Manwinder Kaur Sidhu , Felicity Whitehead , Stefan Kasapis
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引用次数: 0
Abstract
In this investigation, whey protein and agarose were employed as the phase-separated biopolymer system, with vitamin B6 acting as the diffusant. Fourier-transform infrared (FTIR) spectroscopy affirmed the absence of chemical interactions among all constituents within the experimental parameters. X-ray diffraction (XRD) analysis corroborated the uniform dissolution of vitamin B6 within the composite low-solid mixtures. Confocal scanning laser microscopy elucidated the topology of the matrix, providing tangible evidence of the phase-separated whey protein-agarose networks. Small-deformation dynamic oscillation in-shear was employed to establish a rheological blending law model, predicting the phase volume and effective concentration of the individual components (whey protein and agarose) within their respective domains. Subsequently, a diffusion study was conducted, advocating a novel blending law for molecular transport to estimate the theoretical diffusion coefficient of vitamin B6 in the composite gel by leveraging the effective concentration of each polymer within its phase. The outcomes were positively compared to the observed diffusion coefficient of the vitamin from the composite gel using UV–vis spectroscopy. These results underscore the viability of the blending-law diffusion theory in elucidating the molecular transport of hydrophilic vitamins released from aqueous biopolymer composite gels.
期刊介绍:
Food Hydrocolloids publishes original and innovative research focused on the characterization, functional properties, and applications of hydrocolloid materials used in food products. These hydrocolloids, defined as polysaccharides and proteins of commercial importance, are added to control aspects such as texture, stability, rheology, and sensory properties. The research's primary emphasis should be on the hydrocolloids themselves, with thorough descriptions of their source, nature, and physicochemical characteristics. Manuscripts are expected to clearly outline specific aims and objectives, include a fundamental discussion of research findings at the molecular level, and address the significance of the results. Studies on hydrocolloids in complex formulations should concentrate on their overall properties and mechanisms of action, while simple formulation development studies may not be considered for publication.
The main areas of interest are:
-Chemical and physicochemical characterisation
Thermal properties including glass transitions and conformational changes-
Rheological properties including viscosity, viscoelastic properties and gelation behaviour-
The influence on organoleptic properties-
Interfacial properties including stabilisation of dispersions, emulsions and foams-
Film forming properties with application to edible films and active packaging-
Encapsulation and controlled release of active compounds-
The influence on health including their role as dietary fibre-
Manipulation of hydrocolloid structure and functionality through chemical, biochemical and physical processes-
New hydrocolloids and hydrocolloid sources of commercial potential.
The Journal also publishes Review articles that provide an overview of the latest developments in topics of specific interest to researchers in this field of activity.
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