Effects of Dietary Fibre on Satiety in Morbidly Obese Patients Before and After Bariatric Surgery - a Single Center, Randomized, Single-blinded, Cross-over Study.

Brief Summary

Detailed Description

Obesity has reached epidemic proportions worldwide. The only effective treatment option currently available is bariatric surgery, with the gold standard procedure, the Roux-en-Y gastric bypass (RYGB), resulting in dramatic and sustained excess weight loss of 60-75% and often prompt amelioration of type 2 diabetes mellitus (T2DM). The unparalleled efficacy of bariatric surgery in obesity treatment opens a completely new perspective for the development of anti-obesity drugs, and suggests that the gastrointestinal (GI) tract is of much more importance in the control of eating and energy homeostasis than previously thought.Two key GI mechanisms have been identified to inhibit eating: 1) gastric distention resulting in activation of mechanoreceptors and neural gut brain signaling, and 2) small intestinal nutrient sensing resulting in the secretion of satiation peptides such as CCK, GLP-1 and PYY. A completely novel implication of the importance of the GI tract in the control of eating and body weight is the role of the large intestine and the gut microbiome as well as its metabolic products.That the gut microbiome can have potent effects on eating and body weight was first recognized in landmark experiments with germ-free mice that became obese when they were inoculated with microbiota from obese mice or humans, while they remained lean when microbiota was transplanted from lean mice. The exact mechanisms that link the gut microbiome to the control of eating and energy homeostasis remain however, largely unexplored. One suggestion for obesity development is that the 'obese' microbiome may have an increased capacity to extract energy from the same diet as compared with a 'lean' microbiome. In fact, short chain fatty acids (SCFA) formed through bacterial fermentation of indigestible carbohydrates can provide additional energy to the host (about 10% of total energy from the diet). However, whether this is the main cause for obesity development remains controversial because SCFA also stimulate the secretion of leptin, GLP-1 and PYY and, thus, activate eating-inhibitory mechanisms. Because under physiological conditions, a meal will take about 6 hours or longer (depending on meal composition and inter-individual variability of intestinal transit) until it reaches the large intestine so that fermentable meal components can be metabolized to SCFA, the contribution of SCFA in acute eating-inhibitory effects has been questioned in humans. Bariatric patients provide an ideal model to study this mechanism. Based on the anatomical alterations during RYGB surgery resulting in a much faster nutrient transit to the large intestine, it can be hypothesized that a more rapid and more pronounced production of SCFA contributes to the marked acute eating-inhibitory effects as seen after surgery. In addition, RYGB patients have a small stomach pouch about 2% of the size of a normal, un-operated stomach resulting in early distention upon food ingestion. The effect of increased stomach distention and its contribution to the overall effects on eating behavior and weight loss have not been evaluated, to the best of our knowledge. Dietary fibres provide an ideal nutritional intervention to study the underlying eating-inhibitory effects of RYGB surgery. 1) High viscous fibres such as oat beta glucan delay gastric emptying and, thus, may contribute to the eating effect via an increase in gastric distention. 2) Non-viscous, fermentable fibres such as inulin or fructo-oligossachides (FOS) are highly fermented into SCFA in the large intestine upon ingestion, and thus may participate in the eating effect via activation of SCFA receptors and release of satiation hormones. The primary objective in both study A and B is to evaluate the effect of a viscous and fermentable dietary fibre on ad libitum eating in morbidly obese patients before and 6 month after RYGB surgery. In addition, in the pilot study in study B, the primary objective is the time course of fibre-induced large intestinal fermentation. The secondary objectives in both study A and B are to study the effect of a viscous and fermentable dietary fibre on perceived appetite, the production of SCFA, breath hydrogen (as a marker of large intestinal fermentation), the secretion GI satiation hormones and glycaemia in morbidly obese patients before and 6 month after RYGB surgery. The primary study outcome measure in both study A and B is macronutrient and food intake (grams and kcal eaten) at the ad libitum buffet meal as well as time to complete the meal. In addition, in the pilot study in study B, the primary study outcome measure is breath hydrogen and plasma SCFA concentrations. Secondary outcome measures in both study A and B are 1) Appetite ratings (validated visual analogue scales, VAS) including hunger, fullness, thirst, desire to eat, and amount of food desired to eat. 2) Plasma concentrations of SCFA (propionate, acetate, butyrate). 3) Breath hydrogen (as a marker of large intestinal fermentation) 4) Plasma concentrations of gastrointestinal hormones (ghrelin, CCK, GLP-1, PYY and potentially other, yet to be identified gut hormones). 4) Concentrations of plasma insulin and glucagon and blood glucose. Randomized, single-blinded cross-over trial in 24 morbidly obese human subjects undergoing RYGB (study A, n=12; study B, n=12). Study B also includes an additional pilot study in 6 morbidly obese patients before and 6 month after RYGB surgery. Thus, the total number of subjects including the pilot study is 30.

Primary Outcomes

Secondary Outcomes

• short chain fatty acid levels(150 (study A) / 270 (study B) minutes after Fiber intake)
• Appetite ratings on hunger, fullness and satiety(up to 5 hours after fiber intake)
• gut hormones(150 (study A) / 270 (study B) minutes after Fiber intake)
• glucose metabolism(150 (study A) / 270 (study B) minutes after Fiber intake)