The obesity epidemic has led to a enormous increase in the prevalence of type 2 diabetes mellitus (T2D), dyslipidemia and cardiovascular events. Particularly South Asians, who comprise 1/5 of the world population, are at increased risk of developing a disadvantageous metabolic phenotype and these diseases. Moreover, T2D occurs at a younger age and at a lower BMI when compared to white Caucasians. Recent research has shown that South Asians not only have a lower energy expenditure than their Caucasian counterparts, but also less active brown adipose tissue (BAT). For some time, it has been known that adult humans have active BAT. This metabolic tissue produces heat by combusting triglycerides, in contrast to white adipose tissue, which stores this form of energy. It has been shown that activation of BAT has a positive effect on whole body metabolism, via increasing energy expenditure and improving glucose- and lipid metabolism. For this matter, BAT has been proposed as a major key player in energy homeostasis, which may be implemented in the current combat against the obesity epidemic. Aside from cold exposure, more research focuses on pharmacological activation of BAT. Glucagon-like peptide 1 (GLP-1) is an incretin hormone which is produced by intestinal L-cells and upon food intake stimulates insulin secretion by pancreatic beta cells. The GLP-1 analogue Exenatide is a currently much used antidiabetic drug to reduce hyperglycemia via this aforementioned mechanism. Beyond its blood glucose-improving effects, Exenatide has also shown to lower body weight and improve dyslipidemia in T2D patients. Elucidation of the underlying mechanism of these beneficial effects is highly relevant. Recent preclinical research in our group has shown that central activation of the GLP-1 receptor through exenatide increases BAT activity and thereby contributes to weight loss and improvement of dyslipidemia. The aim of this research project is to investigate whether exenatide is also able to activate BAT and increase resting energy expenditure, thereby improving glucose- and lipid metabolism and reducing fat mass and body weight in humans. Moreover, the investigators aim to validate the MRI scan as a novel way to measure BAT activity. The investigators hope that these forthcoming findings lead to the discovery of new treatment strategies against obesity.
The current study is an open-label single arm prospective design, including 24 healthy young lean males (BMI between 18 and 25 kg/m2), of whom 12 Dutch South Asians and 12 Dutch Caucasians. After a medical screening, included subjects will receive 12 weeks of treatment with the GLP-1 analogue exenatide (Bydureon; 2 mg s.c. 1x/wk). Study subjects will visit the LUMC weekly. Before and after treatment there will be a study day, in which BAT (by means of 18F-FDG PET-CT scan and MRI scan), resting energy expenditure (measured by indirect calorimetry) and fat mass (by bio-impedance analysis) will be measured. Moreover, blood will be drawn to investigate the effects of exenatide on lipid- and glucose metabolism.
Study Type
INTERVENTIONAL
Allocation
NA
Purpose
TREATMENT
Masking
NONE
Enrollment
24
exenatide (Bydureon) 2mg s.c. 1x/wk
Leiden University Medical Center
Leiden, South Holland, Netherlands
RECRUITINGThe effect of exenatide on BAT activity and energy expenditure in healthy young South Asian compared to white Caucasian men
Time frame: End of the study, up to 21 months
Visualisation of BAT as measured with MRI scan compared to FDG-PET CT
Time frame: End of the study, up to 21 months
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