A Kinetic Model of Human Thyroid Hormones and Their Conversion Products*

Abstract

We have examined the in vivo distribution and etabolism of radiolabeled T⁴ and T³in 14 normal subjects using a kinetic model. Tracer amounts of \l¹³¹I]T⁴ and \^I25I]T³ were injected simultaneously, and plasma samples were obtained for up to 7 days thereafter. Separation of these samples by thin layer chromatography yielded kinetic curves for ^13II- and ¹²⁵Ilabeled T⁴, T³, iodide, and iodoprotein, which were then used to develop a kinetic model. The model includes several features. 1) Submodels were developed for ^T4, T³, iodide, and iodoprotein which simultaneously fit the observed data. 2) Two other submodels were needed for data fit, the first representing ϒT³, the other representing other intermediates, including the various diiodothyronines. The latter submodel was patterned initially after 3,3’-diiodothyronine kinetics. It was required to account for the delay in appearance of labeled iodide produced from the degradation of T⁴, T³, and ϒT³ and proved to be essential for the successful fit of the data. 3) The model accounts for the conversion of T⁴ to T³ and ϒT³. Even though ϒT³ is quantitatively significant as a degradation pathway for T⁴,its presence does not contribute significantly to total plasma radioactivity after T⁴ administration because of its rapid turnover in comparison with T⁴. 4) The small amount of iodoprotein formed is a major contributor to total plasma radioactivity within 3 days after T³ administration. 5) The model permits the elimination of two methodological errors: that due to the presence of labeled iodide, T³, or T⁴ contaminants in the administered labeled hormones,and that due to the small amount of cross-over between thin layer chromatography peaks. The model provides a concise description of our current understanding of thyroid hormone metabolism and suggests areas where further information is required.(J Clin Endocrinol Metab53: 852, 1981)