Particle size of solid food after human mastication and in vitro simulation of oral breakdown.

Mastication, the first step in food digestion, results in the breakdown of solid food and its lubrication with saliva. Although the rate and extent of starch digestion are closely dependent on the way food is chewed, this factor has not been adequately considered in the preparation of food for in vitro digestion experiments. The purpose of this study was to determine the size distribution of starchy food particles before swallowing and to use an in vitro mincing procedure to simulate how food is divided up during chewing. Foods differing in texture and size (bread, spaghetti and tortiglioni) were chewed by 12 healthy subjects and spat out before swallowing. Chewing time and saliva impregnation were measured for each mouthful. The particle sizes resulting from experiments with chewed and minced bread and pasta were analysed respectively by light laser diffraction and image analysis. Chewing time was longer for bread than pasta, resulting in higher saliva impregnation. Chewed bread showed a bimodal distribution of particle size (30 microns, 500 microns), whereas both kinds of pasta produced particles of similar size (0.5 to 30 mm2) after mastication. Mincing reproduced the division of bread and pasta as achieved by chewing in an acceptable way. From our results it seems that the size of particles resulting from mastication depends on food texture. We succeeded by wetting and mincing food to prepare food in a similar bolus-like form before swallowing. Mincing provides a simple means of simulating the reduction of food into particles for in vitro digestion studies.

Bioavailability of starch in bread rich in amylose: metabolic responses in healthy subjects and starch structure.

OBJECTIVE: This study investigated whether postprandial metabolic responses to bread could be lowered by substituting high amylose maize starch for a part of the flour. DESIGN AND SUBJECTS: Eight healthy subjects consumed test meals of equivalent nutritional composition based on white wheat bread, bread rich in amylose (HAWB) and spaghetti as a breakfast meal. Blood samples were collected to measure insulin and glucose concentration during two hours after consumption. The degree of starch crystallinity was investigated by X-ray diffraction and DSC analysis. RESULTS: HAWB produced low glycaemic (60 +/- 18) and insulinaemic (57 +/- 20) indexes similar to those of spaghetti (83 +/- 46, 61 +/- 16). In vitro amylase hydrolysis of the three foods showed that high amylose content in HAWB significantly lowered starch degradation in bread without affecting hydrolysis kinetics. Addition of amylose in dough increased the resistant starch content of HAWB (14% of dry matter). The resistant starch fraction was mainly composed of crystalline amylose (B-type X-ray diffraction pattern, melting temperature 105 degrees C) attributable to native high amylose maize starch incompletely gelatinised during bread-cooking. CONCLUSIONS: Bread produced by the substitution of high amylose maize starch for a part of wheat flour showed a low glycaemic index. Resistant starch in HAWB corresponded to native crystalline amylose not gelatinised during normal bread-processing conditions.

Physical and chemical transformations of cereal food during oral digestion in human subjects.

Chemical and physical transformations of solid food begin in the mouth, but the oral phase of digestion has rarely been studied. In the present study, twelve healthy volunteers masticated mouthfuls of either bread or spaghetti for a physiologically-determined time, and the levels of particle degradation and starch digestion before swallowing were compared for each food. The amounts of saliva moistening bread and spaghetti before swallowing were, respectively, 220 (SEM 12) v. 39 (SEM 6) g/kg fresh matter. Particle size reduction also differed since bread particles were highly degraded, showing a loss of structure, whereas spaghetti retained its physical structure, with rough and incomplete reduction of particle size. Starch hydrolysis was twice as high for bread as for spaghetti, mainly because of the release of high-molecular-mass alpha-glucans. The production of oligosaccharides was similar after mastication of the two foods, respectively 125 (SEM 8) and 92 (SEM 7) g/kg total starch. Starch hydrolysis, which clearly began in the mouth, depended on the initial structure of the food, as in the breakdown of solid food. These significant physical and chemical degradations of solid foods during oral digestion may influence the entire digestive process.