Using the Chopin Mixolab to model the effects of arabinoxylan ingredients on breadmaking. Part 2: Predicting the effects of combinations of different arabinoxylans
Konstantina Solomou , Nikolina Čukelj Mustač , Mohammad Alyassin , Grant M. Campbell
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引用次数: 0
Abstract
This paper applies the novel approach presented in Part 1 to using the Chopin Mixolab 2 to quantify the effects of arabinoxylans (AX) on the Mixolab torque profile. The approach is illustrated with three contrasting AX products, one extracted from wheat (WhAX), and two extracted from maize, with the original high molecular weight extract, MzAX, further processed into low molecular weight AX (LMzAX). The Arabinoxylan Multiplication Factor (AXMF) of MzAX in relation to water absorption (WAbs) was 2.0, indicating that the MzAX was twice as effective as flour at absorbing water in the dough formulation; the AXMF of WhAX was close to zero, indicating that it had negligible effect on WAbs; and the AXMF of LMzAX was negative, indicating that replacing flour with LMzAX reduced WAbs. AXMF values were quantified in relation to other key measures of the Mixolab profile (Development Time, Stability Time and torque measures related to gluten softening and starch gelatinisation, hydrolysis and retrogradation), illustrating how different AXs influence different elements of bread quality. Baking results using the WhAX and MzAX are also presented, showing the latter giving poorer quality bread. The approach (patent pending, GB2415536.8) allows the combined effects of AX addition and WAbs adjustment on the Mixolab profile to be modelled, and mixtures of AX and other fibre and hydrocolloid ingredients with different properties and functionality to be formulated to precisely target different aspects of bread quality.
期刊介绍:
Official Journal of the European Federation of Chemical Engineering:
Part C
FBP aims to be the principal international journal for publication of high quality, original papers in the branches of engineering and science dedicated to the safe processing of biological products. It is the only journal to exploit the synergy between biotechnology, bioprocessing and food engineering.
Papers showing how research results can be used in engineering design, and accounts of experimental or theoretical research work bringing new perspectives to established principles, highlighting unsolved problems or indicating directions for future research, are particularly welcome. Contributions that deal with new developments in equipment or processes and that can be given quantitative expression are encouraged. The journal is especially interested in papers that extend the boundaries of food and bioproducts processing.
The journal has a strong emphasis on the interface between engineering and food or bioproducts. Papers that are not likely to be published are those:
• Primarily concerned with food formulation
• That use experimental design techniques to obtain response surfaces but gain little insight from them
• That are empirical and ignore established mechanistic models, e.g., empirical drying curves
• That are primarily concerned about sensory evaluation and colour
• Concern the extraction, encapsulation and/or antioxidant activity of a specific biological material without providing insight that could be applied to a similar but different material,
• Containing only chemical analyses of biological materials.
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