Preparation of I-131-labeled human serum prealbumin and its metabolism in normal and sick patients.

Summary. A mathematical analysis of the plasma disappearance curves of simultaneously injected thyroxine-131I and albumin-1251 allows the development of simple formulas for estimating the pool size and transfer kinetics of rapidly exchangeable intracellular thyroxine in man. Evidence is presented that the early distribution kinetics of albumin-125I can be used to represent the expansion of the thyroxine-13I-plasma protein complex into the extracellular compartment. Calculations indicate that approximately 37% of total body extrathyroidal thyroxine is within such exchangeable tissue stores. The average cellular clearance of thyroxine is 42.7 ml per minute, a value far in excess of the metabolic clearance of this hormone. Results of external measurements over the hepatic area and studies involving hepatic biopsies indicate that the liver is an important but probably not the exclusive component of the intracellular compartment. The partition of thyroxine between cellular and extracellular compartments is determined by the balance of tissue and plasma protein binding factors. The fractional transfer constants are inversely related to the strength of binding of each compartment and directly proportional to the permeability characteristic of the hypothetical membrane separating compartments. Appropriate numerical values for these factors are assigned. An increased fractional entrance of thyroxine-""1I into the cellular compartment was noted in a patient with congenital decrease in the maximal binding capacity of thyroxine-binding globulin and in three patients after the infusion of 5,5-diphenylhydantoin. Decreased intracellular space and impaired permeability characteristics were observed in five patients with hepatic disease. Studies of the rate of entrance of thyroxine-'81I and albumin-125I into the pleural effusion of a patient with congestive heart failure suggested that transcapillary passage of thyroxine independent of its binding protein is not a predominant factor in the total distribution kinetics of thyroxine-'31I. The thesis is advanced that the distribution of thyroxine,

Section: Resultssupporting

confidence: 89%

Section: Methodsmentioning

confidence: 99%

Estimation of Rapidly Exchangeable Cellular Thyroxine from the Plasma Disappearance Curves of Simultaneously Administered Thyroxine-131I and Albumin-125I*

Oppenheimer¹,

Bernstein²,

Hasen³

1967

“…Studies of the distribution of labeled serum albumin in humans, however, indicate that the liver contains only a small pool of exchangeable albumin (29). The results of similar investigations have recently been reported on 131I-labeled prealbumin in which there was no evidence for selective hepatic accumulation of TBPA (30,31 (Table II). These results would indicate that TBG does not play an important role in the binding of T4 within the liver.…”

Section: Discussionsupporting

confidence: 65%

The kinetics of distribution between plasma and liver of 131-I-labeled L-thyroxine in man: observations of subjects with normal and decreased serum thyroxine-binding globulin.

Cavalieri¹,

Searle²

1966

All but a few studies concerned with the peripheral metabolism of labeled thyroxine 1 in man have ignored the early phase of equilibration of labeled with unlabeled hormone in the tissues (see review in reference 1). Lennon, Engbring, and Engstrom (2) measured the rate of disappearance of radioactivity from the blood during the initial 50 minutes after intravenous injection of T4-131I in humans. They found that the rate of decline in the level of circulating tracer was abnormally slow in patients with hepatic disease and in untreated cases of hypothyroidism and abnormally rapid in thyrotoxic individuals. Haddad (3) analyzed the plasma curve in normal subjects and fit the data to a two compartment kinetics model representing plasma and tissue pools of thyroxine. More recently, Blomstedt and Plantin (4), using only the time curve of plasma disappearance and the rate of excretion of tracer, proposed a four compartment system to describe the distribution and metabolism of labeled T4 in normal humans. Hepatic localization of radioactivity within hours after the intravenous administration of labeled T4 was observed in several studies in man (5-9).The purpose of the present investigation was to study in a quantitative manner the rate of exchange of labeled T4 between plasma and liver in humans with neither thyroid nor hepatic disease. The method involves body sector counting with externally placed detectors and simultaneous meas-

“…Diminished TBPA capacity, found in all of the present sera, has been shown to be associated with reduced concentration of this protein due to impaired synthesis in acute injury and in chronic illness including hepatic cirrhosis (17,18). While such evidence is not available regarding TBG, similar phenomena would seem reasonable.…”

Section: Discussionmentioning

confidence: 48%

Thyroxine Turnover and Transport in Laennec's Cirrhosis of the Liver*

Inada

Sterling²

1967

Summary. Studies of the metabolism of thyroxine in 14 cases of cirrhosis revealed a variety of deviations from normal. In addition to radiothyroxine turnover studies, determinations were made of the free thyroxine fractions and free thyroxine iodine concentrations in serum (magnesium precipitation method) as well as the maximal binding capacities of thyroxine-binding alpha globulin (TBG) and thyroxine-binding prealbumin (TBPA) by reverse flow paper electrophoresis in a glycine acetate system at pH 8.6.All cases of cirrhosis exhibited diminutions in TBPA capacities but their TBG capacities showed a wide scatter (13.4 to 41.6 jug/100 ml). The free thyroxine fraction was quite variable, with distinct elevations in nine of the 17 sera. The binding proteins appeared to be determinants of the free thyroxine fraction, which in turn, appeared to be a direct determinant of the half-time of turnover. These inferences did not exclude other possible factors including diminished hepatic uptake and metabolism of the hormone in liver disease.Despite considerable alterations in biological half-times, free thyroxine values, and binding proteins, it was remarkable that the absolute hormone disposal was normal in all 14 patients with cirrhosis.