Effect of continuous instant pressure drop treatment on the rheological properties and volatile flavor compounds of whole highland barley flour

[Display omitted] •Continuous instant pressure drop (CIPD) affected thermal and pasting properties.•CIPD enhanced gelatinization stability of whole highland barley flour (WHBF).•A total of 68 volatile compounds were identified in raw WHBF.•CIPD preserved the original flavor of WHBF better than tradi...

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Published in:Food research international 2023-11, Vol.173, p.113408-113408, Article 113408
Main Authors: Chen, Zhiying, Nie, Mengzi, Xi, Huihan, He, Yue, Wang, Aixia, Liu, Liya, Wang, Lili, Yang, Xijuan, Dang, Bin, Wang, Fengzhong, Tong, Li-Tao
Format: Article
Language:English
Subjects:
Continuous instant pressure drop
Rheological properties
Volatile flavor compounds
Whole highland barley flour
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Summary:[Display omitted] •Continuous instant pressure drop (CIPD) affected thermal and pasting properties.•CIPD enhanced gelatinization stability of whole highland barley flour (WHBF).•A total of 68 volatile compounds were identified in raw WHBF.•CIPD preserved the original flavor of WHBF better than traditional hot air treatment. Continuous instant pressure drop (CIPD) treatment effectively reduces microbial contamination in whole highland barley flour (WHBF). Base on it, this study further investigated its effects on flour properties (especially rheological properties) and volatile compounds (VOCs) profile of WHBF, and compared it with that of ultraviolet-C (UV-C), ozone and hot air (HA) treatments. The results showed that the damaged starch content (6.0%) of CIPD-treated WHBF was increased, leading to a rough surface and partial aggregation of starch particle, thereby increasing the particle size (18.06 μm of D10, 261.46 μm of D50 and 534.44 μm of D90). Besides, CIPD treatment exerted a positive influence on the structure and rheological properties of WHBF, including an elevation in pasting temperature and viscosity. Notably, CIPD-treated WHBF exhibited higher storage modulus and loss modulus compared to the other three groups of sterilization treatments, contributing to the formulation of a better-defined and stable gel strength (tan δ = 0.38). UV-C and ozone, as cold sterilization techniques, also induced alterations in specific characteristics of WHBF. UV-C treatment led to changes in WHBF's crystallinity, while ozone treatment caused modifications in the secondary protein structure of WHBF. A total of 68 VOCs were identified in raw WHBF (including 3 acids, 19 alcohols, 25 aldehydes, 1 alkene, 8 esters, 2 ethers, 3 furans, and 7 ketones). The maximum flavor-contributing VOC in CIPD-treated WHBF remained dimethyl sulfide monomer (cabbage aroma), consistent with the raw WHBF. Conversely, in HA-treated WHBF, the maximum flavor-contributing VOC shifted to 2-furanmethanethiol monomer (roasted coffee aroma), altering the initial flavor presentation. These findings will provide strong support for the application of CIPD technology in the powdery foods industry.
ISSN:0963-9969
1873-7145
DOI:10.1016/j.foodres.2023.113408