黄原胶添加对碱法诱导魔芋胶凝胶特性及凝胶机制的影响

doi:10.3864/j.issn.0578-1752.2020.14.017

摘要/Abstract

摘要：

【目的】探究黄原胶添加量对魔芋胶凝胶特性及凝胶机制的影响,为相关凝胶食品的开发利用提供理论依据和技术参考。【方法】以2%的魔芋胶溶胶为基质,通过添加不同浓度的黄原胶,制备混合多糖体系,并在2%的碱浓度（Na₂CO₃）及90℃的高温下加热混合体系2 h,冷却后制得不同黄原胶含量（0-1.5%,w/v）的混合凝胶。通过测定混合凝胶强度,研究去离子水浸泡、2%柠檬酸溶液浸泡和冻融处理对凝胶样品的影响。同时,采用扫描电镜观察不同处理凝胶的微观形貌,探究不同处理及黄原胶添加量对魔芋胶凝胶结构的影响。另外,基于流变学、X-射线衍射以及热重分析等手段,探究魔芋胶-黄原胶混合体系在热碱处理过程中凝胶网络的形成过程,揭示凝胶化机制。【结果】90℃恒温加热2 h后,随黄原胶含量增加,混合凝胶强度反而降低,表明90℃加热过程中,黄原胶的存在影响了魔芋胶凝胶网络的形成。但室温条件下,黄原胶含量越高,混合凝胶强度也越高,表明冷却过程中黄原胶可能加强了凝胶网络。经去离子水、2%柠檬酸溶液浸泡后,各处理凝胶强度均呈下降趋势,以2%柠檬酸溶液浸泡处理后的凝胶强度降低最明显。此外,冻融处理后,魔芋胶凝胶出现明显的析水现象,析水率可达50%,但加入黄原胶后,混合凝胶的析水作用显著降低,黄原胶含量越高,析水作用越弱。流变学测试结果表明,在90℃恒温加热2 h的过程中,随黄原胶添加量增加,体系凝胶化速率减小,表明加入黄原胶降低了魔芋胶凝胶网络的形成。随后对该混合体系进行降温扫描,发现当温度从90℃降低至60℃时,凝胶弹性模量呈明显降低趋势,当温度继续降低至室温时,凝胶弹性模量呈明显增加趋势,转折点所对应的温度为60℃,温度越低,弹性模量越高,表明黄原胶分子在60℃时开始与魔芋胶网络发生协同结合作用。【结论】黄原胶添加可显著提高碱法诱导的魔芋胶凝胶在室温下的凝胶强度,同时可改善该凝胶的冻融稳定性,该结论可为魔芋胶凝胶相关食品的开发提供有益参考。

关键词: 魔芋胶, 黄原胶, 凝胶强度, 流变学特性, 冻融稳定性

Abstract:

【Objective】The effects of xanthan addition amounts on the gel properties and gelation mechanism of konjac glucomannan (KGM) gels were investigated, which was expected to provide a theoretical basis and technique references for developing KGM-related gel foods.【Method】The mixed KGM and xanthan systems were prepared by adding different concentrations of xanthan into 2% KGM solution, and then the mixed polysaccharide systems were subjected to heating at 90℃ for 2 h in the presence of 2% Na₂CO₃. After cooling to room temperature, the composite KGM-xanthan gels were prepared. By determining the gel strength, the effects of deionized water immersion and 2% citric acid immersion as well as freeze-thaw treatment on the composites were investigated. Meanwhile, scanning electron microscope was used to visualize the microstructures of the composite gels, and then the effects of different treatment methods and xanthan addition amounts on the gel structures were also revealed. Moreover, based on rheology, X-ray scattering and thermogravimetric analyses, the gel formation process of the mixed KGM and xanthan systems during heating at hot alkaline condition was explored, and the gelation mechanism was also revealed.【Result】During heating at 90℃ for 2 h, it was found that with the increasing of xanthan addition, the gel strength of the composite gels was decreased, indicating that the presence of xanthan negatively affected the formation of KGM gel network in this process. However, at room temperature, with increasing xanthan content, the gel strength of the composite gels was increased. The higher the xanthan content, the greater the gel strength, indicating that xanthan might strengthen the composite gels during cooling. After dezionized water and 2% citric acid immersion, gel strength decreased, and the gel samples with citric acid immersion showed a more pronounced decreased trend. Besides, after freeze-thaw treatment, KGM gels exhibited significant syneresis effect, with an approximately 50% of syneresis rate. However, after adding xanthan, the syneresis rate of the composite gels was significantly decreased. The higher the xanthan content, the lower the syneresis rate. Rheological test results suggested that during heating at 90℃ for 2 h, with the increasing of xanthan content, the gelling rate of the mixed KGM-xanthan system was decreased, indicating that the addition of xanthan decreased the formation of KGM gel network. Subsequent decreasing temperature sweep results showed that when the temperature decreased from 90℃ to 60℃, the elastic modulus of the composite gels exhibited a decreasing trend. When the temperature was continuously decreased to room temperature, the elastic modulus showed an increasing trend, and the transition temperature was corresponding to 60℃, suggesting that xanthan began to synergistically bind with KGM gel network at this temperature.【Conclusion】The addition of xanthan significantly improved the gel strength of alkali-induced KGM gels at room temperature, and also enhanced the freeze-thaw stability of the gels. This result could provide valuable reference to development of KGM gel-related food.

Key words: konjac glucomannan, xanthan, gel strength, rheological properties, freeze-thaw stability

李晓飞,李培源,李安琪,余文艳,郭绰,杨曦,郭玉蓉. 黄原胶添加对碱法诱导魔芋胶凝胶特性及凝胶机制的影响[J]. 中国农业科学, 2020, 53(14): 2941-2955.

LI XiaoFei,LI PeiYuan,LI AnQi,YU WenYan,GUO Chuo,YANG Xi,GUO YuRong. Effects of Xanthan Addition on the Gel Properties and Gel Mechanism of Alkaline-Induced Konjac Glucomannan Gels[J]. Scientia Agricultura Sinica, 2020, 53(14): 2941-2955.

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编号 No.	3%魔芋胶 3% KGM (g)	魔芋胶干重 KGM dry weight (g)	魔芋胶浓度 KGM concentration (w?v^-1)	5%黄原胶 5% Xanthan (g)	黄原胶干重 Xanthan dry weight (g)	黄原胶浓度 Xanthan concentration (w?v^-1)	去离子水 Deionized water (mL)
0	133.3	4	2%	0	0	0	56.7
1	133.3	4	2%	10	0.5	0.25%	46.7
2	133.3	4	2%	20	1	0.5%	36.7
3	133.3	4	2%	30	1.5	0.75%	26.7
4	133.3	4	2%	40	2	1.0%	16.7
5	133.3	4	2%	50	2.5	1.25%	6.7
6	133.3	4	2%	60	3	1.5%	0

样品Sample	G'_sat	k	R²
2% KGM (Control)	5944.73	3.58×10^-4	0.9800
2% KGM+0.25% Xanthan	4613.90	2.42×10^-4	0.9918
2% KGM+0.5% Xanthan	3853.96	1.14×10^-4	0.9829
2% KGM+0.75% Xanthan	1760.91	0.78×10^-4	0.9915
2% KGM+1.0% Xanthan	1247.19	0.54×10^-4	0.9963