Thermal stability enhancement of berry anthocyanins by co-pigmentation with extracts from natural sources

IF 1.6 4区农林科学

International Journal of Food Engineering Pub Date : 2022-07-01 DOI:10.1515/ijfe-2021-0260

Aichurok T. Mazhitova, Aidaikan M. Kasymakunova, N. Turker

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引用次数: 2

Abstract

Abstract The suitability of mandarin (MP), orange (OP) and pomegranate peel powders (PP) for co-pigmentation of dewberry, viburnum, red hawthorn, black hawthorn, and barberry anthocyanins was investigated. Spectrophotometric measurements indicated co-pigmentation causing both a hyperchromic effect (ΔABSmax = 5–13) and bathochromic shift (Δλvis-max up to 13 nm). The degradation kinetics of anthocyanins were estimated at temperatures ranging from 70 to 90 °C. First-order reactions with rate constants of 0.45–2.93 min−1 and 0.30–2.00 min−1 were observed for the reference and PP co-pigmented samples, respectively. The t1/2 values were 3.90–25.7 h for the reference and 5.8–38.5 h for the co-pigmented samples. The activation energy (Ea) values were higher in co-pigmented samples (49.16–77.77 kJ/mol) than in reference samples (41.82–68.75 kJ/mol), except for black hawthorn, which had a lower Ea value in the co-pigmented sample. The thermodynamic parameters (enthalpy, free energy, and entropy) evaluated indicated a positive effect of co-pigmentation on the thermal treatment of anthocyanins.

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与天然提取物共着色剂增强浆果花青素的热稳定性

摘要研究了桔皮粉(MP)、橙皮粉(OP)和石榴皮粉(PP)对露莓、豆荚、红山楂、黑山楂和杨梅花青素共着色剂的适宜性。分光光度测量表明，共色素沉着引起了深色效应(ΔABSmax = 5-13)和深色偏移(Δλvis-max达13 nm)。在70 ~ 90℃的温度范围内对花青素的降解动力学进行了估计。参考样品和PP共着色样品的一级反应速率常数分别为0.45-2.93 min−1和0.30-2.00 min−1。参考样品t1/2值为3.90 ~ 25.7 h，共色素样品t1/2值为5.8 ~ 38.5 h。除黑山楂的Ea值较低外，共色素样品的Ea值(49.16 ~ 77.77 kJ/mol)高于参比样品(41.82 ~ 68.75 kJ/mol)。热力学参数(焓、自由能和熵)的评估表明，共着色对花青素的热处理有积极的影响。

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来源期刊

International Journal of Food Engineering 农林科学-食品科技

CiteScore

3.20

自引率

0.00%

发文量

审稿时长

3.8 months

期刊介绍： International Journal of Food Engineering is devoted to engineering disciplines related to processing foods. The areas of interest include heat, mass transfer and fluid flow in food processing; food microstructure development and characterization; application of artificial intelligence in food engineering research and in industry; food biotechnology; and mathematical modeling and software development for food processing purposes. Authors and editors come from top engineering programs around the world: the U.S., Canada, the U.K., and Western Europe, but also South America, Asia, Africa, and the Middle East.