内部萃取电喷雾电离质谱直接分析脐橙

在正离子模式下, 分别对不同品质脐橙的内果皮和果肉进行了内部萃取电喷雾电离质谱(iEESI-MS)分析, 在未经过预处理的前提下直接获得了72个脐橙内果皮样品和72个脐橙果肉样品在m/z 50~2000范围内的化学指纹谱图, 鉴定了脐橙组织中氨基酸、 糖类和生物碱等重要化学成分. iEESI-MS化学指纹谱图表明, 脐橙的果肉与内果皮组织中脯氨酸和糖类等成分的组成具有一定的相似性, 而其它化学组分(如水苏碱、 辛弗林等)在2类组织中的含量差异明显. 主成分分析(PCA)结果表明, 样品的iEESI-MS指纹谱图与该脐橙的品质相关, 与样品的实际品质差异一致. 因此, iEESI-MS可直接获得不同品质脐橙差异性化学成分的信息, 从分子水平上判断脐橙品质的优劣.     

芦笋中化学成分的内部萃取电喷雾电离质谱检测

选择芦笋(Asparagus Officinalis L)新鲜茎块和两种干燥茎块为代表性植物组织样品,建立了一种直接检测芦笋中多种化学成分的内部萃取电喷雾电离质谱(iEESI-MS)分析方法。在正离子检测模式下,选择甲醇(CH₃OH)作萃取溶剂,在无需样品预处理的条件下对芦笋组织样品进行直接质谱分析,获得了组织样品在m/z 50~1000范围内的化学指纹谱图,并通过目标离子的碰撞诱导解离(CID)实验,鉴定了对药物和自然产品研发具有重要意义的糖类、氨基酸、生物碱以及芦丁等多种代表性的营养成分。 本方法具有无需样品预处理、样品耗量少、操作简便、分析速度快(单个样品的分析时间少于1 min)等优点,为食源性植物组织样品的快速分析提供了一种质谱分析新方法。     

电喷雾内部萃取电离质谱直接分析蒜瓣组织的研究

固态复杂基体样品的直接电离一般仅发生在样品浅层表面,对固体内部深层物质的质谱分析往往需将样品破碎后才能进行。本研究以蒜瓣样品为例,无需样品预处理,带电的甲醇溶液以2μL/min持续流经蒜瓣深层组织,内部组织中的化学物质选择性地溶解到流动液中,并在蒜瓣组织的尖端形成电喷雾,产生相应气态离子供后续质谱分析。在正离子检测模式下,实验记录了两种蒜瓣样品(共24个)、经不同方式贮存加工后的同种蒜瓣样品(共36个)在m/z 50~2000范围内的化学指纹谱图,并将指纹谱图数据进行主成分分析( PCA),获得了令人满意的分组结果。研究表明,电喷雾内部萃取电离质谱( iEESI-MS)可以直接获取蒜瓣内部组织生物化学信息,鉴定蒜瓣组织中重要的化学成分(如蒜氨酸、蒜素、精氨酸、多糖等),快速识别蒜瓣组织中代谢组分的变化。本方法无需样品预处理、操作简单、分析速度快(单个样品分析时间小于2 min),最大程度避免了生物组织分析过程中活性物质受环境作用(如酸解、空气氧化等)的降解,有望为生物组织样品的代谢组学研究提供一种直接、快速的质谱分析方法。     

直接获取生物组织内部磷脂类物质的质谱分析方法

选择肺癌组织等多种生物组织为代表性样品,在正离子检测模式下,以磷脂类物质丰度、信号强度高为目标,考察了21种不同组成的CH3OH/H2O溶剂体系,获得了最佳溶剂(CH3OH-H2O,30∶70, V/V),建立了一种无需破坏、研磨即可获取组织内部样品中磷脂类物质信号的内部萃取电喷雾电离质谱( iEESI-MS)方法,并成功应用于肺癌、食管癌、猪肉、牛肉、猪肺、猪心等不同生物组织样品中磷脂类物质的直接质谱分析。本方法无需样品预处理,可通过选择合适的萃取溶剂来提高方法的分析灵敏度和选择性,单个样品的平均分析时间少于1 min,样品耗量少,有望为生物组织样品中磷脂类物质的研究提供一种质谱学新方法。     

低温冷冻液液萃取/GC-MS结合保留指数分析香蕉中的挥发性成分

建立了低温冷冻液液萃取(LTF-LLE)/GC-MS结合保留指数对香蕉果肉及果皮中挥发性成分进行分析的方法,采用低温冷冻液液萃取对香蕉样品中的挥发性成分进行提取。分别鉴定出香蕉果肉及果皮中含有39种和32种挥发性成分,其主要成分为酯类物质。果肉果皮所含的挥发性成分在种类及相对含量上有一定差异,果肉中含量较高的组分为丙酸乙酯(11.88%)、乙酸异戊酯(9.45%)、棕榈酸(8.71%)、丁酸异戊酯(7.79%)、乙酸仲戊酯(5.29%),果皮中含量较高的组分为丁酸异戊酯(22.85%)、棕榈酸(15.91%)、硬脂酸(6.86%)、4-烯丙基-2,6-二甲氧基苯酚(6.83%)、亚麻酸(6.34%),果肉果皮所共有的成分有异戊醇、乙酸异丁酯、丁酸、异戊酸、乙酸仲戊酯等19种物质。     

电喷雾萃取电离质谱法分析莲子中的生物碱

在无需样品预处理的前提下,直接对莲子醇提液进行电喷雾萃取电离质谱(EESI-MS)检测,并对其中可能存在的生物碱母离子进行串联质谱分析确认,通过主成分分析(PCA)对不同贮藏时间莲子的醇提液进行区分.研究结果表明,电离电压、离子传输管温度和样品进样流速的最佳条件分别为3.5 kV,250℃和5μL/min;串联质谱结果表明莲子醇提液中存在莲心碱、甲基莲心碱、莲心季铵碱、荷叶碱及O-去甲基荷叶碱等生物碱.PCA可将不同贮藏时间的莲子明显区分在二维平面的不同区域.本方法无需样品预处理,可用于复杂基体样品中生物碱的快速鉴定,与化学计量学结合可对不同新陈度的莲子样品进行有效区分.     

人工神经网络用于直接化学电离质谱分析食用油品质的研究

无需任何样品预处理,采用表面解吸常压化学电离质谱(DAPCI-MS)技术直接对涂覆在载玻片表面的食用油样品和地沟油样品进行检测,快速获得了不同油类样品的质谱信号;并运用改进的反向传输(BP)人工神经网络对DAPCI-MS所得到的油类样品质谱数据进行有监督的分类识别,建立多分组预测模型。结果表明:DAPCI-MS能够承受食用油中复杂基体的影响,可对油类样品进行直接快速质谱分析;误差反转(BP)神经网络具有良好的分类判别能力,对食用油样品质谱数据识别效果比较理想,能够在对地沟油和非地沟油样品进行有效区分的同时,实现对不同品种的食用油的分离及分类判别。本方法分析速度快,信息提取准确,识别精度高,对快速质谱技术结合神经网络在该领域的应用以及食用油品质的快速鉴定具有重要的借鉴意义。     

质谱快速分析猪肉中痕量沙丁胺醇及克伦特罗

采用内部萃取电喷雾电离质谱( iEESI-MS)技术,在无需样品预处理的前提下,采用标准加入法直接对猪肉组织中沙丁胺醇与克伦特罗进行定性和定量分析。结果表明,本实验对猪肉组织中沙丁胺醇与克伦特罗具有较高的灵敏度,单个样品单一指标的检测时间少于30 s。在0.01~1000μg/kg浓度范围内,信号强度对数(Y)与浓度对数(X)具有较好的线性关系,定量限分别为6.2和9.8 ng/kg。本方法分析速度快、样本耗量少、灵敏度高,适用于猪肉中痕量沙丁胺醇与克伦特罗等“瘦肉精”的快速检测。     

表面解吸常压化学电离质谱快速鉴别硫磺熏蒸八角

采用自行研制的表面解吸常压化学电离质谱(DAPCI-MS),无需样品预处理,对硫磺熏蒸八角和未熏八角直接进行正、负离子模式检测,获得其化学指纹图谱,并通过主成分分析(PCA)及聚类分析(CA)方法对所获指纹谱图信息进行分析,进而对不同样品进行鉴别。结果表明,在正、负离子模式下,DAPCI-MS都可对八角表面多种特征化学成分进行分析,快速获得八角的化学指纹谱图,并能够对目标组分进行多级串联质谱鉴定,结合PCA及CA方法可对八角是否经硫磺熏蒸进行快速鉴别。本方法无需样品预处理,灵敏度高,分析速度快,无污染,可望应用于市场上硫熏制品的快速鉴别。     

表面解吸常压化学电离质谱快速鉴别樟木制品

采用自行研制的表面解吸常压化学电离质谱(SDAPCI-MS),在无需样品预处理的情况下,对樟木制品及普通木材进行检测,在正离子模式及m/z 90～400范围内获得其化学指纹图谱,并通过主成分分析(PCA)方法对所获指纹谱图信息进行分析,进而对不同样品进行鉴别。结果表明,SDAPCI-MS能够对樟木表面多种特征化学成分(樟脑,香叶醇等)进行解吸电离,快速获得樟木的化学指纹谱图,并能够对目标组分做多级串联质谱鉴定。结合PCA方法,可对不同品质、不同种类的木材样品进行区分。结果表明,本方法灵敏度高,分析速度快(单个样品分析时间小于3 min),可望应用于珍贵木材快速无损分析及品质鉴定。     

Simultaneous analysis of glycolipids and phospholids molecular species in avocado (Persea americana Mill) fruit

The molecular species of phospholipids (PLs) and glycolipids (GLs) were simultaneously characterized in the pulp and almond of the avocado fruit (Persea americana Mill) of four varieties by means of high performance liquid chromatography-electrospray ionisation ion-trap tandem mass spectrometry. In the pulp, the predominant species of monoglycosyldiglycerides (MGD) were m/z 796.6 (oleic/linolenic and linoleic/linoleic acids) and m/z 800.4 (stearic/linoleic and oleic/oleic acids). One of the main diglycosyldiglycerides (DGD) both in the pulp and almond was m/z 958.5 (oleic/linolenic); however, the pulp was also rich of m/z 962.4 (oleic/oleic), whereas in the almond, m/z 934.5 (palmitic/linoleic and palmitoleic/oleic) and m/z 960.5 (oleic/linoleic and stearic/linolenic) were more abundant. In the almond, the main PL classes (phosphatidic acid (PA), phosphatidylcholine (PC), phosphatidylethanolamine (PE) and phosphatidylinositol (PI)) contained always palmitic/linoleic acids. Alpha-linolenic acid was contained as MGD (linolenic/linolenic) and DGD (linolenic/linolenic), more present in the pulp than in the almond. The major molecular species of glycocerebrosides (GCer) in the pulp and almond carried hydroxy-palmitic acid (C(16h:0))/4,8-sphyngadienine (d(18:2)).     

Fatty acids profiling of avocado seed and pulp using gas chromatography–mass spectrometry combined with multivariate chemometric techniques

In the present study, the profiling of 17 fatty acids (FAs) in avocado seed and pulp was investigated. The fatty acids were extracted with vortex-assisted extraction, methyl esterified and finally preconcentrated by dispersive liquid–liquid microextraction. The preconcentrated fatty acid methyl esters (FAMEs) were analyzed using gas chromatography–mass spectrometry (GC–MS) to obtain qualitative and quantitative information. The GC–MS data were analyzed using multivariate curve resolution-alternating least squares (MCR-ALS) method to overcome general chromatographic problems such as overlapped peaks, background interference and peak shifts. The calibration data were prepared using pure analytical information obtained by MCR-ALS. The linear dynamic ranges and regression coefficients (R ²) for FAMEs were in the range of 0.19–65 mg L^?1 and 0.990–0.999, respectively. The relative standard deviation (RSD%) for determination of FAs in avocado seed and pulp was 0.17–8.84 and 0.64–17.93, respectively. The main FAs in the avocado pulp were: oleic acid (74.25 g Kg^?1), linoleic acid (26.87 g Kg^?1), palmitic acid (26.02 g Kg^?1), palmitoleic acid (1.22 g Kg^?1) and stearic acid (0.05 g Kg^?1). And, the main FAs in the avocado seed were: linoleic acid (1.09 g Kg^?1), palmitic acid (0.47 g Kg^?1), oleic acid (0.33 g Kg^?1), linolenic acid (0.12 g Kg^?1), and palmitoleic acid (0.04 g Kg^?1).     

Antioxidant Activity and Protective effect of Banana Peel against Oxidative Hemolysis of Human Erythrocyte at Different Stages of Ripening

Phytochemicals such as polyphenols and carotenoids are gaining importance because of their contribution to human health and their multiple biological effects such as antioxidant, antimutagenic, anticarcinogenic, and cytoprotective activities and their therapeutic properties. Banana peel is a major by-product in pulp industry and it contains various bioactive compounds like polyphenols, carotenoids, and others. In the present study, effect of ripening, solvent polarity on the content of bioactive compounds of crude banana peel and the protective effect of peel extracts of unripe, ripe, and leaky ripe banana fruit on hydrogen peroxide-induced hemolysis and their antioxidant capacity were investigated. Banana (Musa paradisica) peel at different stages of ripening (unripe, ripe, leaky ripe) were treated with 70% acetone, which were partitioned in order of polarity with water, ethyl acetate, chloroform (CHCl₃), and hexane sequentially. The antioxidant activity of the samples was evaluated by the red cell hemolysis assay, free radical scavenging (1,1-diphenyl-2-picrylhydrazyl free radical elimination) and superoxide dismutase activities. The Folin–Ciocalteu's reagent assay was used to estimate the phenolic content of extracts. The findings of this investigation suggest that the unripe banana peel sample had higher antioxidant potency than ripe and leaky ripe. Further on fractionation, ethyl acetate and water soluble fractions of unripe peel displayed high antioxidant activity than CHCl₃ and hexane fraction, respectively. A positive correlation between free radical scavenging capacity and the content of phenolic compound were found in unripe, ripe, and leaky ripe stages of banana peel.     

桃核中脂肪酸成分分析

：通过GC－MS方法对桃核（核壳，桃仁，种皮）中的脂肪酸化学成分进行分析。鉴定出各种脂肪酸成分及其相对含量，主要成分为棕榈酸，硬酯酸，亚油酸，亚麻酸，油酸等。     

色谱-质谱联用技术在我国3种柚子组分鉴定及指纹图谱建立中的应用

利用色谱-质谱联用技术对我国主要的3个品种柚子果实的不同部位(外表皮、内表皮、内果皮、果肉、种子)的化学组分进行结构鉴定及种类和含量的差异性分析,结果表明,沙田柚、琯溪蜜柚、玉环柚果实5个部位共鉴定出68种不同化学组分物质,包括醇类19种、酯类15种、烯烃类9种、有机酸类8种、酮类7种、烷烃类4种、其他物质6种。其中3个品种柚子外表皮共有的化学组分有7种,含量最高的是柠檬烯(44.03%);内表皮共有的化学组分有6种,含量最高的是油酸酰胺(44.62%);内果皮共有的化学组分有10种,含量最高的是谷甾醇(30.75%);果肉共有的化学组分有11种,含量最高的是软脂酸(20.02%);种子中共有的化学组分有15种,含量最高的是亚油酸(45.83%)。化学组分差异性分析结果表明,沙田柚、琯溪蜜柚、玉环柚3种柚子的外表皮独有的化学组分分别有3种、6种、4种,内表皮分别有3种、4种、8种,内果皮分别有1种、4种、6种,果肉分别有4种、4种、2种,沙田柚、玉环柚种子独有的化学组分均为1种,并对化学组分进行聚类分析和相似度分析。研究结果说明不同品种柚子同一部位的化学组分种类和含量均存在相似性和差异性,特有物质较多,色谱指纹图谱特异性显著,这可为柚类品种鉴定、品质质量控制、原产地溯源等提出一种新的色谱指纹图谱思路。     

UHPLC-TOFMS coupled with chemometric method as a powerful technique for rapid exploring of differentiating components between two Ziziphus species

To rapidly explore the differentiating components and the potential chemical markers for discrimination between those Chinese medicinal herbs with similar chemical characteristics, an ultra-high-performance liquid chromatography (UHPLC)-TOFMS coupled with multivariate statistical analysis method was proposed and validated by using two Ziziphus species (Z. jujuba and Z. jujuba var. spinosa) as the model herbs. After the samples were analyzed using UHPLC-TOFMS, the data sets of retention time (RT)-m/z pairs, ion intensities and sample codes were further processed with orthogonal partial least squared discriminant analysis (OPLS-DA) to holistically compare the difference between the fruits of these two Ziziphus species, and to generate an S-plot. Those compounds correlating to the points at the two ends of "S" were regarded as the most differentiating components between these two kinds of samples. By comparing the mass/UV spectra and retention times with those of reference compounds, these components were finally characterized as zizyberenalic acid, palmitoleic acid, oleic acid, pomonic acid and rutin, and these compounds would be the potential chemical markers for discrimination of these jujube products. The results suggested that this newly established approach could be used to rapidly determine the subtle differences and explore the potential chemical markers for differentiation within the herbs with similar chemical ingredients.     

Variation in minerals, phenolics and antioxidant activity of peel and pulp of different varieties of peach (Prunus persica L.) fruit from Pakistan

Peach (Prunus persica L.), being a potential source of bioactive compounds, has been demonstrated to have medicinal benefits. In this study variation of minerals and antioxidant characteristics (total phenolic contents, total flavonoid contents, reducing power, inhibition of peroxidation using linoleic acid system and DPPH free radical scavenging activity) between peel and pulp parts of different peach varieties, namely Golden, Shireen, and Shahpasand were investigated. The peel and pulp extracts, derived from the varieties analyzed, exhibited an appreciable amount of total phenolics (TP) and total flavonoids (TF), ranging from 1,209.3-1,354.5, 711.7-881.3 mg GAE/100 g and 599.7-785.5, 301.3-499.7 mg CE/100 g on a dry weight basis, respectively. Reducing power of peel and pulp extracts (12.5 mg/mL concentration) ranged from 2.57-2.77 and 1.54-1.99.The inhibition of linoleic acid peroxidation and DPPH scavenging activity of the extracts varied from 70.8-80.9% and 66.8-76.5% in peels, and 51.9-60.1% and 43.4-49.1% in pulps. The mineral analysis revealed that the content of K was highest in both parts of the peach fruit followed by Mg, Ca, Fe, Mn and Zn. The results of our present study indicate that peach peel had significantly higher levels of minerals, antioxidant capacity and phenolics than those of the pulp, suggesting the intake of unpeeled peach as a potential source of high-value components. The peach peel can be a useful as a viable source of natural antioxidants for functional foods and nutraceutical applications.