The focus of this proposal is to define the mechanism by which bariatric surgery acutely improves insulin sensitivity. Our central hypothesis is that drastically reduced caloric intake early after Bariatric surgery improves the pro-inflammatory profile of macrophages, which in turn improves insulin sensitivity and glucose homeostasis.
Bariatric surgery quickly improves tissue specific insulin sensitivity. Changes in glucose metabolism are seen within days after surgery, prior to any significant weight loss--raising the question of a difference between dietary restriction and early food intake after surgery. A major factor in the development of insulin resistance is obesity. It has been noted that by 3 months following Roux-en Y gastric bypass surgery in obese patients with (T2DM), fasting glucose and insulin levels are improved independent of weight loss, insulin resistance in muscle is lowered, and that the pro-inflammatory profile of resident microphages is lowered improving insulin sensitivity. The focus of this proposal is to define the mechanism by which bariatric surgery improves impacts insulin sensitivity. Our long-term goal is to correlate these changes with direct measures of adipose tissue insulin resistance to develop novel immunotherapies towards reducing insulin resistance without surgery. Our central hypothesis is that gastrointestinal rearrangement by various mechanisms impacts adipose tissue and improves the pro-inflammatory profile of macrophages improving insulin sensitivity and glucose homeostasis. To test this hypothesis we propose the following aims: Specific Aim 1. Recruit a patient population and measure insulin sensitivity using homeostatic model assessment (HOMA) to measure insulin resistance (IR), cytokines, incretins, and serum adipokines in morbidly obese patients • prior to and 7-10 days following bariatric surgery while on a hypocaloric diet (surgery group) and •prior to and 7-10 days while following hypocaloric diet similar to bariatric surgery (diet group). Subjects will be assigned to the two arms; subjects assigned to the hypocaloric diet may be offered bariatric surgery after completion of the diet. Specific Aim 2. * Profile inflammatory macrophages, T cells and secreted factors in subcutaneous and visceral adipose tissue of patients prior to and following RYGB and hypocaloric diet treatments. • prior to and 7-10 days following surgery * prior to and 7-10 days following hypocaloric diet similar to bariatric surgery Specific Aim 3. Assess the effects of bariatric surgery on ROS (reactive oxygen species) production, expression of transcription factors and enzymes of mitochondrial biogenesis, tissue FABP4, and biomarkers of oxidative stress and protein carbonylation in patients prior to and following surgery and in control diet subjects maintained on hypocaloric diet. Specific Aim 4. Determine the impact of bariatric surgery on lipolysis and the role of TLQP-21 (a genetically derived peptide that increases energy expenditure and prevents the early phase of diet-induced obesity).
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
57
Roux en Y Gastric Bypass with Hypocaloric liquid diet for 10 days
Hypocaloric liquid diet for 10 days
University of Minnesota
Minneapolis, Minnesota, United States
Measure homeostasis model assessment i.e. estimated change in insulin resistance (HOMA-IR) index
Time frame: Seven days before and 10 days following RYGB or hypocaloric diet similar to RYGB patients
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