食用植物油煎炸过程中的品质变化北大核心CSCD

利用花生油、大豆油、调和油、棕榈油4种食用植物油作为煎炸油对豆腐、裹粉鸡柳、油条3种食材进行煎炸,研究煎炸时间对煎炸油极性组分含量及羰基值的影响,确定煎炸油时间预警点,同时研究了不同煎炸油品种、不同食材对煎炸油极性组分含量的影响。结果表明:极性组分含量、羰基值均与煎炸时间呈正相关(r_(极性组分)=0.809,r_(羰基值)=0.859,P=0.000);煎炸6~11 h煎炸油极性组分含量均值从初始的11.85%增至20.96%,最大值为34.10%,可作为煎炸油质量不达标的时间预警点;煎炸12 h,极性组分含量从低到高依次为花生油、棕榈油、调和油、大豆油,含量分别为21.1%、24.1%、26.8%、27.8%,豆腐、裹粉鸡柳、油条煎炸油中极性组分含量分别为17.7%、25.0%、32.2%;煎炸18 h,极性组分含量增大程度由低到高为棕榈油/调和油、大豆油、花生油,煎炸食材用油为豆腐煎炸油、裹粉鸡柳煎炸油、油条煎炸油。     

A study on monitoring of frying performance and oxidative stability of cottonseed and palm oil blends in comparison with original oils

Blending polyunsaturated oils with highly saturated or monounsaturated oils has been studied extensively; however, in literature there is negligible information available on the blending of refined cottonseed oil with palm olein oil. Blending could enhance the stability and quality of cottonseed oil during the frying process. In the present study, the effects of frying conditions on physicochemical properties of the palm olein-cottonseed oil blends (1:0, 3:2, 1:1, 2:3, and 0:1, w/w) were determined and compared to the pure oils. The frying process of frozen French fries was performed in duplicate at 170 ± 5°C for 10 h without interruption. The oil degradations were characterized during deep-frying applications; peroxide, free fatty acid, and iodine value by standardized methods, fatty acid profile by using a gas chromatography-flame ionization detector, polar and polymeric compounds by using the high-performance size exclusion chromatography/evaporative light scattering detector technique. The present study clearly indicated that the oxidative and frying performances of pure palm olein oil and cottonseed oil significantly improved by blending application. Results clearly indicated that the frying performance of cottonseed oil significantly improved by the blending with palm olein oil. Except that free fatty acid content, all the physicochemical variables were significantly influenced by type of pure and blend oils. By increasing the proportion of palm olein oil in cottonseed oil, the levels of polyunsaturated fatty acids decreased, while saturated fatty acid content increased. The progression of oxidation was basically followed by detecting polar and polymeric compounds. The fastest increments for polar and polymeric compounds were found as 6.30% level in pure cottonseed oil and as 7.07% level in 40% cottonseed oil:60% palm olein oil blend. The least increments were detected as 5.40% level in 40% cottonseed oil:60% palm olein oil blend and 2.27% level in 50% cottonseed oil:50% palm olein oil blend. These levels were considerably below the acceptable levels recommended by the official codex. Therefore, the present study suggested that blending of cottonseed oil with palm olein oil provided the oil blends (50% cottonseed oil:50% palm olein oil and 40% cottonseed oil:60% palm olein oil, w/w) with more desirable properties for human nutrition.     

QUALITY CHANGES OF REFINED-BLEACHED-DEODORIZED (RBD) PALM OLEIN, SOYBEAN OIL AND THEIR BLENDS DURING DEEP-FAT FRYING

The quality changes of refined, bleached and deodorized palm olein (RBDPO) and soybean oil (SBO) and their blends were investigated in this study. The oils were studied during intermittent frying of potato chips at 180PT5C for 5 h per day for 5 consecutive days. The indices used for assessment of changes in quality of the oils were fatty acid composition (FAC), peroxide value (PV), anisidine value (AnV), % free fatty acid (FFA), iodine value (IV), % polar component, polymer content, color, viscosity, smoke point and foaming tendency. The results showed that RBDPO was superior to SBO in frying performance in terms of resistance to oxidation, changes in IV, AnV, foaming tendency, % polar component and polymer content. However, SBO performed better than RBDPO with respect to color, viscosity, FAA content and smoke point. Sensory evaluation showed that potato chips fried in both RBDPO and SBO were equally acceptable by the panelists.     

基于傅里叶变换红外光谱的大豆原油掺伪定量 分析模型研究

目的应用傅里叶变换红外光谱(FTIR)结合最小偏二乘法(PLS)建立大豆原油-棕榈油二元掺伪体系的定量分析模型。方法以42个大豆原油、21个精炼油、88个掺伪油的FIIR谱图为模型样本,预处理方法选用标准正态变量(SNV),在此基础上应用主成分分析(PCA)提取特征变量,随机选取60个掺伪油样组成校正集,28个掺伪油样组成验证集,以PLS方法建立大豆原油的掺伪定量模型。结果 PCA可将大豆原油及精炼油分成独立的2类。经PCA分析,大豆原油中掺入棕榈油的掺伪检测限为5%。PLS校正模型的判定系数R2为0.9926,校正误差均方根RMSEC为1.8121。预测模型的R2为0.9823,交叉验证误差均方根RMSECV为2.8189。同时得到的预测结果的偏差在1.3909%~3.1019%之间,差异不显著,说明此模型可行。结论 FTIR-PLS模型能够实现大豆原油的掺伪定量分析,分析速度快,能够满足大豆原油入库要求,是一种可行的大豆原油掺伪分析方法。     

稻米油在快餐煎炸中的性能研究

本文通过模拟西式快餐门店的煎炸实验,考察了稻米油在快餐煎炸中应用的可行性。通过油脂理化指标、肪酸组成分析及微量成分分析来比较稻米油与棕榈油和大豆油的差异,通过模拟西式快餐门店168℃下煎炸薯条过程中极性物质和酸价的变化,并对薯条进行感官评价,对比稻米油、大豆油与棕榈油的煎炸性能。结果显示:稻米油所含的饱和脂肪酸和不饱和脂肪酸均介于棕榈油和大豆油之间,并且其含有的维生素E与大豆油接近且明显高于棕榈油;另外稻米油还含有12035.74 mg/kg植物甾醇和4359.17 mg/kg谷维素。在煎炸过程中,稻米油的酸价上升速度远远低于大豆油,接近于棕榈油;尽管其初始极性组分较高,但其极性组分在煎炸后期上升比较平稳,至煎炸终点时其极性组分低于棕榈油和大豆油;同时在煎炸过程中,棕榈油、稻米油、大豆油中的维生素E随煎炸时间的延长明显降低,至第6 d对应的含量分别10.01、8.49与2.11 mg/kg;而稻米油中谷维素和植物甾醇含量也随煎炸时间的延长而减少,但至煎炸终点时,仍有较多的保留,含量分别为1531.98和6618.45 mg/kg。另外,感官评价发现,稻米油炸制的薯条比大豆油、棕榈油更酥脆、风味更好,整体喜好度更高。总之,但稻米油具有良好煎炸性能,其煎炸性能明显优于大豆油,可用作西式快餐煎炸油。     

COMPARISON OF THE FRYING STABILITY OF REGULAR AND LOW-LINOLENIC ACID SOYBEAN OILS

The frying stability of a regular soybean oil (RSO) was compared with a modified low linolenic-acid soybean oil (LLSO). The rate of free fatty acid (FFA) formation was similar for both oils during 72 h of frying. Despite a reduction in polyunsaturated fatty acids, however, the rate of formation of total polar compounds (TPC) in LLSO was greater than RSO. The higher production of TPCs in LLSO was explained, in part, by a lower level of tocopherols and a more rapid rate of degradation of the main isomers, γ- and δ tocopherols. This study points to the limitations of predicting frying stability based solely on fatty acid composition.     

西式快餐用煎炸油质量近红外快速检测模型的建立

为对西式快餐用煎炸油质量进行快速监测,选用近红外光谱法（NIRS）联合偏最小二乘法（PLS）,分别建立酸价和极性组分两个煎炸油质量指标的定量模型。结果表明,酸价和极性组分的定标模型校正决定系数（R2）均为0.9974,校正标准差均方根（RMSEC）分别为0.111和0.359,预测标准差均方根（RMSEP）分别为0.171和0.562。盲样验证、精密度及准确度分析结果显示,酸价和极性组分的NIR预测值同真实值的相关方程的相关系数分别为0.9944、0.9761,应用所建模型预测同一煎炸油样品的酸价和极性组分的相对标准偏差（RSD）分别为0.934%和1.278%,表明所建模型对煎炸油样品的酸价和极性组分预测能力较好,且有较好的重现性。因此,基于近红外光谱定量模型,可以对西式快餐用煎炸油质量进行快速、准确地监测。     

COMPARISON OF THE FRYING PERFORMANCE OF REFINED, BLEACHED AND DEODORIZED PALM OLEIN AND COCONUT OIL

The frying performance of refined, bleached and deodorized palm olein (RBDPO) and refined, bleached and deodorized coconut oil (RBDCO) was compared in this study. The oils were studied during intermittent frying of potato chips at 180C for 5 h/day for 5 consecutive days. The indices used for assessment of frying performance of the oils were fatty acid composition (FAC), peroxide value (PV), anisidine value (AnV), % free fatty acid (FFA), iodine value (IV), % polar component, polymer content, color, viscosity, smoke point and foaming tendency. The results showed that RBDPO was superior to RBDCO in frying performance in terms of % FFA, iodine value, foaming tendency and smoke point. However, RBDCO performed better than RBDPO with respect to % polar component, polymer content, resistance to oxidation, color and viscosity. Flavor evaluation showed that potato chips fried in RBDPO were preferred by the panelists.     

以棉籽油为基料油的煎炸专用调和油煎炸品质的研究

以棉籽油为基料油,添加大豆油、菜籽油、棕榈油进行调配,制成煎炸专用的植物调和油。用制得的煎炸调和油进行不间断地煎炸薯条试验,考察煎炸油在煎炸过程中油脂色泽、理化指标及品质的变化情况。结果表明:煎炸调和油的脂肪酸组成合理,满足单不饱和脂肪酸/多不饱和脂肪酸=4.0:0.6的最佳摄入比例。煎炸过程中色泽变化较慢,极性组分超过27%限量的时间为67 h,酸价由(0.18±0.05) mg/g增加至(3.53±0.10) mg/g,羰基价由(9.42±0.12) meq/kg增加至(36.0±0.14) meq/kg,过氧化值和苯并(α)芘没有明显的变化趋势,丙烯酰胺未检出;与河北地区常用于煎炸的三级棉籽油46 h的煎炸寿命和较高的羰基价、过氧化值和苯并(α)芘相比,配制的煎炸调和油的煎炸寿命延长了18 h,稳定性提高了37%,煎炸薯条的平均含油率为18%煎炸感官效果好,可以作为一种新型煎炸调和油。     

饲用油脂品质初步调查分析

目的以油脂中脂肪酸含量和极性成分为依据,用气相色谱法和快速筛查试剂盒对饲料用油脂品质进行初步分析。方法取自国内饲料企业的280份饲料用油脂样品,包括猪油、鸭油、鸡油、大豆油、大豆磷脂油、玉米油、米糠油、棕榈油等动植物油脂和未知种类的油脂,与自制或采购标准的动物油脂和植物油脂,进行脂肪酸种类、含量和极性成分的测定,对其品质作出初步判定。结果脂肪酸分析结果证明,动物油样品和植物油样品中的部分脂肪酸成分含量均发生不同程度的降低或增高;极性成分检测的83个样品中,其中标准值为0.1,极性成分吸光值在0.147～0.947的样品占55个,阳性率达66.26%。结论未知类型样品超过半数为不合格样品;未知油脂样品脂肪酸组成不符合单一油脂比值范围,推断可能为混合油脂。根据极性成分含量高低不同,判断部分样品可能为复炸油。     

棕榈油和大豆油在油条煎炸过程中品质变化研究

以不同熔点棕榈油和棕榈油―大豆油混合油为原料,以大豆油作对照,通过比较油条外观、口感,筛选出适于煎炸油条的棕榈油,再进一步通过测定油条煎炸过程中油脂样品游离脂肪酸(FFA)、过氧化值(PV)、色泽、极性值(PC)、羰基价(COV)等指标,研究两种油在油条煎炸过程中品质变化情况。研究结果表明,熔点14℃棕榈液油和大豆油都适于煎炸油条,且棕榈液油在煎炸过程中具有比大豆油更好氧化稳定性,仅是其游离脂肪酸(FFA)和色泽上升速率快于大豆油。总的来说,两种油在满足煎炸油质量要求前提下,同等数量棕榈油可比大豆油煎炸更多油条。     

气相色谱-质谱联用结合化学计量学分析棕榈油煎炸过程中化学成分的变化

为了探究棕榈油在煎炸过程中化学成分的变化与极性组分之间的相关性,采用气相色谱-质谱联用技术获取了不同煎炸时间煎炸油的化学成分信息,结合化学计量学软件进行数据筛选、主成分分析与聚类分析。结果表明：经过筛选后的数据,不同煎炸时间煎炸油在主成分得分图上区分明显;聚类分析可将煎炸不同时间的煎炸油分成三类,每类之间化学成分差异明显,其中过度煎炸组极性组分含量基本大于27%;初步鉴别出9种煎炸过程中产生的差异性化合物,这些化合物的含量变化均与极性组分含量呈明显的线性关系（R2＞0.95）。研究表明,煎炸油在煎炸过程中化学成分会发生变化,部分变化与极性组分含量呈线性相关,极性组分含量可以作为评判煎炸油劣变程度的有效依据。     

Comparison of the stability of palm olein and a palm olein/canola oil blend during deep‐fat frying of chicken nuggets and French fries

Stability of palm olein (PO) and a blend 50% palm olein/50% canola oil (POC) during deep‐fat frying at 180 °C of French fries (FF) or chicken nuggets (CN) was studied through the determination of physical and chemical parameters in the fresh and used oils. Degradation at the end of the study resulted in total polar compounds of 12–13.5% for PO and 11.5–14.5% for POC and viscosity of 65–123.3 cP for PO and 63–72.8 cP for POC. Lower peroxide values (5.33–6.32) were obtained for the blend (PO had 5.21–8.55). Food type affected colour parameters and p‐anisidine value of the oils. For CN, the lowest fat content and higher hardness were obtained when they were fried in PO. CN caused a faster deterioration in the oils, in comparison with FF, especially in POC. Gas chromatography allowed to observe differences in fatty acids composition for both used oils.     

Comparison of the Frying Performance of Olive Oil and Palm Superolein

Abstract: Deep‐fat frying is an important method of food preparation in which foods are immersed in hot oil. Repeated use of frying oils is a common practice, and in the presence of atmospheric oxygen it produces various undesirable reactions in used oils. Stable frying oils usually require low linolenic acid (LnA < 3%), increased oleic acid (OA > 40%), and decreased linoleic acid (LA < 50%). The aim of this study was to establish the behavior of palm superolein (PSO) (OA 45%; LA 12.5%; LnA 0.2%) and olive oil (OO) during repeated, discontinuous deep frying of French fries. The behavior of the oils under controlled heating conditions was also studied by maintaining all of the process variables the same as those in deep frying, except that there was no food in the oil. The PSO selected to be tested in this study may represent an alternative to OO as a frying medium. Although PSO presented a faster increase in some oxidation indices, such as free fatty acid and total polar compounds, for other indicators, PSO showed better behavior than OO (less formation of C8:0 and lower peroxide value). Practical Application: The super palm olein selected for use in this study can be suggested as a suitable replacement for olive oil for frying and cooking purposes because it provides higher oxidative stability besides the beneficial effects of olive oil on human health. In fact, several studies have indicated that palm oil exhibits similar frying performance to high‐oleic oils, with the advantages of greater availability in the market and a lower price.     

Rapid assessment of the quality of deep frying oils used by street vendors with Fourier transform infrared spectroscopy

Deterioration of deep frying oils used by street vendors is one of the major food safety concerns. Fourier transform infrared (FTIR) spectroscopy coupled with partial least squares (PLS) regression was applied for rapid evaluation of the quality of deep frying oils collected from different street vendors (n = 109) using various frying processes in Shanghai. The levels of free fatty acids (FFA), total polar compounds (TPC), and viscosity of oils were determined with conventional methods and used as reference values for developing PLS models. The FFA (0.07–1.78 mg (KOH)/g) of all tested frying oils were below the maximum allowed value, while 5.5 % of oils had TPC (3.19–54.47 %) above the maximum allowed value (27 %) based upon the related chinese standards. FTIR coupled with PLS regression resulted in less satisfying results for FFA determination (predictability for soybean oils: R² = 0.709, SEP = 0.14, RPD = 1.83), but showed great promise for rapid determination of viscosity (model predictability: R² = 0.921–0.945, SEP = 0.68–0.71, RPD = 3.54–3.98) and TPC (predictability for soybean oils: R² = 0.790–0.931, SEP = 1.89–2.94, RPD = 2.16–3.55) of frying oils from different commercial settings. Developing separated PLS models for shortening and non-shortening oils improved predictability, particularly for the analysis of TPC.     

Short-Chain Fatty Acid Formation during Thermoxidation and Frying

Formation and evolution of the short-chain fatty acids originated by oxidation and remaining bound to the parent triglyceride, specifically heptanoate and octanoate, were studied during thermoxidation of palm olein, conventional sunflower oil and high-oleic sunflower oil at 180°C, as well as in real used frying oils of unknown history collected by Food Inspection Services. Fatty acids were quantified by gas–liquid chromatography following transesterification of samples and using methyl nonanoate and methyl heptadecanoate as internal standards. Alteration level was determined through analyses of polar compounds and polar fatty acids. Results showed high correlation coefficients between short-chain fatty acids and polar compounds or polar fatty acids, thus suggesting that quantification of short-chain fatty acids is a good indication of the total alteration level in used frying oils.     

Composition, stability and acceptability of different vegetable oils used for frying peanuts

The purpose of this work was to determine the chemical stability of vegetable oils in the frying process and the consumer acceptance of fried-salted peanuts prepared in different vegetable oils. Fatty acids composition was determined in sunflower, corn, soybean, peanut and olive oils. A chemical study (free fatty acid and p-anisidine values) of these oils at frying temperature (170 °C) was developed during 96 h. Consumer test of fresh products was performed on fried-salted peanuts prepared in the different oils. Peanut oil and virgin olive oil presented oleic acid as predominant fatty acid (44.8% and 64.2%, respectively), making it more resistant to lipid oxidation at frying temperature than the other refined vegetable oils (sunflower, corn and soybean oils). Virgin olive and peanut oils showed less increment of free fatty acids and p-anisidine value than the other oils along the heating essay. In addition, fried-salted peanuts prepared with refined peanut oil showed higher consumer acceptance than those prepared with other vegetable oils such as sunflower, corn, soybean and olive oils. Peanut oil could be used to fry peanuts obtaining products with higher consumer acceptance and shelf-life, thus preventing loss of their sensory and nutritional quality.     

DEVELOPMENT OF DEEP FRYING EDIBLE VEGETABLE OILS

Refined soybean and rice-bran oils have been selected as base oils for preparation of frying oils. Hexane and acetone fractionation of nontraditional tree seed oils (NTOs) such as sal, mango, mahua and palm fats was carried out at 5–20C. Chemical and chromatographic parameteres were used to fractionate each oil (NTOs) in order to obtain olein-rich and stearin-rich fractions. The stearin fraction obtained at 10 and 15C from hexane and acetone were identical and hence mixed together. The stearin fraction obtained from all the four NTOs were incorporated at 10% level with the conventionally refined (market sample) and physically refined (laboratory sample) soybean and rice-bran oils in order to obtain frying oils. Heat stability parameters of the oils, namely free fatty acids (FFA%), peroxide value (PV), and iodine value (IV) were determined for base oils and frying oils after heating. Values for oil samples changed as follows: A (refined soybean oil and frying oils containing it) % FFA from 0.18 to 0.17–0.19, PV from 3.6 to 4.6–6.0 and IV from 125.3 to 109.2–115.8; B (refined rice-bran oil and frying oils containing it) from 0.21 to 0.19–0.23 for % FFA, 4.0 to 4.6–6.7 for PV and 99.4 to 87.6–92.8 for IV; C (physical refined soybean oil and frying oils containing it) from 0.36 to 0.33–0.36 for % FFA, 5.7 to 7.4–11.2 for PV and 126.9 to 108.9–113.2 for IV; and D (physical refined rice bran oil and frying oils containing it) from 0.79 to 0.75–0.79 for % FFA, 7.1 to 8.2–11.3 for PV and 101.4 to 88.6–93.7 for IV, respectively. However, when base oils were heated as such, their deterioration was much faster. Fatty acid composition, determined by gas chromatography, also supported the results obtained by chemical means. These frying oils showed improved heat stability compared to their base oils.     

西式快餐条件下煎炸油氧化稳定性及其不饱和脂肪酸氧化动力学研究

为了解煎炸油在煎炸过程中的氧化动力学规律,考察了5种常见煎炸油在西式快餐条件下的氧化稳定性,并对煎炸油中主要不饱和脂肪酸（亚麻酸、亚油酸及油酸）的氧化动力学进行研究。结果表明,煎炸过程中,棕榈油的茴香胺值、全氧化值的生成速率及碘值降低幅度最小,相比其他4种煎炸油具有更好的氧化稳定性。大豆油和菜籽油中亚麻酸的反应规律均同时符合0级和1级反应动力学模型;棕榈油、菜籽油、葵花籽油及稻米油中亚油酸的反应规律均同时符合0级和1级反应动力学模型,大豆油中亚油酸符合1级反应动力学模型;棕榈油、大豆油、菜籽油及葵花籽油中油酸的反应规律均同时符合0级和1级反应动力学模型;模型相应的决定系数R2在0.886~0.987之间,均大于0.85,模型拟合程度均较好。表明所构建煎炸油不饱和脂肪酸氧化动力学模型是可行的。     

Frying of potato chips in a blend of canola oil and palm olein: changes in levels of individual fatty acids and tocols

The changes occurring in the levels of nutritionally relevant oil components were assessed during repeated frying of potato chips in a blend of palm olein and canola oil (1:1 w/w). The blend suffered minimal reductions in omega‐3 and omega‐6 polyunsaturated fatty acids. There was no significant difference between the fatty acid composition of the oil extracted from the product and that of the frying medium, in all three cases. The blend also contained a significant amount of tocols which add a nutritional value to the oil. The concentration of the tocols was satisfactorily retained over the period of oil usage, in contrast to the significant loses observed in the case of the individual oils. The blend also performed well when assessed by changes in total polar compounds, free fatty acids, p‐anisidine value. When fried in used oil, the product oil content increased progressively with oil usage time. This study shows that blended frying oils can combine good stability and nutritional quality.