小叶臭黄皮叶挥发油化学成分的研究

采用水蒸气蒸馏法提取小叶臭黄皮叶挥发油,运用毛细管气相色谱-质谱联用法对挥发油成分进行了分析,共分离出84个峰,鉴定了其中的66种成分,所鉴定成分占挥发油总量的94.52%.其主要化学成分为α-芹子烯(15.76%)、石竹烯(15.05%)、β-芹子烯(9.54%)、α-蒎烯(6.43%)和α-石竹烯(5.39%)等.     

利用GC-MS技术分析油橄榄叶挥发油化学成分

本文采用同时蒸馏萃取法(SDE)提取油橄榄叶挥发油化学成分,利用气相色谱-质谱(GC-MS)联用方法分析并用峰面积归一化法得出各化学成分在挥发油中的百分含量。结果从油橄榄叶挥发油中分离出62各色谱峰,鉴定出56个化合物,占挥发性组分总量的95.6%。其中主要成分为α-芹子烯(13.13%)、β-芹子烯(10.15%)、β-石竹烯(14.29%)、橙花叔醇(6.72%)、α-石竹烯(6.60%)、3-己烯-1-醇(5.03%)、苯乙醛(5.61%)等。     

石油菜挥发油和超临界流体萃取物化学成分的GC-MS分析

首次利用水蒸气蒸馏法和超临界流体萃取法(SFE)对石油菜地上部位进行提取,分别获得挥发油和SFE萃取物,采用气相色谱-质谱联用技术(GC-MS)结合计算机数据库检索对这两种提取物的化学成分进行了分析鉴定,采用峰面积归一化法测定了其中各个化学成分的相对含量。从挥发油中共分离出39个色谱峰,鉴定了其中28个化学成分,已鉴定出的成分的相对含量总和占化合物检出总量的91.90%,化合物类型均为萜类。从SFE萃取物中共分离出136个色谱峰,鉴定了其中65个化学成分,已鉴定出的成分的相对含量总和占化合物检出总量的58.17%,化合物类型包括萜类、芳香族类和脂肪族类。挥发油和SFE萃取物均含有α-蒎烯、石竹烯和桉油烯醇,其他成分则存在较大差异。     

野花椒果皮挥发性成分的研究

采用水蒸气蒸馏法提取野花椒果皮挥发油,出油率为0．603％。运用气相色谱-质谱联用技术分析,从野花椒果皮挥发油中分离出150个色谱峰,鉴定了107个化合物,占总量的92．96％,主要有1,8-桉油素（17．91％）、柠檬烯（12．66％）β-榄香烯（9．81％）、α-萜品醇（7．61％）β-芹子烯（4．81％）、β-芹子烯（3．79％）、α-石竹烯（3．71％）等。     

火麻仁挥发油的化学成分研究

本文采用水蒸气蒸馏法提取传统中药火麻仁中的挥发油,用GC毛细管柱进行分析,面积归一化法测定其相对含量,并用GC-MS鉴定其化学成分.共检出90个色谱峰,鉴定其中62个化合物,占挥发油总量的89 25%.鉴定的成分包括44种烃类化合物、7种芳香族化合物和11种脂肪族化合物及其衍生物.烃类化合物中以萜类为主,占挥发油总量的32.01%,相对含量较高的单萜及其衍生物包括β-芳樟醇(1.66%)、β-顺式-罗勒烯(1.30%)、樟脑(0.93%)、冰片和薄荷醇(0.44%);相对含量较高的倍半萜及其衍生物包括大牦牛儿烯 D(8.20%)、α-芹子烯(5.23%)、β-丁香烯(3.65%)、氧化石竹烯(2.22%)、δ-愈创木烯(1.55%)和α-丁香烯(1.19%).     

中药法落海挥发油化学成分研究

目的：分析和鉴定法落海中挥发油的化学成分。方法：用蒸馏法提取法落海中的挥发油，借助GC-MS法将挥发油中各化学成分进行分离和鉴定，用峰面积归一化法测定其相对含量。结果：法落海挥发油离子流图共有99个峰，鉴定出了77种化合物，占挥发油总量96.1%，其中主要成分为：α-蒎烯（27.33%）、α-水芹烯（9.87%），十二烷醇（8.41%）、罗勒烯（7.24%）、4,4,6,6-四甲基-二环[3.1.0]己-2-烯（5.55%）、肉豆蔻脑酸（3.58%）、蛇麻烯（2.76%）等。结论：本实验采用GC-MS联用技术分析了法落海中所含挥发油成分，使用峰面积归一化法计算挥发油中的相对含量，该方法操作简单，灵敏度高，检测效果好。简要讨论主要成分中化学成分的药理作用，为开发利用法落海提供理论依据。     

滨海前胡不同部位挥发油化学成分GC-MS分析

采用水蒸气蒸馏法分别提取滨海前胡Peucedanum japonicum根、茎叶、花及果实中挥发油,使用GC-MS分析挥发油并鉴定其化学成分,比较不同部位挥发油的化学成分及含量差异。结果显示,从根、茎叶、花和果实挥发油中分别鉴定出58、36、40和45种化学成分, 分别占各部位挥发油总量的95.60%、98.03%、95.82%和95.36%。四个部位共鉴定出79个化学成分, 其中有相同化合物20种,主要成分为α-侧柏烯、α-蒎烯、β-月桂烯、β-蒎烯等。     

棘托竹荪挥发油化学成分及抑菌作用的研究

利用水蒸汽蒸馏法提取棘托竹荪的挥发油,得油率为0．45％。应用气相色谱－质谱联用系统首次对其挥发油的化学成分进行研究。以FFAP柱分离出36个峰,用质谱法鉴定出28个成分,其主要成分为13－甲基－环氧十四烷－2－酮（23．53％）、亚油酸（17．56％）、芹子烯（12．37％）、棕榈酸（8．20％）、9－十六碳烯酸（7．84％）、（－）－Lepidozenal(7.82%)等,占总挥发油的97.76%,对挥发油进行抑菌试验,其结果为：桔黄青霉、啤酒酵母最敏感,黑根霉、黑曲霉次之,白色假丝酵母、金色葡萄球菌,大肠杆菌稍差。     

棘托竹荪挥发油化学成分及抑菌作用的研究*

利用水蒸汽蒸馏法提取棘托竹荪的挥发油,得油率为0.45%。.应用气相色谱—质谱联用系统首次对其挥发油的化学成分进行研究。以FFAP柱分离出36个峰,用质谱法鉴定出28个成分,其主要成分为13-甲基-环氧十四烷-2-酮 (23.53%)、亚油酸(17.56%)、芹子烯(12.37%)、棕榈酸(8.20%)、9-十六碳烯酸(7.84%)、(-)-Lepidozenal(7.82%)等, 占总挥发油的97.76%。对挥发油进行抑菌试验,其结果为:桔黄青霉、啤酒酵母最敏感, 黑根霉、黑曲霉次之,白色假丝酵母、金色葡萄球菌,大肠杆菌稍差。     

小黄皮叶挥发油的化学成分

利用水蒸气蒸馏法提取小黄皮叶挥发油,运用毛细管气相色谱-质谱联用法对挥发油进行了分析,分离出40个峰,鉴定了其中的37种成分,所鉴定成分占挥发油总量的99.87%,其主要化学成分为单萜及倍半萜类化合物。     

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%.     

锦鸡儿属分析生物地理学的研究

将锦鸡儿属（Caragana）植物分布区划分成13个。在分支系统学基础上,进行了分布区的成分分析。以种类和系为分布特征,进行分布区的聚类分析和最小生成树分析。分布区分支图、表征图和最小生成树从不同方面表达了分布区的关系。锦鸡儿属的分布区被分成东亚和古地中海两大部分。其中分别来自这两部分的前苏联远东-我国东北与阿尔泰-萨彦岭分布区有密切关系。基于分布区分支图,属的分布区分别由这两个分布区衍生,同时结合属的种系发生关系,推断本属可能起源于东西伯利亚,时间为第三纪中新世末-上新世。生态适应上,分类群是由东部温带中生性类型向西部旱化和寒化方向发展的。     

大花金挖耳不同部位挥发油化学成分比较分析

采用GC-MS技术,对利用水蒸气蒸馏法从大花金挖耳根、茎、叶、花及花托等5个部位获得的挥发油组分进行了分析.从大花金挖耳5种挥发油中共鉴定出99种成分,从根、茎、叶、花及花托分别鉴定出了37、34、47、29和40种化合物,已鉴定的组分分别占相应挥发油的85.86%、84.98%、83.06%、84.58%和89.06%.5个部位挥发油化学组成差异较大,根挥发油主要成分为倍半萜类和酯类;茎挥发油主要为倍半萜和烯类(包括烯醇、烯酸、烯酮);叶和花挥发油主要为烯类(包括烯醇、烯酸、烯酮)和酯类;花托挥发油主要为倍半萜类和二萜类.     

Chemical composition and phytotoxicity of volatile essential oil from intact and fallen leaves of Eucalyptus citriodora

A total of 23 volatile constituents was identified and characterized by GC and GC-MS in the volatile essential oil extracted from intact (juvenile and adult) and fallen (senescent and leaf litter) leaves of lemon-scented eucalyptus (Eucalyptus citriodora Hook.). The leaves differed in their pigment, water and protein content, and C/N ratio. The oils were, in general, monoterpenoid in nature with 18 monoterpenes and 5 sesquiterpenes. However, a great variability in the amount of essential oils and their individual constituents was observed in different leaf tissues. The amount was maximum in the senescent leaves collected from the floor of the tree closely followed by that from juvenile leaves. In all, 19 constituents were identified in oil from juvenile and senescent leaves compared to 23 in adult leaves and 20 in leaf litter, respectively. Citronellal, a characteristic monoterpene of the oil reported hitherto was found to be more (77-78%) in the juvenile and senescent leaves compared to 48 and 54%, respectively, in the adult leaves and leaf litter. In the adult leaves, however, the content of citronellol--another important monoterpene-- was very high (21.9%) compared to other leaf types (7.8-12.2%). Essential oil and its two major monoterpenes viz. citronellal and citronellol were tested for their phytotoxicity against two weeds (Amaranthus viridis and Echinochloa crus-galli) and two crops (Triticum aestivum and Oryza sativa) under laboratory conditions. A difference in the phytotoxicity, measured in terms of seedling length and dry weight, of oil from different leaves and major monoterpenes was observed. Oil from adult leaves was found to be most phytotoxic although it occurs in smaller amount (on unit weight basis). The different toxicity of different oil types was due to the relative amount of individual monoterpenes present in the oil, their solubility and interactive action. The study concludes that oil from senescent and juvenile leaves being rich in citronellal could be used as commercial source of citronellal whereas that from adult leaves for weed management programmes as it was the most phytotoxic.     

Essential Oils of Polyalthia suberosa Leaf and Twig and Their Cytotoxic and Antimicrobial Activities

Essential oils from the leaf and twig of Polyalthia suberosa (Roxb.) Thwaites were analyzed using GC/MS/FID. A total of sixty-three constituents were namely identified accounting for 96.03 and 94.12 % in the hydrodistilled oils of the leaf and twig, respectively. Monoterpenes, monoterpenoids, sesquiterpenes, and sesquiterpenoids were characteristic derivatives of P. suberosa essential oils. Sesquiterpenes bicyclogermacrene (26.26 %) and (E)-caryophyllene (7.79 %), and monoterpene β-pinene (12.71 %) were the major constituents of the leaf oil. Sesquiterpenes (E)-caryophyllene (17.17 %) and α-humulene (9.55 %), sesquiterpenoid caryophyllene oxide (9.41 %), and monoterpenes camphene (8.16 %) and tricyclene (6.35 %) were to be main components in the twig oil. The leaf oil indicated cytotoxic activity against three cancer cell lines HepG2, MCF7 and A549 with the IC₅₀ values of 60.96–69.93 μg/mL, while the twig oil inhibited MCF7 with the IC₅₀ value of 66.70 μg/mL. Additionally, the twig oil successfully suppressed the growth of the negative Gram bacterium Pseudomonas aeruginosa, fungus Aspergillus niger, and yeast Candida albicans with the same MIC value of 50 μg/mL, whereas the leaf oil had the same result on the negative Gram bacterium Escherichia coli.     

软枣猕猴桃挥发物质的提取及GC-MS分析

采用气相色谱—质谱联机的分析方法,从软枣猕猴桃挥发成分中共分离出13个组分,鉴定了12个组分,占全部组分的 99.03%。其主要成分是酯类、醇类物质,其中丁酸乙酯的相对含量高达 86.89%。     

广西小叶红叶藤挥发油化学成分及抗氧化性研究

采用气相色谱-质谱联用技术对小叶红叶藤挥发油的化学成分进行分析,并用DPPH·法、ABTS,+法和铁氰化钾还原法对其抗氧化能力进行研究.结果表明:从小叶红叶藤挥发油分离出221个色谱峰,共鉴定64个化合物,占挥发油总量的95.72％,主要成分为dl-薄荷酮(53.43％)、(E)-薄荷酮(14.20％)、5-甲基-2-...     

Essential oil yield,composition, bioactivity and leaf morphology of Juniperus oxycedrus L. from Bulgaria and Serbia

Juniperus oxycedrus L. (Cupressaceae Bartlett) is widely distributed in countries with a Mediterranean climate. All plant parts contain highly aromatic essential oil (EO) and recently there have been efforts to introduce it as a cultivated crop. The species is known for its large morphological and chemical variation and its debatable taxonomic status. This study aimed to (1) compare content, composition, and antimicrobial activity of J. oxycedrus EO samples from plants growing in Bulgaria and Serbia, and (2) quantify morphological variations of leaves. Тhe EO content (yield) in dried juniper leaves varied from 0.06% (Кopaonik, Serbia) to 0.24% (Markovo, Bulgaria). We identified 51 EO constituents, belonging to monoterpenes, sesquiterpenes, and diterpenes. The class monoterpenes (monoterpene hydrocarbons and oxygenated monoterpenes) were the predominant compounds, representing 38.6–65.4% of the total EO, consisting primarily of α-pinene, limonene, sabinene, β-pinene, and β-myrcene. In addition, α-pinene was the major oil constituent in plants from all locations. Sesquiterpenes (sesquiterpene hydrocarbons and oxygenated sesquiterpenes) were the second largest class of constituents, which represented 19.3% tо 33.6% of the total EO. γ-Elemene was found only in the EO of J. oxycedrus from Bulgaria, while a high concentration of α-curcumene was found only in samples from Serbia (7.5–7.8%). Significant differences in antimicrobial activity of the EO were found in bacterial strains Bacillus cereus and Streptococcus pneumoniae. There was no significant difference among the mean leaf width of the six combinations location x sex, and the overall leaf mean width was 1.24 mm. However, there was a significant difference between the mean leaf lengths. In this study, none of the studied populations had a higher concentration of limonene than of α-pinene, indicating that the flora of the two countries include J. oxycedrus and not the previously reported J. deltoides. The results revealed significant variation in EO profile that may contribute to the development of new cultivars of J. oxycedrus.     

Essential oil composition of Senecio graciliflorus DC: Comparative analysis of different parts and evaluation of antioxidant and cytotoxic activities

The essential oil of different parts of Senecio graciliflorus DC was obtained by hydrodistillation and analysed by GC-FID and GC–MS for the first time. A total of 17, 20, 19 and 17 constituents were identified comprising 99.90, 95.50, 98.93 and 95.96% of the essential oil of flower, leaf, stem and root parts of Senecio graciliflorus respectively. Monoterpene hydrocarbons predominated in the essential oil with 85.28% in flower, 57.53% in leaf, 67.74% in stem and 64.98% in root oil. α-pinene, cis-ocimene, 1,2,3-trimethylcyclohexane and β-pinene were the major constituents of the essential oil. The flower essential oil exhibited a strong antioxidant potential displaying IC₅₀ values of 21.6 ± 0.6 and 26.0 ± 1.0 μg/ml in DPPH and hydroxyl radical assays respectively. On the other hand the essential oil of flower and root displayed highest cytotoxicity against lung (A-549) cancer cell lines (IC₅₀ = 19.1 ± 0.9 and 21.3 ± 1.1 μg/ml respectively. This study which represents the first report of the essential oil composition and bioevaluation of Senecio graciliflorus, can serve as a new source of cytotoxic and antioxidant activity.     

Chemical composition of the essential oils of ripe berries of Juniperus oxycedrus L., growing wild in Kosovo

The main objective of this work was to study the essential oil composition of ripe Juniperus oxycedrus L. berries and its natural variation among wild populations in Kosovo. Essential oil was analysed using GC-FID and GC–MS. Plant materials were collected from five locations in Kosovo in August and September of 2011. In total, twenty-seven compounds were identified in the essential oils. The main components were β-myrcene (45.5–56.9%), α-pinene (10.2–36.6%), dl-limonene (3.6–13.8%) and germacrene D (1.7–8.7%). Of the total identified compounds, monoterpenes constituted the highest percentage of all components (70.24–88.22%), followed by oxygenated sesquiterpenes (4.9–11.4%), sesquiterpenes (3.5–11.0%), oxygenated monoterpenes (0.2–2.7%) and oxygenated diterpenes (0.0–1.7). Hierarchical Cluster Analysis (HCA) and Principal Component Analyses (PCA) were used to identify any geographical variations in essential oil composition. Statistical analysis suggests that the clustering of populations is not related to their geographic location, but rather seemed to be linked to local selective forces acting on chemotype diversity.