Thyroid function studies in the nephrotic syndrome.

Total serum and urinary thyroxine (T4), triiodothyronine (T3), and thyroxine-binding globulin (TBG) as well as serum free T4, thyroid-stimulating hormone (TSH), and T3 resin uptake (T3RU) were measured in seven patients with the nephrotic syndrome. The nephrotic syndrome was defined by proteinuria exceeding 3 g/24 h. All patients were clinically euthyroid. Most values for total serum T4, free T4, T3, T3RU, TBG, and TSH were within normal limits. However, the mean serum T3 and TBG values were significantly lower in patients compared with the control group. The values (mean +/- 2 SD) for urinary T4 were 24.3 +/- 20.3 in the patient group and 1.5 +/- 0.7 microgram/24 h in the control group. Urinary T3 values for patients and the control group were 2100 +/- 856 and 848 +/- 253 ng/24 h respectively. Urinary TBG was 2.1 +/- 1.8 mg/24 h in the patients and undetectable in the control group. There was no correlation between daily urinary T3 and T4 and urinary TBG. There was a weak correlation between daily urinary protein excretion and urinary T4 (r = 0.5).     

Reference values for thyroid 24 hours 123I uptake

To establish references for thyroid 24 h 123I uptake value (TUV), we reviewed 475 patients who had free T4 and TSH dosages, and TUV measured 24h after the administration of 123I. The patients were separated in 3 groups: hyperthyroid, euthyroid and hypothyroid, according to thyroid hormone results. The mean and standard deviation (SD) of the TUVs were calculated for each group. We used the unpaired T test to compare the means and ROC curves to evaluate the best TUV to separate the groups. The mean and SD of TUVs for the groups were: hyperthyroid (36.5% +/- 16.5%), euthyroid (14.4% +/- 5.48%) and hypothyroid (13.7% +/- 7.5%). The unpaired T test showed statistically significant difference between hyperthyroid and euthyroid groups (p < 0.01). There was no significative difference between hypothyroid and euthyroid groups (p = 0.55). The 23% TUV has the best sensitivity (80%)/specificity (93%) ratio to separate hyperthyroid from euthyroid groups. There was not a good TUV to separate euthyroid form hypothyroid groups. In conclusion, it can be established 23% as the optimal superior limit for the normal uptake values. However, it was not possible to establish a suitable inferior limit, due to the expressive overlay of TUVs of hypothyroid and euthyroid groups.     

Epinephrine-induced alterations in urinary cyclic AMP in hyper- and hypothyroidism.

Although ratios of urinary cyclic AMP (cAMP) to creatinine were found in this study to be elevated in hyperthyroidism, as previously reported, this elevation appears to result primarily from a decrease in the rate of urinary creatinine excretion associated with the hyperthyroid state and not to be due to an increase in the urinary cAMP production rate. Indeed, there was no significant alteration observed in the urinary cAMP excretion found in 15 hyper-, 12 eu-, and 5 hypothyroid subjects. However, a slight, but significant increase in the 24-hour urinary cAMP excretion was noted in ambulating hyperthyroid subjects (8.5 +/- 2.4 muMol/day; normal 5.2 +/- 1.6 muMol/day; P less than .05). In contrast, the effect of the infusion of 0.05 mug/kg/min of epinephrine over a 2-hour period, resulted in a significantly greater rise in urinary cAMP excretion in hyperthyroid patients (0.83 +/- 0.07 muMol/h) compared to euthyroid subjects (0.53 +/- 0.4 muMol/h; P less than .005). Furthermore, hypothyroid subjects had no significant rise in urinary cAMP excretion after epinephrine infusion (P less than .001). Cardiovascular end-organ response to the epinephrine infusion was also greater in the hyperthyroid subjects and virtually absent in the hypothyroid group. These results suggest that there may be a significant alteration in the cAMP generating systems in states of thyroid hormone excess or insufficiency, and that provocative stimuli, such as epinephrine, may have its end-organ response modified by thyroid hormone effects on adenylate cyclase-cyclic AMP generating systems.     

The effect of treatment of hyper- and hypothyroidism on urinary excretion of cyclic adenosine 3',5'-monophosphate.

The urinary excretion of cyclic adenosine 3',5'-monophosphate (cyclic AMP) was examined in patients with hyperthyroidism and primary hypothyroidism, before treatment and at least six months later on return to euthyroid status. Urinary cyclic AMP excretion was significantly greater in the hyperthyroid group than in the hypothyroid group both in the basal state (P less than 0.01) and the ambulant state (P less than 0.001). In ambulant hyperthyroid patients absolute urinary cyclic AMP excretion (mumol/24 h) was significantly greater (P less than 0.05) prior to treatment than on return to euthyroid status. In the hypothyroid group no significant change occurred after treatment with 1-thyroxine (P greater than 0.05). The mechanism of changes in urinary cyclic AMP excretion in thyroid disease are discussed.     

3,5-DIIODOTYROSINE AND THYRONINE IN THE URINE OF PATIENTS WITH CHRONIC RENAL DISEASE

Urinary 3,5-diiodotyrosine (DIT) and thyronine (T0) excretion was investigated in 18 patients with chronic renal disease. In accord with previous findings serum T4 and thyroid hormone binding proteins measured in 17 patients were in the low or normal range. Urinary albumin excretion was elevated in all 18 and T4 binding prealbumin (TBPA) in 15 of the 18. Urinary T0 excretion measured in 12 patients was also significantly lower than normal (mean +/- SD 4.4 +/- 2.6 vs 15.8 +/- 5.8 nmol/24 h renal vs normal 2 P less than 0.001). In contrast urinary DIT excretion was significantly elevated in renal patients compared with normal subjects (2.0 +/- 1.5 vs 0.75 +/- 0.41 nmol/24 h, respectively). Possible sources of the increased DIT are discussed.     

AN IMPROVED METHOD FOR THE RADIOIMMUNOASSAY OF FREE-THYROXINE IN SERUM DIALYSATES

A convenient, sensitive radioimmunoassay of free thyroxine in serum dialysates is described. The method utilizes a solid phase separation system (pre-formed double antibody) and a relatively short incubation period (220 min) with a staggered addition of tracer. Blanks were low and consistent. The normal range for non-pregnant euthyroid samples (n= 59) was 11–23 pmol/1. Third trimester pregnancy samples were mostly within the normal range but at the lower end. Patients on T4 replacement showed a much wider variation in free T4 levels with many samples in the hyperthyroid region. Some hypothyroid samples had undetectable free T4 levels and hyperthyroid samples were frequently greater than 80 pmol/l.     

Thyroxine uptake by human hepatoma cells from serum of patients submitted to long-term thyroxine suppressive therapy

The significance of thyroxine (T4) uptake from serum in the assessment of thyroid status was evaluated, using human hepatoma (Hep G2) cells, in 30 euthyroid subjects, 6 hypothyroid and 19 hyperthyroid patients, and in 23 athyreotic cancer patients under T4 suppressive therapy. Cellular thyroxine (CT4) was determined according to Sarne and Refetoff, J. Clin. Endocrinol. Metab. 61: 1046, 1985. CT4 averaged 9.9 +/- 2.8 pg/well (mean +/- SD, range 5.7-15.3) in euthyroid subjects, 1.5 +/- 1.0 pg/well (range 0.05-4.2) in hypothyroid patients, 40.5 +/- 18.8 pg/well (range 18.3 +/- 104.7) in hyperthyroid patients, and 23.7 +/- 7.2 pg/well (range 14.2-40.2) in T4-treated patients. In eu-, hypo- and hyperthyroid patients, a significant correlation was observed between CT4 and free T4 index (FT4I), free T4 (FT4) or Sex Hormone Binding Globulin (SHBG) values. In T4-treated patients, CT4 values were correlated with FT4I values, but not with FT4 or SHBG levels. All T4-treated patients with elevated SHBG levels had elevated FT4, FT4I and CT4 values. In contrast, of the 16 T4-treated subjects with normal serum SHBG concentrations, all but one had normal FT3, 3 (19%) had elevated FT4, 10 (62%) elevated FT4I and 13 (81%) elevated CT4, but all (100%) had undetectable TSH levels. Thus, considering serum SHBG concentrations as a parameter of hepatic tissue response to thyroid hormone, CT4 values, at least in T4-treated patients, do not accurately reflect the liver responsiveness to thyroid hormone action.     

Free thyroxine values in dried blood spots on filter paper in newborns are related to both gestational age and birth body weight

The results of free thyroxine (FT4) measurements in dried blood spots on filter paper in 744 euthyroid newborns (616 at term, 128 preterm), 10 newborns with congenital hypothyroidism and 4 euthyroid newborns with congenital TBG deficiency are reported. FT4 was measured by column adsorption chromatography of free hormone followed by radioimmunoassay in the eluate. FT4 values averaged 24 +/- 0.2 pmol/L (mean +/- SE) in euthyroid newborns, 23.0 +/- 0.9 pmol/L in euthyroid newborns with TBG deficiency (p = NS), and 5.7 +/- 0.4 pmol/L in hypothyroid newborns (p less than 0.001 vs both groups). Total T4 (TT4) values in newborns with TBG deficiency were not different from those in hypothyroid newborns, but were significantly lower than those in euthyroid newborns without TBG abnormalities. FT4 values were higher in full-term newborns than in preterm newborns (25.2 +/- 0.3 vs 21.2 +/- 0.5 pmol/L, p less than 0.001). In both full-term and preterm newborns FT4 values in dried blood spots increased with birth body weight (bbw), virtually plateauing when bbw was greater than 2,500 g. The cut-off values established on the basis of the bbw (8.0 and 13.1 pmol/L for a bbw of less than or equal to 2,500 g and greater than 2,500 g, respectively) showed higher specificity and predictive value of positive results than the cut-off values based on the gestational age. In any case, the sensitivity, specificity and predictive values of FT4 determinations proved to be higher than those of TT4 and TSH measurements.(ABSTRACT TRUNCATED AT 250 WORDS)     

Decreased adrenergic sensitivity in patients with hypothyroidism

Cardiovascular sensitivity to catecholamines was assessed in 15 patients with hypothyroidism (mean [+/- SEM] thyroxine [T4] index 2.7 +/- 0.5 micrograms/100 ml, thyroid stimulating hormone [TSH] 136.9 +/- 48.3 microU/ml), aged 45 +/- 4 years and in 8 healthy control subjects. The study was repeated in 10 patients with hypothyroidism 4.0 +/- 0.5 months after thyroid replacement therapy (T4 index 9.9 +/- 2.1 micrograms/100 ml, TSH 3.5 +/- 1.3 microU/ml). In addition, basal, average and maximal heart rates were measured using 24 h ambulatory electrocardiographic (ECG) monitoring, and plasma levels of epinephrine and norepinephrine were determined before and after thyroid replacement. Heart rate increased less after bolus injection of 0.8, 1.6 and 3.2 micrograms of isoproterenol in the hypothyroid (10 +/- 2, 15 +/- 2 and 21 +/- 4 beats/min, respectively) than in the euthyroid (16 +/- 3, 22 +/- 3 and 30 +/- 4 beats/min, respectively) state (p less than 0.05). Control subjects reacted similarly to patients receiving thyroid replacement. Basal heart rate (64 +/- 3 versus 68 +/- 3 beats/min, p less than 0.05) and maximal heart rate (116 +/- 5 versus 133 +/- 5 beats/min, p less than 0.05) were lower on 24 h ambulatory ECG monitoring in the hypothyroid than euthyroid state despite higher basal plasma norepinephrine levels (394 +/- 45 versus 315 +/- 45 pg/ml, p less than 0.05). Thus, patients with hypothyroidism display a decreased cardiac chronotropic response to beta-adrenergic stimulation. This may contribute in part to the decreased basal and maximal daily heart rates seen in patients with hypothyroidism, which occurs despite elevated plasma norepinephrine levels.     

Plasma norepinephrine kinetics, dopamine-beta-hydroxylase, and chromogranin-A, in hypothyroid patients before and following replacement therapy

Whether the increased plasma norepinephrine level reported in hypothyroidism is the result of impaired norepinephrine (NE) clearance or increased NE release by nerve terminals is unknown. We, therefore, measured plasma NE levels and clearance in 11 hypothyroid patients before [T4 index, 41.2 +/- 7.7 nmol/L (mean +/- SEM); TSH, 71.4 +/- 23.0 mU/L] and 4 +/- 0.5 months after thyroid replacement (T4 index, 136.4 +/- 24.4 nmol/L; TSH, 3.2 +/- 1.2 mU/L) and in 8 healthy volunteers. Plasma dopamine-beta-hydroxylase and chromogranin-A, which are coreleased with NE by sympathetic nerve endings, were also measured. Plasma NE was higher in the hypothyroid (2.37 +/- 0.24 nmol/L) than in the euthyroid state (1.86 +/- 0.24 nmol/L; P less than 0.02) or in the controls (1.87 +/- 0.27 nmol/L). Plasma clearance of NE, however, was not affected after thyroid replacement (hypothyroid, 2.08 +/- 0.31 L/min; euthyroid, 1.94 +/- 0.21 L/min; controls, 1.86 +/- 0.15 L/min). There was no significant change in plasma dopamine-beta-hydroxylase (hypothyroid, 720 +/- 139 nmol/mL.h; euthyroid, 553 +/- 97 nmol/mL.h) or plasma chromogranin-A (hypothyroid, 48.9 +/- 7.1 ng/mL; euthyroid, 42.9 +/- 5.3 ng/mL) after thyroid replacement. We conclude that the increased plasma NE in hypothyroid patients is not due to a change in plasma clearance, but is more likely secondary to increased NE release.     

Immediate effects of furosemide on renal hemodynamics in chronic liver disease with ascites

Furosemide occasionally causes azotemia in patients with ascites, independently of induced volume depletion. To define this effect, we measured renal clearances in patients with chronic liver disease and ascites and in nonascitic controls. Furosemide (80 mg i.v.) transiently increased p-aminohippurate clearance in controls (from 693 +/- 67 to 928 +/- 93 ml/min) and in 11 patients with ascites (from 418 +/- 81 to 526 +/- 80 ml/min). In contrast, in 13 patients with ascites, p-aminohippurate clearance fell by 34% (from 545 +/- 51 to 360 +/- 24 ml/min) within 20 min and by 41% within 60 min, and inulin clearance fell by 19% at 20 min and by 30% at 60 min. The renal effects lasted approximately 4 h. The renal response could not be predicted by renin activity, urinary prostaglandin excretion, urinary sodium, or clinical characteristics. In all 14 patients who received oral furosemide, p-aminohippurate clearance fell within 90 min (by 24%) and remained suppressed for at least 4 h. These immediate effects of furosemide on renal perfusion may contribute to azotemia in some patients with ascites.     

Iodine kinetic studies during amiodarone treatment

Iodine kinetic studies were performed serially in 15 patients taking 300 mg amiodarone/day for 6 months to assess the biological significance of the high iodine content of the drug. Urinary inorganic iodide excretion increased from 0.25 +/- 0.03 (+/- SE) mumol/mmol creatinine before treatment to over 7 mumol/mmol during therapy. Thyroid iodide clearance fell from 5.93 +/- 0.82 ml/min to less than 0.5 ml/min, while plasma inorganic iodide rose from 0.05 +/- 0.01 mumol/liter to approximately 2.2 mumol/liter during treatment. Thyroid absolute iodide uptake rose from 16.3 +/- 2.7 to 54.6 +/- 5.7 nmol/h after 6 weeks of therapy (P less than 0.001). Thereafter, it progressively declined, but it was still significantly elevated (32.0 +/- 4.3 nmol/h) after 24 weeks (P less than 0.01). The calculated daily excretion of inorganic iodide rose to over 80 mumol during the study, accounting for about 10% of amiodarone iodine. During this time, the patients all had the characteristic plasma thyroid hormone changes associated with amiodarone therapy, i.e. increased T4, free T4, and rT3 and decreased T3, while remaining clinically euthyroid. The massive increase in available inorganic iodide during amiodarone treatment is probably responsible for the induction of both the hypothyroidism and the thyrotoxicosis that can occur in patients receiving the drug.     

A negative iodine balance is found in healthy neonates compared with neonates with thyroid agenesis

We studied the effects of the presence or absence of the thyroid gland on the iodine metabolism and excretion in term Dutch newborns by performing a retrospective study of the urinary iodine excretion in 193 term newborns with abnormal congenital hypothyroidism screening results. Thirty-six euthyroid newborns with decreased thyroxine-binding globulin levels were compared with 157 hypothyroid patients, 54 due to thyroid agenesis and 103 due to thyroid dysgenesis. A significant difference in the urinary iodine excretion was observed between the agenesis group (mean: 28 micrograms/24 h) and the euthyroid newborns (mean: 46 micrograms/24 h, P=0.001). In conclusion, healthy, euthyroid, term newborns excreted more iodine in their urine than newborns with thyroid agenesis. These results strongly indicated the existence of a temporarily negative iodine balance: the excretion of iodine prevailed over the intake and the newborn's thyroidal iodine, stored during pregnancy, could be used for thyroxine synthesis in the postnatal period. Since healthy term neonates were able to maintain adequate plasma free thyroxine concentrations under normal TSH stimulation, the prenatally acquired iodine stores could be considered sufficiently high to compensate for the transient postnatal losses.     

Plasma atriopeptin concentrations in hyperthyroidism, euthyroidism, and hypothyroidism: studies in man and rat

Atriopeptin (AP) is a polypeptide produced by atrial myocytes that is capable of inducing diuresis, natriuresis, and vasodilatation. Because thyroid dysfunction is known to be associated with alterations in both renal function and vasomotor control, we investigate the possible effects of varying thyroid function on AP in humans and rats. Plasma AP concentrations were determined in hyperthyroid and hypothyroid patients and normal subjects. Plasma AP was also measured in some patients after the iv infusion of 1 L 150 mmol/L NaCl and after treatment of hyperthyroidism or hypothyroidism. Plasma and atrial AP concentrations were measured in hyperthyroid, euthyroid, and hypothyroid rats. Plasma AP concentrations did not differ in the hyperthyroid (n = 22), euthyroid (n = 45), and hypothyroid (n = 16) subjects [47.1 +/- 18.2 (mean +/- SD), 45.1 +/- 28.9, and 42.4 +/- 20.0 pg/mL, respectively]. After NaCl infusion, mean plasma AP concentrations did not increase significantly in any of the three groups. Treatment of hyperthyroidism and hypothyroidism did not result in a significant change in plasma AP levels. In contrast, plasma AP concentrations were significantly higher in T4-treated (hyperthyroid) rats than in either euthyroid or propylthiouracil-treated (hypothyroid) rats [621 +/- 17 vs. 266 +/- 41 (P less than 0.01) and 210 +/- 28 pg/mL (P less than 0.001), respectively], whereas atrial AP contents were similar in the three groups of rats. We conclude that hyperthyroidism and hypothyroidism in man are not associated with significantly altered plasma AP concentrations. The higher plasma AP levels in T4-treated rats may reflect the relatively shorter duration or greater severity of thyroid dysfunction or thyroid hormone-induced myocardial hypertrophy in the animals.     

Elevated plasma immunoreactive neuropeptide Y concentrations and its increased urinary excretion in patients with advanced diabetic nephropathy.

Neuropeptide Y (NPY) is a potent vasoconstrictor peptide that is abundant in the brain and the peripheral sympathetic nervous system. In the present study we investigated possible changes in plasma immunoreactive (IR)-NPY concentrations and urinary IR-NPY excretion in patients with non-insulin dependent diabetes mellitus (NIDDM) and the relationship to diabetic complications, such as nephropathy and neuropathy. IR-NPY in plasma and urine was measured by radioimmunoassay in 69 patients with NIDDM. Plasma IR-NPY concentrations in patients with advanced nephropathy (creatinine clearance <30 ml/min) (100.5 +/- 10.3 pmol/l, n=9, mean +/- SEM) were higher than in the control subjects (55.0 +/- 6.8 pmol/l, n=15) (P<0.02). Urinary excretion of IR-NPY and fractional excretion of NPY were also increased in the patients with advanced nephropathy. Sephadex G-50 column chromatography of the urine extracts obtained from healthy subjects, diabetic patients with renal failure and non-diabetic patients with renal failure showed an immunoreactive peak eluting in the NPY position. On the other hand, neither plasma nor urinary IR-NPY was high in patients with retinopathy, or in patients with peripheral neuropathy. The present study has, for the first time, shown high plasma IR-NPY concentrations and urinary IR-NPY excretion in NIDDM patients with advanced nephropathy.     

Determinants of changes in plasma homocysteine in hyperthyroidism and hypothyroidism

OBJECTIVE: Hyperhomocysteinaemia is a risk factor for premature atherosclerotic vascular disease and venous thrombosis. The aim of the present study was to assess plasma total homocysteine (tHCys) concentrations in hypo- as well as hyperthyroid patients before and after treatment, and to evaluate the role of potential determinants of plasma tHCys levels in these patients. DESIGN: Prospective follow up study. PATIENTS: Fifty hypothyroid and 46 hyperthyroid patients were studied in the untreated state and again after restoration of euthyroidism. MEASUREMENTS: Fasting plasma levels of tHCys and its putative determinants (plasma levels of free thyroxine (fT4), folate, vitamin B(12), renal function, sex, age, smoking status and the C677T polymorphism in the methylenetetrahydrofolate reductase (MTHFR) gene were measured before and after treatment. RESULTS: Restoration of the euthyroid state decreased both tHCys (17.6 +/- 10.2-13.0 +/- 4.7 micromol/l; P < 0.005) and creatinine (83.9 +/- 22.0-69.8 +/- 14.2 micromol/l; P < 0.005) in hypothyroid patients and increased both tHCys (10.7 +/- 2.5-13.4 +/- 3.3 micromol/l; P < 0.005) and creatinine (49.0 +/- 15.4-66.5 +/- 15.0 micromol/l; P < 0.005) in hyperthyroid patients (values as mean +/- SD). Folate levels were lower in the hypothyroid group compared to the hyperthyroid group (11.7 +/- 6.4 and 15.1 +/- 7.6 nmol/l; P < 0.05). Pretreatment tHCys levels correlated with log fT(4) (r = - 0.47), folate (r = - 0.21), plasma creatinine (r = 0.45) and age (r = 0.35) but not with C677T genotype. Multivariate analysis indicated that pretreatment log(fT(4)) levels and age accounted for 28% the variability of pre-treatment tHCys (tHCys = 14.2-5.50 log(fT(4)) + 0.14 age). After treatment the logarithm of the change (Delta) in fT(4) (expressed as the post-treatment fT(4)/pre-treatment fT(4) ratio) accounted for 45% of the variability in change of tHCys ( tHCys = - 0.07-4.94 log ( fT(4))); there was no independent contribution of changes in creatinine which was, however, strongly related to changes in tHCys (r = 0.61). CONCLUSIONS: Plasma tHCys concentrations increased in hypothyroidism and decreased in hyperthyroidism. Plasma fT(4) is an independent determinant of tHCys concentrations. Lower folate levels and a lower creatinine clearance in hypo-thyroidism, and a higher creatinine clearance in hyperthyroidism only partially explain the changes in tHCys.     

Renal prostaglandin E2 and other vasoactive modulators in refractory hepatic ascites: response to peritoneovenous shunting

To assess the role of renal prostaglandin E2 in the pathogenesis of refractory ascites, in relation to renal sodium handling and circulating levels of vasoconstrictive substances, we studied 12 cirrhotic patients with refractory ascites before and after peritoneovenous shunting. Baseline values for urinary prostaglandin E2 excretion, sodium excretion, and creatinine clearance, as well as serum aldosterone, plasma renin activity, and plasma free norepinephrine, were obtained preoperatively with patients on a sodium- and fluid-restricted diet. Diuretics were also withheld. Similar parameters were measured immediately postoperatively during four consecutive 2-h intervals, then again at 2 wk and 3 mo. In patients with refractory ascites, mean baseline urinary prostaglandin E2 excretion was significantly elevated (2.5 +/- 0.8 pmol/min), compared with that in both normal controls and cirrhotics without ascites (1.3 +/- 0.3 pmol/min). A significant natriuresis occurred immediately postoperatively and persisted at 2 wk and 3 mo. Concomitantly, the elevated levels of preoperative vasoconstrictor substances gradually normalized by 2 wk. Urinary prostaglandin E2 excretion, however, rose transiently in the immediate postoperative period and then fell gradually to within the normal range by 3 mo. Enhanced renal prostaglandin E2 synthesis, therefore, does not play a role in the sustained improvement in sodium homeostasis after peritoneovenous shunting in patients with refractory ascites.     

Urinary excretion of carnitine in patients with hyperthyroidism and hypothyroidism: Augmentation by thyroid hormone

Urinary excretion of carnitine and serum concentrations of carnitine, triglyceride, and free fatty acids were measured in 54 hyperthyroid and 13 hypothyroid patients, and the results were compared with those of normal subjects. In hyperthyroid patients urinary excretion of carnitine was highly increased above that of the control subjects. On adequate treatment with antithyroid drug, carnitine excretion was reduced to the normal range, and serum lipids changed in parallel. In contrast, carnitine excretion was markedly reduced in hypothyroid patients. After substitution therapy with thyroid hormones the excretion increased in these patients. This change was associated with a marked reduction of serum triglyceride. There was an inverse correlation between urinary excretion of carnitine and serum triglyceride concentration. Carnitine excretion was significantly correlated with serum thyroxine concentration in hyper- and hypothyroid patients. The results suggest that thyroid hormones play an important role in carnitine metabolism, which in turn influences serum triglyceride metabolism.     

Is thyrotropin-releasing hormone immunoreactivity in peripheral blood an estimate for hypothalamic thyrotropin-releasing hormone release?

The significance of TRH for pituitary function is still unresolved mainly due to limitations in determining in vivo hypothalamic TRH release. We therefore examined whether TRH immunoreactivity (TRH-IR) in peripheral blood is an index for hypothalamic TRH release. Peripheral TRH-IR varied between 10 and 55 pmol/l and was similar in euthyroid and hypothyroid rats, but lower in hyperthyroid rats. Destruction of the hypothalamic paraventricular area reduced peripheral TRH-IR, while stimulation of this area increased it. Clearance of TRH during continuous TRH infusion was 1.9 +/- 0.2, 3.5 +/- 0.3 and 5.9 +/- 0.8 ml/min in hypothyroid, euthyroid and hyperthyroid rats, respectively. These and previous data on TRH in hypophysial portal blood indicate that 5-25 pmol TRH/l peripheral blood is of hypothalamic origin. Chromatography revealed that TRH-IR from hypothalamus and portal blood co-eluted with TRH, but in peripheral blood two peaks were found, one of which was authentic TRH. Thus, peripheral TRH-IR alters in experimental conditions and part of it seems to be of hypothalamic origin. However, the presence of TRH-like material in peripheral blood not identical to TRH and the fact that experimental conditions alter TRH clearance indicate that peripheral TRH-IR is not an index for hypothalamic TRH release.     

Caloric restriction does not alter thyrotropin secretion in hypothyroidism

The effect of caloric restriction, as a model of nonthyroid illness, on serum thyroid hormone and TSH concentrations in hypothyroid patients was studied to determine if pituitary-thyroid function is altered in such patients, as it is in euthyroid subjects. Serum T4, T3, and TSH concentrations and serum TSH responses to TRH were measured in 5 untreated hypothyroid patients and 10 hypothyroid patients receiving T4 replacement therapy before and after restriction of caloric intake to 500 cal daily for 7 days. In 5 untreated hypothyroid patients, the mean serum T3 concentration declined 17%, from 75 +/- 14 (+/- SE) to 62 +/- 11 ng/dl. The mean basal serum TSH concentrations were 154 +/- 67 (+/- SE) microU/ml before and 161 +/- 75 microU/ml at the end of the period of caloric restriction, and the serum TSH responses to TRH were similar on both occasions. In 10 T4-treated hypothyroid patients, the mean serum T3 concentration declined 35%, from 110 +/- 8 to 71 +/- 8 ng/dl. In this group, mean basal serum TSH concentrations were 17 +/- 5.1 microU/ml before and 18.2 +/- 7.0 microU/ml at the end of the period of caloric restriction, and as in the untreated hypothyroid patients, the serum TSH responses to TRH were similar on both occasions. Mean serum T4 concentrations and serum free T4 index values did not change in either group. These results indicate that caloric restriction in both untreated and T4-treated hypothyroid patients is accompanied by 1) reduced serum T3 concentrations, as it is euthyroid subjects, and 2) no alterations in basal or TRH-stimulated TSH secretion.