Annual variations in serum thyroid-stimulating hormone and thyroid hormones and in their responses to thyrotrophin-releasing hormone in the reindeer

The reindeer in its natural habitat is subject to great annual variations in ambient temperature, illumination and nutrition. To ascertain the effect of these environmental factors on thyroid function, serum thyroid-stimulating hormone (TSH), thyroxine (T4), tri-iodothyronine (T3) and reverse T3 (rT3) concentrations were measured four times a year (2 June, 8 October, 21 November, and 24 February) in 14 animals housed outdoors at latitude 69 degrees 10'N. They all showed statistically significant (P < 0.05) seasonal changes. Serum TSH and T4 were highest in February (623 +/- 30 ng/ml and 287 +/- 19 nmol/l respectively). TSH was lowest in October (318 +/- 47 ng/ml) and T4 in November (199 +/- 19 nmol/l). The T3 concentration was highest in November (3.0 +/- 0.3 nmol/l) and lowest in June (1.8 +/- 0.2 nmol/l). In contrast, rT3 was highest in June (3.6 +/- 1.2 nmol/l) and lowest in November (1.9 +/- 0.6 nmol/l). Thus, there was an inverse relationship between T3 and rT3 (linear regression r = -0.406, P < 0.01). TSH, T4, T3 and rT3 responses to exogenous thyrotrophin-releasing hormone (synthetic TRH; 500 micrograms i.m.) were determined in ten animals. The magnitude of their response to TRH was significantly (P < 0.05) dependent on the time of year. When compared with the control level all the parameters rose significantly (P < 0.05). The greatest rise in serum TSH occurred in October (219 +/- 151%) and the smallest in February (66 +/- 53%).(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of oral administration of anti-inflammatory doses of prednisone on thyroid hormone response to thyrotropin-releasing hormone and thyrotropin in clinically normal dogs

Prednisone was given orally to 12 dogs daily for 35 days at an anti-inflammatory dosage (1.1 mg/kg of body weight in divided dose, q 12 h) to study its effect on thyroxine (T4) and triiodothyronine (T3) metabolism. Six of these dogs were surgically thyroidectomized (THX-Pred) and maintained in euthyroid status by daily SC injections of T4 to study peripheral metabolism while receiving prednisone; 6 dogs with intact thyroid gland (Pred) were given prednisone; and 6 additional dogs were given gelatin capsule vehicle as a control group (Ctrl). Baseline T4 concentration after 4 weeks of treatment was not significantly different in dogs of the THX-Pred or Pred group (mean +/- SEM, 2.58 +/- 0.28 or 3.38 +/- 0.58 micrograms/dl, respectively) vs dogs of the Ctrl group (2.12 +/- 0.30 micrograms/dl). A supranormal response of T4 to thyrotropin was observed in dogs of the Pred group, but the T4 response to thyrotropin-releasing hormone was normal. Baseline T3 concentration in dogs of both steroid-treated groups was significantly (P < 0.05) lower after 2 and 4 weeks of prednisone administration vs pretreatment values, but normalized 2 weeks after prednisone was stopped. Free T3 (FT3) and T4 (FT4) fractions and absolute FT3 and FT4 concentrations were not altered by prednisone administration. Reverse T3 (rT3) concentration in vehicle-treated Ctrl dogs (26.6 +/- 3.5 ng/dl) was not different from rT3 concentration in dogs of the THX-Pred (25.7 +/- 4.3 ng/dl) and Pred (28.9 +/- 3.8 ng/dl) groups after 4 weeks of medication.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis of pulsatile secretion of thyrotropin and growth hormone in the hypothyroid rat

To characterize the role of TRH in the generation of TSH pulsatility as well as the effect of hypothyroidism on episodic GH secretion, blood was constantly withdrawn (30-60 microliters/min) from rats treated with 0.02% methimazole in the drinking water for 8-10 days. This treatment significantly reduced circulating levels of both T3 and T4 and elevated plasma TSH; however, since thyroid hormone titers were still detectable (T3, 39.6 +/- 5.3 vs. 89.8 +/- 5.3 ng/dl in euthyroid animals), methimazole-treated rats were referred to as being mildly hypothyroid. TSH was found to be secreted in secretory bursts, consisting of one to several peaks in these rats. Pulsar analysis of TSH secretory profiles revealed a mean pulse frequency of 2.8 pulses/h, a mean pulse amplitude of 10 ng/pulse, and a mean pulse duration of 0.2 h. Euthyroid rats exhibited similar fluctuations of circulating TSH levels; however, due to the variability of the TSH RIA in the range of euthyroid TSH titers, no significant pulsatility was detected by Pulsar. Mean plasma TSH levels in eu- and hypothyroid rats were 2.3 +/- 0.3 and 14.6 +/- 1.8 ng/ml, respectively. To confirm that the TRH antiserum (TRH-AS) used in the present study for passive immunization had sufficient binding capacity to absorb endogenous TRH release, euthyroid rats were pretreated with either normal rabbit serum or TRH-AS, followed by the injection of clonidine (100 micrograms/kg BW, iv). This alpha 2-adrenergic agonist caused a significant (P < 0.01) 12.7-fold rise in plasma TSH levels in normal rabbit serum-treated animals, which was completely abolished by TRH-AS pretreatment, indicating that clonidine stimulates TSH secretion via activation of hypothalamic TRH release. When TRH-AS was slowly infused into hypothyroid rats that were sampled frequently for the detection of TSH pulsatility, it caused a significant (60.3%; P < 0.01) decrease in mean TSH levels, with TSH titers approaching euthyroid concentrations 1 h after the infusion of TRH-AS. The antiserum treatment also caused the disappearance of statistically significant (Pulsar) TSH secretory pulses. Mild hypothyroidism shifted the GH secretory profiles from a low frequency, high amplitude in euthyroid animals to a high frequency, low amplitude pattern in hypothyroid rats. Mean GH levels in hypothyroid rats were 76% lower than those in euthyroid controls. These findings show that TSH is secreted in a pulsatile fashion in the hypothyroid rat and that TRH is predominantly responsible for the generation of TSH pulsatility.(ABSTRACT TRUNCATED AT 400 WORDS)     

Hormonal changes and pituitary histological and immunocytochemical studies of patients with multiple organ failure

OBJECTIVE: We investigated the correlation between the endogenous hormonal changes of pituitary-adrenal and pituitary-thyroid hormones and the prognosis of patients in multiple organ failure, and elucidated the mechanism of blunted thyrotropin (TSH) secretion by histological and immunocytochemical studies of anterior pituitary glands. PATIENTS: Forty-three patients were studied who had been admitted to the intensive care unit of Sapporo Medical University Hospital and had been diagnosed as having multiple organ failure. MEASUREMENTS: Pituitary adrenal hormones [corticotropin (ACTH), cortisol] and pituitary thyroid hormones [TSH, triiodothyronin (T3), free-T3, thyroxine (T4), free-T4, thyroxine-binding globulin (TBG)] were measured, and TSH and prolactin (PRL) responses thyrotropin-releasing hormone (TRH) were examined within 24 hours of admission to the ICU. Individual variables were compared between survivors (n = 19) and nonsurvivors (n = 24). Thirteen patients (five survivors, eight nonsurvivors) were investigated again before discharge from the ICU or death. Morphology was examined by hematoxilin-eosin staining, and avidin-biotin-peroxidase complex immunostaining was used to demonstrate the spectrum of TSH in 14 nonsurvivors. RESULTS: (1) ACTH levels remained within the normal range, while cortisol levels increased to above normal levels. Neither hormone showed significant differences between survivors and nonsurvivors. In nonsurvivors, cortisol levels decreased before death despite the increased ACTH levels. (2) T3 and free-T3 levels decreased markedly to below normal values, and reverse-T3 levels increased markedly to above normal values. Nonsurvivors showed significant differences in TSH, T4 and reverse-T3 levels compared with survivors. (3) TSH response to TRH was blunted in both groups but PRL response to TRH was normal. Nonsurvivors showed severely depressed TSH response. Nonsurvivors continued to show blunted TSH response to TRH, while this improved in survivors. (4) The histological study did not show very serious damages to anterior pituitary glands as TSH secretion was depressed. Many TSH immunoreactive cells were also observed by immunocytochemical study. CONCLUSION: Decreased cortisol, low T4 levels and blunted TSH response to TRH correlated with mortality in MOF patients. Histological and immunocytological studies suggest that blunted TSH secretion is not caused by pituitary damages or TSH exhaustion but by disturbances in TSH secretion. This blunted TSH secretion is reversible and its improvement is an indicator of survival.     

Recurrent goiter, hyperthyroidism, galactorrhea and amenorrhea due to a thyrotropin and prolactin-producing pituitary tumor

A 22-year-old woman with recurrent goiter, hyperthyroidism, galactorrhea, and amenorrhea due to a pituitary tumor is described. She had been treated surgically twice for recurrent goiter with tracheal compression. Despite clinical signs of hyperthyroidism and slightly elevated plasma thyroid hormone levels (T4: 11 mug/dl; T3: 189 ng/dl), without thyroid hormone replacement therapy the basal TSH level was elevated up to 23 muU/ml and could not be suppressed by exogenous thyroid hormones: even when the serum thyroid hormone levels were raised into the thyrotoxic range (T4: 16.2 mug/dl T3: 392 ng/dl), the basal TSH fluctuated between 12 and 29 muU/ml. The basal PRL level was elevated up to 6000 muU/ml. The administration of TRH (200 mug iv) led only to small increments of TSH and PRL levels. Bromocriptin (5 mg p.o.) or l-dopa (0.5 g p.o.) suppressed TSH and PRL values significantly. After transsphenoidal hypophysectomy, TSH and PRL were below normal and the patient development panhypopituitarism. The adenoma showed two cell types which could be identified as lactotrophs and thyrotrophs by electronmicroscopy and immunofluorescence. From these data we conclude that the patient had a pituitary tumor with an overproduction of thyrotropin and prolactin.     

Role of protein degradation in the growth of livers after a nutritional shift

Four patients with idiopathic pituitary dwarfism were shown to have growth hormone (GH), adrenocorticotropin (ACTH), and luteinizing hormone (LH) deficiencies. Basal levels of thyrotropin (TSH) were within normal range in three patients and slightly elevated in one. Exaggerated and delayed responses were obtained after TSH-releasing hormone (TRH) stimulation. Serum thyroxine (T4) values were low (2.3 +/- 0.4 mug/100 ml), while triiodothyronine (T3) levels were in the normal range (1.22 +/- 0.25 ng/ml), both rising substantially after exogenous TSH and consecutive TRH administration. Their hypothyroid state was, therefore, probably due to TRH deficiency. To examine the dose of L-T4 necessary to produce inhibition of the TSH response to TRH, 50 mug/m2/day of L-T4 was administered to these patients. At the end of 4 weeks of replacement, serum T4 rose to 5.2 +/- 0.5 mug/100 ml, whereas T3 was unchanged from the previous levels, after which TSH responses to TRH were completely suppressed in all patients. As a control group, six patients with primary hypothyroidism received gradually increasing doses of L-T4 for 4-week periods, and TSH response to TRH was tested at the end of each dosage of L-T4, until complete inhibition of TSH release was obtained. The primary hypothyroid patients required approximately 150 mug/m2/day of L-T4 for suppression of TSH response to TRH. At this dosage, serum T4 and T3 levels were 8.5 +/- 0.9 mug/100 ml and 2.34 +/- 0.5 ng/ml respectively, which were significantly higher than those levels in the pituitary dwarfs (P less than 0.001 for T4 and P less than 0.01 for T3). These observations indicate that the set point of TSH release in feedback inhibition by throxine is low in idiopathic hypopituitarism with TRH deficiency, and TRH seems to control the pituitary sensitivity to feedback regulation of thyroid hormones.     

Familial insensitivity of the pituitary and periphery to thyroid hormone: a case report in two generations and a review of the literature

A clinically euthyroid 2-yr-old girl was found to have diffuse goiter that measured 3 X 5.5 cm with a prominent systolic bruit. Serum free T4 (3.4 ng/dl) and serum T3 (360 ng/dl) remained elevated for the next 10 months even though she remained clinically euthyroid. Elevation of serum free T4 (3.0 ng/dl) and serum T3 (265 ng/dl) was also present in the 24-yr-old nongoitrous mother who had symptoms and signs of hypothyroidism. Following intravenous injection of TRH, basal TSH levels of 2.7 and 2.8 microunits/ml increased to peak values of 17 and 21 microunits/ml at 30 min in the daughter and mother, respectively. Administration of exogenous T3 followed by sequential testing with boluses of TRH revealed retention of TSH responsiveness in both daughter and mother during pretreatment with dosage regimens of T3 below 125 micrograms daily. Maintenance of TSH responsiveness to TRH in the presence of elevated levels of serum free T4 and serum T3 indicates relative pituitary insensitivity to thyroid hormone which could be overridden by increasing the circulating levels of serum T3 three to fivefold over the already elevated basal levels. The absence of clinical signs of thyrotoxicosis indicates peripheral insensitivity to thyroid hormone with elevated circulating concentrations presumptively compensating for the defect. Resistance to thyroid hormone in two generations of the same family suggests genetic inheritance, and is concordant with four earlier reports of familial aggregation in this syndrome.     

Changes in thyroid hormone levels during growth hormone therapy in initially euthyroid patients: lack of need for thyroxine supplementation

The occurrence of central hypothyroidism in previously euthyroid children during GH therapy has been reported with widely varying incidence. We monitored the acute effects on the hypothalamic-pituitary-thyroid axis in 15 euthyroid children with classic GH deficiency during the first year of GH therapy. All were initially euthyroid, as assessed by normal baseline TSH, T4, free T4, and T3 levels and negative antithyroid antibodies. A thyroid profile (T4, free T4 index, T3, rT3, and TSH) was performed at baseline and 1, 3, 6, 9, and 12-15 months after GH therapy began; a TRH stimulation test was performed at baseline and after 1, 3, and 9 months of therapy. By 1 month, there were significant decreases in T4, free T4 index, and rT3, and significant increases in T3 and the T3/T4 ratio. The changes from baseline values were greatest at 1 month, were almost universal for all thyroid values, and showed a gradual return to baseline from 3-12 months. There were no clinical signs of hypothyroidism and no change in baseline or TRH-stimulated TSH levels or in cholesterol levels, and all patients grew at velocities expected for the treatment schedule. There is little evidence for the development of clinically significant hypothyroidism in the great majority of initially euthyroid patients after GH therapy is begun. T4 supplementation is seldom needed in such patients.     

Plasma lipoprotein(a) levels in patients with hyperthyroidism

Thyroid function and regulation were studied in 14 consecutive male outpatients with asymptomatic human immunodeficiency virus (HIV) infection (CDC II/III, n = 8) or AIDS (CDC IV, n = 6) who were free of concomitant infections and hepatic dysfunction, and in eight healthy, age- and weight-matched male controls. Blood was sampled every 10 minutes over 24 hours for measurement of thyrotropin (TSH). Thereafter, thyroid hormones and TSH responsiveness to thyrotropin-releasing hormone (TRH) were measured. Triiodothyronine (T3) and thyroxine (T4) did not differ between HIV-infected patients and controls, but HIV patients had lower thyroid hormone-binding index ([THBI] HIV patients, 1.01 +/- 0.02; controls, 1.11 +/- 0.03; P < .02), free thyroxine (FT4) index (94 +/- 3 v 110 +/- 4, P < .01), FT4 (11.8 +/- 0.4 v 14.3 +/- 0.4 pmol/L, P < .01), and reverse triiodothyronine (rT3) values (0.18 +/- 0.01 v 0.26 +/- 0.02 nmol/L, P < .001) and higher thyroxine-binding globulin ([TBG] 20 +/- 1 v 16 +/- 1 mg/L, P < .02) values. Mean 24-hour TSH levels were increased in HIV patients (2.39 +/- 0.33 v 1.44 +/- 0.16 mU/L, P < .05), associated with increased mean TSH pulse amplitude and TSH responsiveness to TRH. No differences were observed between asymptomatic HIV-seropositive and AIDS patients. In conclusion, there is a hypothyroid-like regulation of the pituitary-thyroid axis in stable HIV infection, which differs distinctly from the euthyroid sick syndrome in non-HIV-nonthyroidal illnesses.(ABSTRACT TRUNCATED AT 250 WORDS)     

Membrane fusion in organelle biogenesis

Enteric bacteria have been postulated to have a role in thyroid economy by promoting the hydrolysis of thyroid hormone conjugates of biliary origin, thus permitting the absorption and recycling of thyroxine (T4) and triiodothyronine (T3). An enterohepatic circulation of T3 might be more pronounced under conditions in which type I iodothyronine deiodinase activity (5'D-I) is inhibited, because this augments the accumulation of T3 sulfate conjugates in bile. This potential of increased gut reabsorption of T3 might explain, at least in part, the failure of serum T3 values to decrease appreciably when marked reductions in peripheral 5'D-I activity are induced by selenium deficiency or 6-anilino-2-thiouracil (ATU) administration. Thus, studies were performed to determine the effect of intestinal decontamination, in the absence and in the presence of 5'D-I inhibition, on plasma T4 and T3 concentrations. Groups of adult male rats received either enteric antibiotics or no antibiotics for 12 days and then, in half of the rats in each group, treatment for 10 days with ATU, a 5'D-I inhibitor that does not affect thyroid hormone synthesis. The activity of intestinal arylsulfatase and arylsulfotransferase, enzymes that catalyze hydrolysis of thyroid hormone conjugates, was reduced markedly by approximately 87% in rats that received antibiotics, regardless of whether or not they also received ATU. The ATU treatment markedly inhibited liver 5'D-I activity in antibiotic-treated as well as in non-antibiotic-treated rats (control = 399 +/- 32 U/mg protein (mean +/- SEM); ATU = 152 +/- 17: antibiotics = 351 +/- 29; antibiotics + ATU = 130 +/- 10; p < 0.01) and significantly increased plasma T4 and T3 sulfate (T4S, T3S) concentrations (control: T4S = 2.8 +/- 0.4 and T3S = 6.7 +/- 1.3 ng/dl; ATU: T4S = 6.2 +/- 1.4 and T3S = 10.6 +/- 2.1 ng/dl; antibiotics: T4S = 1.8 +/- 0.2 and T3S = 3.6 +/- 1.0 ng/dl; antibiotics + ATU: T4S = 6.8 +/- 0.7 and T3S = 9.7 +/- 1.8 ng/dl; p < 0.05). The ATU treatment was associated with a significant increase in plasma T4 and rT3 concentrations but did not affect plasma T3 concentrations, and intestinal decontamination did not alter these ATU-associated effects on circulating thyroid hormones. These results suggest that anaerobic enteric bacteria in the rat do not have an important role in recycling of thyroid hormones, either under normal conditions or in circumstances where 5'D-I activity is markedly reduced, and that increased gut absorption of T3 from T3S cannot explain the near-normal serum T3 values found when peripheral 5'D-I activity is markedly decreased.     

Plasma prolactin responses to thyrotropin-releasing hormone in patients with breast cancer

Plasma human prolactin levels were measured by homologous radioimmunoassay in patients with primary breast cancer and in normal women of similar age. In normal controls mean (+/- SEM) basal plasma prolactin levels were 11.9 +/- 1.5 ng/ml and intravenous injection of synthetic thyrotropin-releasing hormone (TRH), 500 mug, caused a significant rise in plasma prolactin in all subjects examined with a maximum response of 52.6 +/- 3.3 ng/ml (mean +/- SEM). Markedly high plasma prolactin levels and exaggerated plasma prolactin responses to TRH were demonstrated in some patients with breast cancer. However, mean basal plasma prolactin levels and mean plasma prolactin increments following TRH in patients with breast cancer did not differ significantly from those in normal subjects. Plasma prolactin responses to TRH were slightly blunted during the administration of androgen in patients with breast cancer. These results suggest that some of the patients with primary breast cancer have abnormal prolactin secretion.     

Effect of axial bulbus length and preoperative squint angle on the effect of horizontal combined squint operations

OBJECTIVE: We examined zinc (Zn) status in relation to thyroid function in disabled persons, because the association between Zn deficiency and thyroid function remains controversial. METHODS: After measuring serum free 3,5,3'-triiodothyronine (T3) and free thyroxine (T4) in 134 persons, TSH-releasing hormone (TRH) injection test and estimation of Zn status were conducted in persons with low free T3. RESULTS: Thirteen had low levels of serum free T3 and normal T4. Patients with elevated levels of serum 3,3',5'-triiodothyronine (rT3) showed an enhanced reaction of serum thyrotropin (TSH) after TRH injection. Nine of 13 patients had mild to moderate Zn deficiency evaluated by body Zn clearance and increased urinary Zn excretion. After oral supplementation of Zn sulphate (4-10 mg/kg body weight) for 12 months, levels of serum free T3 and T3 normalized, serum rT3 decreased, and the TRH-induced TSH reaction normalized. Serum selenium concentration (Type 1 T4 deionidase contains selenium in the rat) was unchanged by Zn supplementation. CONCLUSION: Zn may play a role in thyroid hormone metabolism in low T3 patients and may in part contribute to conversion of T4 to T3 in humans.     

Unchanged 5'-deiodinating activity during the induction of a nonthyroidal illness

We investigated the formation of a "nonthyroidal illness" (NTI) in pigs undergoing ventricular fibrillation (VF) and resuscitation. Seven minutes after VF twenty-one pigs received either Epinephrine (E: 45 micrograms/kg B.W.; n = 7), Norepinephrine (NE: 45 micrograms/kg B.W.; n = 7), or Vasopressin (VP: 0.8 U/kg B.W.; n = 7). We determined the serum concentrations (sc) of total T4 (TT4), FT4, total T3 (TT3) and rT3 120 min before, during (t0), and 5, 15, 60 and 120 min after VF. At the end of the observation period we figured out the in-vitro T3-generation (kM, Vmax), the in-vitro rT3-generation, the in-vitro rT3-decomposition (kM, Vmax) and the content of cytosolic sulfhydryls (total sulfhydryls, non-protein bound sulfhydryls) in liver and kidney specimen. Animals not undergoing VF served as controls (C) for parameters measured in the intracellular compartment. TT4- and TT3-sc decreased to 3.3 +/- 0.6 micrograms/dl (p < 0.05, vs. t0) and 15.2 +/- 4.1 ng/dl (p < 0.05, vs t0), resp. FT4-sc remained stable for five minutes (2.63 +/- 0.41 ng/dl) before declining to 1.8 +/- 0.39 ng/dl (p < 0.05, vs. t0). The rT3-sc raised finally to 46.9 +/- 7.3 ng/dl (p < 0.05, vs t0). Iodothyronine sc did not exhibit differences between E-, NE- and VP-treatment. Neither in-vitro T3-generation, nor in-vitro rT3-generation, nor in-vitro rT3-decomposition nor intracellular sulfhydryl content were affected by the events of VF and resuscitation as compared to the controls.(ABSTRACT TRUNCATED AT 250 WORDS)     

Plasma renin and aldosterone in thyroid diseases

The effect of thyroid hormones on the renin-angiotensin-aldosterone system has not been fully resolved. Highly specific immunoassays for measurement of renin, aldosterone, free T4 (fT4), free T3 (fT3) and ultrasensitive TSH enables a direct and more accurate measurement of these hormones. We investigated the relationship between plasma renin, aldosterone and thyroid hormones in the basal state and after intravenous frusemide. This is a cross-sectional study involving 37 patients with thyrotoxicosis, 42 rendered euthyroid with normal fT4, fT3 and TSH levels, 17 with euthyroid levels of fT4 and fT3 but suppressed TSH, and 11 with hypothyroidism. Basal plasma renin was significantly higher in thyrotoxicosis (63.4 +/- 9.8 microU/ml, mean +/- SEM) compared to euthyroid (32.7 +/- 4.4 microU/ml) and hypothyroid (26.7 +/- 9.8 microU/ml). Basal plasma renin for euthyroid with suppressed TSH (41.0 +/- 7.4 microU/ml) was significantly higher than hypothyroid (p = 0.02). Basal plasma aldosterones were not significantly different except for suppressed TSH (157.7 +/- 13 pg/ml), which was higher than normal (109.9 +/- 10.4 pg/ml; p = 0.04). Following frusemide, plasma renin and aldosterone were significantly increased in all groups. Plasma renin was highly correlated to fT3 (r = 0.405, p < 0.001), total T3 (r = 0.359, p < 0.001), fT4 (r = 0.331, p < 0.001) and TSH (r = 0.300, p < 0.001) in the basal state, but less to total T4 (r = 0.248, p < 0.01). Plasma renin correlated poorly to serum aldosterone (r = 0.212, p < 0.03). This study clearly showed that regulation of renin was mainly influenced by fT3, and that aldosterone response to frusemide was blunted in thyrotoxicosis despite normal electrolytes.     

Treatment of hypothyroidism with once weekly thyroxine

We compared daily T4 therapy with 7 times the normal daily dose administered once weekly in 12 hypothyroid subjects in a randomized cross-over trial. At the end of each treatment we measured serum free T4 (FT4), free T3 (FT3), rT3, and TSH levels and multiple markers of thyroid hormone effects at the tissue level repeatedly for 24 h. Compared with daily administration, the mean serum TSH before the administration of weekly T4 was higher (weekly, 6.61; daily, 3.92 microIU/mL; P < 0.0001), and the mean FT4 (weekly, 0.98; daily, 1.35 ng/dL; P < 0.01) and FT3 (weekly, 208, daily, 242 pg/dL; P < 0.01) were lower. A minimally elevated serum total cholesterol during weekly administration (weekly, 246.8; daily, 232.6 mg/dL; P < 0.03) was the only evidence of hypothyroidism at the tissue level. Compared with daily administration, the mean peak FT4 following weekly administration of T4 was significantly higher (weekly, 2.71; daily, 1.59 ng/dL; P < 0.0001), as was the mean peak FT3 level (weekly, 285; daily, 246 pg/dL; P < 0.01). None of the tissue markers of thyroid hormone effect changed compared to daily T4, and there was no evidence of treatment toxicity, including cardiac toxicity. During weekly T4 administration, autoregulatory mechanisms maintain near-euthyroidism. For complete biochemical euthyroidism a slightly larger dose than 7 times the normal daily dose may be required.     

Ingestion of androgenic-anabolic steroids induces mild thyroidal impairment in male body builders

Self-administration of very high doses of androgenic anabolic steroids is common use in power athletes because of their favorable effect on performance. Since androgenic steroids decrease serum T4-binding globulin (TBG) concentrations dramatically, we were interested in the effects of this procedure on thyroid function: we performed TRH tests (200 micrograms Relefact, i.v.), with blood withdrawal before and for 180 min after injection, for determination, using RIA kits, of serum concentrations of total and free T4, total T3, TSH, and TBG in 13 young (20-29 yr old) male body builders with clinically normal thyroid glands, who were all in the same state of training. Five of these athletes admitted taking androgenic anabolic steroids at an average total dose of 1.2 g/week for at least 6 weeks before the tests. TBG, total T4, and total T3 were significantly (P < 0.001) decreased, whereas basal TSH and free T4 were not significantly different from the values of the other 8 without androgenic steroids. The maximum TSH increase after TRH administration (mean +/- SE, 16 -/+ 6 vs. 9 -/+ 4 mU/L; P < 0.05) was relatively increased, whereas the T3 response to TRH (0.61 -/+ 0.10 vs. 1.13 -/+ 0.13 nmol/L; P < 0.05) was relatively decreased in the group receiving androgens. The 5 patients taking androgens had significantly greater weight (114 vs. 90 kg; P < 0.01) and higher total cholesterol levels (6.3 -/+ 1.3 vs. 3.8 -/+ 0.3 mmol/L; P < 0.05) together with very low high density lipoprotein cholesterol levels (0.20 -/+ 0.03 vs. 1.03 -/+ 0.10; P < 0.001) than the controls. PRL levels were normal and similar in both groups. We conclude from our results that high dose androgenic anabolic steroid administration leads to a relative impairment (within the normal range) of thyroid function. Whether this is due to a direct thyroid hormone release (or synthesis?)-blocking effect of these steroids needs further investigation.     

Blur and contrast as pictorial depth cues

OBJECTIVE: Infusion of GH secretagogues appears to be a novel endocrine approach to reverse the catabolic state of critical illness, through amplification of the endogenously blunted GH secretion associated with a substantial IGF-I rise. Here we report the dynamic characteristics of spontaneous nightly TSH and PRL secretion during prolonged critical illness, together with the concomitant effects exerted by the administration of GH-secretagogues, GH-releasing hormone (GHRH) and GH-releasing peptide-2 (GHRP-2) in particular, on night-time TSH and PRL secretion. PATIENTS AND DESIGN: Twenty-six critically ill adults (mean +/- SEM age: 63 +/- 2 years) were studied during two consecutive nights (2100-0600 h). According to a weighed randomization, they received 1 of 4 combinations of infusions, within a randomized, cross-over design for each combination: placebo (one night) and GHRH (the next night) (n = 4); placebo and GHRP-2 (n = 10); GHRH and GHRP-2 (n = 6); GHRP-2 and GHRH + GHRP-2 (n = 6). Peptide infusions (duration 21 hours) were started after a bolus of 1 microgram/kg at 0900 h and infused (1 microgram/kg/h) until 0600 h. MEASUREMENTS: Serum concentrations of TSH and PRL were determined by IRMA every 20 minutes and T4, T3 and rT3 by RIA at 2100 h and 0600 h in each study night. Hormone secretion was quantified using deconvolution analysis. RESULTS: During prolonged critical illness, mean night-time serum concentrations of TSH (1.25 +/- 0.42 mlU/l) and PRL (9.4 +/- 0.9 micrograms/l) were low-normal. However, the proportion of TSH and PRL that was released in a pulsatile fashion was low (32 +/- 6% and 16 +/- 2.6%) and no nocturnal TSH or PRL surges were observed. The serum levels of T3 (0.64 +/- 0.06 nmol/l) were low and were positively related to the number of TSH bursts (R2 = 0.32; P = 0.03) and to the log of pulsatile TSH production (R2 = 0.34; P = 0.03). GHRP-2 infusion further reduced the proportion of TSH released in a pulsatile fashion to half that during placebo infusion (P = 0.02), without altering mean TSH levels. GHRH infusion increased mean TSH levels and pulsatile TSH production, 2-fold compared to placebo (P = 0.03) and 3-fold compared to GHRP-2 (P = 0.008). The addition of GHRP-2 to GHRH infusion abolished the stimulatory effect of GHRH on pulsatile TSH secretion. GHRP-2 infusion induced a small increase in mean PRL levels (21%; P = 0.02) and basal PRL secretion rate (49%; P = 0.02) compared to placebo, as did GHRH and GHRH + GHRP-2. CONCLUSIONS: The characterization of the specific pattern of anterior pituitary function during prolonged critical illness is herewith extended to the dynamics of TSH and PRL secretion: mean serum levels are low-normal, no noctumal surge is observed and the pulsatile fractions of TSH and PRL release are reduced, as was shown previously for GH. Low circulating thyroid hormone levels appear positively correlated with the reduced pulsatile TSH secretion, suggesting that they have, at least in part, a neuroendocrine origin. Finally, the opposite effects of different GH-secretagogues on TSH secretion further delineate particular linkages between the somatotrophic and thyrotrophic axes during critical illness.     

Bacillus thermoamyloliquefaciens KP1071 alpha-glucosidase II is a thermostable M(r) 540,000 homohexameric alpha-glucosidase with both exo-alpha-1,4-glucosidase and oligo-1,6-glucosidase activities

The lethality of acute renal failure exceeds 50% due to multiorgan dysfunction. In such critically ill patients a reduction of thyroid hormone concentrations without clinical symptoms or laboratory evidence of hypothyroidism frequently occurs. Selenium has recently been shown to play a major role in thyroid hormone metabolism. The aim of this study was to investigate the possible influence of selenium on thyroid hormone metabolism in acute renal failure. Changes in thyroid metabolism were related to the severity of multiorgan failure and to the clinical course. Thyroxine (T4), tri-iodothyronine (T3), free-T4, free-T3, thyrotropin (TSH), serum creatinine, and plasma selenium concentrations in 28 patients (mean age 60 +/- 13) with acute renal failure and multiple-organ dysfunction syndrome were determined initially, and every 3 days after hospital admission. The plasma selenium concentration was found to be reduced compared to normal controls (32 +/- 14 vs. 70-120 micrograms/L). T4 (56 +/- 15 nmol/L, normal range 64-148), T3 (1.31 +/- 0.38 nmol/L, normal range 1.42-2.46), free-T3 (3.1 +/- 1.0 pmol/L, normal range 4.7-9.0), and free-T4 (10.8 +/- 4.0 pmol/L, normal range 10.3-25.8) values were low in 50-70% of the patients at the time of presentation. Plasma TSH concentrations were within the normal range (0.59 +/- 0.79 mU/L, normal range 0.25-3.1), and no clinical symptoms of hypothyroidism were observed. T4 concentration was higher in patients who survived acute renal failure compared to nonsurvivors (62 +/- 22 vs. 51 +/- 16 nmol/L, p < 0.05). Plasma selenium concentration was lower in patients with a severe organ dysfunction syndrome (36 +/- 10 vs. 29 +/- 19 micrograms/L) and correlated with the number of organ failures in these patients (r = -0.247, p < 0.05). T4 and free-T4 values paralleled decreasing selenium concentrations (r = 0.35, p < 0.05). Thyroid hormone levels were reduced in patients with acute renal failure without an increase in TSH. An increase in T4 concentrations became apparent during treatment and may be related to a favorable outcome in acute renal failure. Thyroid hormone concentrations paralleled plasma selenium levels, indicating a possible influence of selenium on thyroid function in acute renal failure.     

Changes in the degree of sialylation of carbohydrate chains modify the biological properties of circulating thyrotropin isoforms in various physiological and pathological states

Variation in asparagine-linked carbohydrate chains have a major impact on TSH biological properties. In particular, highly sialylated TSH is characterized by impaired intrinsic bioactivity and prolonged half-life. The aim of the present study was to investigate the changes in the degree of sialylation of circulating TSH isoforms that may occur in several physiological and clinical situations. Bioactivity and terminal sugar residues of immunopurified TSH were studied in 26 normal adults (day- and nighttime serum pools), 2 cord serum pools from normal fetuses during the third trimester, 1 fetus with primary hypothyroidism (PH; 27th week), 1 fetus with resistance to thyroid hormone (RTH; 28th and 33rd weeks), 24 patients with PH (before and during L-T4 treatment), and 5 patients with RTH before and during triiodothyrocetic acid (TRIAC) treatment. Nighttime TSH isoforms have an increased degree of sialylation compared to daytime TSH (35.8 +/- 9.7% vs. 23.8 +/- 5.8%; P < 0.03), thus accounting for the lower bioactivity [biological/immunological TSH ratio (TSH B/I), 1.3 +/- 0.4 vs. 2.0 +/- 0.2; P < 0.0007]. In adult PH, TSH isoforms are highly sialylated (45.4 +/- 7.6%; P < 0.007), showing an impaired bioactivity (0.7 +/- 0.3; P < 0.001). L-T4 therapy was accompanied by a trend toward normalization of TSH biological properties; TSH B/I was higher (1.0 +/- 0.3; P < 0.01), and the degree of sialylation was lower (36.8 +/- 7.0%; P < 0.02). A significant inverse correlation between TSH B/I values and the degree of sialylation was observed (P < 0.001). In normal fetuses, extremely bioactive asialo-TSH isoforms are circulating during the 3rd trimester. The impaired thyroid hormone action, such as that occurring in hypothyroid or RTH fetuses, induces an early expression of alpha-2,6-sialyltransferase activity within thyrotropes and results in the secretion of high amounts of sialylated TSH isoforms (34.6% and 26.3%). A hybrid TSH with peculiar terminal sugar residues and enhanced bioactivity is circulating in patients with RTH (TSH B/I, > or = 2.2). Treatment with low doses of TRIAC can initially reduce thyroid hormone secretion in RTH, mainly through the secretion of TSH isoforms with changed terminal sugar residues and reduced bioactivity (TSH B/I, 0.9-1.7). In conclusion, changes in the terminal sialic acid residues modulate the biological properties of circulating TSH, play a relevant physiopathological role in various situations, and contribute to adjust thyroid-stimulating activity to temporary needs.     

Thyroid-stimulating hormone promotes the secretion of vascular endothelial growth factor in thyroid cancer cell lines

BACKGROUND: Vascular endothelial growth factor (VEGF) is a vascular endothelial cell-specific mitogen secreted by some cancer cells and is a major regulator of angiogenesis. Because thyroid-stimulating hormone (TSH) promotes growth and progression of thyroid cancers, we postulated that TSH may increase the production and secretion of VEGF by thyroid cancer cells. METHODS: We examined primary cultures of normal human thyroid (NT 1.0), medullary thyroid cancer (MTC 1.1), and cell lines derived from the papillary (TPC-1), follicular (FTC-133), and Hürthle cell (XTC-1) thyroid cancer. We quantified the concentration of VEGF in conditioned medium by means of enzyme-linked immunosorbent assay. RESULTS: Cell lines derived from thyroid secrete VEGF. Basal VEGF secretion was similar in normal and thyroid cancer cells, except XTC-1, which has high basal secretion (p < 0.01). All thyroid cancer cells secrete significantly more VEGF than normal thyroid cells after TSH (10 mIU/ml) stimulation (p < 0.05). TSH stimulated secretion of VEGF in FTC-133 (8.2 ng/dl versus 18.8 ng/dl), TPC-1 (5.5 ng/dl versus 26.9 ng/dl), and MTC 1.1 (5.9 ng/dl versus 13.4 ng/dl) cell lines (p < 0.01), but not in NT 1.0 (8.4 ng/dl versus 9.9 ng/dl) and XTC-1 (25.4 ng/dl versus 31.2 ng/dl) cells. CONCLUSIONS: These results suggest that VEGF secretion is constitutively activated in some thyroid cancers and that VEGF secretion is stimulated by TSH; thus TSH may promote growth in some thyroid cancers by stimulating VEGF secretion and angiogenesis.