Developmental changes in rat thyroid responsiveness to thyrotropin administered by the subcutaneous and peroral route

It has been demonstrated that orally administered thyrotropin (bovine, bTSH) evokes an increase in circulating T4 and T3 levels in 15-day-old suckling rat pups, but not in weaned animals. Because the feedback mechanisms of the hypothalamo-pituitary-thyroid axis change dramatically during the neonatal period, we chose to examine the efficacy of exogenous bTSH in eliciting a thyrostimulatory response via the subcutaneous (sc) or peroral (po) route in rat pups at 5, 8, 12, and 15 days postpartum. Suckling pups were divided into four groups and received one of the following: (i) 2 IU bTSH/100 g body wt administered sc; (ii) distilled H2O (dH2O) sc; (iii) 2 IU bTSH/100 g body wt given po; (iv) dH2O po. Animals were sacrificed at Time 0 and 1, 2, and 3 hr post-treatment, and the collected serum was analyzed for T4 and T3 by RIA. Maximum serum T4 levels were attained at 2-3 hr post-treatment, and the T4 response to sc-bTSH was significantly greater than that of the po-bTSH groups at all ages examined. This difference became progressively greater with increasing age, due to a persistent decline in T4 responsiveness in animals receiving po-bTSH. No significant differences in T4 or T3 levels attained were observed in 8-day-old rat pups treated with rat vs bovine TSH, either sc or po. Percentage T4 response (vs basal levels) steadily declined between Days 5 and 15 postpartum, in both sc- and po-bTSH treatment groups. Percentage T3 responsiveness to sc-bTSH also declined between 5 and 12 days postpartum, after which time T3 generation increased. Our results suggest that the neonatal rat is highly responsive to exogenous TSH late in the first week of life, and that the permeability of the gut at this stage of development further facilitates the impact of orally ingested TSH in the suckling.     

Thyroid function tests in children with congenital hypothyroidism on L-thyroxine treatment

The plasma levels of thyroxine (T4), triiodothyronine (T3), free T4 (FT4), free T3 (FT3), reverse T3 (rT3) and immunoradiometrically assayed thyrotropin (IRMA TSH) have been measured in 28 L-T4-treated children with congenital hypothyroidism as well as in a control group (group C). The patients were subdivided into 2 groups according to the nonsuppressed (group A) or suppressed (group B) TSH response to TSH-releasing hormone (TRH). Basal IRMA TSH correlated with the TSH increment after TRH and it was significantly lower in group B vs. groups A and C, while no difference was present between groups A and B in regard to T4, FT4 and rT3, all higher than in group C. FT3 levels were similar in the 3 groups. In children, as in adults, basal IRMA TSH seems to be a reliable index in monitoring overtreatment.     

Changes in the hypothalamic-pituitary-thyroid axis during acute starvation in non-obese patients

We investigated changes in the hypothalamic-pituitary-thyroid axis before, during, and after fasting in twenty-one non-obese euthyroid patients with psychosomatic diseases. Blood samples for free T3 (FT3), T3, free T4 (FT4), T4, reverse T3 (rT3), and TSH were obtained from all patients before and on the 5th day of fasting, and in 11 of the same individuals on the 5th day of refeeding. Serum TSH and T3 responses to TRH were also evaluated in 10 patients before and on the 5th day of fasting. During the fast, FT3, T3 and TSH levels decreased significantly and rT3 levels increased significantly whereas FT4 and T4 levels remained within the normal range. Maximal delta TSH, peak TSH levels, max delta T3, peak T3 levels, and net secretory responses to TRH decreased significantly. Peak TSH levels and max delta TSH to TRH correlated well with basal levels of TSH. A statistically significant negative correlation between basal levels of FT4 and TSH was observed. After refeeding, there was a significant increase only in TSH which returned to prefasting values. These results demonstrated that in a state of "low T3" during acute starvation a reduction in serum T3 might depend partly on TSH-mediated thyroidal secretion.     

Effect of methadone on TSH and thyroid hormone secretion

The hypothalamus-pituitary-thyroid function was studied in 15 male patients on chronic methadone treatment (40 mg/day). No significant variations of TSH, T4, T3 and rT3 levels were documented, either in basal conditions or after TRH stimulation; however a reduced TSH pituitary response was recorded in some patients (6 out of 15).     

Effects of chronic anticonvulsant monotherapy on endocrine system in prepubertal children with convulsive disorders. Preliminary data

Effects of phenobarbital (PB), carbamazepine (CBZ) and sodium valproate (VPA) monotherapy on endocrine functions were investigated in 7 clinically prepubertal children aged 5-10 8/12 years. The following meaning results were observed: normal PRL release, low basal T4 levels in PB-, CBZ-treated children and normal T4 basal level in the VPA-treated child; normal T3, rT3, TBG and TSH basal values and normal TSH release in all treated children, normal FSH release in PB-, CBZ- and VPA-treated females, high LH levels before and after LHRH injection in CBZ- and PB-treated females; normal levels in the VPA-treated one, normal basal FSH levels and increased releases in PB- and CBZ-treated males, high LH levels before and after LHRH injection in PB- and CBZ-treated males, normal basal and peak levels of GH.     

The pituitary-thyroid axis in patients with pituitary disorders

The pituitary-thyroid axis of 12 patients, exposed to transsphenoidal pituitary microsurgery because of nonfunctioning adenomas (6), prolactinomas (3) and craniopharyngioma (1), or to major pituitary injury (1 apoplexy, 1 accidental injury), was controlled more than 6 months following the incidents. The patients did not receive thyroid replacement therapy and were evaluated by measurement of the serum concentration of thyroxine (T4), 3,5,3'-triiodothyronine (T3), 3,3',5'-triiodothyronine (rT3), T3-resin uptake test and thyrotropin (TSH, IRMA method) before and after 200 micrograms thyrotropin releasing hormone (TRH) iv. The examination also included measurement of prolactin (PRL) and cortisol (C) in serum. Apart from 1 patient with pituitary apoplexy all had normal basal TSH levels and 9 showed a significant TSH response to TRH. Compared to 40 normal control subjects the 12 patients had significantly decreased levels of T4, T3 and rT3 (expressed in free indices), while the TSH levels showed no change. Five of the patients, studied before and following surgery, had all decreased and subnormal FT4I (free T4 index) after surgery, but unchanged FT3I and TSH. The levels of FT4I were positively correlated to both those of FT3I and FrT3I, but not to TSH. The TSH and thyroid hormone values showed no relationship to the levels of PRL or C of the patients exposed to surgery. It is concluded that the risk of hypothyroidism in patients exposed to pituitary microsurgery is not appearing from the TSH response to TRH, but from the thyroid hormone levels.     

Significance of serum thyrotropin and plasma dopamine concentration in the regulation of thyroid function in elderly subjects

In our previous study, we observed a tendency towards an age-related increase in the serum thyrotropin (TSH) concentration. Regulatory mechanisms of TSH secretion in elderly subjects were studied. In 43 elderly subjects, serum TSH did not correlate significantly with serum T4, T3 free T4 or rT3. Further, those with increased TSH (greater than 5 mU/l, 9 subjects) did not overlap with those with low T3 (less than 0.92 nmol/1, 8 subjects). Increases in serum TSH were not associated with the presence of circulating anti-thyroid autoantibodies. A TRH test using a 500 micrograms single bolus injection was performed in 15 subjects. TSH response (basal: 1.92 +/- 1.42 (s.d.) mU/1, peak: 11.25 +/- 5.33 mU/1, sigma: 26.74 +/- 12.89 mU/1, respectively) did not differ significantly from that of younger subjects. T3 response after TRH varied greatly and a close correlation was observed between basal T3 and peak T3 (r = 0.86), and also between peak T3 and delta T3 (r = 0.81). A significant correlation was observed between sigma TSH and basal T3 (r = 0.60). Neither plasma cortisol, epinephrine nor norepinephrine concentrations showed any significant correlation with basal and TRH-stimulated TSH or T3 concentrations. However, the plasma dopamine concentration correlated significantly with sigma TSH (r = 0.60) and basal T3 (r = 0.52), respectively. In conclusion, the increase in serum TSH observed in elderly subjects was felt to represent a physiological adaptation to maintain serum T3. Low T3 subjects appear to have a disturbance in this mechanism, with decreased TSH and T3 response to TRH stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thyroid function and trisomy 21. TSH increase and rT3 deficiency

An excess of thyrotropin (TSH) with normal levels of tetraiodothyronine (T4) and of 3,5,3'-triiodothyronine (T3) was confirmed in the serum of 78 trisomy 21 children. A severe deficiency of 3,3',5'-triiodo-thyronine (rT3 or reverse T3) was observed and the decrease of the rT3/TSH ratio was highly significant. These new facts suggest that the rT3 deficiency plays a peculiar role in trisomy 21 (maybe through the regulation of one or few steps of monocarbons' metabolism). A systematic control of thyroid function (including the patient's rT3 level) is mandatory for the follow-up of every trisomy 21 patient.     

Effects of anticonvulsant monotherapy in pregnancy on the newborn endocrine system. Preliminary data

Pituitary-thyroid axis function and gonadotropin secretion were evaluated by a combined TRH and LHRH test in 4 newborn female infants appropriate for gestational age of mothers treated by AEDs throughout pregnancy. We found: high basal FSH levels with normal FSH reserve, normal LH-HCG levels both before and after LHRH stimulation, normal TSH and T4 levels both before and after TRH stimulation, high T3 basal values with a normal increase after TRH and low rT3 basal values. It is suggested an AED increased T4 deiodination towards T3 in the newborn liver without a marked impairment of the endocrine functions of the fetus.     

Serum TSH, T4, T3, FT4, FT3, rT3, and TBG in youngsters with non-ketotic insulin-dependent diabetes mellitus

Several parameters of thyroid function were studied in 112 non-ketoacidotic youngsters with insulin-dependent diabetes mellitus (IDDM). Levels of thyroxine (T4), reverse triiodothyronine (rT3), thyroxine-binding globulin (TBG) and T3 were lower than in controls, whereas FT4, and FT3 were normal. T4 levels in IDDM patients were positively related to T3, rT3 and TBG, and inversely related to haemoglobin A1 (HbA1). However, only 4 patients showed biochemical hypothyroidism (T4 less than 5 micrograms/100 ml), whereas their FT4, FT3 and thyroid-stimulating hormone (TSH) levels were normal. Concurrent variations of T3 and rT3 levels were found in IDDM patients; thus, their T3/rT3 ratios were stable or higher than in controls, indicating that peripheral deiodination of T4 is preferentially oriented to production of rT3 only during ketoacidosis. Although changes in thyroid function may reflect the degree of metabolic control of diabetes in a large population, the clinical usefulness of serum thyroid hormone measurements in an individual case still appears to be limited.     

Apparent increase in type I 5'-deiodinase activity induced by antiepileptic medication in mentally retarded subjects

BACKGROUND/OBJECTIVES: Thyroid function measurements in 3 mentally retarded patients treated with antiepileptic drugs (phenytoin or carbamazepine) showed normal thyroid-stimulating hormone (TSH) responses in spite of markedly low levels of total thyroxine (T(4)), triiodothyronine (T(3)), and free thyroxine (FT(4)) concentrations; free triiodothyronine (FT(3)), as well as mean thyroxine-binding globulin (TBG) concentrations were normal. The objective of the present investigations was to determine if antiepileptic medication in these patients contributed to the disparate TSH and thyroid hormone (TH) levels. METHODS: Thyroid tests and other laboratory parameters were measured by conventional techniques. RESULTS: Circulating TH changes noted in retarded patients were similar to those observed in control subjects receiving carbamazepine alone. Reverse T(3) (rT(3)) levels in all patients were either undetectable or below the normal range. CONCLUSIONS: As type I 5'-deiodinase has a higher affinity for rT(3) than T(4), an increased activity of this enzyme would enhance rT(3) deiodination and reduce serum rT(3) concentration whereas enhanced T(4) deiodination would aid in normalizing intracellular FT(3) concentration. The finding of normal serum FT(3) concentration was consistent with normal TSH response and clinical euthyroidism in both retarded and control subjects. While phenytoin-induced increase in type I 5'-deiodinase has been previously noted, the present studies demonstrate a similar effect of carbamazepine on 5'-deiodinase.     

Unusual features of neonatal thyroid function in small-for-gestational-age lambs. Origin of plasma T4 and T3 deficiencies

Thyroid function was studied in small for gestational age (SGA) or control newborn lambs. Neonatal changes in plasma concentrations of TSH, T3, rT3, total and free T4 were monitored, and thyroid scintigraphs were performed. Responsiveness of the hypothalamic-pituitary-thyroid axis to cold exposure and TRH or TSH administration was assessed. In addition, T4 and T3 kinetic studies were performed. In agreement with results obtained in babies, plasma T3, total T4 and free T4 concentrations were depressed in low birth weight animals, whereas TSH and rT3 levels were not affected. Thyroid size expressed relatively to the body weight was higher in SGA animals, thus suggesting that a partial compensation for low thyroid hormone levels had occurred during the fetal life. Plasma TSH and T4 concentrations increased by a same extent after exposure to cold and TRH or TSH administration in SGA and control lambs; however, the rise in T3 levels was depressed in the former in all stimulation tests. T3 and T4 production rates were similar in the two experimental groups. In SGA lambs, the metabolic clearance rate and the total distribution space of these two hormones were significantly increased; the fast T3 pool was higher, and the slow T3 pool lower than in control animals. All these results demonstrate that, despite low circulating thyroid hormone concentrations, SGA lambs are not hypothyroid. An increased T4 and T3 storage in the extravascular compartment is probably the major factor involved in the occurrence of this plasma deficiency.(ABSTRACT TRUNCATED AT 250 WORDS)     

The role of estrogen in the TSH and prolactin responses to thyrotropin-releasing hormone in postmenopausal as compared to premenopausal women.

The basal and TRH (Thyrotropin-Releasing Hormone) stimulated TSH (Thyrotropin) and PRL (Prolactin) responses (incremental area; IA) to 200 micrograms TRH was studied in 13 pre- and 13 postmenopausal women of 60 years of age. Both groups consisted of healthy women, none had goiter and all were negative for thyroid autoantibodies. The serum levels of TSH, T3, T4 and SHBG (sex hormone-binding globuline) were in the normal range and did not differ significantly between the groups. There were no differences in basal TSH (1.3 +/- 0.5 vs 1.4 +/- 0.5 mIU/l) or PRL (6.4 +/- 2.7 vs 6.6 +/- 2.5 micrograms/l) or for PRL IA (498 +/- 126 vs 584 +/- 165) between pre- and postmenopausal women. However, for TSH IA there was a slight decrease (15%), but not significant, in the postmenopausal group compared to the premenopausal group (1630 +/- 598 vs 2067 +/- 893). In conclusion, a weak but not significant decrease in the TSH response to TRH in postmenopausal women may be explained by the lower endogenous estradiol level.     

Metabolism of thyroxine in acute viral hepatitis

Aim of this report was to define the correlation between hepatic acute damage and thyroxine metabolism. We have studied plasma levels of T4, T3, rT3 and TSH in 18 adult male subjects with acute viral hepatitis. No significant variation of T4, T3 and TSH plasma levels was found in different phases of disease. However, plasma rT3 levels were clearly elevated in 72% of patients in the first 7 days (mean 440 pg/ml vs 198 pg/ml of normal controls) and in 17% of cases in the second 10 days of disease (mean 269 pg/ml). Plasma rT3 concentration was always normal in the subsequent phases of disease. Our results indicate a diversion of peripheral thyroxine metabolism in the early stages of acute hepatitis.     

Anomalies in thyroid function in children with trisomy 21

Thyroid function of 60 children with Down (DS) aged 3 months to 16 years was studied by evaluation of serum concentration of ultra-sensitive thyroid stimulating hormone (TSH), free T4 and T3 (FT4, FT3), total T4 and T3 (T4 and T3) and reverse T3 (rT3). Each DS child was matched to a control of the same age. The concentration of TSH was increased in DS children while the concentration of rT3 of the DS children was significantly decreased compared to the controls as was the ratio rT3/TSH. These results showed that thyroid function of DS children is abnormal.     

The effect of propylthiouracil on thyroid-stimulating hormone-induced alterations in iodothyronine secretion from perfused dog thyroids

The aim of this study was to see whether the inhibitory effect of propylthiouracil on thyroidal secretion of 3,5,3'-triiodothyronine (T3) and 3,3',5'-triiodothyronine (rT3) could be reproduced in intensively stimulated thyroids, and to elucidate whether an increase in the fractional deiodination of thyroxine (T4) to T3 and rT3 during iodothyronine secretion might be responsible for the transient fall in the T4/T3 and T4/rT3 ratios in thyroid secretion seen in the early phase after stimulation of thyroid secretion. For this purpose T4, T3 and rT3 were measured in effluent from isolated dog thyroid lobes perfused in a non-recirculation system using a synthetic hormone free medium. 1 mmol/1 propylthiouracil induced a significant reduction in thyroid-stimulating hormone (TSH) stimulated T3 and rT3 release while the release of T4 was unaffected. This supports our previous conclusion that T4 is partially monodeiodinated to T3 and rT3 during thyroid secretion. Infusion of 1 mmol/l propylthiouracil for 30 min or 3 mmol/l propylthiouracil for 120 min did not abolish the transient fall in effluent T4/T3 and T4/rT3 induced by TSH stimulation. Thus, this phenomenon seems not to depend on intrathyroidal iodothyronine deiodinating processes.     

Thyroid hormone regulation by stress and behavioral differences in adult male rats

Thyroid hormones are essential regulators of growth, development and normal bodily function and their release is coordinated by the hypothalamic-pituitary-thyroid (HPT) axis. While the HPT axis has been established as an acutely stress-responsive neuroendocrine system, relatively little is known about the mechanisms of its stress regulation. The present study examined acute stress-induced changes in peripheral hormone levels [triiodothyronine (T3); thyroxine (T4), thyroid-stimulating hormone (TSH), reverse triiodothyronine (rT3)] and central mRNA levels of regulators of the HPT axis [thyrotropin-releasing hormone (TRH), somatostatin (SST), type II deiodinase (D2)] in response to an inescapable tail-shock, a rodent model of stress. Additionally, we examined whether individual differences in spontaneous exploratory behavior in an open field test predicted basal levels of TH or differential susceptibility to the effects of stress. The stress condition was associated with decreases in peripheral T3, T4 and TSH, but not rT3, when compared with controls. No changes were observed in TRH or SST mRNA levels, but there was a trend suggesting stress-related increases in D2 mRNA. We also found that an animal's exploratory behavior in an unfamiliar open field arena was positively related to peripheral thyroid hormone levels and predicted the magnitude of stress-induced changes.In conclusion, we found suggestive evidence for stress-induced decrease in central drive HPT axis, but the central mechanisms of its stress regulation remain to be elucidated. Additionally, we found that individual differences in animals' exploratory behavior were correlated with peripheral TH levels.     

Relationship between the thyroidal and gonadal axes during the estrous cycle of ewes of different breeds and ages

In order to define the patterns of TSH, T4, T3, rT3, GH and cortisol during the estrous cycle of sheep, pluriparous and primiparous ewes were synchronized with progestagen-impregnated pessaries (Veramix) at the start of the normal breeding season. After the pessaries were removed (day 0), daily blood sampling was carried out in cannulated ewes during the ovulatory cycle. Hormonal analyses of TSH, T4, T3, rT3, GH, cortisol, LH and progesterone (P) were performed by RIA. P and LH levels during the cycle were conform to the literature and were not different between the primiparous and pluriparous ewes of different breeds used in this study. Neither age nor breed influenced the hormone patterns. A significant negative correlation was found between TSH and P during the cycle, although the correlation between P and T4 was not significant; during the estrous period, low P levels were paralleled by high T4 levels, whereas the reverse was observed during the luteal phase. Higher T3 levels and T3/T4 ratios were observed during the luteal phase. No obvious pattern of rT3 and cortisol during the cycle was found. The GH concentration increased during the 17 days of the cycle. A positive correlation with P was calculated. During the estrous cycle obvious changes in thyroid hormones, GH and TSH occurred. However, this study shows no causal relationship between the thyroid and the gonadal axes.     

Pituitary-thyroid axis sensitivity and neonatal changes in plasma iodothyronine, thyreostimulin and cortisol levels in the preterm lamb: comparison of two experimental models

The influence of a 7 days prematurity, induced by oestrogen or dexamethasone injection to the mothers, on neonatal changes in plasma T4, T3, reverse T3 (rT3), TSH and cortisol levels was studied in 6 full term, 6 oestrogen preterm and 6 dexamethasone preterm lambs. In addition, the pituitary-thyroid axis sensitivity was assessed by the magnitude of the response to TRH administration. At birth, plasma cortisol and T3 levels, as the value of the T3/T4 ratio, were significantly lower in the two groups of preterm lambs than in full term animals; however, whereas plasma T3 concentrations and values of the T3/T4 ratio remained low in oestrogen lambs, they were quickly restored and elevated T3 levels associated to high T4 levels could be even observed in dexamethasone lambs; in this last group, these abrupt changes could be a consequence of raised TSH plasma concentrations recorded at birth. Moreover, if plasma rT3 levels and values of the rT3/T4 ratio were similar during the first hours of life in dexamethasone and full-term lambs, they were significantly higher in oestrogen animals. The responsiveness of the pituitary-thyroid axis to TRH was normal in dexamethasone animals, but was significantly enhanced in oestrogen ones, probably as a consequence of low T3 levels.     

Behaviour of serum T3, rT3, TT4, FT4 and TSH levels after exercise on a bicycle ergometer in healthy euthyroid male young subjects

In order to know thyroid function during physical activity, just studied by several authors without univocal findings, we have submitted 10 young subjects, non athletes, aged 22-25 years (mean age 23, 6 +/- 1, 43) to a biologically maximal exercise on a bicycle ergometer. We have also examined the change of TSH serum levels during exercise. Our data show an evident increase of T4 (18, 60% at 10'), p less than 0.025, an increment of FT4 (28, 49 soon after the strain), and no relevant change of T3 and rT3 serum levels. Moreover TSH values show a reduction at 30' (-26, 15%) in comparison with the basal level. Our findings confirm the known increment of T4 and FT4 serum level after physical activity. It can be due, more than an hemoconcentration supported by others, to a real rise of thyroid incretion as in our opinion TSH levels reduction suggests. Concluding we think that the increase of T4 and decrease of TSH could be due to a direct influence of the physical activity on the system interested in their production.