Outcome of treating hypothyroidism with thyreoideum

The results of hypothyreosis therapy with thyroideum (dried thyroid gland) were assessed in 40 patients. The study aimed at establishing proper dosage and assaying blood serum T4, T3, and TSH levels. Daily dose of 1 tablet (0.2 mg of iodine) improved clinical status but did not cover the daily requirement of the body for thyroid hormones. An increase in daily dose to 2 tablets (0.4 mg of iodine) produced nearly complete compensation of hypothyreosis. However, such a daily dose was often associated with adverse reactions, especially in patients with arterial hypertension or atherosclerosis. Thyroid hormones assay has shown that dried thyroid gland administered in daily dose of 0.4 mg normalizes serum T3 levels whereas serum T3 levels remained constantly low, and TSH increased as in non-treated disease. An increase of the daily dose to 0.6 mg of iodine produces excessive increase in serum T3 levels with clinical symptoms of T3 toxicity.     

Accumulation of zinc in rainbow trout (Oncorhynchus mykiss) after waterborne and dietary exposure

An acromegalic patient with nontoxic autonomous goiter was sequentially treated with octreotide and bromocriptine. Before therapy, serum GH, PRL and insulin-like growth factor-I (IGF-I) levels were increased. Free T3 and free T4 were within the normal range with suppressed TSH levels, whereas 123Iodine-uptake of thyroid was 5.6% after 24 h. During treatment with octreotide and bromocriptine, serum GH, PRL, and IGF-I became normal and free T3 and free T4 were slightly but significantly decreased, but TSH levels remained very low. After thyroidectomy, thyroglobulin, free T3 and free T4 were further decreased, and the TSH levels were recovered to normal. These findings suggested that octreotide and bromocriptine inhibit the release of thyroid hormones from the autonomous thyroid gland directly or indirectly through the decline in IGF-I.     

Iodothyronine content of human thyroid albumin

Stable thyroid hormones (T4 and T3)1) have been demonstrated in pure albumin isolated from normal human thyroid tissue iodinated in vivo. Five samples of albumin were separated from other thyroid proteins by acrylamide gel electrophoresis. After pronase hydrolysis, the content of Thyroid hormones was measured chemically (T4 + T3) as well as by competitive radioactive measurement (T4) and radioimmunoassay (T3). The purity of the albumin and validity of these measurements were confirmed by different techniques. The synthesis of thyroid hormones is not therefore a property unique to Tg and may occur in albumin. However the amount of iodothyronines in the albumin (average 0.004 residue per molecule) is much less than that found in Tg (0.5 residue per molecule). In the albumin as in Tg the number of hormone residues per molecule is proportional to the number of atoms of iodine. At an equivalent iodine concentration, the albumin seems capable of forming the thyroid hormones as well as Tg. The difference between these two proteins, in their capacity to synthesize thyroid hormones, seems to depend on their capacity for iodination. This difference of iodination does not seem to be linked with the number of tyrosyl residues, but might be related to the position of these residues.     

Inhibition in the senso-motor cortex of cats

The clinical course from birth and serial measurements of serum T3, T4 and TSH in an infant with untreated neonatal thyrotoxicosis are reported. The thyroid hormone levels fell exponentially with time at rates very much slower than those previously reported for the maternally-transmitted thyroid stimulating antibody generally thought to cause the disorder. Steady physiological levels of thyroid hormones were achieved after 110 days (serum T3 = 3.4 NMOL/L, T4 = 118 nmol/l). TSH first rose to a measurable level after about 90 days.     

Thyroid profile in normal pregnancy

The aim of this study was to update the thyroid hormone profile in normal pregnant women with adequate iodine nutrition, to analyze the physiological changes that occur during pregnancy and to know the role that TBG and bHCG exert on these changes. One hundred six pregnant women without goiter, former thyroid diseases or positive antimicrosomal antibodies were studied. Fifty three of them were prospectively followed during the gestational period. Thirty age matched non pregnant women were studied as a control group. Serum T3t, T4t, T41, conventional and IRMA TSH, rT3, TBG, bHCG, antimicrosomal antibodies and urinary iodine content were measured. Median urinary iodine content was 18.9 ug/ml in pregnant women, discarding iodine deficiency, the main observed changes occurred between weeks 6 and 14 with significant elevations of T3t, T4t, T41, rT3, TBG and bHCG and TSH decrease. There was a positive correlation between TBG and T3t and T4t indicating a causal relationship. There was a negative correlation between T41 and TSH and between TSH and bHCG and a positive correlation between T41 and bHCG, suggesting a thyroid stimulator effect of bHCG which would raise T41 and thus inhibit TSH secretion.     

Central hyperthyroidism

Central hyperthyroidism is a rare condition in which thyrotoxicosis results from primary overproduction of TSH by the pituitary gland with subsequent thyroid enlargement and hyperfunction. The two known causes of central hyperthyroidism are TSH-producing pituitary tumors (TSHomas) and the syndrome of PRTH. Both of these entities are characterized by clinical thyrotoxicosis, diffuse goiters, elevated circulating levels of free T4 and T3, and a nonsuppressed serum TSH. It is critical to distinguish central hyperthyroidism from the much more common types of primary hyperthyroidism, all of which have undetectable TSH values. TSHomas and PRTH can usually be differentiated from one another by measuring the serum alpha-subunit and the TSH response to intravenous TRH or exogenous thyroid hormone, and by pituitary imaging studies. TSHomas are usually benign adenomas arising from the monoclonal expansion of neoplastic thyrotropes. Causative oncogenes have not yet been convincingly identified. PRTH is a nonneoplastic disorder caused by inherited mutations in the gene for the thyroid hormone receptor beta; it is a poorly understood variant of GRTH. For unclear reasons, in PRTH, the pituitary gland is resistant to the feedback inhibitory effects of circulating thyroid hormones while peripheral tissues respond normally, causing patients to experience the toxic peripheral effects of thyroid hormone excess. TSHomas are best treated by transphenoidal surgical removal. Radiotherapy is indicated for inoperable or incompletely resected tumors. Octreotide administration is a useful adjunct for preoperatively reducing tumor size and for the medical management of surgical treatment failures. PRTH is ideally treated by chronically suppressing TSH secretion with medications such as D-thyroxine, TRIAC, octreotide, or bromocriptine. If such therapy is ineffective or unavailable, thyroid ablation with radioiodine or surgery may be employed with subsequent close monitoring of both thyroid hormone status and pituitary gland size.     

Effect of (-)-N-[(S)-hexahydro-l-methyl-2, 6-dioxo-4-pyrimidinylcarbonyl]-L-histidyl-L-prolinamide (TA-0910), a new TRH analog, on plasma levels of TSH and thyroid hormones in rats

The stimulatory effect of TA-0910 on the secretions of thyroid-stimulating hormone (TSH) and thyroid hormones was investigated in male and female rats. Single intravenous administration of TA-0910 at 8.3 nmol/body acutely elevated the plasma TSH level, with delayed and moderate increases of T3 and T4 in plasma. Similar increments of plasma TSH and thyroid hormones were observed when TRH was injected at the dose of 0.83 nmol/body. Oral administration of TA-0910 at 2.75 mumol/body was equally potent or slightly more potent to secrete TSH than TRH at 0.275 mumol/body. The elevated TSH by TA-0910 decreased to the control level within 2 hr after intravenous injection or within 6 hr after oral administration; on the other hand, the higher levels of the thyroid hormones were retained for up to 4 and 6 hr after intravenous and oral administration, respectively. These findings indicate that TA-0910 and TRH stimulate the secretion of TSH and thyroid hormones by a similar manner and that the TSH-secreting activity of TA-0910 is lower by an order of magnitude compared with that of TRH.     

The "feto-maternal" thyroid function interrelationships in an iodine-deficient region in Africa--the role of T3 in possible fetal defence

The thyroid status was investigated in 26 pregnant African women at term delivery in an iodine-deficient region (Jengere) of Nigeria, West Africa including the measurement of serum T4, T3, TSH, thyroxine binding capacity, TBG, free thyroxine index (FT4I) and the results were matched with those obtained in a corresponding group of 46 women at delivery in Jos, the non-iodine-deficient region which was used as a control. Corresponding cord-blood samples were obtained from all the neonates of the two groups. Twenty-three urinary samples in the former and 14 in the latter group were analysed for iodide levels to ascertain the degree of iodine deficiency. The results demonstrate that compared to the values seen in the Jos group the maternal serum T4, T3 and FT4I levels were significantly reduced in the iodine-deficient group, while TSH, TBG and thyroxine binding capacity were elevated. Cord serum samples showed a corresponding fall in T4 and FT4I levels in the group from the iodine-deficient region, while the T3 levels were significantly elevated with a concurrent significant rise in TSH and TBG levels. Significant correlations were found between the maternal and cord serum T4, TSH, TBG, thyroxine binding capacity and FT4I levels, but not T3. From these findings we suggest that fetal T3 plays an important defensive role against the danger of long-standing environmental iodine deficiency.     

Training for Iowa physicians

"Autonomous" thyroid nodule is a localized nodular lesion of the thyroid gland characterized by growth, iodine uptake and function, all independent from TSH control. These nodules represent a heterogeneous anatomic and clinical entity. The clinical diagnosis is based upon a negative suppression of nodule iodine uptake and scan imaging by T3 administration. The nodule function is determined by high serum thyroid hormone levels and/or low TSH (measured by ultrasensitive assay). Etiology and pathogenesis of these nodules is not yet completely clarified. Both genetic and environmental factors determine nodule growth and function: thyroid cells, in fact, are genetically heterogeneous and may have intrinsic (congenital) characteristics that may promote the growth of cellular clones having mitotic and functional activity that is partially independent of TSH. In these particular cell clones, environmental factors like iodine deficiency or other goitrogens may favour the growth of autonomous nodules and also, by activating their function, may induce toxicity. The autonomous thyroid nodules need to be treated only when they become toxic: in this case both surgical excision or radioiodine may be used.     

Thyroid hormone production and its regulation]

Thyroid gland fulfills two functions. On one hand, it synthesizes and builds up stocks of thyroid hormones in thyroglobulin molecules of the colloid in its follicles, such as they can maintain the hormonal secretion during several days and even weeks. To do this, it captures and concentrates plasma iodide through a specific membrane transporter and it oxidizes iodide through the action of thyroperoxidase and H2O2. This makes it able to bind to tyrosine residus of thyroglobulin. Then, the iodotyrosines can form the thyroid hormones (T4 and T3) by a coupling reaction. On the other hand, thyroid secretes the hormones after internalization and proteolysis of thyroglobulin. All the steps of synthesis and secretion are regulated by pituitary TSH, through a negative feed-back action of T4 and T3. Thus, any increase or decrease of circulating thyroid hormones induces the opposite modification of TSH. In addition, an important fraction of plasma and tissue T3 is produced through the extrathyroidal monodeiodination of T4 by enzymes (5' deiodases) which are regulated by the nutritional status and by thyroid hormones.     

Running economy: comparison of body mass adjustment methods

Iodine plays a central role in thyroid physiology, being both a major constituent of thyroid hormones (THS) and a regulator of thyroid gland function. This review concerns those aspects of thyroid physiology in which significant advances have been made in recent years. We have known for decades that the thyroid gland concentrates iodine (I-) against an electrochemical gradient by a carrier-mediated mechanism driven by ATP. A similar I- uptake mechanism is found in other organs, including salivary glands, stomach, choroid plexus, and mammary glands, but only in the thyroid does TSH regulate the process. This past year saw a major advance with the cloning of the thyroid I- transporter. This development opens the way to an elucidation of the regulation of I- transport in the normal gland and in thyroid neoplasms that lack this property ("cold" nodules). All of the subsequent steps in TH biosynthesis, from oxidation and organification of iodide to the secretion of T4 and T3 into the circulation, are stimulated by TSH and inhibited by excess iodine. Recently, some of the regulatory mechanisms have been clarified. The function of the major TH-binding proteins in plasma is to maintain an equilibrium between extracellular and cellular hormone pools. Transthyretin, the principal T4-binding protein in cerebrospinal fluid, may play a similar role in the central nervous system. Although it generally is agreed that cellular uptake of TH is a function of the unbound (free) form of the hormone, there is evidence that certain TH-binding plasma proteins (i.e., apolipoproteins) may serve specific transport functions. The intracellular concentration of T3, the active TH, is determined by the rates of cellular uptake of T4 and T3, the rates of metabolic transformation, including conversion of T4 to T3, and the rate of T3 efflux. The latter has been assumed to be a passive process. However, recent studies by our group in San Francisco have shown that T3 is transported out of cells by a specific, saturable, verapamil-inhibitable mechanism. This T3 efflux system is widespread among cells from many tissues, and, at least in liver, modulates intracellular and nuclear concentration of the hormone and thereby influences TH action.     

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.     

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.     

Circulating thyroid hormone concentrations and placental thyroid hormone receptor expression in normal human pregnancy and pregnancy complicated by intrauterine growth restriction (IUGR)

Thyroid hormones are critical to growth and development of the human fetus. Abnormal placental development, a major cause of intrauterine growth restriction (IUGR), is associated with a high perinatal mortality and morbidity. Thyroid status has been postulated to play a role in the pathogenesis of such morbidity. In the present study, we have investigated fetal thyroid function and placental expression of thyroid hormone receptor (TR) alpha and beta variants during normal human pregnancy and in pregnancy associated with IUGR. Measurement of free thyroid hormones and TSH concentrations revealed significant rises in free T4 and free T3 between the second and third trimesters of normal pregnancy. Serum concentrations of free T4 and free T3 were lower in fetuses affected by IUGR, although serum TSH levels were not significantly different. Immunocytochemistry demonstrated the presence of TR alpha1, alpha2, and beta1 proteins within the nuclei of trophoblast and stromal placental cells. Immunostaining for these TR variants increased with increasing gestation in normal placenta. Comparison of IUGR placental samples with normal samples revealed greater immunostaining for TR alpha1, alpha2, and beta1 variants in IUGR. Examination of pretranslational expression of TR alpha1, alpha2, beta1, and beta2 variants by semiquantitative RT-PCR revealed increasing expression of TR alpha1, alpha2, and beta2 messenger RNAs with increasing gestation in normal pregnancy, which "mirrored" post-translational expression. However, and in contrast, there were no significant differences in expression of TR messenger RNAs in normal and IUGR placenta. The present findings of reduction in serum free thyroid hormones and increased expression of TR alpha and beta proteins in association with IUGR highlight the potential importance of thyroid status in influencing long-term fetal outcome in this condition.     

Pregnancy following thyroid hormone treatment in a patient with amenorrhea-galactorrhea due to primary hypothyroidism

A 32-year-old female with amenorrhea-galactorrhea due to primary hypothyroidism was treated with thyroid hormones, and serum levels of thyrotropin (TSH), prolactin (PRL), triiodothyronine (T3), thyroxin (T4), and T3 resin sponge uptake (RT3U) were measured throughout the course of treatment. The elevated serum levels of TSH and PRL fell into the normal range following T3 treatment. Subsequently, the menstrual cycle was restored within 1 month, and galactorrhea completely ceased and conception was achieved within 3 months. Desiccated thyroid was administered during pregnancy, and the patient gave birth to a female infant. Impaired secretion of PRL during pregnancy and poor milk secretion with blunted response of PRL to the suckling stimulus during the puerperium were noted.     

Acute effects of chundosunbup qi-training on blood concentrations of TSH, calcitonin, PTH and thyroid hormones in elderly subjects

The present study investigated how the systemic treatment of a programmed exercise, ChunDoSunBup (CDSB) Qi-training, affects the secretion of thyroid and parathyroid hormones in elderly subjects (10 male and 5 female). Plasma concentrations of thyroid stimulating hormone (TSH), triiodothyronine (T3), thyroxine (T4), parathyroid hormone (PTH), ionized calcium, and calcitonin were determined. CDSB Qi-training induces a slight increase in TSH. Both T4 and T3 were increased at the mid-time of CDSB Qi-training (p < 0.05). There were significant correlations only between T3 and T4 at mid-training. This shows that increase in the plasma level of T3 was associated with the secretion of T4. The plasma concentrations of calcitonin and PTH were increased at mid-time and post-time of CDSB Qi-training. But ionized calcium was decreased slightly by CDSB Qi-training. These results suggest that Qi-training modulates the secretion of thyroid hormones, calcium metabolism, and parathyroid hormones in the elderly. However, whether the long-term practice of CDSB Qi-training might change bone metabolism and have longitudinal effects on the thyroid hormone of the elderly need further investigation.     

Hypothyroid patients showing shortened responsiveness to oral iodized oil have paradoxically low serum thyroglobulin and low thyroid reserve. Thyroglobulin/thyrotropin ratio as a measure of thyroid damage

In Central Africa, all of northern Zaire is very severely deficient in iodine. A peculiar feature of this endemia is that iodine deficiency and the ensuing thyroid gland stimulation not only leads to goitre formation but also to progressive thyroid involution and to myxoedematous cretinism. An iodine supplementation trial based on oral administration of small doses of iodine was made in 81 schoolchildren. All of them received a small dose of iodine (0.1 ml containing 48 mg) per os and the thyroid status was followed during 4 months. Blood and urine samples were collected at the start of the study, then 2 weeks, 2 months and 4 months after iodine administration. Before iodine supplementation the mean urinary iodine level was 0.18 +/- 0.02 micromol/l, and 10% of the subjects had a urinary iodine level below 0.08 micromol/l. Fifty-two percent of the subjects had a serum thyrotropin (TSH) level above 10 mU/l. All the subjects responded to the administration of iodine. and all of them recovered a euthyroid status. Most of them were still euthyroid at the end of the study. However. within 4 or even 2 months, some subjects (15 % of the total) reverted to hypothyroidism. At the entry of the study these subjects were all hypothyroid and had elevated TSH and paradoxically low serum thyroglobulin (TG) values. In myxoedematous cretins living in the same area, even lower serum TG levels were found. Together with the absence of goitre, a paradoxically low serum TG Suggests a low thyroid reserve, and in the present case a reduced amount of functional thyroid tissue. We show that the serum TG/TSH ratio may be used as a predictive index of thyroid reserve and of positive response to iodine administration. These data further suggest that thyroid damage is not confined to myxoedematous cretins. but is widely distributed in the phenotypically normal population. Widely distributed thyroid damage may render iodine prophylaxis based on oral administration unpredictable.     

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.     

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.     

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.