In-vitro starch hydrolysis of chitosan incorporating whey protein and wheat starch composite gels.

The study examined the influence of chitosan, incorporated into whey protein and wheat starch thermo gels, on the in-vitro hydrolysis of the polysaccharide. Gels were subjected to the following external conditions containing α-amylase at constant incubation temperature of 37 °C: In the first procedure, they were immersed in phosphate buffer (0.05 M) and maintained at pH 6.9 throughout the entire digestion. In the second instance, they were introduced into a salt solution, with pH and total volume adjusted at times in sync with the human gastrointestinal tract. Results indicate that low and medium molecular weight chitosan, in combination with whey protein, were effective at enhancing the protective barrier against starch degradation. Less maltose was liberated from gels containing medium molecular weight chitosan, as opposed to the low molecular weight counterpart, and results compare favorably with the outcome of the in-vitro digestion of binary whey protein and wheat starch composites.

Recent advances in complementary and replacement therapy with nutraceuticals in combating gastrointestinal illnesses.

The digestive system provides nourishment to the whole body. Disorders in this system would result in many associated illnesses as the body is deprived of essential nutrients. Gastrointestinal diseases, in particular, gastric ulceration, inflammatory bowel diseases and colorectal cancer have become more prevalent in all population age groups. While this can be attributed to diet and lifestyle changes, the measures to combat these illnesses with conventional drugs is losing popularity owing to the harsh side effects, drug resistance and lack of patient compliance. The focus of this review is to endorse promising nutraceutical dietary components such as phytosterols, polyphenols, anthocyanins and polyunsaturated fatty acids and their synergistic value, in combination with conventional management of key gastrointestinal diseases. As most of these nutraceuticals are labile compounds, the need for protection and delivery using a carrier system is stressed and the methods for targeting to specific parts of the gastrointestinal tract are discussed. A section has also been devoted to perspectives on co-encapsulation methods of drugs and nutraceuticals using different particle systems. Multilayered carrier systems like double layered and core shell particles have been proposed as an exemplary system to co-encapsulate both drugs and nutrients while keeping them segregated.

The influence of chitosan on the structural properties of whey protein and wheat starch composite systems.

The structural properties of medium molecular weight chitosan (CHT), whey protein isolate (WPI) and native wheat starch (WS) from low- to intermediate-solid single systems and composite matrices were investigated. Analysis involved monitoring the thermal behavior of these biopolymers during controlled heating from 25 up to 95 °C and subsequent cooling to 5 °C under small deformation dynamic oscillation in-shear and micro differential scanning calorimetry experiments. Further information regarding the molecular interactions of components and overall network morphology of the systems was revealed through subjecting thermally developed gels to large deformation compression testing, scanning electron microscopy and infrared spectroscopy. Our study found a significant change in the structure of WPI networks upon incorporation of CHT in preparations due to electrostatic forces developing between the two polymeric constituents. In the tertiary system, the presence of low levels of starch contributed to a reduction in the firmness of the gel matrix. However, at higher additions of the polysaccharide, a recovery in the stored energy of composite materials was apparent, as recorded in the thermomechanical protocol.

Phase behaviour and in vitro hydrolysis of wheat starch in mixture with whey protein.

Network formation of whey protein isolate (WPI) with increasing concentrations of native wheat starch (WS) has been examined. Small deformation dynamic oscillation in shear and modulated temperature differential scanning calorimetry enabled analysis of binary mixtures at the macro- and micromolecular level. Following heat induced gelation, textural hardness was measured by undertaking compression tests. Environmental scanning electron microscopy provided tangible information on network morphology of polymeric constituents. Experiments involving in vitro starch digestion also allowed for indirect assessment of phase topology in the binary mixture. The biochemical component of this work constitutes an attempt to utilise whey protein as a retardant to the enzymatic hydrolysis of starch in a model system with α-amylase enzyme. During heating, rheological profiles of binary mixtures exhibited dramatic increases in G' at temperatures more closely related to those observed for single whey protein rather than pure starch. Results from this multidisciplinary approach of analysis, utilising rheology, calorimetry and microscopy, argue for the occurrence of phase separation phenomena in the gelled systems. There is also evidence of whey protein forming the continuous phase with wheat starch being the discontinuous filler, an outcome that is explored in the in vitro study of the enzymatic hydrolysis of starch.