28份国产特级初榨橄榄油中多酚含量及其变化规律北大核心CSCD

为了对我国油橄榄产业提供基础数据支持,采用国际油橄榄理事会推荐的HPLC法检测特级初榨橄榄油中的多酚含量,分析了我国不同产地的28份市售食用特级初榨橄榄油样品的多酚含量,并对不同生产年度和不同产地单果级特级初榨橄榄油中多酚含量变化规律进行了分析。结果表明:市售国产特级初榨橄榄油中均含有较为丰富的多酚类化合物,多酚含量范围为(63.885±2.345)mg/kg~(307.325±6.865)mg/kg;特级初榨橄榄油中多酚含量受贮存时间的影响较大,同时不同产地中适合生产高多酚含量特级初榨橄榄油的品种具有差异。不同特级初榨橄榄油样品之间多酚含量波动较大,需要通过多种方法来防止油脂中多酚类化合物的降解,以保证油品的质量,并因地制宜对油橄榄品种进行优化筛选。     

甘肃陇南单品种初榨橄榄油化学组分及与感官属性的关系研究

研究采用热脱附-气相色谱-质谱(TD-GC-MS)对甘肃陇南生产的6个单品种初榨橄榄油的挥发性组分及多酚含量进行测定,并对6个单品种初榨橄榄油挥发性组分及多酚含量与其感官属性的关系进行分析。结果表明:鉴定出22种挥发性组分;甘肃陇南各单品种初榨橄榄油的活体香气主要呈现果味,C6醛醇类物质对初榨橄榄油果味有积极影响;6个单品种初榨橄榄油中多酚含量(401.77~780.34 mg/kg)较高,多酚类物质对橄榄油苦味的影响较大;辛辣味的来源则有待进一步研究。     

凉山州4个引进品种初榨橄榄油的品质分析

对凉山州4个引进品种(佛奥、奥托卡、豆果、城固32)初榨橄榄油的酸值、过氧化值、α-生育酚含量、豆甾醇含量和β-谷甾醇含量以及脂肪酸组成进行测定,并采用主成分分析综合评价了凉山州4个引进品种初榨橄榄油的品质。结果表明:4个品种初榨橄榄油的酸值和过氧化值均较低;城固32的α-生育酚含量和β-谷甾醇含量最高,分别为164.48 mg/kg和1 149.59 mg/kg,除奥托卡的豆甾醇含量较低外,其余3个品种差异较小;4个品种初榨橄榄油的脂肪酸组成差异较小,不饱和脂肪酸含量为77.34%~82.17%,饱和脂肪酸含量为17.09%~18.87%。综合评价表明4个品种初榨橄榄油中奥托卡的品质最好。     

甘肃武都区5个主栽品种初榨橄榄油的品质分析

以甘肃武都区主栽的5个品种初榨橄榄油(佛奥、莱星、鄂植8、科拉蒂、皮削利)为研究对象,分析了其外观品质、风味特征、酸值、过氧化值、生物活性成分含量和脂肪酸组成。结果表明:5种初榨橄榄油的色泽和风味有一定关系,色泽较深的科拉蒂口味较重,佛奥、皮削利次之,莱星和鄂植8的色泽较浅、口味也较淡;5种初榨橄榄油的酸值(KOH)和过氧化值分别在0.21~0.49 mg/g和4.82~9.65 mmol/kg之间,均符合国家标准要求;5个品种初榨橄榄油中总黄酮和总多酚的含量分别在459.94~708.08μg/g和108.66~257.22μg/g之间,其中科拉蒂的均最高;主要脂肪酸组成及含量为棕榈酸(C16∶0)7.04%~14.31%、棕榈油酸(C16∶1)0.14%~1.27%、硬脂酸(C18∶0)0.98%~1.82%、油酸(C18∶1)74.73%~82.91%、亚油酸(C18∶2)6.77%~9.27%、亚麻酸(C18∶3)0.16%~0.35%,其中科拉蒂的油酸含量最高;5个品种初榨橄榄油的角鲨烯含量在0.07%~0.27%之间。综合分析表明,5个品种初榨橄榄油均具有优良品质,其中科拉蒂的综合品质最佳。     

陇南3个品种油橄榄果实品质比较分析

以陇南市经济林研究院大堡油橄榄品种示范园的3个栽培品种‘阿斯’‘奇迹’‘莱星’果实为原料,观察不同品种不同采摘时间果皮颜色变化,测定果实含油率、多酚含量、黄酮含量及橄榄油脂肪酸组成和含量的变化趋势。结果表明:在生长发育过程中,果皮转色最早的品种为‘莱星’,其次为‘阿斯’,‘奇迹’最晚;‘奇迹’果实含油率总体呈上升趋势,‘阿斯’‘莱星’果实含油率总体呈先上升后下降趋势,含油率最高的品种为‘莱星’,其次为‘奇迹’,‘阿斯’最低;3个品种果实的多酚和黄酮含量呈波浪式的变化;脂肪酸主要成分油酸、棕榈酸、亚油酸、硬脂酸含量在不同品种间差异较大,MUFA/PUFA、C18∶1/C18∶2也不同,橄榄油品质稳定性不同,11月10日至11月30日3个品种MUFA/PUFA、C18∶1/C18∶2较高,其中‘莱星’的MUFA/PUFA、C18∶1/C18∶2高于其他2个品种。综合分析,以含油率、多酚含量为指标确定最佳采摘时间,‘阿斯’果实最佳采摘时间在次年3月10日至3月20日,‘奇迹’果实最佳采摘时间在次年2月10日至2月20日,‘莱星’果实最佳采摘时间在次年1月30日至2月20日。3个品种中‘莱星’果实品质最佳,‘奇迹’次之,‘阿斯’果实品质最差。     

陇南两种单品种初榨橄榄油的化学性质和脂肪酸组成随成熟度的变化

分析了陇南2个品种初榨橄榄油的化学性质和脂肪酸组成随成熟度增加的变化规律。结果表明：随着成熟度的增加2个品种的鲜果出油率增加且存在显著性差异。初榨橄榄油风味成分中氮氧化合物、含硫以及烷烃类化合物变化幅度较大,通过电子鼻可以区分不同品种不同成熟度的橄榄油。恩帕特雷和科拉蒂的k232、270值最高分别为1.85和1.91、0.18和0.14,多酚、黄酮含量变化范围分别为2.39～4.53和7.47～10.39、0.07～0.40和0.75～2.84 mg/g。氧化稳定时间在第6（6.28 h）和第5(16.71 h)成熟度为最高。酸价的变化范围分别为0.37～1.02和0.19～0.38 mg/g,过氧化值的变化范围分别为2.92～8.32和2.38～5.19 mmol /kg,油酸含量分别为72.36%～77.76%和59.23%～65.73%,亚油酸含量分别为7.70%～11.81%和9.74%～15.86%,SFA含量分别为11.81%～13.15%和14.25%～20.99%,PUFA含量分别为8.34%～12.36%和10.92%～16.84%,MUFA含量为72.69%～78.50%和62.36%～68.20 %。同一品种的MUFA/PUFA、C18:1/C18:2和MUFA含量变化趋势一致,与PUFA呈相反的变化趋势,2个品种之间各种脂肪酸含量差异明显,上述测定指标完全符合GB 23347—2009中特级初榨橄榄油的标准。科拉蒂的出油率、多酚、黄酮、油酸含量和氧化稳定时间明显大于恩帕特雷,而酸价、过氧化值低于后者。综合考虑认为科拉蒂的初榨橄榄油品质优于恩帕特雷,恩帕特雷和科拉蒂分别在第6和第5成熟度的初榨橄榄油品质最好。     

初榨橄榄油风味化合物研究进展

阐述了初榨橄榄油风味的主要来源途径即脂氧合酶途径,对影响初榨橄榄油风味特征的若干因素如品种和地理环境,油橄榄果实成熟度,加工工艺,储藏条件等因素进行了讨论和分析.介绍了初榨橄榄油中挥发性化合物的分析检测方法,并且展望了橄榄油风味化合物研究的应用和发展前景.     

初榨橄榄油中的微生物群及其对橄榄油品质的影响

初榨橄榄油生产环境相对开放,榨取橄榄油的原料、环境及设备中的微生物群都可能进入初榨橄榄油,对油脂品质产生影响。为全面认识初榨橄榄油中微生物群以及从微生物层面控制初榨橄榄油品质,从食品微生物学研究的视角,综述了初榨橄榄油中酵母菌、细菌和霉菌等主要微生物群,分析了油橄榄枝叶、果实和初榨橄榄油中的微生物群对油脂品质的影响,介绍了采后储存的油橄榄果实及储存期的初榨橄榄油品质与微生物群之间的关系,探讨了对有害微生物群影响初榨橄榄油品质的防控措施。研究认为酵母菌对初榨橄榄油储存期间的品质起主要的影响作用。通过避免采摘和储存过程中油橄榄果实的损伤,保证加工过程中清洗用水和设备的洁净,控制储存环境温度、光照和氧含量等措施,可以有效防控有害微生物对橄榄油品质的负面影响。     

初榨橄榄油中多酚类化合物含量随油橄榄果 生长发育的累积变化

旨在为甘肃陇南橄榄油的质量评价和油橄榄鲜果采收时间提供指导,探究了不同品种初榨橄榄油（VOO）中多酚类化合物（PPs）随油橄榄果生长发育的累积变化。以甘肃陇南不同成熟度的8个品种油橄榄鲜果为原料,采用压榨法获得VOO,利用反相高效液相色谱法同时测定VOO中的9种PPs含量。结果表明：VOO中总多酚的含量主要由酪醇和橄榄苦苷决定,橄榄苦苷是含量最高的PPs,且其含量随油橄榄果成熟度指数（MI）变化最明显;VOO中木犀草苷含量均较低,阿魏酸和芹菜素仅在个别品种中检测到,芦丁在所测油品中均未检测到;‘阿斯’‘鄂植8号’‘中山24号’和‘佛奥’4个品种VOO的PPs评估数据表现良好,分别在MI为0～1.0、2.0～4.0、0～2.0和5.0～7.0表现最佳,建议这4个品种油橄榄鲜果的采收时间分别为9月下旬、11月上旬、9月下旬至10月上旬以及11月下旬,而‘切姆拉尔’VOO在PPs种类和总含量等评估数据中表现不佳。综上,可以依据不同MI的油橄榄鲜果制备的VOO中多酚含量,尤其是酪醇和橄榄苦苷含量,确定不同品种油橄榄鲜果的采收时间,并进行VOO的品质评价。     

国内初榨橄榄油品质特性研究

以国内种植的油橄榄为原料,研究了油橄榄品种、成熟度以及堆放时间对初榨橄榄油脂肪酸组成、酸值、过氧化值及风味的影响。结果表明：不同品种油橄榄的初榨橄榄油中油酸和亚油酸含量差异较大,油酸含量范围65.85%~80.08%,亚油酸含量范围2.61%~17.18%;初榨橄榄油的酸值随油橄榄成熟度的升高而降低,其中鄂植8号酸值（KOH）从0.35 mg/g下降到0.26 mg/g;紫果的初榨橄榄油过氧化值低于青红果和红果;油橄榄堆放时间延长会使初榨橄榄油的过氧化值略有增加,而酸值的增加程度因品种而异。不同形式的油橄榄初榨橄榄油在风味上均能很好地区分。     

Has the use of talc an effect on yield and extra virgin olive oil quality?

The maximization of both extraction yield and extra virgin olive oil quality during olive processing are the main objectives of the olive oil industry. As regards extraction yield, it can be improved by both acting on time/temperature of malaxation and using physical coadjuvants. It is well known that, generally, increasing temperature of malaxation gives an increase in oil extraction yield due to a reduction in oily phase viscosity; however, high malaxation temperature can compromise the nutritional and health values of extra virgin olive oil, leading to undesirable effects such as accelerated oxidative process and loss of volatile compounds responsible for oil flavor and fragrance. The addition of physical coadjuvants in olive oil processing during the malaxation phase, not excluded by EC regulations owing to its exclusively physical action, is well known to promote the breakdown of oil/water emulsions and consequently make oil extraction easier, thus increasing the yield. Among physical coadjuvants, micronized natural talc is used for olive oil processing above all for Spanish and Italian olive cultivars. The quality of extra virgin olive oil depends on numerous variables such as olive cultivar, ripeness degree and quality, machines utilized for processing, oil storage conditions, etc. However, the coadjuvants utilized in olive processing can also influence virgin olive oil characteristics. The literature highlights an increase in oil yield by micronized natural talc addition during olive processing, whereas no clear trend was observed as regards the chemical, nutritional and sensory characteristics of extra virgin olive oil. Although an increase in oil stability was reported, no effect of talc was found on the evolution of virgin olive oil quality indices during storage. © 2016 Society of Chemical Industry     

Influence of the malaxation time and olive ripening stage on oil quality and phenolic compounds of virgin olive oils

The main objective of this study was to evaluate the influence of the malaxation time (Mt) and ripening stage on oil quality and phenolic compounds of Hojiblanca and Picual virgin olive oils. In both varieties of oil, phenolic content and oxidative stability decreased as ripening progressed. The total level of tocopherols diminished by up to 40% as fruit ripened. The compositions of palmitic, stearic, lignoceric, oleic, linoleic and linolenic acids were significantly influenced by the ripening process. The present work shows that an increased Mt promoted the increase of free acidity (up to 13.3%) and tocopherols (up to 11.6%) and negatively affected the oxidative stability and the concentration of phenols. Further research is required to determine ripening stages and malaxation conditions for all olive oil varieties to achieve a satisfactory balance between the improvement of both oil yield and oil quality and composition.     

Influence of olive paste preparation conditions on virgin olive oil triterpenic compounds at laboratory-scale

The influence of olive paste preparation conditions on the triterpenic content of virgin olive oils from Arbequina and Picual cultivars was investigated. For this purpose, three sieve diameters of the hammer mill (4, 5, and 6 mm), two malaxation temperatures (20 and 30 °C), and two malaxation times (20 and 40 min) were tested. Results obtained showed that for Arbequina oils, a finer crushing level resulted in higher maslinic acid and erythrodiol content. Increasing malaxing temperature and time lead to a rise in both oleanolic and maslinic acid concentration, whereas erythrodiol content increased only for the longer malaxation time. For Picual oils, higher concentrations of oleanolic acid, maslinic acid, and uvaol were obtained by prolonging the paste malaxation time. A finer crushing level resulted also in an increase of maslinic acid content. These findings suggest that virgin olive oil triterpenic composition can be improved by regulating olive paste preparation conditions.     

Using Lipid Profiles for the Characterization of Turkish Monocultivar Olive Oils Produced by Different Systems

The aim of this study was to characterize the biochemical profiles of the virgin olive oils produced in various districts of Aegean and South East Anatolia regions of Turkey over two growing seasons (2001–2002). The olive oils were extracted by classic hydraulic pressing, three phase continuous system, Abencor oil method at laboratory scale, and foot oil process from monocultivar Turkish olives, including Ayvalik, Memecik, Nizip Yaglik, Gemlik, Domat, and Uslu. Total phenolics, ortho-diphenols, oxidative stability, and total chlorophylls of the oils differed by location. The cis-trans fatty acids, triacylglycerols, and the actual versus theoretical equivalent carbon number of 42 (ECN 42) triglycerol content (ΔECN42) were within national and international averages. Oil samples from the three phase continuous system had higher total phenolic contents than those of the hydraulic pressure system. Turkish monocultivar virgin olive oil samples were classified by biochemical profiles using the principal component and hierarchical cluster analyses multivariate statistical methods. Clustering analysis defined groups according to growing location. Triacylglycerols and fatty acid profiles can be used for identification of monocultivar olive oils with regard to authenticity and classification.     

The influence of ripening and crop year on quality indices,polyphenols, terpenic acids,squalene, fatty acid profile,and sterols in virgin olive oil (Koroneiki cv.) produced by organic versus non‐organic cultivation method

The chemical composition of virgin olive oil is determined by numerous factors. The aim of this study was to evaluate the influence of the olive ripening stage, and crop year on the quality indices of Koroneiki cv. virgin olive oil of organic vs non‐organic cultivation. Drupes of organic and of non‐organic cultivation were sampled at four successive ripening periods in crop years 2000 and 2004. Quality indices, total and simple polyphenols, terpenic acids, squalene, fatty acid profile, and sterols were measured. Statistical analysis demonstrated that peroxide value differed according to cultivation method and according to crop year. Organic Koroneiki cv. olive oils exhibited higher total phenols content. Total phenols differed mainly according to crop year and maturation phase, but also according to cultivation method. Total unsaturated and saturated fatty acids differed according to cultivation method, crop year and maturation. Oleic and palmitoleic acids varied according to cultivation method and according to maturation process. Cholesterol, campesterol and stigmasterol differed according to maturity, while β‐sitosterol differed according to crop year. Overall, olive oil from organic cultivation was of superior quality compared to non‐organic, while composition of olive oils was greatly variable during maturation, whereas it was also affected by the crop year.     

Changes in volatile compounds and oil quality with malaxation time of Tunisian cultivars of Olea europea

While there has been considerable work examining the effect of malaxation time on different characteristics of olive oils, there have been few that deal with all the major aspects. Here, the influence of malaxation time was evaluated using major local Tunisian (cv. Chemlali and Chetoui) cultivars. Standard characteristics were measured as well as detailed analyses of volatile compounds were conducted. Headspace solid‐phase microextraction (HS‐SPME) was applied to the analysis of volatile compounds of virgin olive oils from Chemlali and Chetoui varieties with differing malaxation time. Twenty‐seven compounds were characterised by GC‐FID and GC–MS. Compounds belonging mainly to alcohols, esters, aldehydes, ketones and hydrocarbons chemical classes characterized the volatile profile. Significant differences in the proportion of volatiles from oils of different malaxation time were detected. The results suggest that besides genetic factors, malaxation time influences volatile formation. The main variables that were affected by malaxation time were the total amount of phenols and composition of the volatile compounds. At malaxation time of 30 min, Chemlali and Chetoui olive oils presented the highest total phenol content (244.19 and 877.63 mg kg^?1, respectively), while the lowest content was observed at 60 min from regardless of cultivars. In turn, this influenced the oxidative stability and peroxide value. It was also clear that the cultivars behaved differently and this prevented general conclusions being made for all of the quality characteristics.     

Changes during storage of quality parameters and in vitro antioxidant activity of extra virgin monovarietal oils obtained with two extraction technologies

Extraction technology has a great effect on quality of olive oils. This paper studied 18 months of storage of two Sardinian extra virgin monovarietal oils obtained with a traditional and with a low oxidative stress technology. Oil samples were subjected to the following chemical analyses: acidity, peroxide value, ultraviolet light absorption K₂₃₂ and K₂₇₀, carotenoids, chlorophylls, tocopherols and total polyphenols. The antioxidant capacity of oils, polyphenol extract and oil extract (remaining after polyphenol extraction) was also determined as radical scavenging activity. The results show that both extraction technologies resulted in minor changes in legal and quality indices during storage, due surely to the high quality of the oils as well as to the very good storage conditions used. Oils obtained with the low oxidative stress technology showed lower peroxide value and acidity and resulted in up to 103% higher total polyphenol content as well as increased radical-scavenging activity, with respect to oils obtained with the traditional technology.     

Influence of malaxation conditions on characteristic qualities of olive oil

While there has been considerable work examining the effect of extraction methods and malaxation conditions on different characteristics of olive oils, there have been few that deal with all the major aspects. Here we have evaluated three different extraction techniques and the influence of time and temperature during malaxation using a major Italian (cv. Coratina) and the main Cretan (cv. Koroneiki) cultivars. Standard characteristics were measured as well as detailed analyses of alcohols, steroids and phenolics were conducted. Quality was also assessed by Panel tests. The main variables were the total amount and composition of the phenolics. In turn, this influenced the oxidative stability and sensory quality. It was also clear that the cultivars behaved differently and this prevented general conclusions being made for all of the quality characteristics.     

Modelling of virgin olive oil extraction using response surface methodology

Malaxation of the paste is the most important step for virgin olive oil extraction because it affects both oil yield and quality. In this work the influence of temperature and mixing time on oil yield, quality parameters and oil composition in photosynthetic pigments and total polyphenols is assessed by using Response Surface Methodology. Seven Picual‐variety olive samples from two consecutive seasons, with different maturity index, were used. Results show that temperature and malaxation time exert a positive influence in olive yield, with optimal values ranging from 20.1 to 32.2 °C and from 73.3 to 90 min. Oil quality decreased slightly as temperature and time of malaxation were increased. Top quality oils were obtained below 30 °C and shorter mixing time. The oil content in photosynthetic pigments increased with temperature and mixing time, while total polyphenols increased with temperature but decreased with mixing time.