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以大豆毛油为研究对象,研究其在不同气体(Ar、N2、CO2)、不同体积分数(95%、98%)气调储藏过程中主要品质变化规律,构建预测模型并进行预测和验证,为毛油安全储藏及品质预测提供理论依据。结果表明,储藏期间N2、Ar、CO2气调油脂POV分别比CK显著降低了72.7%~91.5%、74.2%~92.2%和75.7%~89.9%,气调处理抑制POV效果显著,且Ar效果最好,其次为N2和CO2;Ar和N2气调抑制AV效果显著,CO2处理则具有显著促进作用。三种气体体积分数98%气调储藏大豆毛油POV和AV不同程度低于体积分数95%。基于POV,运用一级氧化动力学模型结合Arrhenius 方程建立储藏期预测模型,拟合精度高(R2>0.95),验证效果好,预测储藏期相对误差为8.3%。结合实测和预测模型预测结果得出,25、40、50、60℃情况下,CK组储藏期分别为69、38、26、19 d,Ar 98%和N2 98%组储藏期分别为155、104、83、66 d和129、92、76、63 d,Ar气调处理对维持大豆毛油储藏品质效果好于N2气调,但差异不显著,且体积分数越高,效果越好。 相似文献
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葡萄籽油和亚麻籽油储藏期间氧化对功能性成分影响 总被引:1,自引:0,他引:1
通过实验研究35℃恒温避光储藏亚麻籽油和葡萄籽油过氧化值、p–茴香胺值、脂肪酸组成和维生素E含量变化,探讨储藏期间油脂氧化劣变对其功能性成分影响。结果表明,经60天储藏,葡萄籽油、亚麻油过氧化值分别达241.30 mmol/kg、248.72 mmol/kg;p–茴香胺值为32.20、104.06;油脂脂肪酸组成不饱和脂肪酸减少0.35%和0.41%,亚油酸和亚麻酸分别降低0.20%和0.09%、0.23%和1.04%,反式脂肪酸含量基本没有变化;维生素E含量显著降低均未检出;储藏期间亚麻籽油氧化对功能性成分影响均大于葡萄籽油。 相似文献
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采用气相色谱法对7种特种油脂的脂肪酸组成进行分析,并对烘箱法加速氧化前后7种特种油脂的过氧化值(POV)和TBA值进行测定。结果表明:7种特种油脂的不饱和脂肪酸含量均显著高于饱和脂肪酸含量;黄秋葵籽油棕榈酸含量最高,为26.86%,木瓜籽油油酸含量最高,为36.80%,哈密瓜籽油亚油酸含量最高,为62.31%,牡丹籽油α-亚麻酸含量最高,为39.21%;加速氧化条件下,牡丹籽油和黄秋葵籽油的POV上升较慢,品质稳定性较好,而核桃油、小麦胚芽油、玉米胚芽油和木瓜籽油的POV上升速度较快,品质容易下降;加速氧化条件下,黄秋葵籽油、哈密瓜籽油、玉米胚芽油等的TBA值相对较低且稳定,而核桃油的TBA值最高且随温度升高增加较快。 相似文献
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为研究高油大豆和低油大豆油脂体组成及乳化稳定性和氧化稳定性差异,本试验分析了高油大豆和低油大豆油脂体基本组成、脂肪酸组成、磷脂组成、生育酚组成,同时比较了高油大豆油脂体与低油大豆油脂体乳化性及乳化稳定性、过氧化值及TBARS值。研究表明,高油大豆油脂体蛋白质含量显著低于低油大豆油脂体(P0.05),而高油大豆油脂体的脂肪含量显著高于低油大豆油脂体(P0.05);高油大豆油脂体的棕榈酸和亚油酸含量显著低于低油大豆油脂体(P0.05),而十七碳酸、油酸、二十碳一烯酸和α-亚麻酸含量显著高于低油大豆油脂体(P0.05),高油大豆油脂体的总不饱和脂肪酸质量分数(83.08±0.05)%显著高于低油大豆油脂体(81.86±0.12)%(P0.05);高油和低油大豆油脂体中脑磷脂、卵磷脂和溶血磷脂酰胆碱含量无显著差异(P0.05);高油大豆油脂体中DL-α-生育酚和γ-生育酚含量显著高于低油大豆油脂体(P0.05);高油大豆油脂体和低油大豆油脂体的乳化性无显著差异(P0.05),而高油大豆油脂体的乳化稳定性显著高于低油大豆油脂体(P0.05);14 d热处理条件下,高油大豆油脂体的过氧化值和TBARS值均高于低油大豆油脂体。上述研究表明,高油大豆和低油大豆的油脂体之间的组成和稳定性都存在差异。 相似文献
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为深入了解微胶囊化技术对牡丹籽油储藏稳定性和货架期的影响,采用Avrami’s公式分析牡丹籽油微胶囊的油保留率,考察牡丹籽油微胶囊在储藏期间的释放动力学;通过监测过氧化值(POV)的变化,对牡丹籽油微胶囊进行氧化动力学研究。结果表明:牡丹籽油微胶囊的释放反应介于扩散限制动力学和一级释放动力学之间;经过微胶囊化,牡丹籽油的POV上升速率降低,25℃储藏条件下货架期显著延长,45℃储藏条件下仍然可保持较高不饱和脂肪酸含量。研究表明微胶囊化可有效降低牡丹籽油的氧化速度,提高牡丹籽油的储藏稳定性,延长货架期。 相似文献
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为探索脉冲强光(IPL)处理对富含油脂食品的影响,采用能量为500 J的IPL对菜籽油进行照射,研究IPL处理对储藏过程中菜籽油氧化稳定性及相关成分的影响。结果表明,IPL处理可诱导菜籽油的氧化,增加总酚含量,降低α-生育酚含量,但其主要不饱和脂肪酸含量变化不明显(P0. 05)。IPL处理组和对照组菜籽油储藏过程中的氧化程度均随时间的延长而增加,但处理组菜籽油过氧化值(POV)和p-茴香胺值(p-AV)的变化比对照组缓慢。储藏32 d后,处理组菜籽油POV值、p-AV值和主要不饱和脂肪酸含量均显著低于对照组(P0.05),而总酚含量仍显著高于对照组,α-生育酚含量则与对照组相比无显著差异。IPL处理能延缓储藏期内菜籽油的氧化及酚类物质含量的下降。本研究为IPL技术用于富脂食品的加工提供参考。 相似文献
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对油菜籽壳粕和脱壳后的菜籽肉粕中提取液的总酚含量、对DPPH 自由基清除能力以及FRAP 抗氧化能力进行比较,并采用液质联用法对提取液中的主要成分进行鉴定,对其中的芥子酸和芥子碱进行定量分析。结果表明:菜籽肉粕提取液中的总酚含量、对DPPH 自由基清除能力以及FRAP 抗氧化能力约为菜籽壳粕中的两倍,芥子酸和芥子碱的含量分别为菜籽壳粕中的约2.5 倍和1.5 倍。通过对实验室溶剂除油的菜籽粕与工业高温粕比较发现,高温榨油过程会使菜籽的总酚含量、抗氧化性、芥子酸和芥子碱含量有所下降,其中总酚含量下降了12.06%,DPPH 自由基和FRAP 抗氧化值分别降低10.0% 和5.6%,芥子酸和芥子碱含量分别下降了5.6% 和21.12%。 相似文献
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对茶叶籽毛油进行了6个月的储藏实验,模拟工厂实际情况,探究光照、温度和密闭性对茶叶籽毛油品质的影响。结果表明:热榨茶叶籽毛油储藏稳定性较冷榨茶叶籽毛油好,储藏条件对茶叶籽毛油品质的影响大小依次为光照、温度和密闭性;储藏6个月后,茶叶籽毛油酸值、过氧化值增幅均超过100%,氧化稳定指数降幅超过60%,生育酚含量降幅为20%~50%,角鲨烯含量降幅为50%~83%,茶多酚含量降幅为25%~70%;相关性分析发现,热榨茶叶籽毛油的氧化稳定性与生育酚、茶多酚含量相关性较高,冷榨茶叶籽毛油的氧化稳定性则与角鲨烯含量相关性较高。因此,茶叶籽毛油必须避光储藏,同时维持温度稳定,低温尤佳。 相似文献
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油脂储藏过程中茴香胺值、过氧化值的变化研究 总被引:3,自引:0,他引:3
油脂在常温储藏条件下,空气是影响茴香胺值(AV)的主要N素,不同阶段AV变化速度不同,氧化期的速度远大于诱导期,并且AV向逐步增大的方向发展;油脂精炼程度越高,AV上升越快:抗氧化剂能降低油脂AV增长速度,并使AV呈上升、下降、再上升的波浪式上升趋势:油脂中不饱和脂肪酸含量越高越易氧化,且亚麻酸含量的影响远大于亚油酸。阳光辐射显著加速油脂氧化,AV约是对照组的15倍,到90d时。能明显闻到油脂样品酸败的味道,油脂风味已发生变化。AV和过氧化值(POV)之间没有共通性,但是,POV上升速度远大于AV。全氧化值(TV)较AV、POV的变化更显著。 相似文献
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为解决单一食用油中营养组分缺陷问题,以大豆油、橄榄油、鱼油和亚麻籽油为基料油,测定其酸值、过氧化值、水分及挥发物含量和脂肪酸组成,然后按照中国营养学会关于脂肪酸推荐摄入量的要求,依据不同基料油的脂肪酸组成计算其配比并配制调和油,最后测定调和油的营养成分。结果表明:大豆油、橄榄油、亚麻籽油、鱼油的酸值、过氧化值、水分及挥发物含量均符合相关国家标准,4种油脂配制调和油的最适配比为45%、45%、8%、2%;调和油中主要微量营养成分及其含量为角鲨烯2.18 mg/kg、β-胡萝卜素0.474 mg/kg、α-生育酚73.6 mg/kg、β-生育酚0.6 mg/kg、γ-生育酚132.0 mg/kg、δ-生育酚20.4 mg/kg、总甾醇5 700 mg/kg。所得调和油符合中国营养学会关于脂肪酸推荐摄入量的要求,是一种营养平衡调和油。 相似文献
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Vegetable Oils Replace Pork Backfat for Low-Fat Frankfurters 总被引:6,自引:0,他引:6
Low-fat frankfurters (10% fat, 12.5% protein) with olive, corn, sunflower or soybean oils, compared to control (29.1% animal fat, 10.4% protein) had 67% lower total fat, 40–45% lower saturated fatty acids, 50–53% lower calories, reduced cholesterol and 20% higher meat protein. Although they had darker red color they were 6–7.2% lower in processing yield and had higher purge accumulation, were firmer and less juicy. The type oil had no effect (P>0.05) on these characteristics but affected fatty acid composition. Frankfurters with olive oil had 41.8% higher monounsaturated fatty acids and those with seed oils 5–7 times higher polyunsaturated fatty acids. Soybean oil increased lin-olenic acid content and negatively affected overall acceptability and shelf-life. 相似文献
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Microencapsulation of Oils: A Comprehensive Review of Benefits,Techniques, and Applications 总被引:1,自引:0,他引:1 下载免费PDF全文
Amr M. Bakry Shabbar Abbas Barkat Ali Hamid Majeed Mohamed Y. Abouelwafa Ahmed Mousa Li Liang 《Comprehensive Reviews in Food Science and Food Safety》2016,15(1):143-182
Microencapsulation is a process of building a functional barrier between the core and wall material to avoid chemical and physical reactions and to maintain the biological, functional, and physicochemical properties of core materials. Microencapsulation of marine, vegetable, and essential oils has been conducted and commercialized by employing different methods including emulsification, spray‐drying, coaxial electrospray system, freeze‐drying, coacervation, in situ polymerization, melt‐extrusion, supercritical fluid technology, and fluidized‐bed‐coating. Spray‐drying and coacervation are the most commonly used techniques for the microencapsulation of oils. The choice of an appropriate microencapsulation technique and wall material depends upon the end use of the product and the processing conditions involved. Microencapsulation has the ability to enhance the oxidative stability, thermostability, shelf‐life, and biological activity of oils. In addition, it can also be helpful in controlling the volatility and release properties of essential oils. Microencapsulated marine, vegetable, and essential oils have found broad applications in various fields. This review describes the recognized benefits and functional properties of various oils, microencapsulation techniques, and application of encapsulated oils in various food, pharmaceutical, and even textile products. Moreover, this review may provide information to researchers working in the field of food, pharmacy, agronomy, engineering, and nutrition who are interested in microencapsulation of oils. 相似文献
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Malongil B. Reena Belur R. Lokesh 《International Journal of Food Science & Technology》2012,47(1):203-209
The effect of feeding blended and interesterified oils containing palm oil (PO) and rice bran oil (RBO) on serum and liver lipids was evaluated in rats. The PO and RBO were blended to contain saturated, monounsaturated and polyunsaturated fatty acids in the proportion of 1:1.5:1. The blended oil was subjected to transesterification reaction using immobilized lipase, lipozyme IM‐RM. Rats were fed a diet containing blended or interesterified oils for 8 weeks. Rats fed PO showed significantly higher levels of cholesterol in serum and liver as compared to those given RBO, blended oil of PO with RBO or interesterified oil. Rats fed blended oils showed a significant decrease in serum cholesterol by 51% compared to rats fed PO. Feeding interesterified oil to rats resulted in decrease in serum cholesterol by 56% compared to rats fed PO, which was 10% lower compared to that observed in rats given blended oil. The present study indicated that a combination of PO with RBO can significantly lower serum lipids in rats as compared to those given diet containing PO alone. 相似文献