不同海拔细叶亚菊挥发油成分的比较

采集不同海拔的细叶亚菊地上部分为原料，采用水蒸馏法提取挥发油。用GC-MS对挥发油进行化学成分分析，通过SPSS 22.0统计软件分析共有成分与海拔高度的相关性。不同海拔高度细叶亚菊中挥发油成分差异明显，共有成分5种，分别为樟脑、α-蒎烯、β-蒎烯、桉叶油素、（-）-4-萜品醇。各海拔挥发油中含量最高的化学物质依次为桉叶油素、樟脑、邻-异丙基苯、樟脑、桉叶油素。各海拔相对含量在5%以上的化合物相同的只有桉叶油素。相关性分析结果显示这5种共有成分的含量与海拔并无显著相关性。海拔高度对挥发油中共有成分含量的变化无规律性影响。     

基于GC-MS的荆芥和荆芥穗饮片挥发油中化学成分特征分析

分析荆芥和荆芥穗饮片挥发油中化学成分特征的差异,为其质量评价及临床应用提供依据。本研究收集市场上不同来源的荆芥和荆芥穗饮片,首先,采用水蒸气蒸馏法提取样品总挥发油,并利用GC-MS对荆芥和荆芥穗样品中的挥发油成分及含量进行测定;其次,利用SIMCA14.1软件对荆芥与荆芥穗中挥发油共有成分相对含量进行主成分分析、聚类分析;最后,利用OPLS-DA结合t-test筛选导致荆芥和荆芥穗挥发油存在差异的代谢标志物。结果表明,荆芥中挥发油总含量普遍低于荆芥穗,荆芥和荆芥穗挥发油含量的差异达极显著水平;荆芥中挥发油成分种类多于荆芥穗,荆芥与荆芥穗挥发油成分特征存在差异,各自聚为一类;OPLS-DA结果结合t检验共筛选出薄荷酮、异胡薄荷酮、β-石竹烯、柠檬烯、β-蒎烯、胡薄荷酮、香芹醇、顺-p-2,8-薄荷二烯醇、1-辛烯-3-醇、4-异丙烯基甲苯10种引起两种饮片差异的主要代谢标志物。因此,荆芥与荆芥穗两种饮片挥发油的化学成分特征存在差异,该差异与其临床功效的相关性还有待进一步研究。     

孜然芹种子挥发油化学成分的研究

本文用毛细管气相色谱和 GC/MS 联用技术,从孜然芹(Cuminum cyminum L.)种子挥发油中鉴定出:α-蒎烯、β-蒎烯、莰烯、月桂烯、γ-松油烯、对-聚伞花素、异松油烯、芳樟醇、胡薄荷酮、枯茗醛和桃金娘醛11个组分。又用硅胶柱层析,并经 IR、MS 和 NMR 等波谱法解析,确证了已知化合物的结构为     

国产野生薄荷挥发油化学组分变异及其化学型

采用气－质联用的方法,对国产野生薄荷（ＭｅｎｔｈａｈａｐｌｏｃａｌｙｘＢｒｉｑ．）居群的挥发油成分进行了分析,２２个样品可归纳为６个化学型：（１）薄荷酮－胡薄荷酮型（ｍｅｎｔｈｏｎｅ－ｐｕｌｅｇｏｎｅｔｙｐｅ）;（２）胡椒酮型（ｐｉｐｅｒｉｔｏｎｅｔｙｐｅ）;（３）氧化胡椒酮－氧化胡椒烯酮型（ｐｉｐｅｒｉｔｏｎｅｏｘｉｄｅ－ｐｉｐｅｒｉｔｅｎｏｎｅｏｘｉｄｅｔｙｐｅ）;（４）芳樟醇－氧化胡椒酮型（ｌｉｎａｌｏｏｌ－ｐｉｐｅｒｉｔｏｎｅｏｘｉｄｅｔｙｐｅ）;（５）香芹酮型（ｃａｒｖｏｎｅｔｙｐｅ）;（６）薄荷醇－乙酸薄荷酯型（ｍｅｎｔｈｏｌ－ｍｅｎｔｈｙｌａｃｅｔａｔｅｔｙｐｅ）。结合地理分布和薄荷属单萜类成分生物合成途径,对上述主要类型进行了讨论。     

裂叶荆芥花穗腺鳞代谢规律研究

为揭示荆芥穗腺鳞在不同开花序列中数量性状及内含物的代谢规律,本实验通过对荆芥穗不同开花序列的萼片进行腺鳞密度及半径的测算,以腺鳞指数拟合评价其数量性状的动态变化;同时对不同开花序列腺鳞内含物中6种单萜类成分(β-月桂烯、d-柠檬烯、dl-薄荷酮、薄荷呋喃、胡薄荷酮、β-石竹烯)进行气相色谱检测与定量研究。结果显示:腺鳞的主要发生阶段为开花前期,并于开花期基本完成;荆芥穗开花后,腺鳞因受到外界因素的影响数量逐渐减少;以D10轮为界,腺鳞中对薄荷烷型单萜类成分的代谢过程存在明显的物候迭代规律,并致使胡薄荷酮在腺鳞内含物中蓄积。说明荆芥穗腺鳞于开花期基本完成其数量性状增长及内含物的合成,但薄荷酮、薄荷呋喃、β-石竹烯等化合物在开花后期仍处于旺盛代谢状态,并且其含量变化可直接造成荆芥穗药效性质的改变,因此D10轮可作为荆芥穗的采收节点。     

裂叶荆芥不同部位香精油组成研究

采用水蒸气蒸馏法,分别从裂叶荆芥的叶、茎和花三个不同部位提取香精油并进行气相色谱/质谱分析.结果发现,叶、茎、花的香精油分别含有23、29、26种组分.叶和花香精油的组成和含量基本相似,主要成分是含量分别为15.09%、14.51%的薄荷酮和29.26%、31.36%的(+)-胡薄荷酮等单萜化合物以及含量分别为17.09%、5.00%的α-律草烯等倍半萜.而茎香精油的萜类化合物含量较低,含薄荷酮为4.15%,(+)-胡薄荷酮为7.68%,但其乙酯含量相对较高,如(E)-9-十六碳烯酸乙酯含量为11.92%,异戊酸乙酯为9.38%.     

园柏挥发油化学成分的GC—MS分析

利用毛细管气相色谱保留指数定性、标准样品叠加和色谱－质谱－计算机联用技术,对园柏挥发油的化学成分进行了分离和鉴定,共鉴定出单萜烃１６个、倍半萜烃１８个,并测得了各化合物的相对含量。其主要成分是：香桧烯、α－蒎烯、萜品醇－４、柠檬烯、γ－萜品烯和对一花烃。     

杜香植物资源开发利用的基础研究——Ⅰ.杜香油化学成分的研究

应用气相色谱-质谱联用技术,对杜香挥发油的化学成分进行分析,共鉴定出桧烯、α-萜品烯、γ-萜品烯、萜品烯-[4]-醇、桃金娘烯醛等18个化合物,并测定了各成分在挥发油中的含量。     

滇产薄荷的化学研究

研究了滇产３８个薄荷样品,测定了样品的得油率及化学成分。滇产薄荷的得油率在０．１８％￣０．５２％之间。从挥发油中鉴定出了１００多种化学成分,主要含醇、酮、酯、萜烯类化合物。栽培的家薄荷挥发油富含香芹酮、柠檬烯,其化学分类属于香芹酮系列。野生薄荷挥发油富含薄荷醇和薄荷酮,属于薄荷酮系列;部分野薄荷样品,富含香芹酮、环氧辣薄荷烯酮或芳樟醇,属于混合系列。     

巴巴拉百合花的天然香气成分研究

采用水蒸气蒸馏法对巴巴拉百合花挥发油进行了提取．通过毛细管气相色谱-质谱联用法分离并鉴定了其化学成分．并用气相色谱面积归一化法测定了各成分的相对百分含量。共分离出62个峰,确定了其中60种化合物,所鉴定化合物的含量占全油的99．71％．主要化学成分为：萜二烯(59．43％);3,7-二甲基-1．6-辛二烯-3-醇(20．10％);(R)-4-甲基-1-(1-甲基乙基)-3-环己烯1醇(11．32％);3异丙烯基-5,5-二甲基环已烯(4．05％);2-氨基苯甲酸-3,7-二甲基-1,6-辛二烯-3-酯(3．52％);( )-α-萜品醇(p-薄荷-1-酮-8-醇)(2．22%);β-月桂烯(1．08％)。以上7种化合物占总挥发油的94．72％。     

Chemical composition of the fixed and volatile oils of Nigella sativa L. from Iran

The chemical composition of the extracted fixed oil (total fatty acid composition) and volatile oil of Nigella sativa L. seeds grown in Iran were determined by GC and GC/MS. Eight fatty acids (99.5%) and thirty-two compounds (86.7%) have been identified in the fixed and volatile oils, respectively. The main fatty acids of the fixed oil were linoleic acid (55.6%), oleic acid (23.4%), and palmitic acid (12.5%). The major compounds of the volatile oil were trans-anethole (38.3%), p-cymene (14.8%), limonene (4.3%), and carvone (4.0%).     

GC-MS法分析曼陀罗挥发油的化学成分

用水蒸气蒸馏法从曼陀罗中提取挥发油,并用气相色谱/质谱联用技术(GC-MS)对挥发油的化学成分进行分离鉴定,用气相色谱峰面积归一化法确定各组分的相对含量.结果从曼陀罗挥发油中鉴定出58种化合物,占总挥发油量的92.37%.其中主要成分为5,6-二氢-6-戊基-2H-吡喃-2-酮(44.29%)、二苯胺(12.50%)、四十四烷(10.41%)、二十烷(4.19%)、(E)-3-己烯-1-醇(2.38%)、3,7,11,15-四甲基-2-十六碳烯-1-醇(2.28%)等.     

Volatiles of Curcuma mangga Val. & Zijp (Zingiberaceae) from Malaysia

Analysis by GC and GC/MS of the essential oil obtained from Malaysian Curcuma mangga Val. & Zijp (Zingiberaceae) rhizomes allowed the identification of 97 constituents, comprising 89.5% of the total oil composition. The major compounds were identified as myrcene (1; 46.5%) and β-pinene (2; 14.6%). The chemical composition of this and additional 13 oils obtained from selected Curcuma L. taxa were compared using multivariate statistical analyses (agglomerative hierarchical cluster analysis and principal component analysis). The results of the statistical analyses of this particular data set pointed out that 1 could be potentially used as a valuable infrageneric chemotaxonomical marker for C. mangga. Moreover, it seems that C. mangga, C. xanthorrhiza Roxb., and C. longa L. are, with respect to the volatile secondary metabolites, closely related. In addition, comparison of the essential oil profiles revealed a potential influence of the environmental (geographical) factors, alongside with the genetic ones, on the production of volatile secondary metabolites in Curcuma taxa.     

Volatile oil composition of the aerial parts of Ajuga orientalis L. from Iran

The volatile oil content and composition of the aerial parts of Ajuga orientalis L. (Lamiaceae) grown in northern parts of Iran have been analyzed by GC/MS. Thirty compounds were identified, representing 97.9% of the total oil. The main compounds were germacrene-D (24.2%), beta-cubebene (18.3%), beta-caryophyllene (16.9%) and alpha-cubebene (5.3%).     

Essential oil of trees of the genus Ocotea (Lauraceae) in Costa Rica. I. Ocotea brenesii

The chemical composition of the essential oils from leaves and wood of Ocotea brenesii Standl. growing wild in Costa Rica was determined by capillary GC/FID and GC/MS. From the leaves, 64 compounds were identified, corresponding to 85.9% of the oil, and from the wood 57 compounds were identified corresponding to 69.0% of the oil. The major constituents identified in the leaf oil were alpha-copaene (21. 1%), 8-cadinene (9.2%), spathulenol (7.3%), globulol (5.6%) and beta-caryophyllene (5.2%). The major constituents of the wood oil were alpha-copaene (6.6%), caryophyllene oxide (6.3%). beta-caryophyllene (6.1%) and humulene epoxide (4.6%).     

Chemical composition of volatile oil from Cinnamomum zeylanicum buds

The hydro-distilled volatile oil of the Cinnamomum zeylanicum (C. zeylanicum) buds was analyzed using GC and GC-MS for the first time. Thirty-four compounds representing approximately 98% of the oil was characterized. It consists of terpene hydrocarbons (78%) and oxygenated terpenoids (9%). alpha-Bergamotene (27.38%) and alpha-copaene (23.05%) are found to be the major compounds. A comparison of the chemical composition of the oil was made with that of flowers and fruits.     

飞机草挥发油的化学组成及其对植物、真菌和昆虫生长的影响

飞机草挥发油对5种植物幼苗生长有显著的抑制作用,受抑制的大小排序为黑麦草＞白菜＞萝卜＞四季豆＞水稻．中等浓度(800mg·L-1)飞机草挥发油对水稻稻温病菌的抑制作用最强,对长春花疫病菌的抑制作用次之,对香蕉枯萎病菌的抑制作用最弱;其抑茵串分别为61．40％、29．27％和14．44％．10-20μl·株^-1的飞机草挥发油对小菜峨和黄曲条跳甲有显著的驱避产卵作用．经GC／MS,飞机草挥发油的化学成分主要是萜类化合物,如反式—石竹烯(16．58％)、δ—杜松烯(15．85％)、α—可巴烯(11．58％)、氧化石竹烯(9．63％)、大根香叶烯(4．96％)和α—Lu草烯(4．32％)。     

Campanula portenschlagiana Roem. et Schult.: Chemical and Antimicrobial Activities

The phytochemical profile and the antimicrobial effects of the volatile oil and the aqueous extract of Campanula portenschlagiana, a wild growing plant endemic to Croatia, were described. In the volatile oil, 53 compounds were identified by GC‐FID and GC/MS analyses. Diterpene alcohols constituted the major compound class with labda‐13(16),14‐dien‐8‐ol as the main compound. The aqueous extract was characterized by the total phenolic content. The antimicrobial potential of the volatile oil and the aqueous extract was evaluated against a diverse range of microorganisms comprising food‐spoilage and food‐borne pathogens. The volatile oil exhibited interesting and promising antimicrobial effects against the tested species, which were generally more pronounced against Gram‐negative bacteria. In addition, the inhibitory effect of this volatile oil was also evaluated against eleven extended‐spectrum β‐lactamase (ESBL)‐producing isolates. The results suggest that the C. portenschlagiana volatile oil might be used as antimicrobial agent against ESBL‐producing isolates and Gram‐negative bacteria.     

拳卷地钱挥发油成分分析

采用水蒸气蒸馏法从拳卷地钱中提取挥发油成分,并用气相色谱-质谱法(GC—MS)联机分析,共分 离出25个峰,鉴定了其中10种物质,占挥发油总组分的40．0％。在所分离的化合物中,碳氢化合物5种,烃 类含氧衍生物5种。主要成分为norpinane和hedycaryol,另外8种含量均在1％以上。在气相色谱分析中, 选择了合适的色谱条件,采用非极性的HP5柱,对地钱挥发油中的弱极性和非极性成分有较好的分离效果。