Pharmacological Activation of Brown Adipose Tissue Metabolism

Type 2 Diabetes

Lean tissue intracellular triglycerides (ICTG) accretion is an important marker of lean tissue lipotoxicity that significantly contributes to the development of type 2 diabetes (T2D). The mechanisms leading to excess exposure of lean tissues to fatty acids involve metabolic dysfunctions of adipose tissues and lean tissues themselves. Understanding the role of white and brown adipose tissue in this metabolic dysfunction is particularly important in predicting, preventing and treating T2D and many of its associated cardiovascular complications. A recent breakthrough has been the demonstration that the acute oral administration of a β3 adrenergic agonist, mirabegron (200 mg), significantly increases BAT glucose uptake in healthy individuals. This suggests that mirabegron could be used as a pharmacological tool to selectively activate BAT metabolism as part of the mechanistic studies on BAT. It also suggests that mirabegron could be used pharmacologically for chronic activation of BAT in clinical trials to treat obesity and T2D. However, there are some outstanding issues regarding the use of mirabegron to activate BAT. First, there has been no direct comparison of the effect of acute cold vs. mirabegron on BAT metabolism. Second, there has been no demonstration of the effect of mirabegron on BAT oxidative metabolism since glucose uptake is only a surrogate of BAT energy expenditure. Third, acute administration of mirabegron led to significant increases in blood pressure and cardiac work, suggesting that it may also enhance energy expenditure in other organs in addition to BAT, thus confounding the role of BAT in energy homeostasis. Therefore, much remains to be known about the effect of mirabegron on BAT and cardiac energy metabolism before this drug can be used as a selective activator of BAT oxidative metabolism. The purpose of this study is to directly compare BAT oxidative metabolism under cold vs. β3-adrenergic agonist stimulation in lean healthy individuals. The investigator hypothesizes that the acute oral administration of a lower dose of mirabegron (50 mg) will result in an increase in BAT oxidative metabolism and whole-body energy expenditure, to a similar extent as cold exposure, without influencing the cardiovascular responses previously seen with the higher dose (200 mg).

The first step of the study will be direct comparison of mirabegron (protocol A) vs. cold-induced (protocol B) BAT metabolic activation using 11C-acetate to measure BAT metabolic activity. The principle of this method is measurement of tissue fast disappearance of 11C, a marker of tissue 11CO2 production. This fast tissue 11C clearance thus gives an index of tissue oxidative metabolism. Ten healthy, non obese men will undergo two identical 5h procedures in which BAT metabolism will be stimulated with a β3-agonist (mirabegron 50mg) or using cold exposure, in random order. The investigator just received approval from Health Canada to use mirabegron as part of these metabolic investigations. In brief, baseline blood samples and indirect calorimetry will be performed between time -60 to -30 min followed by i.v. injection of 11C-acetate with 30 min dynamic PET/CT scanning at room temperature in both protocol A and B. Mirabegron will be administered orally at time 0 in protocol A whereas acute cold exposure protocol using a water-conditioned cooling suit will be applied from time 120 to 300 min in protocol B. At time 210 min (i.e. Tmax of plasma mirabegron level or 90 min after the onset of cold exposure), i.v. injection of 11C-acetate will be repeated followed by 30 min dynamic PET/CT scanning. I.v. injection of 18-fluorodeoxyglucose (18FDG) will be performed at time 270 min, followed by 30 min dynamic PET/CT scanning to determine BAT net glucose uptake and a whole-body PET/CT scan to determine BAT volume of metabolic activity and organ-specific glucose partitioning.

Canada