The nocturnal thyroid-stimulating hormone surge is absent in overt, present in mild primary and equivocal in central hypothyroidism.

The nocturnal TSH surge was studied in controls, in 34 patients with hypothalamic/pituitary disease and in 21 patients with primary hypothyroidism. It was absent in 5/12 hypothyroid patients and in 5/22 euthyroid patients with hypothalamic/pituitary disease (42% vs 23%, NS). Central hypothyroidism relative to euthyroidism was associated with a lower absolute (0.3 +/- 0.4 vs 0.9 +/- 1.0 mU/l, p less than 0.05) and relative (24 +/- 31 vs 63 +/- 51%, p less than 0.05) nocturnal rise in TSH. In primary hypothyroidism, the nocturnal TSH surge was absent in eight of ten patients with overt, in one of five patients with mild and in none of six patients with subclinical hypothyroidism. The relative nocturnal rise in TSH was normal in mild (54 +/- 33%) and subclinical (92 +/- 69%), but decreased in overt hypothyroidism (2 +/- 10%). Plasma T4 was positively and 09.00 plasma TSH negatively related to the relative nocturnal TSH surge in primary hypothyroidism, but not in central lesions. In both conditions, however, a positive relationship was observed between the relative nocturnal TSH surge and the relative increase of TSH to TRH. In conclusion: (a) The nocturnal TSH surge is usually absent in overt hypothyroidism but present in mild primary hypothyroidism and equivocal in central hypothyroidism. This limits its usefulness as an adjunct in the diagnosis of central hypothyroidism. (b) The magnitude of the nocturnal TSH surge in patients with hypothalamic/pituitary disease or primary hypothyroidism is directly related to the TSH response to TRH, and thus appears to be determined by the directly releasable TSH pool of the pituitary.     

Diagnosis of hidden central hypothyroidism in survivors of childhood cancer

To determine how often central hypothyroidism remains undetected by routine out-patient tests of thyroid hormone, we studied 208 pediatric cancer survivors referred for evaluation because of signs of subtle hypothyroidism or hypopituitarism. Of the 208 (68 females and 140 males), 110 had brain tumors, 14 had other head/neck tumors, 11 had solid tumors remote from head and neck, and 73 had leukemia. Patients were evaluated 1-16 yr (mean, 6.1+/-4.1 yr) after tumor diagnosis. The nocturnal TSH surge and response to TRH were measured. Of 160 patients with free T4 in lowest third of normal, 34% had central hypothyroidism (blunted TSH surge or low/delayed TSH peak or delayed TSH decline after TRH); 9% had central hypothyroidism with mild TSH elevation (mixed hypothyroidism). Another 16% had mild primary hypothyroidism (TSH, 5-15 mU/L). Of 48 with free T4 in the upper two thirds of normal, 14% had central hypothyroidism; 17% had mild primary hypothyroidism. Incidence of central, mixed, and mild primary hypothyroidism 10 yr after tumor diagnosis was significantly related to total cranial radiation dose (P < 0.0001). Of 62 patients with central hypothyroidism, 34% had not developed GH deficiency. TSH surge identified 71%, and response to TRH identified 60% of those with central hypothyroidism. More than half of the slowly growing patients who have received cranial or craniospinal radiation for childhood cancer develop subtle hypothyroidism. In our study group, 92% of patients with central hypothyroidism and 27% with mixed hypothyroidism would have remained undiagnosed using baseline thyroid function tests alone. Both TSH surge and response to TRH must be evaluated to identify all of these patients.     

Blunted nocturnal TSH surge does not indicate central hypothyroidism in patients after pituitary surgery.

The thyrotropin-releasing hormone stimulation test (TRH test) is commonly used as part of the endocrine evaluation after pituitary surgery. However, some patients with a normal thyrotropin (TSH) response to TRH after pituitary surgery develop central hypothyroidism during follow-up. On the other hand, hypothyroidism does not necessarily ensue in patients with a blunted TSH response. As TSH is secreted in a pulsatile fashion with maximum secretion in the early morning, we investigated whether measurement of the nocturnal TSH surge is useful for predicting development of thyrotropic function after pituitary surgery. Serum TSH concentrations were measured at hourly intervals from 16.00 h to 06.00 h in 13 healthy volunteers and in 10 patients within 2 weeks after pituitary surgery. A standard TRH test using i.v. injection of 200 microg synthetic TRH was performed the next morning. Three and six months later thyroid function was reassessed in all patients by measuring thyroid hormones and TSH. Healthy volunteers showed a clear nocturnal TSH surge from a nadir of 0.55 +/- 0.27 microIU/ml at 18.00 h to a peak concentration of 1.82 +/- 0.97 microU/ml at 06.00 h (p = 0.0015). DeltaTSH during TRH test was 6.31 +/- 2.27 microIU/ml. In contrast, following pituitary surgery, patients invariably showed a blunted nocturnal increase in TSH concentration, which was 0.27 +/- 0.20 microIU/ml at 18.00 h and 0.33 +/- 0.26 microIU/ml at 06.00 h (p = 0.044). DeltaTSH during TRH test was 1.99 +/- 2.51 microIU/ml and was subnormal in 8 out of 10 patients. Levothyroxine supplementation was initiated in two of these patients, because free T4 levels were also subnormal and clinical hypothyroidism was present. In the remaining patients with subnormal TRH response, no case of central hypothyroidism was identified at the follow-up visits after 3 and 6 months. We conclude from these data that both nocturnal TSH surge and TRH test are subnormal after pituitary surgery and do not indicate that central hypothyroidism will develop.     

Deficient nocturnal surge of thyrotropin in central hypothyroidism

In normal individuals, serum TSH concentrations have a circadian pattern characterized by a nocturnal surge which begins in the late afternoon and reaches its peak after midnight. We assessed the nocturnal surge of TSH in 16 patients with pituitary and/or hypothalamic diseases, 6 of whom were judged to be hypothyroid. To assess the magnitude of the nocturnal surge in individual patients, TSH was measured in 5 serum samples obtained during the normal time of the TSH nadir in the late afternoon and in 5 samples obtained during the normal time of the peak of serum TSH after midnight. A significant nocturnal surge of TSH was defined as a significantly greater mean nighttime TSH level than the mean daytime TSH concentration. The nocturnal TSH surge was absent in the 6 patients with central hypothyroidism, while it was present in the 10 euthyroid patients with central lesions. In 6 hypothyroid patients who did not have pituitary or hypothalamic lesions, the nocturnal TSH surge was intact, indicating that hypothyroidism per se does not account for the deficient nocturnal TSH surge in central hypothyroidism. We conclude that central hypothyroidism is characterized by a deficient nocturnal surge of TSH, and accordingly, we suggest that evaluation of the circadian pattern of TSH may be a useful adjunct in making the diagnosis of hypothyroidism in patients with diseases involving the pituitary or hypothalamus.     

Hypothyroidism and deficiency of the nocturnal thyrotropin surge in children with hypothalamic-pituitary disorders

The circadian pattern of serum TSH in normal children, aged 5-18 yr, is characterized by a nocturnal surge and is presumably related in some way to a biological clock within the central nervous system. To look for patients deficient in the nocturnal TSH surge, we studied 52 children with hypothalamic-pituitary disorders. Thirteen of the children were hypothyroid, as judged by subnormal serum free T4 (FT4). The hypothyroid patients had a mean nocturnal TSH surge of 22% (range, -30% to +114%), significantly less than that of normal controls (mean, 124%; 95% confidence limits, 47-300%; n = 96; P less than 0.01). Only 1 of the hypothyroid children had a value for the nocturnal TSH surge (114%) that was within the normal range. Nineteen of the 52 patients with hypothalamic-pituitary disorders had subnormal nocturnal TSH surges; their mean iodothyronine values were significantly less than those of the 33 patients with normal surges [total T4, 73 +/- 4 (mean +/- SE) vs. 109 +/- 3 nmol/L (P less than 0.01); FT4, 13 +/- 1.0 vs. 19 +/- 0.5 pmol/L (P less than 0.01)]. These data demonstrate a clear association of a deficient nocturnal TSH surge and low iodothyronine concentration in children with hypothalamic-pituitary disorders. We performed both TRH tests and nocturnal TSH surge tests in 11 of the children with central hypothyroidism; TRH was abnormal in only 2, while the nocturnal surge test was abnormal in 10 of the 11. We suggest that the nocturnal surge of TSH is important for maintenance of thyroid function and conclude that the nocturnal TSH surge is a much more sensitive test than the TSH response to TRH for the diagnosis of central hypothyroidism.     

The lack of nocturnal serum thyrotropin surge in patients with nontoxic nodular goiter may predict the subsequent occurrence of hyperthyroidism

TSH secretion, with particular regard to the nocturnal TSH surge, was evaluated in 115 subjects with non-toxic nodular goiter. All patients were clinically and biochemically euthyroid. After 18-36 months of follow-up (mean, 24 months), hyperthyroidism occurred in 21 (18%; group 1), while the remaining 94 remained euthyroid (82%; group II). The analysis of hormonal data at the time of first observation showed that the 2 groups had similar total and free T4 and T3 serum concentrations. Morning serum TSH values in group I were lower than those in group II patients (0.6 +/- 0.1 vs. 1.1 +/- 0.1 mU/L; P less than 0.001); this difference was even more striking for the nocturnal values (0.6 +/- 0.1 vs. 2.2 +/- 0.2 mU/L; P less than 0.0001); nocturnal values were significantly lower than morning values in group II, but not in group I. The mean peak TSH value after TRH was also significantly reduced in group I (5.5 +/- 0.4 vs. 9.2 +/- 0.7 mU/L; P less than 0.001). Morning TSH values in group II did not differ from those in controls (1.3 +/- 0.1 mU/L), whereas nocturnal and TRH stimulated peak TSH values were slightly but significantly lower. The nocturnal serum TSH values in control subjects were 62-390% higher than morning values. The nocturnal TSH surge was abolished in 18 of 21 (86%) group I patients and in 7 of 94 (8%) group II patients. TRH testing resulted in an absent or blunted TSH responses in 5 subjects in group I and 6 in group II. Analysis by the Galen and Gambino predictive model; comparing the abolition of the nocturnal TSH surge and the abnormal TRH test as predictors of the subsequent occurrence of hyperthyroidism, showed that the former had higher sensitivity (86% vs. 24%) and predictivity (72% vs. 45%). In conclusion, the results of the present study demonstrate that the evaluation of the nocturnal TSH surge may be useful in identifying patients with nontoxic nodular goiter in whom hyperthyroidism may eventually occur. Patients who lack the nocturnal serum TSH surge are more prone to develop thyroid hyperfunction; their thyroid status should, therefore, be more carefully and frequently monitored.     

Circadian variation of thyrotropin in childhood

We evaluated the circadian variation of serum TSH in 96 normal children, aged 5-18 yr. Blood samples were obtained hourly for 24 h, and serum TSH was measured using an immunoradiometric assay with a sensitivity of 0.2 mU/L and an intraassay coefficient of variation of 4.9%. The nadir serum TSH value, defined by the three consecutive hourly TSH concentrations having the lowest mean, occurred between 1000 and 1900 h, while the peak TSH value, defined by the three consecutive hourly TSH concentrations having the greatest mean, occurred between 2100 and 0600 h. The mean nadir serum TSH was 1.6 +/- 0.1 mU/L, and the mean peak TSH was 3.7 +/- 0.2 mU/L. The mean nocturnal TSH surge (percent increase in TSH from nadir to peak) was 144% (95% confidence limits, 50-300%) and did not correlate with serum T4, free T4, or T3 concentrations. Seventy-six children were given TRH (7 micrograms/kg). The mean peak serum TSH after TRH was 16.0 +/- 1.1 mU/L (95% confidence limits, 9.0-42.0 mU/L), and it occurred by 30 min after TRH administration in 92% of the children. The absolute peak nocturnal serum TSH and peak post-TRH serum TSH values correlated significantly (r = 0.62; P less than 0.001), while age, gender, and pubertal status did not correlate with either the nocturnal TSH surge or the TSH response to TRH. We conclude that normal children have a circadian variation of serum TSH characterized by a nocturnal TSH surge, and that the peak of serum TSH, which occurs at night, correlates with the peak serum TSH level after TRH administration.     

Subtle primary hypothyroidism in patients treated for acute lymphoblastic leukemia

We evaluated serum thyroid hormone and thyroid antibody levels, the serum TSH response to TRH, and the circadian pattern of serum TSH in 10 children and adolescents after radiation therapy for acute lymphoblastic leukemia. Four patients had received central nervous system preventive cranial irradiation and intrathecal chemotherapy, and the remaining 6 patients were treated with craniospinal irradiation for central nervous system relapse. Serum total T4 and T3 concentrations were within the normal range and thyroid antibodies were negative in all patients. Four patients who had received craniospinal irradiation had low free T4 levels. Prior to TRH administration, the overall mean serum TSH concentration was 5.4 +/- 1.3 mU/l, and the mean peak response to TRH was 33 +/- 6.5 mU/l. Both were significantly increased when compared to the levels observed in our control population (p less than 0.05 and less than 0.025, respectively). The overall mean nadir diurnal TSH was 3.6 +/- 0.8 mU/l, and the mean peak nocturnal TSH was 6.9 +/- 1.3 mU/l, both significantly elevated when compared to normal children (p less than 0.025). The mean nocturnal TSH surge, however, was not significantly different from normal. Four of 6 children treated with craniospinal irradiation, and one of four children treated with cranial irradiation had increased basal and peak serum TSH concentrations in response to TRH. One of the patients treated with cranial irradiation had an abnormal nocturnal TSH surge. We conclude that subtle primary hypothyroidism is relatively common in patients with acute lymphoblastic leukemia, particularly in those who have been treated with craniospinal irradiation.     

Circadian changes in pulsatile TSH release in primary hypothyroidism

OBJECTIVE: We evaluated pulsatile and circadian TSH secretion in primary hypothyroidism. DESIGN: In a prospective study, blood was sampled every 10 minutes during 24 hours for assay of TSH (IRMA). Thyroid hormones and TSH responsiveness to TRH were then measured. SUBJECTS: Nine patients with overt primary hypothyroidism, seven patients with subclinical hypothyroidism and 16 healthy controls. MEASUREMENTS: Computer-assisted analysis by the Desade and Cluster programs. RESULTS: Both computer-assisted programs revealed an increased TSH pulse amplitude in both overt and subclinical hypothyroidism versus controls (Desade: 36.9 +/- 31.4 (mean +/- SD) (P < 0.001) and 2.8 +/- 1.9 (P < 0.001) vs 0.4 +/- 0.2 mU/l; Cluster: 25.6 +/- 25.1 (P < 0.001) and 2.4 +/- 1.4 (P < 0.001) vs 0.4 +/- 0.2 mU/l). TSH pulse frequency remained unchanged with approximately 10 pulses/24 hours. A highly significant correlation was found between the mean 24-hour TSH concentration and the TSH pulse amplitude in all controls and patients but not to TSH pulse frequency. The nocturnal TSH surge was absent in six out of nine patients with overt primary hypothyroidism. The deficient nocturnal rise of TSH in primary hypothyroidism vs controls (22 +/- 51 vs 82 +/- 41%, P < 0.001), was associated with a loss of the usual nocturnal increase in TSH pulse amplitude and frequency. CONCLUSIONS: Mean 24-hour TSH pulse amplitude is increased in primary hypothyroidism, but TSH pulse frequency remains unchanged. The decrease of the nocturnal TSH increase in primary hypothyroidism is associated with a loss of the usual nocturnal increase in TSH pulse amplitude and frequency.     

Nocturnal serum thyrotropin (TSH) surge and the TSH response to TSH-releasing hormone: dissociated behavior in untreated depressives

TSH secretion, with particular regard to the nocturnal surge of the hormone, was evaluated in 15 women (age range, 35-66 yr; mean, 50 yr) with untreated major endogenous depression and 15 healthy women (age range, 32-67 yr; mean, 53 yr) using an ultrasensitive assay. Mean morning (0830 h) TSH values did not differ in the 2 groups (1.3 +/- 02 mU/L in depressives and 1.4 +/- 0.1 mU/L in controls), whereas mean nighttime (2400-0200 h) values were significantly reduced in depressives (1.5 +/- 0.3 vs. 3.1 +/- 0.3 mU/L; P less than 0.0005). At variance with the control group, morning and nighttime TSH values did not differ in the depressives. The nocturnal serum TSH surge was abolished in 14 of 15 depressed patients. The mean peak TSH value after TRH was slightly yet significantly lower in the depressives. Patients with subnormal (less than 0.4 mU/L) TSH values in the morning had a serum TSH increase after TRH less than 2 mU/L in 5 of 6 cases and a lack of the nocturnal TSH surge in 6 of 6. Among the 9 patients with normal TSH values in the morning, the nocturnal serum TSH surge was lost in 8 of 9, whereas the response to TRH was normal in all. The depressives, at variance with other reports, showed significantly lower values of total and free thyroid hormones. Mean serum sex hormone-binding globulin (SHBG) and ferritin were also significantly reduced. In conclusion, major endogenous depression is associated with a major impairment of TSH secretion, which baseline TSH measurements in the morning and the evaluation of the TSH response to TRH may not reveal. In this regard, the loss of the nocturnal serum TSH rise would appear to be a more sensitive indicator of hypothalamus-pituitary-thyroid axis alterations in depressives than the TRH test, which is commonly used in the evaluation of these patients. The lack of the nocturnal TSH surge may be responsible for the reduced thyroid hormone secretion and supports the case for some degree of central hypothyroidism in endogenous depression.     

Decreased nocturnal surge of thyrotropin in nonthyroidal illness

To evaluate the regulation of TSH secretion in nonthyroidal illness (NTI) we studied the nocturnal TSH surge in 11 healthy controls and 26 NTI patients; none of the patients was on medication known to interfere with TSH secretion. The presence of a nocturnal TSH surge was defined as a mean nighttime TSH (the mean of 5 samples taken hourly from 0000-0400 h) significantly greater than the mean daytime TSH (the mean of 5 samples taken from 1500-1900 h). A nocturnal TSH surge was present in 11 of 26 NTI patients and in 11 of 11 controls (P less than 0.01). Both the absolute (0.3 +/- 0.1 vs. 1.0 +/- 0.2 mU/L; P less than 0.01) and relative (11 +/- 6% vs. 71 +/- 12%; P less than 0.001) nocturnal TSH surges were lower in NTI patients than in controls. NTI patients had lower plasma T3 (1.11 +/- 0.08 vs. 1.84 +/- 0.11 nmol/L; P less than 0.001) and higher plasma rT3 (0.81 +/- 0.24 vs. 0.23 +/- 0.01 nmol/L; P less than 0.001) concentrations than controls, but T4, FT4, and TSH values were similar in both groups. No differences were found between the 15 NTI patients without nocturnal TSH surge and the 11 patients with a nocturnal TSH surge in sex distribution, age, caloric intake, or plasma T4 and T3, but hospital mortality was slightly, although not significantly, higher in those with an absent nocturnal TSH surge. An absent nocturnal TSH surge occurred in 2 of 2 patients with a low TSH (less than 0.4 mU/L), in 11 of 20 patients with a normal TSH (0.4-4.0 mU/L), and in 2 of 4 patients with a high TSH (greater than 4.0 mU/L). Pituitary TSH responsiveness to TRH was similar in patients with or without a nocturnal TSH surge. We conclude that NTI is frequently associated with a decreased nocturnal TSH surge. This phenomenon is not related to ambient plasma T4, T3, or TSH concentrations or pituitary TSH responsiveness to TRH. A decreased nocturnal TSH surge appears to be one of the features of the sick euthyroid syndrome and is probably related to hypothalamic dysregulation.     

Evaluation of the nocturnal serum thyrotropin (TSH) surge, as assessed by TSH ultrasensitive assay, in patients receiving long term L-thyroxine suppression therapy and in patients with various thyroid disorders

Circadian variations of serum TSH concentrations have been reported, with higher values occurring in the late evening or early morning. In patients receiving long term L-T4 suppression therapy, it may be important to achieve suppression of TSH secretion throughout the day. To investigate whether undetectable serum TSH values in the morning are associated with undetectable serum TSH levels at night, serum TSH concentrations were measured by an ultrasensitive immunoradiometric assay in 16 normal subjects, 20 hyperthyroid patients, 10 patients with primary hypothyroidism (either untreated or inadequately treated with L-T4), 1 patient with central hypothyroidism, 10 patients with nontoxic nodular goiter, 5 patients with functioning thyroid adenoma, 20 patients receiving L-T4 replacement therapy, and 30 patients receiving L-T4 suppression. In 6 subjects blood was drawn at hourly intervals for 24 h; in 2 normal subjects a major TSH surge occurred between 2300-0100 h, with other minor peaks, and the same pattern was found in two patients receiving L-T4 replacement, whereas in 2 patients receiving L-T4 suppression, serum TSH was constantly below the limit of detection of the assay (i.e. less than 0.07 mU/L). In the remaining patients blood was drawn at hourly intervals between 2300-0200 h and on the next morning before (0830-0900 h) and 30 min after iv TRH administration. In normal subjects, in patients receiving L-T4 replacement therapy, and in hypothyroid patients, serum TSH values at night were higher than in the morning, with normal responses to TRH in the first 2 groups and exaggerated responses in the latter. The patient with central hypothyroidism had no nocturnal TSH surge and no TSH response to TRH. In all hyperthyroid patients, serum TSH was undetectable both at night and during the day, and none had a serum TSH response to TRH. Among patients with nontoxic goiter, 7 had detectable serum TSH in the morning, with higher values at night, and a normal response to TRH; the remainder had undetectable serum TSH both at night and in the morning, and subnormal or absent TSH responses to TRH. All 5 patients with a functioning thyroid adenoma had undetectable serum TSH levels in the morning and during the night, and subnormal or absent TSH responses to TRH. Of the 30 patients receiving long term (greater than 6 months) L-T4 suppression therapy, 28 had undetectable serum TSH both during the night and in the morning and unresponsiveness to TRH.(ABSTRACT TRUNCATED AT 400 WORDS)     

TSH determination in central hypothyroidism

Central hypothyroidism is one of the limitations of the use of sensitive TSH assays as first line screen in evaluating thyroid function. Studies on this subject are however scarce. The aim of the present study is to evaluate the usefulness of TSH assay before and after TRH on a large series of patients with central hypothyroidism. Fifty two patients presenting with post-partum hypopituitarism (Sheehan's Syndrome), 32 hypothyroids and 20 euthyroids were studied, as well as 21 normal females. There was no difference in TSH basal levels (TSH0) between the hypothyroid (1.43 +/- 0.98 mU/l), the euthyroid patients (1.45 +/- 0.83 mU/l) and the controls (1.32 +/- 0.58 mU/l). Delta TSH (TSH 30 mn after TRH-TSH0) was higher (p < 0.001) in the control group (8.48 +/- 3.76 mU/l) than in the euthyroid group (2.63 +/- 2.22 mU/l) that had a better (p < 0.001) response than the hypothyroid group (0.93 +/- 1.11 mU/l). Ten euthyroid patients had impaired response to TRH, while 6 hypothyroids had a normal test. This test has no advantage over basal TSH in central hypothyroidism diagnosis. TRH test gives many misleading results and have an elevated cost/benefit ratio as compared with the characteristic combination of low thyroxinemia and non elevated TSH0.     

The influence of long-term low dose thyrotropin-releasing hormone infusions on serum thyrotropin and prolactin concentrations in man

The purpose of the present study was to evaluate in man the relative thyrotroph and lactotroph response to a 48-h low dose constant TRH infusion. Before, during, and after the 75 ng/min TRH constant infusion, serum samples were obtained every 4 h in six euthyroid ambulating male subjects for measurements of TSH, PRL, T4, and T3. The TSH response, employing a specific and sensitive human TSH RIA, demonstrated a significant rise from the mean basal pre-TRH value of 2.35 +/- 0.64 microU/ml (+/- SEM) to 3.68 +/- 0.80 (P < 0.005) during the TRH infusion; this value fell below the basal level to 1.79 +/- 0.47 (P < 0.05) post infusion. Serum T4 values were increased above basal both during (P < 0.025) and after (P < 0.025) TRH infusion, whereas serum T3 values were not significantly changed throughout the entire study period. The daily TSH nocturnal surge was augmented in both absolute and relative terms during the first 24 h or the TRH infusion, unchanged during the second 24 h of infusion, and inhibited during the first postinfusion day. Other than a minimal increase in serum PRL during the first few hours of the infusion, no significant alteration in the mean basal concentration or circadian pattern of PRL secretion was evident during or after the low dose TRH infusion. These findings would indicate that 1) near-physiological stimulation of the pituitary with TRH produces a greater stimulation of TSH release than of PRL release and 2) the factor or factors producing the circadian TSH surge may not be mediated through fluctuations in endogenous TRH.     

Usefulness of thyrotropin (TSH)-releasing hormone test and nocturnal surge of TSH for diagnosis of isolated deficit of TSH secretion

Six patients with idiopathic isolated deficit of TSH secretion were examined and reported on. Their clinical symptoms and routine biochemical data were unclear and were not specific for hypothyroidism. Serum triiodothyronine, free thyroxine and TSH levels were slightly low or low-normal. Basal metabolic rate and thyroidal (123)I-uptake were also slightly low or low-normal. The response of serum TSH to TRH stimulation was blunted in all patients. No nocturnal surge of serum TSH level could be seen in any of the patients. Empty sella was revealed in three patients, and pituitary microadenoma in one patient via magnetic resolution imaging. Antihuman pituitary cytosol antibody was seen in five patients. Autoimmunity may have played a role in the pathogenesis of idiopathic isolated TSH deficiency. Routine examination of thyroid function cannot easily detect this disease. TSH response to TRH stimulation and nocturnal surge of TSH should be examined when this disease is suspected.     

Concanavalin-A, lentil, and ricin lectin affinity binding characteristics of human thyrotropin: differences in the sialylation of thyrotropin in sera of euthyroid, primary, and central hypothyroid patients

TSH from human serum was separated into classes by serial lectin affinity chromatography using Concanavalin-A (ConA), lentil, and ricin lectins. TSH from 10 euthyroid subjects, 40 patients with primary hypothyroidism, and 1 patient with central hypothyroidism was studied. The patterns of ConA and lentil affinity binding were similar for diverse patients; forms of TSH that bound firmly to ConA also tended to bind firmly to lentil. Differences in TSH-ricin binding suggested that there were differences in the sialylation of TSH in sera of euthyroid, primary, and central hypothyroidism patients. For euthyroid subjects, 16.1 +/- 5.4% (mean +/- SD) of the TSH bound to ricin, while after neuraminidase treatment, 38.4 +/- 5.4% bound. For patients with primary hypothyroidism, 23.5 +/- 6.0% of the TSH bound to the ricin, while after neuraminidase treatment, 65.7 +/- 8.8% bound. The increase in ricin binding induced by neuraminidase treatment was significantly higher for TSH from patients with primary hypothyroidism than in that from euthyroid subjects (42.3 +/- 7.6% vs. 22.3 +/- 4.4%; P less than 0.01) and was greater for long term than for short term hypothyroid patients (49.5 +/- 5.0% vs. 36.5 +/- 6.5%; P less than 0.01). While 30% of native TSH from the serum of the patient with central hypothyroidism bound to ricin, the amount bound increased only 17.6% after neuraminidase treatment. McKenzie bioassay of pituitary-derived TSH that was similarly fractionated using ricin failed to show detectable differences in bioactivity among the lectin column fractions. Thus, 1) circulating human TSH can be consistently separated into discrete classes using serial lectin affinity chromatography; 2) there is relatively more core fucosylation of the less processed high mannose and hybrid forms of TSH and less core fucosylation of more processed complex forms; 3) ConA and lentil binding of TSH in primary and central hypothyroidism is similar to that in the euthyroid state; 4) patients with primary hypothyroidism have more sialylated TSH than a patient with central hypothyroidism or euthyroid subjects; and 5) the degree of TSH sialylation increases with prolonged primary hypothyroidism.     

Impaired intrathyroidal iodine organification and iodine-induced hypothyroidism in euthyroid women with a previous episode of postpartum thyroiditis.

Postpartum thyroiditis (PPT) is common and occurs in 1.7 to 16.7% of pregnant women, depending upon the study population. Most of these women develop transient hypothyroidism and thyroid function usually returns to normal. We have studied 11 euthyroid women with a previous history of PPT to determine the incidence of subtle defects in thyroid function measured by iodide-perchlorate (I-ClO4) discharge tests and TRH tests and to determine whether these women would develop iodide-induced hypothyroidism. Seven (64%) had positive I-ClO4 discharge tests and 5 (46%) had an abnormally high TSH response to TRH. Thyroid antimicrosomal and antithyroid peroxidase were positive in 8 women (73%) with a previous episode of PPT. The administration of pharmacological amounts of iodide (10 drops of saturated solution of potassium iodide daily) for 90 days to these 11 women resulted in elevated basal and TRH stimulated serum TSH concentrations in 8 (72.7%) compared to TSH values during iodide administration to women who had never been pregnant. Antimicrosomal and antithyroid peroxidase concentrations did not change during iodide administration. These findings strongly suggest that euthyroid women with a previous episode of PPT have permanent subtle defects in thyroid hormone synthesis and are inordinately prone to develop iodide-induced hypothyroidism, similar to findings previously reported in euthyroid subjects with Hashimoto's thyroiditis, with a previous episode of painful subacute thyroiditis, or previously treated with radioactive iodine or surgery for Graves' disease.     

Hypothalamo-pituitary regulation of thyrotrophin secretion in chronically catheterized Brattleboro rats

Plasma TSH rhythms were measured in Brattleboro (DI) and control Long-Evans (LE) rats with an intracardiac catheter allowing repeated sampling in conscious unstressed animals. The TSH response to thyrotrophin-releasing hormone (TRH; 500 ng/100 g body weight) was also determined. Finally, hypothalamic and pancreatic TRH concentrations and TRH-degrading activity (TRH-DA) were measured by specific radioimmunoassay. Long-Evans rats had a 24-h rhythm with a major modulatory 8-h component. In DI rats, only the 24-h rhythm was detected. The mean 24-h rhythm-adjusted mean TSH level was higher in DI than in LE rats (1.38 +/- 0.05 and 1.14 +/- 0.06 micrograms/l respectively, P less than 0.01). The peak TSH response to TRH was significantly increased in DI rats while the pituitary concentration of TSH was also higher (0.93 +/- 0.09 vs 0.39 +/- 0.06 micrograms/mg wet weight in LE, P less than 0.001). Hypothalamic TRH and TRH-DA were similar in both strains. The response to propylthiouracil-induced hypothyroidism was identical in both strains. We conclude that DI rats have a normal pituitary sensitivity to tri-iodothyronine but a central dysfunction in the pituitary environment leading to some alterations of TSH secretion.     

Cranial irradiation and central hypothyroidism.

Cranial irradiation causes thyrotropin (TSH)-releasing hormone (TRH) secretory abnormalities. TRH deficiency leads to abnormal glycosylation of TSH alpha and beta subunits and loss of the normal circadian pattern of TSH secretion (low in the afternoon, a surge in the evening, higher at night). This disruption results in either mixed hypothyroidism (raised TSH with abnormal secretory kinetics) or central hypothyroidism (abnormal secretory kinetics without raised TSH). Although primary hypothyroidism is more common in the general population and cancer survivors, the cumulative incidence of central and mixed hypothyroidism is high during the ten years after cranial irradiation. Monitoring for decline in free thyroxine (FT(4)) and rise in serum TSH, and early recognition using TSH surge and TRH tests, are clinically valuable. Early thyroid hormone replacement therapy to achieve serum FT(4) in the upper half of the normal range is crucial for maintaining optimal health and growth in cancer survivors.     

Abnormalities of hypothalamic-pituitary-thyroid axis in patients with primary empty sella

Primary empty sella (PES) is a very frequent neuroradiological finding in the general population, that can induce hypopituitarism. Some studies focused on the association of PES with GH deficiency (GHD) or hypogonadotropic hypogonadism (HH), while data regarding the involvement of hypothalamic-pituitary-thyroid (HPT) axis, despite sporadic reports of central hypothyroidism, or the occurrence of hypoadrenalism (HA) are scanty. In this study, thyroid function and TSH response to exogenous TRH injection (TRH/TSH) were investigated in 43 patients [10 men and 33 women; aged (mean +/- SD), 48+/-12 yr] with PES: 22 patients had total and 21 partial PES. Forty healthy subjects (9 men and 31 women; aged 46+/-12 yr) were enrolled as a control group. Central hypothyroidism was found only in 2/43 cases, whereas one patient showed primary hypothyroidism. In euthyroid patients, mean serum TSH levels were significantly lower than controls (TSH: 1.0+/-0.7 vs 1.4+/-0.6 mU/l, p<0.01) and 79% of them showed abnormal TRH/TSH responses (TRH test was performed in 34 euthyroid patients: 17 cases with total and 17 cases with partial PES), but mean serum free T4 (FT4) and free T3 (FT3) values were not significantly lower than controls (FT4: 15.9+/-0.4 vs 15.0+/-2.1 pmol/l, p=NS; FT3: 5.3+/-1.2 vs 5.8+/-1.5 pmol/l, p=NS). Moreover, no significant differences were evident in mean serum TSH, FT4 and FT3 between patients with total and partial PES (TSH: 1.1+/-0.7 vs 0.9+/-0.8 mU/l, p=NS; FT4: 16.3+/-2.6 vs 15.7+/-2.2 pmol/l, p=NS; FT3: 5.4+/-1.3 vs 5.2+/-0.8 pmol/l, p=NS) and the TRH/TSH peak was impaired or exaggerated/delayed in 9 and 3 patients with total and in 12 and 3 cases with partial PES. No significant differences in the prevalence of abnormal TRH/TSH responsiveness were found between patients with partial or total PES (chi2=1.6, p=NS). Other impairment of pituitary function was detected in 23/43 patients: GHD was present in 15 cases, HH in 11 and central HA in 5 patients. Isolated or combined hypopituitarism was present in 17 and in 6 patients, respectively. In conclusion, pituitary dysfunction is very frequent in patients with PES, but central hypothyroidism occurs rarely. The entity of arachnoid herniation into the sellar fossa does not play a significant role on the degree of HPT axis dysfunction.