Urinary total T3 levels as a method to monitor metabolic changes in relation to variation in caloric intake in captive bonobos (Pan paniscus).

Monitoring metabolic activity in wild living animals has become of particular interest in the field of ecological research. Methods for the repeated non-invasive sampling of individuals are needed. Thyroid hormones (TH) are involved in the regulation of metabolic activity, and their measurement can be used as a proxy to monitor metabolic changes. During periods of low energy intake, serum TH levels are reduced, leading to a decrease in metabolic activity. Using urine samples collected during a food restriction experiment in captive bonobos we validated a total triiodthyronin (TT3) enzyme immunoassay (EIA) for the monitoring of metabolic changes. We found that the majority of immune reactivity of the assay in the urine samples could be explained through immunoreactivity to T3. Furthermore, urinary T3 was stable through repeated freeze-thaw cycles but prolonged exposure to room temperature lead to degradation. Most importantly, we found that for all animals urinary total T3 levels were higher when more digestible energy was consumed. We concluded that urinary total T3 measurements are a suitable method for monitoring metabolic changes in bonobos and potentially in a wide range of animal species.

Correlation between urinary cadmium and thyroid hormones in outdoor workers exposed to urban stressors.

OBJECTIVES: The aim of this study is to evaluate whether exposure to low concentrations of cadmium (Cd) can have effects on the thyroid hormone level of outdoor workers exposed to urban pollutants. METHODS: The study was conducted on a final sample of 277 individuals (184 males and 93 females). The environmental monitoring of Cd was evaluated through the use of portable dosimeters, while the biological monitoring was achieved through the assessment of urinary Cd and thyroid hormones. The total sample was divided according to sex and task. The Pearson's correlation coefficient among the variables was calculated after subdivision on the basis of sex and task. The multiple linear regression was performed to take into account the major confounding factors. RESULTS: Statistical tests showed a negative correlation between urinary Cd levels and free triiodothyronine and free thyroxine and a positive correlation between urinary Cd and thyroid-stimulating hormone levels. CONCLUSIONS: Our early results seem to point out that occupational exposure to low concentrations of Cd present in urban air affects the thyroid hormone levels in exposed workers.

Age-related changes in thyroid hormone levels of bonobos and chimpanzees indicate heterochrony in development.

We present information on age related changes of thyroid hormone levels in bonobos (N = 96) and chimpanzees (N = 100) ranging between one and 56 years of age. Fresh urine samples were used for hormone measurements with a commercial competitive total triiodothyronine (T3) ELISA. In both species, immature individuals had higher TT3 levels than adults and there was a marked decrease in TT3 levels between age classes. The two species differed in terms of the timing of TT3 level changes, with chimpanzees experiencing a significant decline in TT3 levels after 10 years of age and bonobos after 20 years of age. The decline of TT3 in chimpanzees appears to coincide with the time when somatic growth terminates while TT3 values in bonobos decrease much later. This temporal asymmetry in urinary thyroid hormone levels indicates heterochrony in the ontogenetic changes of the two sister species and developmental delay in bonobos. The prolongation of high TT3 levels in bonobos, which is characteristic of immatures of both Pan species may affect the behavior of bonobos; namely, the low intensity of aggression they display. Given that developmental studies are often based on post-mortem analyses of skeletons, measures of urinary thyroid hormones offer a non-invasive tool for exploring ontogenetic changes in living wild and captive hominoids.

Maternal thyroid function in different conditions of iodine nutrition in pregnant women exposed to mild-moderate iodine deficiency: an observational study.

OBJECTIVE: We examined the effect of different conditions of nutritional iodine intake on maternal thyroid function throughout gestation in a cohort of healthy, anti-thyroid antibody-negative women from a mild-moderately iodine-deficient (ID) area. DESIGN: Observational cohort study. PATIENTS: The study included 168 women receiving prenatal preparations containing 150 µg of iodine from early pregnancy (150-I group); 105 women who had regularly used (>2 years) iodized salt prior to becoming pregnant (I-salt group); 160 women neither taking iodine supplements nor using iodized salt (no-I group). MEASUREMENTS: Maternal TSH, FT3 and FT4 were determined throughout gestation. RESULTS: Mean TSH concentrations were higher among the 150-I women than in the remaining two groups, and in a high proportion of them, TSH values were found to exceed the upper limit for gestational age. Conversely, the prevalence of low free-thyroxine levels in the 150-I women was similar to that observed in the I-salt women and markedly lower than that recorded for the no-I group. CONCLUSIONS: The regular use of iodine-containing supplements proved effective in reducing the risk of inappropriately low FT4 levels during pregnancy. The observed TSH increase in 150-I women may be because of a transient stunning effect on the thyroid gland, occurring as a result of the abrupt increase in daily iodine intake. Whilst the importance of gestational iodine supplementation is undisputed, we believe that in mild-moderately ID areas, women considering conception should be advised to take iodine supplementation for several months prior to pregnancy.

Iodine metabolism: preferential renal excretion of iodide derived from triiodothyronine deiodination.

Measurements were made in rats of the relative rates of accumulation in urine or in the thyroid of radioactive iodide derived from simultaneous injections of (131)I-labeled triiodothyronine and (125)I-labeled iodide. The data indicate that deiodination of triiodothyronine by the kidney results in a loss into the urine of iodine which does not enter the general body iodide pool. This renal "iodide leak" should be considered in kinetic models of iodine metabolism.

Comprehensive Metabolic Profiling Reveals a Lipid-Rich Fingerprint of Free Thyroxine Far Beyond Classic Parameters.

Objective: Thyroid hormones are ubiquitously involved in human metabolism. However, the precise molecular patterns associated with alterations in thyroid hormones levels remain to be explored in detail. A number of recent studies took great advantage of metabolomics profiling to outline the metabolic actions of thyroid hormones in humans. Methods: Among 952 participants in the Study of Health in Pomerania, data on serum free thyroxine (FT4) and thyrotropin and comprehensive nontargeted metabolomics data from plasma and urine samples were available. Linear regression analyses were performed to assess the association between FT4 or thyrotropin and metabolite levels. Results and Conclusion: After accounting for major confounders, 106 of 613 plasma metabolites were significantly associated with FT4. The associations in urine were minor (12 of 587). Most of the plasma metabolites consisted of lipid species, and subsequent analysis of highly resolved lipoprotein subclasses measured by proton nuclear magnetic resonance spectroscopy revealed a consistent decrease in several of these species (e.g., phospholipids) and large low-density lipoprotein and small high-density lipoprotein particles. The latter was unique to men. Several polyunsaturated and saturated fatty acids displayed an association with FT4 in women only. A random forest-based variable selection approach using phenotypic characteristics revealed higher alcohol intake in men and an adverse thyroid state and menopause in women as the putative mediating factors. In general, our observations have confirmed the lipolytic and lipogenic effect of thyroid hormones even in the physiological range and revealed different phenotypic characteristics (e.g., lifestyle differences) as possible confounders for sex-specific findings.

The effects of an acute load of thyroxine on the transport and peripheral metabolism of triiodothyronine in man.

In order to examine the question of whether thyroxine-binding globulin (TBG) influences significantly the peripheral metabolism of 3,3',5-triiodo-L-thyronine (T(3)) in vivo, paired studies of the effects of a large intravenous load of L-thyroxine (T(4)) on the kinetics of (131)I-labeled T(3) metabolism were carried out in five normal subjects. After the T(4) load, both the early distributive loss of labeled T(3) from serum and the volume of T(3) distribution, observed after distribution equilibrium had been attained, were greatly increased. These alterations were consistent with those to be expected from displacement of T(3) from its extracellular binding sites. After the T(4) load, however, the fractional rate of T(3) turnover was decreased. This finding is ascribed either to competition between T(3) and T(4) for common intracellular pathways of degradation or excretion or to displacement of T(3) from sites of more rapid to sites of less rapid metabolism. These effects of alterations in the binding activity of TBG on the peripheral metabolism of T(3), together with those previously reported by others, are consistent with the interpretation that T(3) is significantly bound by TBG in vivo. However, it is suggested that the effects of alterations in the T(3)-TBG binding interaction on the metabolism of T(3) are obscured by alterations in the extracellular-cellular partitioning of T(4) that would result from concurrent alterations in T(4)-binding by TBG.

Augmentation of the peripheral metabolism of L-triiodothyronine and L-thyroxine after acclimation to cold. Multifocal stimulation of the binding of iodothyronines by tissues.

Increased metabolism of thyroid hormones was observed in rats adapted to an ambient temperature of 4 degrees C. The increased hormonal degradation was manifested in enhanced metabolic, urinary deiodinative, biliary, and fecal clearances of iodothyronines. Increased metabolic clearances were due to stimulation of cellular hormonal disposition, evidenced by elevated intrinsic cellular clearances. After adaptation, the concentration of protein-bound iodine in plasma was decreased, and the binding of the hormones by plasma proteins was increased. The enhanced rate of metabolism of iodothyronines was associated with stimulation of the binding of these hormones by diverse tissues, suggesting the participation of extrahepatic degradative foci in the increased hormonal deiodination observed in vivo. Increased hepatocellular binding and a significantly enlarged hepatic distribution space of thyroxine were noted. Hepatocellular binding of triiodothyronine was similarly augmented, and a smaller but significant increase in the hepatic space of this iodothyronine was detected. Analysis of the hepatic subcellular partition of iodothyronines 35 min after the intravenous administration of isotopically labeled thyroid hormones disclosed increased hormonal binding by the microsomal fraction in cold-adapted animals and an attendant increase in the microsomal protein concentration. Partial microsomal subfractionation in a discontinuous sucrose gradient indicated that the observed stimulation of microsomal hormonal binding was associated with proliferation of the smooth endoplasmic reticulum.

[Determining the thyroid hormones T3 and T4 in the urine: an unreliable test for hypothyroidism]. / Bepaling van schildklierhormoon (T3 en T4) in de urine: een weinig betrouwbare test voor de diagnose 'hypothyreoïdie'.

A 24-year-old woman complained of tiredness, sensitivity to cold, and feelings of depression. A diagnosis of hypothyroidism based on decreased 24 h urinary T3 and T4 excretion was made, and she was treated with levothyroxin. No blood tests were done. She was referred with the question if she had other endocrine disorders. Her periods were regular, and on physical examination no abnormalities except slight acne were found. Similarly, hypothyroidism was diagnosed by decreased thyroid hormone excretion in 24 h urine, again without blood tests, in a 68-year-old woman whose mother had a goitre, and who had already been prescribed liothyronine. She had no complaints, and physical examination was unremarkable. The thyroid gland was not palpable. Thyroid peroxidase antibodies were absent in both patients. After discontinuation of medication with thyroid hormones they both remained euthyroid. It is concluded that thyroid disease did not exist in those 2 patients. Measurement of 24 h urinary T3 and T4 excretion is not an accurate diagnostic test for hypothyroidism.

Triclosan and triclocarban exposure and thyroid function during pregnancy-A randomized intervention.

Triclosan and triclocarban (TCs) are broad-spectrum microbicides found in household and personal wash products. We sought to determine whether TC exposure from wash products or urinary triclosan level modified thyroid function during pregnancy or anthropometric measurements at birth. A randomized intervention of wash products with or without TCs, including toothpaste, enrolled pregnant women from 20 weeks' gestation. Urinary triclosan, TSH, T4 and T3 were assessed at enrollment, 36weeks' gestation and/or post-delivery; anthropometric measures at birth were ascertained from medical records. 78 and 76 mothers were assigned to the TC-containing and no-TC-containing product arms, respectively. No differences were observed in any thyroid function measure at any time point or in any anthropometric measurement at birth between either exposure arms or lowest and highest urinary triclosan quartile groups. TCs from wash products, primarily liquid and bar soaps, did not affect thyroid function measures during pregnancy or babies' anthropometric measures at delivery.

Effect of radish (Raphanus sativus Linn.) on thyroid status under conditions of varying iodine intake in rats.

Cruciferous plants viz. cabbage, cauliflower, turnip, radish, mustard etc. that contain goitrogenic/antithyroid substances, constitute a portion of regular human diet. The effect of chronic feeding of fresh and cooked radish, R. sativus under varying state of iodine intake on morphological and functional status of thyroid in albino rats was evaluated by thyroid gland morphology and histology, thyroid peroxidase activity, serum triiodothyronine, thyroxine and thyrotropin levels. The consumption pattern of iodine and goitrogens of cyanogenic origin was evaluated by measuring urinary iodine and thiocyanate levels respectively. After chronic radish feeding, increased weight of thyroid gland, decreased thyroid peroxidase activity, reduced thyroid hormone profiles and elevated level of thyrotropin were observed resembling a relative state of hypoactive thyroid gland in comparison to control even after supplementation of adequate iodine.

Low serum thyroxine and high serum triiodothyronine in nephrotic rats: etiology and implications for bioavailability of protein-bound hormone.

Traditionally, it has been thought that the bioavailable fraction of circulating serum hormones, i.e. that which is available for cellular uptake and is physiologically active, is limited to the free (nonprotein bound) hormone. However, recent evidence, based on acute organ uptake of labeled hormone, suggests that the amount of hormone which is bioavailable in vivo may exceed that which is calculated to be free in vitro. To explore the bioavailability of circulating protein-bound thyroid hormones under steady state conditions in vivo, we altered serum thyroid hormone-binding proteins in rats by inducing nephrotic syndrome with puromycin aminonucleoside. Nephrotic rats (serum albumin, 1.1 g/dl) were found to have a marked reduction in serum T4 [2.1 +/- 0.2 (SEM) vs. 6.5 +/- 0.3 microgram/dl; P less than 0.01] and an elevation of serum T3 [141 +/- 8 vs. 51 +/- 2 ng/dl; P less than 0.01]. Estimated T4 production rate was normal in nephrotic rats, and the 3- to 4-fold increase in T4 MCR appeared to account for the marked reduction in serum T4. By contrast, increased serum T3 levels in nephrotic rats reflected both a reduction (55%) in T3 MCR and an increased rate of peripheral conversion of T4 to T3. A circulating inhibitor of T4 binding to serum proteins appeared to be present in nephrotic rats. The changes in the various serum components of thyroid hormone [T4-binding prealbumin (TBPA)-bound, albumin-bound, free] produced by nephrotic syndrome were compared with the corresponding changes in indices of thyroid hormone bioavailability (MCR, urinary excretion, hepatic content, TSH suppression, single pass extraction by liver). These comparisons suggested that nephrotic syndrome results in increased bioavailability of circulating T4 and decreased bioavailability of circulating T3. The bioavailable fraction of circulating T3 in vivo seemed to include both free T3 and that which is albumin bound in vitro. The bioavailable fraction of circulating T4 resembled free T4 more than non-TBPA-bound T4 (= albumin bound + free), although a nephrosis-induced increase in bioavailability of TBPA-bound T4 was also possible. We conclude that nephrotic rats have low serum T4, which is related to accelerated T4 clearance, and high serum T3, which is related both to decreased T3 clearance and increased peripheral conversion of T4 to T3. Under steady state conditions in vivo, bioavailable circulating T3 appears to include both free T3 and the T3 that is bound to albumin in vitro.

Rat enterohepatic circulation and intestinal distribution of enterally infused thyroid hormones.

The enterohepatic circulation (recycling), intestinal (gut) distribution, metabolism, and excretion of enterally infused thyroid hormones were studied in the intact rat under approximately normal physiological steady state conditions. Rats with 7-day osmotic minipumps implanted ip received constant intraduodenal infusions to steady state of very small trace doses of either 125I-labeled T3 (T3*) or T4 (T4*). Enterohepatic and other pathways remained open to normal function, and in particular, there was no biliary diversion or ligation. Complete feces and urine were collected daily, to assess daily distributions of radioactivity and establishment of the steady state, which occurred by day 3. On day 7, rats were anesthetized, blood was sampled, whole intestine and minipumps were removed, and the gut was separated into six segments. Fecal samples and the contents of each gut section were homogenized, ethanol extracted, evaporated, and reconstituted in NaOH for quantitative aqueous chromatography along with infusate, urine, and plasma samples, on Sephadex G-25 columns. No T3* or T4* was found in urine, but feces contained 39% of the T3* infused and 36% of the T4* infused in steady state. Statistically significant amounts of both T3* and T4* in systemic plasma on day 7 clearly indicated absorption of the hormones from the intestine, distinctly demonstrating an enterohepatic circulation of T3 and T4 under experimental conditions closely approximating the physiological steady state. This also establishes the intestine (with its contents) as an exchangeable hormone pool, physiologically internal to the system regulating thyroid hormones and their distribution. Gut contents contained 52 times more T3* and 4.34 times more T4* than corresponding plasma pools in steady state. Kinetic analysis of the data indicated that somewhat more than half of the T3* or T4* infused was absorbed from gut to liver (primary absorption), and up to 34% of the T3* infused and 43% of the T4* infused reached the systemic circulation (secondary absorption/bioavailability). Gut contents longitudinal distribution data 1) confirm existing evidence that thyroid hormone conjugates, formed elsewhere, exist in gut contents and are hydrolyzed there; 2) demonstrate that deconjugation becomes quantitatively significant, and thus may be initiated, at the level of the cecum; and 3) strongly suggest that absorption of unconjugated hormone occurs from at least the small intestine, all under normal physiological conditions.

A multicompartmental model for iodide, thyroxine, and triiodothyronine metabolism in normal and spontaneously hyperthyroid cats.

A comprehensive multicompartmental kinetic model was developed to account for the distribution and metabolism of simultaneously injected radioactive iodide (iodide*), T3 (T3*), and T4 (T4*) in six normal and seven spontaneously hyperthyroid cats. Data from plasma samples (analyzed by HPLC), urine, feces, and thyroid accumulation were incorporated into the model. The submodels for iodide*, T3*, and T4* all included both a fast and a slow exchange compartment connecting with the plasma compartment. The best-fit iodide* model also included a delay compartment, presumed to be pooling of gastrosalivary secretions. This delay was 62% longer in the hyperthyroid cats than in the euthyroid cats. Unexpectedly, all of the exchange parameters for both T4 and T3 were significantly slowed in hyperthyroidism, possibly because the hyperthyroid cats were older. None of the plasma equivalent volumes of the exchange compartments of iodide*, T3*, or T4* was significantly different in the hyperthyroid cats, although the plasma equivalent volume of the fast T4 exchange compartments were reduced. Secretion of recycled T4* from the thyroid into the plasma T4* compartment was essential to model fit, but its quantity could not be uniquely identified in the absence of multiple thyroid data points. Thyroid secretion of T3* was not detectable. Comparing the fast and slow compartments, there was a shift of T4* deiodination into the fast exchange compartment in hyperthyroidism. Total body mean residence times (MRTs) of iodide* and T3* were not affected by hyperthyroidism, but mean T4* MRT was decreased 23%. Total fractional T4 to T3 conversion was unchanged in hyperthyroidism, although the amount of T3 produced by this route was increased nearly 5-fold because of higher concentrations of donor stable T4. Analysis of the data indicates that the increased overall T4* turnover (decreased MRT) in hyperthyroidism is due to increased losses through pathways other than T3 formation. Conjugation, with subsequent deiodination, is proposed as one possibly important pathway. Results of this multicompartmental analysis are compared with those of noncompartmental analysis of the same data and with results of similar model analyses in other species.

A new method for measurement of the conversion ratio of thyroxine to triiodothyronine in euthyroid man.

A new method for the measurement of the conversion ratio (CR) of T4 to T3 in euthyroid man is described. In contrast to previously described studies, this investigation relied on sampling of urine rather than plasma after isotopic labeling of the study subject. The CR value determined in six euthyroid men was 0.482 +/- 0.014. Thus, approximately half of the daily T4 production is converted to T3 as determined by this method. A major advantage of this technique is its reproducibility, as demonstrated by the low coefficient of variation of 6.8% in the study group, which is not significantly different from the 6.7% coefficient of variation for replicate determinations on the same sample. Thus, this method may be useful tool in comparing the CR of T4 to T3 in man under varying conditions even if only small differences in conversion efficiencies exist between groups. One apparent discrepancy observed in the present study is that the calculated T3 produced from the conversion of T4 exceeded the simultaneously calculated daily T3 production rate measured in blood. The cause of this discrepancy is presently unknown, but may represent T3 produced from T4 by renal or extrarenal sources which is excreted without contributing to the T3 blood production rate. However, the reproducibility of the method and the smaller amounts of labeled isotope required show promise that this technique may be useful in assessing T4 to T3 conversion in a variety of altered metabolic states.

Triiodothyronine and thyroxine in urine. I. Measurement and application.

Urinary triiodothyronine (T3) and thyroxine (T4) were measured by RIA, and T4 was also measured by competitive protein binding (CPB). pH 1-hydrolysable conjugates were 48% of total urinary T3, and enzyme- or pH 1-hydrolysable conjugates were 55% and 61% of total urinary T4. The mean unconjugated T3 excretion was 34.3 ng/h (0.99 mug T3/g creatinine) in normal subjects (no day-night rhythm found), 1.56 mug/g in late pregnancy, 0.82 mug/g in neonates (1-12 days), and was also unchanged in persons with high or low thyroxine-binding globulin (TBG). In thyrotoxicosis, mean T3 excretion was 281 ng/h, no values being in the normal range. In primary hypothyroidism it was 18.3 ng/h, but over half the values were in the normal range. The mean urinary unconjugated T4 was 82.2 ng/h (1.37 mug T4/g creatinine) in normal subjects, 1.6 mug/g in neonates, and unchanged in persons with high or low TBG, except that in pregnancy high values were compatible with increases protein excretion. Apparently increased day-time T4 excretion compared with night-time excretion may also be due to changes in protein excretion rate. The mean T4 in thyrotoxicosis was 337 ng/h (12% of values in the normal range) and 32.8 ng/h in primary hypothyroidism (over half the normal range). All the assays, especially that of T4 by CPB gave readings which were incorrect with protein concentrations above 100 mg/l. Urinary T3 and T4 assays for clinical purposes have few practical advantages over serum assays, despite the relationship of urine T3 and T4 to serum unbound levels.

Urinary immunoprecipitation method for estimation of thyroxine to triiodothyronine conversion in altered thyroid states.

A new method is described for the estimation of T4 to T3 conversion in man and is applied to the study of hyperthyroid and hypothyroid clinical states. The method employs simultaneous iv injection of [125I]T4 and [131I]T3 with isolation of the labeled T3 tracers in 4- to 8-day pooled urine samples by a combination of solvent extraction, desalting, and immunoprecipitation procedures. Using [131I]T3 as a recovery standard, the T4 to T3 conversion ratio was found to be 0.470 +/- 0.011 in euthyroid subjects. This confirmed our earlier findings of 0.482 +/- 0.014 using a paper chromatographic method and nonsimultaneous isotope administration. The conversion ratio was increased in hypothyroidism to 0.535 +/- 0.011 (P less than 0.02) and decreased in hyperthyroidism to 0.415 +/- 0.009 (P less than 0.01). These changes parallel the fraction of the radioiodine collected in the urine for both T4 and T3; normal values are 77 +/- 4% for T4 and 76 +/- 4% for T3, values in hypothyroidism are 79 +/- 1% for T4 and 79 +/- 3% for T3, and values in hyperthyroidism are 58 +/- 3% for T4 and 58 +/- 5% for T3 (P less than 0.01). These findings indicate that 1) urinary T4 to T3 conversion values are highly reproducible in euthyroid as well as hyperthyroid and hypothyroid states; 2) the reduction in T4 to T3 conversion in hyperthyroidism probably reflects increased T4 disposal by nondeiodinative pathways and possibly the reverse in hypothyroid states; and 3) since urinary T4 to T3 conversion values in euthyroid subjects exceeded all reported conversion values in blood, there may be an alternate pathway of T3 production and disposal which is not reflected in the blood T3 production rate.

Triiodothyronine (T3)-binding immunoglobulins in a euthyroid woman: effects on measurement of T3 (RIA) and on T3 turnover.

A 36-year-old woman with nodular goiter, nervousness, and tachycardia was evaluated for T3 toxicosis. Her serum thyroxine level, resin T3 uptake, and thyroidal radioiodine uptake were normal. Her T3 (RIA), by a technique employing charcoal to separate bound and free T3, was reported as indeterminate due to an interfering substance; by a double-antibody method, her T3 (RIA) was 325 ng/dl. Further studies of the patient's serum revealed an abnormal T3-binding protein which misgrated in the beta-gamma globulin zone on paper electrophoresis and gel filtration chromatography (Sephadex G-200), and was precipitated from serum by rabbit anti-human Fab antibody. The gamma globulin fraction of the patient's serum, separated by a standard technique, showed strong binding activity toward [125I]T3, with an association constant of 4.1 X 10(8) 1/mole (Scatchard plot). In a similar system, labeled T4 was not bound. To avoid artefacts which this T3-binding protein might produce in assaying unextracted serum, T3 (RIA) was performed on an ethanol extract of serum and found to be 191 ng/dl, a slight elevation. However, the metabolic clearance rate of injected [125I]T3, estimated by non-compartmental analysis of the serum decay curve or by the specific activity or urinary T3, was about 16 1/day, a low value, so that the T3 production rate, 31 mug/day, was normal. The patient's symptoms disappeared with the resolution of domestic problems, and she appeared clinically euthyroid. Serum TSH was 5.0 uU/ml and antithyroglobulin titer, 1:16. A test for antibodies to thyroid microsomes was negative. We postulate that this subject was euthyroid, but had a concentration of T3-binding immunoglobulin which was sufficient to produce modest slowing of T3 turnover, borderline elevation of extractable T3 (RIA), and a major artefact in the T3 (RIA) measurement of unextracted serum. A similar abnormality may account for other instances of high T3:T4 ratios in serum.

A radioimmunoassay for measurement of thyronine and its acetic acid analog in urine.

A sensitive and specific RIA has been developed to measure thyronine (To) in urine. The RIA used an anti-To antibody obtained from a rabbit immunized with a L-To-human serum albumin conjugate and [3H]To as the radioligand. The acetic acid analog of To (ToAc), that is the diphenyl structure with an acetic acid side-chain, cross-reacted strongly with the antibody. Relative to To, it cross-reacted 160% in phosphate-buffered saline, pH 7.4, and 100% in 0.075 mol/L barbital buffer, pH 8.6, containing sodium salicylate (final concentration, 8 mg/mL). The latter conditions were employed for the RIA, and the results reported thus reflect the presence of To and/or ToAc. 3-Monoiodothyronine, 3'-monoiodothyronine, 3',5'-diiodothyronine, and 3,5-diiodothyronine cross-reacted with the anti-To antibody 1.9%, 1.7%, 0.3%, and 0.2%, respectively; the cross-reactivity of other To derivatives and tyrosine and its derivatives was less than 0.05%. Urinary To and/or ToAc excretion in 12 normal subjects averaged 16 +/- 2 (+/- SE) micrograms/day (59 +/- 9 nmol/day) or 14 +/- 2 micrograms/g creatinine (5.9 +/- 0.6 nmol/mmol creatinine). Treatment of urine from normal subjects with beta-glucuronidase or sulfatase did not significantly alter the To content. Column and thin layer chromatographic studies revealed that 83% and 61%, respectively (range, 37-100%), of urinary To immunoreactivity was attributable to ToAc. The mean daily excretion of To in 20 patients with nonthyroidal illness [NTI; 22 +/- 4 micrograms/day (82 +/- 17 nmol/day)] was similar to that in normal subjects, but was elevated when expressed as nanomoles per mmol creatinine (20 +/- 2; P less than 0.001), because creatinine excretion was reduced in the NTI patients. The mean daily urinary To excretion in 13 patients with hyperthyroidism due to Graves' disease was slightly elevated [29 +/- 6 micrograms/day (108 +/- 21 nmol/day); P less than 0.1], but was clearly elevated when expressed as nanomoles per mmol creatinine (37 +/- 8; P less than 0.001), again because creatinine excretion was reduced in these patients. The mean urinary To excretion was subnormal in 13 patients with hypothyroidism and was significantly (P less than 0.005) less than that in the NTI patients regardless of the manner in which the results were expressed. Analysis of pronase hydrolysates of thyroid glands obtained at autopsy from euthyroid patients suggested that the To content of the thyroid approximates only 1.2% that of T4, supporting the thesis that prior iodination of tyrosine is critical for the coupling process in the thyroid.(ABSTRACT TRUNCATED AT 400 WORDS)

Comparison of plasma and urinary methods for the direct measurement of the thyroxine to 3,5,3' - triiodothyronine conversion rate in man.

A further development of a new method recently proposed for the direct measurement of the conversion ratio (CR) of T4 to T3 in man is presented. [125I]T4 and [131I]T3 are injected simultaneously, and Sephadex chromatography is performed on urine samples to determine [125I]T3 formed in vivo, while plasma samples are used to measure the injected tracers. CR is calculated with the assumption that urinary [125I]T3 closely reflects [125I]T3 appearing in plasma after the injection of precursor [125I]T4. Four normal subjects and six patients with various thyroid disorders were studied using this method. The experimental data were also analyzed by our previous method based on plasma sampling only and by two recently described methods based on urinary measurements. These comparisons were made in an attempt to ascertain whether there is any systematic difference between the conversion values derived from plasma data and those derived from urinary data. Using plasma data alone, the CR was 28.6 +/- 3.4% (mean +/- SEM) in a group of four normal subjects, 37%, in two untreated hypothyroid patients, 40.2% in one hypothyroid subject receiving T4 treatment, 30.9% in one hyperthyroid patient, 24.9% in one patient with selective hyperthyroxinemia due to amiodarone treatment, and 10.7% in one normal subject after iopanoic acid administration. These values were in excellent agreement with those obtained by the modified procedure described here, in which both urinary and plasma measurements are used. Of the methods using urinary data alone, however, one gave similar results, while the other systematically overestimated the CR, possibly due to delayed excretion of labeled T4 metabolites into the urine. We conclude that 1) the analytical procedure to separate the labeled tracers and metabolites in urine or plasma is critical for the accurate estimation of CR; 2) when an adequate separation procedure is available, plasma and urinary methods for measuring CR yield comparable results; and 3) the plasma method should be used when, in addition to CR, other kinetic (distribution and turnover) parameters of T4 and T3 metabolism are to be estimated.