is an effective hypocholesterolemic drug that inhibits cholesterol synthesis selectively in the liver, but could have potential side effects on the adrenal gland, ovary, and testis, as these three glands use cholesterol for their hormonal biosynthesis. In this report, we examined adrenal and sex steroids in 10 type IIA hypercholesterolemic patients (three with familial [FH] and seven with polygenic hypercholesterolemia) over a period of 1 year on simvastatin therapy in order to confirm in vivo its selective action. Furthermore, we evaluated the adrenal reserve by a corticotropin rapid test, before starting treatment and again at the end of the third month on 20 mg of simvastatin per day, then at the sixth and 12th month on 40 mg/d. There was a significant lowering of total cholesterol (TC) (-31%), low-density lipoprotein cholesterol (LDL-C) (-39%), and apolipoprotein (apo) B (-39%); no statistically significant differences were seen in cortisol response to the corticotropin test between baseline and simvastatin-treated patients. No variation of any sex steroid was observed in patients of either gender. We conclude that long-term therapy with high-dose simvastatin does not interfere with either adrenocortical function or sex hormone production.

Alpha-adrenoreceptor blockade with thymoxamine reduces basal thyrotrophin levels but does not influence circadian thyrotrophin changes in man.

We have tested the hypothesis that alpha-adrenergic drive is involved in the nocturnal increase in TSH in man. Seven mildly hypothyroid women (basal TSH levels 5.0-11.0 mU/l), aged 38-60 years, and nine euthyroid women, aged 27-60 years, were studied. Subjects underwent alpha-adrenergic blockade by infusion of thymoxamine (210 micrograms/min from 19.00 to 24.00 h); the same women were used as controls, with saline infused on different nights. Subjects were not allowed to sleep during the study period. A clear evening rise in basal TSH levels was apparent in both normal subjects and patients. Although overall secretion of TSH was slightly decreased in normal subjects (mean +/- S.E.M. area under the curve, 29.93 +/- 0.96 vs 30.71 +/- 0.80 mU/l per h; P less than 0.05), thymoxamine infusion did not produce any major alteration in the gradual rise in TSH levels during the evening (incremental change above baseline +0.96 +/- 0.21 during control infusion and +0.97 +/- 0.27 mU/l during thymoxamine infusion). In mildly hypothyroid patients the TSH changes were exaggerated and alpha-adrenergic blockade caused a reduction in basal TSH levels and a delayed rise in TSH (incremental change above baseline +2.93 +/- 1.42 during control infusion and +2.26 +/- 0.73 mU/l during thymoxamine infusion; P less than 0.02). Overall TSH secretion was significantly decreased by thymoxamine (mean +/- S.E.M. area 106 +/- 2.45 mU/l per h vs 123.32 +/- 3.68 in the control study; P less than 0.0001).(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of oral administration of melatonin on GH responses to GRF 1-44 in normal subjects.

In order to investigate the role of melatonin on the neuroregulation of GH secretion, eight healthy male volunteers each underwent four separate tests in random order separated by at least 1 week. Following oral administration of melatonin (500 mg at -60 min and at -30 min) plasma GH levels were higher than after placebo at 45 min (mean +/- SEM 2.9 +/- 0.8 vs 0.9 +/- 0.4 ng/ml, P less than 0.01) and 60 min (mean +/- SEM 2.9 +/- 0.4 vs 0.8 +/- 0.1 ng/ml, P less than 0.05). Likewise, after prior administration of melatonin, GH responses to GRF 1-44 (1 micrograms/kg i.v. at 0 min) were greater than placebo plus GRF at 15 min (mean +/- SEM 22.4 +/- 6.1 ng/ml vs 11.3 +/- 2.3 ng/ml, P less than 0.05), 45 min (mean +/- SEM 26.2 +/- 5.3 ng/ml vs 13.3 +/- 2.5 ng/ml, P less than 0.01) and 60 min (mean +/- SEM, 24.7 +/- 7.4 ng/ml vs 11.1 +/- 2.5 ng/ml, P less than 0.05). In contrast we did not observe any effect of either 10(-9)M, 10(-7)M melatonin on in-vitro basal GH release and GH responses to 10(-8)M GRF by rat anterior pituitary cells in monolayer culture. These data suggest that melatonin plays a facilitatory role in the neuroregulation of GH secretion, probably by acting at the hypothalamic level.