Thyroid Function and Physiology


Before jumping right into a discussion of the use of thyroid hormone for fat loss, a little review of thyroid function and physiology might be in order. The thyroid gland secretes two hormones of interest to us, thyroxine (T4) and triiodothyronine (T3). T3 is considered the physiologically active hormone, and T4 is converted peripherally into T3 by the action of the enzyme deiodinase. The bulk of the body's T3 (about 80%) comes from this conversion. The secretion of T4 is under the control of Thyroid Stimulating Hormone (TSH) which is produced by the pituitary gland. TSH secretion is in turn controlled through release of Thyrotropin Releasing Hormone which is produced in the hypothalamus. This is analogous to testosterone production, where GnRH from the hypothalamus causes the pituitary to release LH, which in turn stimulates the testes to produce testosterone.

In addition to T3, it has recently been recognized that there exist two additional active metabolites of T3: 3,5 and 3,3' diiodothyronines, which we will collectively call T2. Studies have shown that 3,3'-T2 may be more effective in raising resting metabolic rate when hypothyroid subjects are treated with T3, than when normal (euthyroid) subjects are given T3. Therefore in normal subjects 3,5-T2 may be the principal active metabolite of T3 (1)

Like the hypothalamic-pituitary-gonadal axis, the thyroid gland is under negative feedback control. When T3 levels go up, TSH secretion is suppressed. This is the mechanism whereby exogenous thyroid hormone suppresses natural thyroid hormone production. There is a difference though between the way anabolic steroids suppress natural testosterone production and the way T3 suppresses the thyroid. With steroids, the longer and heavier the cycle is, the longer your natural testosterone is suppressed. This is not the case with exogenous thyroid hormone.

An early study that looked at thyroid function and recovery under the influence of exogenous thyroid hormone was undertaken by Greer (2). He looked at patients who were misdiagnosed as being hypothyroid and put on thyroid hormone replacement for as long as 30 years. When the medication was withdrawn, their thyroids quickly returned to normal.

Here is a remark about Greer's classic paper from a later author:


"In 1951, Greer reported the pattern of recovery of thyroid function after stopping suppressive treatment with thyroid hormone in euthyroid [normal] subjects based on sequential measurements of their thyroidal uptake of radioiodine. He observed that after withdrawal of exogenous thyroid therapy, thyroid function, in terms of radioiodine uptake, returned to normal in most subjects within two weeks. He further observed that thyroid function returned as rapidly in those subjects whose glands had been depressed by several years of thyroid medication as it did in those whose gland had been depressed for only a few days" (3)

These results have been subsequently verified in several studies.(3)(4) So contrary to what has been stated in the bodybuilding literature, there is no evidence that long term thyroid supplementation will somehow damage your thyroid gland. Nevertheless, most bodybuilders will choose to cycle their T3 (or T4 which in most cases works just as well) as part of a cutting strategy, since T3 is catabolic with respect to muscle just as it is with fat. As previously mentioned, long term T3 induced hyperthyroidism is also catabolic to bone as well as muscle.

The proviso about T4 vs T3 for weight loss alluded to above needs some elaboration. There have been a number of studies that have shown that during starvation, or when carbohydrate intake is reduced to approximately 25 to 50 grams per day, levels of deiodinase decline, hindering the conversion of T4 to the physiologically active T3.(5) From an evolutionary standpoint this makes sense: during periods of starvation the body, teleologically speaking, would like to reduce its basal metabolic rate to preserve fat and especially muscle stores. However, a recent study demonstrating the effectiveness and safety of the ketogenic diet for weight loss recorded no change in circulating T3 levels.(6) So this issue not completely settled. Nevertheless, persons contemplating thyroid supplementation during ketogenic dieting might prefer T3 over T4 since the bulk of the research does suggest a decline in the peripheral conversion of T4 to T3 during low carb dieting.

Now that we have reviewed a little about thyroid function, let's consider just how it is that thyroid hormone exerts its fat burning effects.



Increased Oxidative Energy Metabolism


Thyroid hormone has long been recognized as a major regulator of the oxidative metabolism of energy producing substrates (food or stored substrates like fat, muscle, and glycogen) by the mitochondria. The mitochondria are often called the "cell's powerhouses" because this is where foodstuffs are turned into useful energy in the form of ATP. T3 and T2 increase the flux of nutrients into the mitochondria as well as the rate at which they are oxidized, by increasing the activities of the enzymes involved in the oxidative metabolic pathway. The increased rate of oxidation is reflected by an increase in oxygen consumption by the body.

T3 and T2 appear to act by different mechanisms to produce different results. T2 is believed to act on the mitochondria directly, increasing the rate of mitochondrial respiration, with a consequent increase in ATP production. T3 on the other hand acts at the nuclear level, inducing the transcription of genes controlling energy metabolism, primarily the genes for so-called uncoupling <a href="http://www.allsportsnutrition.com/listproducts.php?style=category&value=PROTEIN" target="_blank">protein</a>s, or UCP (see below). The time course of these two actions is quite different. T2 begins to increase mitochondrial respiration and metabolic rate immediately. T3 on the other hand requires a day or longer to increase RMR since the synthesis of new <a href="http://www.allsportsnutrition.com/listproducts.php?style=category&value=PROTEIN" target="_blank">protein</a>s, the UCP, is required (1).

There are a number of putative mechanisms whereby T2 is believed to increase mitochondrial energy production rates, resulting in increased ATP levels. These include an increased influx of Ca++ into the mitochondria, with a resulting increase in mitochondrial dehydrogenases. This in turn would lead to an increase in reduced substrates available for oxidation. An increase in cytochrome oxidase activity has also been observed. This would hasten the reduction of O2, speeding up respiration. These and a number of other proposed mechanisms for the action of T2 are reviewed by Lannie et al.(7)

What is the fate of the extra ATP produced during hyperthyroidism? There are a number of ways by which the increased ATP promotes an increase in metabolic activity, including the following:

Increased Na+/K+ATPase. This is the enzyme responsible for controlling the Na/K pump, which regulates the relative intracellular and extracellular concentrations of these ions, maintaining the normal transmembrane ion gradient. Sestoft(7) has estimated this effect may account for up to to 10% of the increased ATP usage.


Increased Ca++-dependent ATPase. The intracellular concentration of calcium must be kept lower than the extracellular concentration to maintain normal cellular function. ATP is required to pump out excess calcium. It has been estimated that 10% of a cell's energy expenditure is used just to maintain Ca++ homeostasis. (1)


Substrate cycling. Hyperthyroidism induces a futile cycle of lipogenesis/lipolysis in fat cells. The stored triglycerides are broken down into free fatty acids and glycerol, then reformed back into triglycerides again. This is an energy dependent process that utilizes some of the excess ATP produced in the hyperthyroid state (8). Futile cycling has been estimated to use approximately 15% of the excess ATP created during hyperthyroidism (8)


Increased Heart Work. This puts perhaps the greatest single demand on ATP usage, with increased heart rate and force of contraction accounting for up to 30% to 40% of ATP usage in hyperthyroidism (9)