Optimization of deacidification for concentrated grape juice

被引：11

作者：

Li, Ning ^{[1
,2
]}

Wei, Yue ^{[3
]}

Li, Xuemeng ^{[3
]}

Wang, Jiahui ^{[3
]}

Zhou, Jiaqian ^{[3
]}

Wang, Jie ^{[1
,2
]}

机构：

[1] Agr Univ Hebei, Coll Food Sci & Technol, Baoding 071001, Peoples R China

[2] Hebei Agr Prod Proc Engn Technol Res Ctr, Baoding 071001, Hebei, Peoples R China

[3] Agr Univ Hebei, Coll Sci & Technol, Huanghua, Hebei, Peoples R China

来源：

FOOD SCIENCE & NUTRITION | 2019年 / 7卷 / 06期

关键词：

anion-exchange resin; concentrated grape juice; optimized deacidification; tartaric acid; RESPONSE-SURFACE METHODOLOGY; MAIN ORGANIC-ACIDS; TARTARIC ACID; LIQUID-CHROMATOGRAPHY; MALIC-ACID; WINE; WATER; FERMENTATION; EQUILIBRIUM; PROFILES;

D O I：

10.1002/fsn3.1037

中图分类号：

TS2 [食品工业];

学科分类号：

0832 ;

摘要：

Excessive organic acids in grape juice will not only result in poor taste but will also cause turbidity and sedimentation. Tartaric acid exerts the most significant acidity among all organic acids in grape juice. In this study, we used tartaric acid as the main target and anion-exchange resin to remove tartaric acid from concentrated grape juice. Factors influencing the removal process were optimized by liquid chromatography with ultraviolet detection and statistical analysis for optimal deacidification of concentrated grape juice. Use of the anion-exchange resin 335 treat the concentrated grape juice at a ratio of 1:6 (2:11.98) at 15.57 degrees C for 4.35 hr. The tartaric acid removal rate reached 69.01%; the anion-exchange resin 335 demonstrated the best removal effect.

引用

页码：2050 / 2058

页数：9

共 50 条

[21] Treatment of grape juice by osmotic evaporation
Versari, A
Ferrarini, R
Tornielli, GB
Parpinello, GP
Gostoli, C
Celotti, E
JOURNAL OF FOOD SCIENCE, 2004, 69 (08) : E422 - E427
[22] Improving acidity and flavors of citrus juice as well as its antioxidant activity by cofermentation with deacidification bacteria combination
Li, Minyi
Qin, Junwei
Zhong, Bin
Hao, Fangrun
Wu, Zhenqiang
FOOD BIOSCIENCE, 2023, 53
[23] Biodenitrification of concentrated red beet juice
Walkowiak-Tomczak, Dorota
EUROPEAN FOOD RESEARCH AND TECHNOLOGY, 2012, 235 (04) : 693 - 698
[24] Whole, concentrated and reconstituted grape juice: Impact of processes on phenolic composition, "foxy" aromas, organic acids, sugars and antioxidant capacity
Prudencio Dutra, Maria da Conceicao
Viana, Arao Cardoso
Pereira, Giuliano Elias
Mirella Resende Nassur, Rita de Cassia
Lima, Marcos dos Santos
FOOD CHEMISTRY, 2021, 343
[25] THE GROWTH AND SURVIVAL OF PICHIA-MEMBRANAEFACIENS DURING FERMENTATION OF GRAPE JUICE
MORA, J
ROSSELLO, C
AMERICAN JOURNAL OF ENOLOGY AND VITICULTURE, 1992, 43 (04): : 329 - 332
[26] Potential of yeasts isolated in botrytized grape juice to be new wine yeasts
Miki, Takeo
Ito, Yoshiaki
Kuroha, Kazumasa
Izawa, Shingo
Shinohara, Takashi
FOOD SCIENCE AND TECHNOLOGY RESEARCH, 2008, 14 (04) : 345 - 350
[27] Resveratrol and a novel tyrosinase in Carignan grape juice
Gilly, R
Mara, D
Oded, S
Zohar, K
JOURNAL OF AGRICULTURAL AND FOOD CHEMISTRY, 2001, 49 (03) : 1479 - 1485
[28] Spectrophotometric assay for arginine in grape juice and must
Austin, KT
Butzke, CE
AMERICAN JOURNAL OF ENOLOGY AND VITICULTURE, 2000, 51 (03): : 227 - 232
[29] Grape juice or wine: which is the best option?
Barbalho, Sandra Maria
Bueno Ottoboni, Alda Maria M.
Ragassi Fiorini, Adriana Maria
Guiguer, Elen Landgraf
Teixeira Nicolau, Claudia Cristina
Goulart, Ricardo de Alvares
Prync Flato, Uri Adrian
CRITICAL REVIEWS IN FOOD SCIENCE AND NUTRITION, 2020, 60 (22) : 3876 - 3889
[30] Characterization and recovery of tartaric acid from wastes of wine and grape juice industries
Yalcin, D.
Ozcalik, O.
Altiok, E.
Bayraktar, O.
JOURNAL OF THERMAL ANALYSIS AND CALORIMETRY, 2008, 94 (03) : 767 - 771

← 1 2 3 4 5 →