Physicochemical Properties and Functional Compounds of Commercial Green Tea Seed Oil

Physicochemical properties of green tea seed oil including cold test,color,flash point,gravity,refraction index,moisture content,acid value,iodine value,unsaponifiable matter and saponification value were investigated.Fatty acid composition and catechin content of the oil was determined by GC and HPLC analysis.The oil is stable at low temperature.High flash point(267.8 ± 5.1℃) showed the high thermal stability of green tea seed oil as well,which support for suitability to use as cooking oil.Specific gravity and refraction index of green tea seed oil was found as 0.913 and 1.4679,respectively.Color of the oil was measured as 99.7 ± 0.2 for lightness,1.9 ± 0.1 for greenness and 6.6 ± 0.1 for yellowness.Acid value(KOH mg/ml),iodine value,unsaponifiable matter(%) and saponification value of green tea seed oil were 0.21,104.1,0.11 and 215,respectively.Fatty acids compositions of green tea seed oil was found to be dominated by oleic acid(81.3%) and presence of minor amount of linoleic acid(4.8%),palmitic acid(4.6%),palmitoleic acid(3.3%),linolenic acid(3.2%) and stearic acid(1.0%).The presence of antioxidative compounds such as(-)-epicatechingallate(207.2 ± 0.2 g /g) and(-)-epigallocatechin gallate(99.5 ± 0.6 g/g) in the oil could enhance its shelf life during storage.

Production of Cocoa Butter Replacer by Dry Fractionation, Partial Hydrogenation, Chemical and Enzymatic Interesterification of Tea Seed Oil

Production of cocoa butter replacer (CBR) from tea seed oil through common modification methods of oils (dry fractionation, partial hydrogenation, chemical and enzymatic interesterification) was evaluated. Some physico-chemical properties (iodine, saponification, acid and peroxide values) and fatty acid composition (FAC) of modified samples were analyzed and compared with a reference cocoa butter (CB). Solid and liquid fractions for large amounts of unsaturated fatty acids (approx. 80%) and thereby lower iodine values (81 - 85 gI2/100g) than that of CB (37% and 34 gI2/100 g, respectively), are not suitable as CBR. Among all ratios of chemically and enzaymatically interesterified oil blends (20%, 25% and 30% of hydrogenated tea seed oil with 80%, 75% and 70% of tea seed oil/liquid fraction/solid fraction), the samples with ratio of 30:70 from both chemical and enzymatic interesterification had FAC and iodine value closer to that of CB. A comparision between chemically and enzymatically interesterified samples (CISs and EISs, respectively), in terms of solid fat content (SFC) indicated that although the SFC values in EIS were much lower than that of CB, but the thermal behavior of this sample is comprable to CB at 20℃- 30℃ (sharp melting point of CB).

Thermal Behavior and UV Properties of Organomodified Kaolin Oleochemically Derived from Rubber Seed Oils (<i>Hevea brasiliensis</i>) and Tea Seed Oils (<i>Camellia sinensis</i>)

Kaolin was modified using a chemical complex of hydrazine hydrate and oleochemical sodium salts derived from rubber seed oil (SRSO) and tea seed oil (STSO) respectively. Characterization of the pristine kaolin and the modified kaolins were performed using Scanning Electron Microscopy (SEM), Simultaneous Thermogravimetric/Differential Thermal Analysis (TG/DTA) and UV Spectrophotometry. TG/DTA revealed that the incorporation of the oleochemical salts enhanced thermal decomposition of kaolin into metakaolin. Ultraviolet spectrophotometric studies conducted on the modified kaolin show for the first time that the SRSO-modified kaolin and STSO-modified kaolin have a peak absorbance wavelengths of 312.72 nm and 314.26 nm respectively. This shows that the modified kaolin is a promising candidate for sunscreen applications.

New Process for Extracting Oil and Starch from Tea Seeds

A new process for extracting oil and starch from tea seed was introduced. The new process included one special link compared with all of the processes used now for tea seed oil and starch production. The link was static fermentation by which oil bodies and starch were separated naturally from tea seeds. By the process, tea seed oil and starch which were in conformity with government standards about edible oil and starch were successfully produced with 16% and 8% of production rate, respectively. The new process has many advantages, such as more simple equipments, lower production cost and whole natural products, etc..

Determination of Tea Saponin in Camellia Seed Oil with UV and HPLC Analysis

A simple procedure is described for the HPLC and UV determination of tea saponin in tea seed oil. Determinate was accomplished with UV wavelength detection 550 nm for saponification sample, and HPLC was done under conditions: C18 analytical column of TC-C18, 4. 6 × 250 mm, column temperature at room temperature, injected sample volume was 10 μL, mobile phase’s methanol, flow-rate 0.8 ml/min and detection wavelength 280 nm.

Anti-Fatigue Effect of Blended <i>Camellia oleifera Abel</i>Tea Oil and Ge-132 in Mice

Nowadays, people are busier and busier for working and living, and suffer a lot of pressure on their body or mind. Therefore, people are prone to have fatigue activity and decrease their working efficiency and happiness. It was reported that fatigue is a common symptom in the community, with up to half of the general population complaining of fatigue. More and more researchers devoted themselves to studying natural active ingredients in organism as the anti-fatigue drugs to release fatigue symptom. However, these natural ingredients were difficult to obtain from plants, animals and microorganisms by separating and purifying. In addition, some active substances have many side effects. In our study, we employed tea seed oil as main ingredients blended with bis-(carboxyethylgermanium) sesquioxide (Ge-132) to investigate the effects of anti-fatigue on mice by administrating mice with low dose, intermediate dose and high dose of tea seed oil complex for 0, 2 or 4 weeks. The specific tests of studying effects of anti-fatigue were body weight, weight-loaded force swimming, blood urea nitrogen, blood lactic acid and hepaticglycogen. And the results showed that appropriate level of tea seed oil complex could decrease the body weight and prolong the weight-loaded swimming time, and had an active effect on the bloodurea nitrogen, hepatic glycogen and blood lactic acid level mice, which significantly embodied the anti-fatigue activity of tea seed oil complex.

基于反射光谱的油茶籽油掺伪量快速测定及特征波长特性研究

为了探索紫外-可见-近红外反射光谱测定油茶籽油掺伪量的方法,按照不同掺伪比例制备了244个油茶籽油掺伪大豆油、菜籽油、花生油、玉米油的样本,以自主搭建的实验平台采集所制备样本在200~1100 nm范围内的反射光谱。将原始光谱进行Savitzky-Golay(SG)-连续小波变换(CWT)预处理后,利用Kennard-Stone(K-S)算法以2∶1的比例将样本划分成校正集和预测集。采用竞争性自适应重加权算法(CARS)、连续投影算法(SPA)、自主软收缩算法(BOSS)、迭代变量子集优化算法(IVSO)进行特征波长选择,分别建立基于支持向量机(SVM)、极限学习机(ELM)、随机森林(RF)的油茶籽油掺伪量快速预测模型,同时对特征波长的特性进行了研究。结果表明:原始光谱经过SG-CWT(L5)预处理和BOSS特征波长筛选后,建立的基于SVM的油茶籽油掺伪量快速预测模型能够鉴别掺伪量为1%及以上的油茶籽油,该模型在十折交叉验证和网格搜索法下得到最佳惩罚因子(c)和核函数(γ)分别为5.2780和0.1088,其预测决定系数(R_(P)^(2))、预测均方根误差(RMSE_P)、预测平均绝对误差(MAE_(P))分别为0.9985、0.0134、0.0102。特征波长聚集程度和陡度对模型预测结果存在一定影响。综上,建立的基于反射光谱的油茶籽油掺伪量快速预测模型预测误差小,预测效果较好。

基于气相色谱-离子迁移谱技术分析不同预处理技术对压榨山茶油风味的影响

旨在提升山茶油风味品质,采用气相色谱-离子迁移谱(GC-IMS)技术分析微波、烘烤、蒸制3种预处理技术对压榨山茶油中挥发性成分的影响,并结合正交偏最小二乘判别分析(OPLSDA)、相对气味活度值(ROAV)和聚类分析比较不同预处理压榨山茶油挥发性成分的差异。结果表明:不同预处理压榨山茶油中共鉴定出40种挥发性成分,其中醛类18种(40.02%~51.88%)、醇类9种(10.99%~19.85%)、酮类6种(19.37%~27.35%)、酯类3种(4.21%~11.44%)、吡嗪类2种(1.25%~6.50%)、烃类1种(0.19%~0.32%)和酸类1种(0.35%~2.16%),其中微波预处理压榨山茶油的挥发性物质含量最高,其次为烘烤、蒸制的;OPLS-DA建立的模型能够有效地区分不同预处理压榨山茶油,并根据变量投影重要性(VIP)值大于1筛选出了10种特征挥发性成分,分别是2-甲基丁醛D、3-甲基丁醛D、2,3-戊二酮、乙酸甲酯、2-甲基吡嗪、丙酮、3-羟基-2-丁酮、顺-2-庚烯醛、正己醇、1-丁醇,其中前5种为关键风味成分(ROAV大于1);聚类分析表明不同预处理压榨山茶油的10种特征挥发性成分存在差异,分类结果与OPLS-DA分类基本一致。综上,不同预处理技术所得压榨山茶油的风味不同,可通过OPLS-DA和聚类分析进行区分。

纳米茶籽油微囊对低脂猪肉糜制品品质影响

高脂产品低脂化符合消费者对健康的追求,是未来肉制品发展方向之一。本文以无茶籽油脂肪替代肉糜为对照组,考察了两种形式的茶籽油(Tea seed oil,TSO)及纳米微囊化茶籽油(Nano tea seed oil microcapsules,NTM)代替猪背膘对猪肉糜制品理化性质的影响,对不同脂肪替代肉糜制品保水性、蒸煮得率、水分分布、质构、微观结构、脂肪氧化水平等指标进行了研究。结果表明,添加50%、70%NTM可以改善添加TSO造成的肉糜制品保水能力的下降;NTM替代组的T_(21)弛豫时间、占比与无替代对照组组差异不显著(P>0.05),而TSO替代组不易流动水占比显著下降(P<0.05);NTM替代组,其L^(*)、b^(*)值较于无茶籽油替代组有所增强,a^(*)降低,且具有明显的脂肪氧化抑制效果,有效延长贮藏期;微观结构结果表明,NTM替代组油脂分布较TSO添加组更均匀,与蛋白质结合更紧密;质构特性结果表明,TSO替代会造成质构的劣化,而NTM可以改善劣化情况,其中添加70%NTM的肉糜弹性和粘度优于50%和70%NTM替代组。综上,添加70%NTM可以均匀分布于猪肉糜中,并与蛋白质之间形成更多的氢键,从而达到稳定低脂猪肉糜保水力,硬度,弹性等理化性质的目的。因此添加70%NTM的低脂肉糜品质最优。

不同加工方式的油茶籽油对变应性接触性皮炎的抗炎效果

为了明确不同加工方式的油茶籽油对变应性接触性皮炎(ACD)的治疗效果,并探究油茶籽油中的主要抗炎物质,分别制备低温压榨油茶籽油、热榨油茶籽原油、热榨精炼油茶籽油、土榨油茶籽油和超临界CO_(2)油茶籽油,分析不同加工方式及添加不同活性物质的油茶籽油对ACD模型小鼠耳廓肿胀的影响,并结合ELISA法、HE染色和免疫组化探究其对小鼠炎症的抑制效果。结果表明:超临界CO_(2)油茶籽油对ACD小鼠耳廓肿胀的抑制率最高,与阳性对照组相比其小鼠血清中炎症因子TNF-α、IL-1β和IL-6含量降低率超过10%,炎症细胞浸润程度明显好转,耳廓肿胀组织中NF-κB阳性表达量与阴性对照组相比无显著差异;预防性给药的抗炎效果普遍低于造模后给药;倍数添加角鲨烯和生育酚的油茶籽油对ACD小鼠耳廓肿胀的抑制率显著提高,在50%左右,且角鲨烯、生育酚处理组小鼠耳廓组织中NF-κB阳性表达量与阴性对照组无显著差异。因此,外用超临界CO_(2)萃取的油茶籽油治疗小鼠ACD效果最佳,其抗炎效果并非源于单一活性成分,与角鲨烯和生育酚等活性成分均密切相关。

湖南省主要品种油茶籽油的营养品质研究

我国长江流域及以南地区,都是油茶种植的最佳地区,以湖南省种植面积为最多。为探究湖南不同油茶的生产适应性,分析湖南不同油茶品种的差异性,研究不同品种对油茶籽油品质的影响,包括湖南省6个全国主推品种:华鑫、华金、华硕、湘林210、湘林1号和湘林27号,还有其他主要种植品种,如衡东大桃系列、湘林系列、和湘林97号。该研究对不同品种油茶籽油的脂肪酸组成与活性物质含量进行分析检测,应用聚类分析和主成分分析方法综合评价。结果显示,油茶籽油主要脂肪酸为油酸、棕榈酸和亚油酸;不饱和脂肪酸含量超过88%。油茶籽油中甾醇总含量为583.35~1623.79 mg/kg,主要组分为Δ7-豆甾烯醇和β-谷甾醇,占甾醇总量85%以上。油茶籽油中生育酚以α-生育酚为主,占总生育酚80%以上。油茶籽油的角鲨烯含量为70.49~304.32 mg/kg。油茶籽油中多酚含量为3.37~19.14 mg/kg。聚类分析将油茶籽油样品分为5类,主成分分析结果表明,Y15华硕油茶籽油综合评分最高。

基于电子鼻与HS-SPME-GC-MS技术的武夷茶区3种茶叶籽油挥发性香气成分的比较分析

以武夷茶区3种茶叶籽油为研究对象,首先采用定量描述分析法(QDA)对3种茶叶籽油的感官属性进行了分析,然后利用顶空固相微萃取气相色谱-质谱联用技术(HS-SPME-GC-MS)结合电子鼻(E-nose)对其挥发性香气成分进行了区分和比较。结果表明,不同品种茶叶籽油在多个感官属性上差异明显,E-nose可有效区分3种茶叶籽油,GC-MS在3种茶叶籽油中共检测出52种挥发性香气成分,并采用香气活力值(OAV)确定了3种茶叶籽油的关键香气物质,3种茶叶籽油香气成分和关键香气物质的组成、含量各不相同。研究结果可为不同品种茶叶籽油的品种鉴别提供一定的理论依据。

油茶籽壳多糖超声辅助提取工艺优化及抗氧化活性分析

旨在为开发利用油茶籽壳多糖提供基础,以油茶籽壳为原料,通过单因素试验结合响应面法对超声辅助提取多糖的工艺条件进行优化,并对超声辅助提取油茶籽壳多糖(CFP-U)的理化性质(分子质量、单糖组成、傅里叶变换红外光谱、紫外光谱、微观结构)和体外抗氧化活性(羟自由基、超氧阴离子自由基和ABTS+自由基清除率)进行了测定。结果表明:CFP-U的最优超声辅助提取工艺条件为超声时间20min、超声功率650W、液料比40∶1,在此条件下油茶籽壳多糖的得率为(3.28±0.06)%;高效凝胶渗透色谱分析表明,CFP-U的纯度较高,分子质量为91.6kDa;高效液相色谱分析表明,CFP-U的单糖由平均摩尔比为0.05∶0.14∶0.05∶1.00∶0.05∶0.30∶0.35∶0.41的甘露糖、鼠李糖、葡萄糖醛酸、半乳糖醛酸、葡萄糖、半乳糖、木糖和岩藻糖构成;红外光谱表明,CFP-U存在α-糖苷键、β-糖苷键和吡喃糖环;紫外全波长扫描表明,CFP-U中基本不含蛋白质;扫描电子显微镜观察发现,CFP-U呈不规则形态,为片状结构,表面光滑;体外抗氧化活性测定表明CFP-U能有效清除羟自由基、超氧阴离子自由基和ABTS+自由基,并在一定浓度范围内呈剂量效应关系,且抗氧化活性优于传统热水法提取的油茶籽壳多糖。综上,采用超声辅助法可以有效提取油茶籽壳多糖,且油茶籽壳多糖具有较强的体外抗氧化能力。

黑茶籽油成分分析及其对于H_(2)O_(2)诱导HFF-1细胞氧化损伤的保护作用

对茶籽油的活性成分及其抗氧化活性进行研究。对不同产地的茶籽油的脂肪酸、α-生育酚含量进行了测定,发现黑茶籽油的三种不饱和脂肪酸(油酸、亚油酸、亚麻酸)总含量(83.72%),α-生育酚(1.33 mg/g)相比于其他茶籽油(绿茶籽油、普洱茶籽油)、山茶籽油(有机山茶油)和油茶籽油(有机油茶籽油、古树茶籽油)含量更高。在此基础上,测试了黑茶籽油对于DPPH自由基、ABTS自由基、羟基自由基的清除能力。结果表明黑茶籽油在0.15 g/mL质量浓度时,对于DPPH、ABTS自由基的清除率分别93.08%和94.85%;在0.3 g/mL质量浓度下,对羟基自由基的清除率为91.25%,相较于其他茶籽油表现出更好的自由基清除效果。此外,还测定了黑茶籽油对于双氧水诱导的人成纤维细胞(HFF-1)氧化应激以及衰老的抑制作用。细胞增殖实验、活性氧自由基测定实验和β-半乳糖苷酶染色实验的结果表明,黑茶籽油在10~50μg/mL质量浓度下对双氧水诱导的HFF-1细胞氧化应激具有一定的保护作用,表现出抗氧化、抗衰老的活性。

高油酸葵花籽油与油茶籽油的抗炎、抗刺激及抗湿疹功效研究

旨在为油茶籽油与高油酸葵花籽油在化妆品中的应用提供数据支撑,通过体外3D表皮模型EpiKutis构建体外急性损伤及类湿疹表皮模型,以低温压榨高油酸葵花籽油和油茶籽油处理模型,检测其组织活力、炎症因子释放量、组织形态结构和胸腺基质淋巴细胞生成素(TSLP)含量,评价高油酸葵花籽油和油茶籽油的抗炎、抗刺激、抗湿疹功效。结果表明:高油酸葵花籽油与油茶籽油对模型组织活力均无显著影响;油茶籽油能显著降低模型炎症因子释放量,而高油酸葵花籽油不能显著降低模型炎症因子释放量;高油酸葵花籽油与油茶籽油对模型组织形态结构均有一定改善;高油酸葵花籽油与油茶籽油均能极显著降低模型TSLP含量。综上,油茶籽油与高油酸葵花籽油对皮肤刺激性炎症均具有一定的抑制和缓解作用,具有显著的抗湿疹功效;同时,油茶籽油对皮肤刺激性损伤具有一定的抑制和缓解作用。

不同环境因子下茶籽油在储藏过程中的品质变化

该研究评估茶籽油在不同温度和气体环境下的储藏稳定性,分析其质量指标变化情况。结果显示,高温条件下茶籽油的甘油三酯结构稳定性下降,氧化程度加深。然而,经过CO_(2)和N_(2)气调处理后的茶籽油的酸价和过氧化值显著降低,证明气调处理可以有效抑制甘油三酯结构的破坏。此外,在高温条件下,茶籽油中的生育酚、油酸和亚油酸损失严重,而气调处理可以保护上述活性物质不被破坏。因此,低温和无氧气调处理将是茶籽油质量控制的重要手段。

湖南无性系油茶品种在剑河县的试种结果分析

该次试验在贵州省黔东南州中部的剑河县引种湖南无性系油茶品种,引进4个湖南无性系油茶品种,分别是湘林1号、湘林4号、湘林27和湘林210,研究4个无性系油茶品种产量、树高和冠幅、成活率和保存率以及无性系油茶品种果实质量。结果证明,不同无性系油茶品种生长指标存在差异,湘林1号和湘林210单株产果量较高,鲜果产量高于其他油茶品种,差异有统计学意义(P<0.05);树高整体排序是湘林1号>湘林210>湘林4号>湘林27;湘林1号成活率和保存率分别是95%和90%,湘林210的成活率和保存率分别是96%和90%,均高于其他油茶品种;4个无性系油茶品种果实质量均比较可观,湘林1号和湘林210的横径、纵径指标无明显差异(P>0.05),但高于其他品种(P<0.05),湘林1号的鲜果出籽率、干籽含油率高于其他品种(P<0.05),湘林210的鲜果含油率高于其他品种(P<0.05)。由此认为,4个湖南无性系油茶品种在剑河县试种结果良好,均可适应剑河县种植环境,其中湘林1号和湘林210的种植优势更明显,可作为剑河县一带的主栽油茶品种。

基于电子鼻气味指纹图谱快速鉴别茶籽油

以不同产地、不同类型、不同工艺和不同质量的茶籽油为研究对象,通过电子鼻技术获取茶籽油的风味信息,结合Loading负载分析、主成分分析(PCA)、线性判别分析(LDA)等对电子鼻传感器数据进行解读。通过欧氏距离(ED)、马氏距离(MD)和判别函数法(DFA)对未知样品进行鉴别,以期建立不同茶籽油的快速、准确鉴别方法。结果表明:加工工艺极大地影响了茶籽油的气味差异,电子鼻响应值雷达图及Loading负载分析均表明W1S、W1W、W2S、W2W传感器对茶籽油样品具有较好的响应值,通过ED、MD、DFA可以识别不同类型和不同质量的茶籽油。基于PCA的LDA可以有效鉴别不同类型的茶籽油,模型准确性高,其确定性大于99%。电子鼻技术结合化学计量学可以快速、有效鉴别不同的茶籽油并为茶籽油掺伪的快速鉴别提供借鉴。

油茶鲜果预处理方式对低温压榨油茶籽油品质的影响

为更多地保留活性成分,提高油茶籽油品质,研究了油茶鲜果6种不同预处理方式(剥壳-摊晒、直接摊晒、堆沤-摊晒、剥壳-烘干、直接烘干、堆沤-烘干)对油茶籽主要成分以及低温压榨油茶籽油中3种理化指标(酸值、过氧化值、多环芳烃)和4种微量活性成分(维生素E、维生素K_(1)、角鲨烯、多酚)的影响。结果表明:油茶鲜果预处理方式对油茶籽主要成分(脂肪、蛋白质、淀粉)影响不大;6种不同预处理方式对低温压榨油茶籽油的理化指标和微量活性成分均有一定的影响,其中剥壳-烘干处理油茶鲜果在油茶籽油的酸值、多环芳烃、维生素E、角鲨烯指标上较其他预处理方式存在一定优势。综上,采用剥壳-烘干对油茶鲜果进行预处理,可在一定程度上提高油茶籽油品质。

红外与微波预处理油茶籽对其原油DPPH自由基清除能力的影响

为了研究油茶籽油氧化稳定性机制,了解不同预处理方式对油茶籽油抗氧化能力的影响,以DPPH自由基清除能力为指标,对油茶籽分别经红外与微波预处理后得到的油茶籽原油及其极性组分和非极性组分抗氧化能力进行分析。结果表明:油茶籽分别经红外和微波预处理后,得到的油茶籽原油及其极性、非极性组分DPPH自由基清除能力变化显著;红外预处理的油茶籽所制油茶籽原油及其非极性组分的DPPH自由基清除能力高于相应微波预处理,其最大值分别高3.53μg/g和6.47μg/g;微波预处理的油茶籽所制油茶籽原油中极性组分的DPPH自由基清除能力最大值比相应红外预处理的高38.77μg/g。油茶籽原油对DPPH自由基的清除能力主要来自其极性组分,非极性组分的DPPH自由基清除能力弱于极性组分。