共查询到19条相似文献,搜索用时 140 毫秒
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茵陈挥发油的超临界CO2萃取法与水蒸气蒸馏法提取的比较 总被引:10,自引:0,他引:10
采用超临界CO2萃取法与水蒸气蒸馏法从菌陈中提取挥发油,用GC-MS法测定其化学成分和相对含量,对两种提取方法所得的挥发油进行比较,水蒸气蒸馏法提取菌陈挥发油的产率为0.03%(w),主要成分为匙叶桉油烯醇、吉玛烯D、反式-石竹烯、2,4-戊二炔苯、β-金石欢烯等;超临界CO2萃取法提取的产率为0.15%(w),主要成分为百里酚、β-红没药烯、2-异丙基-4-甲基-1-甲氧基苯、异百里酚、2-特丁基-4-(2,4,4-三甲基戊基)苯酚、β-杜松烯等。 相似文献
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姜科姜黄属植物有效成分的研究 总被引:13,自引:0,他引:13
研究不同产地姜科姜黄属植物挥发油的化学成分,了解不同产地姜科姜黄属植物挥发性成分的差别,为控制其药材质量提供理论依据。采用水蒸气蒸馏法提取不同产地姜科姜黄属植物的挥发油,用气相色谱—质谱联用仪对其进行分离测定,结合计算机检索对分离的化合物进行结构鉴定,应用色谱峰面积归一化法测定各成分的相对百分含量。结果发现,不同产地姜科姜黄属植物的水蒸气蒸馏提取物得率在0.20%~2.13%之间,分别鉴定出24~40个化学成分。不同品种、不同产地姜科姜黄属植物的挥发油含量和其所含成分有较大差别,文献报道的某些有效成分如莪术酮、莪术二酮、莪术醇和表莪术酮在某些供试品中未检测到。实验中10个供试品药材中挥发性成分主要为单萜类及倍半萜类化合物及其衍生物,倍半萜类化合物的百分含量(44.57%~88.65%)明显高于单萜类化合物的百分含量(1.63%~26.69%)。 相似文献
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同时蒸馏萃取GC-MS分析刺异叶花椒叶挥发油化学成分 总被引:1,自引:0,他引:1
研究黔产刺异叶花椒叶挥发油的化学成分,采用同时蒸馏萃取提取并用气相色谱-质谱进行分离测定,共分离出67种成分,鉴定出37个化合物,主要成分为萜烯化合物及其衍生物,柠檬烯为19.31%,里哪醇为15.26%,桧烯为13.60%。 相似文献
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气相色谱-质谱技术分析红松松塔挥发性成分 总被引:8,自引:0,他引:8
采用水蒸气蒸馏法,对红松松塔挥发性成分进行提取和研究,最佳蒸馏时间5.5h,挥发油提取率1.28%。利用气相色谱-质谱联用技术对提取的挥发油成分进行分析,共鉴定出32种化学成分,主要为单萜和倍半萜类化合物,其中相对含量较高的有α-蒎烯(44.258%)、D-柠檬烯(23.426%)、β-蒎烯(8.674%)、有石竹烯(3.462%)、β-月桂烯(3.018%)等。研究结果表明红松松塔挥发油中富含α-蒎烯、D-柠檬烯、石竹烯等多种具有药理活性的成分。因此,红松松塔是一种具有较好前景的天然药用资源。 相似文献
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追风伞挥发油的化学成分研究 总被引:7,自引:0,他引:7
研究了贵州产追风伞 (LysimachiatrientaloidesHemsl.)挥发油的化学成分。采用水蒸汽蒸馏法提取追风伞挥发性成分 ,用气相 质谱进行分离测定 ,结合计算机质谱图库检索技术对分离的化合物进行结构鉴定 ,从中鉴定出 4 0种化学成分 ;应用峰面积归一化法测定各成分的相对含量。水蒸汽蒸馏提取物的提取率是 0 11%。研究结果表明 ,贵州产追风伞挥发油的主要成分为萜烯类及其含氧衍生物等 ,主要有广藿香醇 (2 2 5 4 % )、乙酸龙脑酯(16 17% )、γ 古芸烯 (3 2 7% )、δ 愈创烯 (2 6 2 % )、橙花叔醇 (2 0 2 % )、芳樟醇 (1 99% )和棕榈酸 (1 96 % )。 相似文献
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The root and leaf essential oils, present in trace amounts in Amsonia illustris Woods. (Apocynaceae), were isolated by steam distillation and their chemical constituents identified by GC-FID and GC-MS. More than 80% of the thirty volatile compounds in the leaf oil were identified, the major constituents being mainly sesquiterpenes like a-humulene (14.5%), beta-caryophyllene (12.4%) and guaiol (11.6%). The volatile ingredients of the root oil were pinocampheol, methyl salicylate, (2E,4E)- decadienal, eugenol and trans-isoeugenol. 相似文献
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研究了大叶黄杨叶、茎、果挥发油的化学成分及抗病毒活性。 采用超临界二氧化碳萃取,应用气相色谱-质谱联用(GC-MS) 法鉴定挥发油化学成分,考察体外抗病毒作用。 共鉴定133个化合物,大叶黄杨叶挥发油中主要有2-乙氧丙烷(41.92%)、(E)-2-己烯-1-醇(17.8%)、 (E)-香叶醇(7.86%)、甲基环己烷(6.60%)等;大叶黄杨茎挥发油中主要有甲氧基苯基肟(33.10%)、二十八烷(14.34%)、α-甲基-α-[4-甲基-3-戊烯基]环氧乙烷甲醇(12.48%)、甲苯(11.88%)、二十一烷(7.74%) 等;大叶黄杨果挥发油中主要有苯甲醛(15.52%)、甲苯(15.03%)、甲基环己烷(14.76%)、(Z)-3-己烯-1-醇(10.98%)等。 大叶黄杨叶、茎、果的环己烷、乙醚萃取挥发油对特定病毒有显著抑制效果。 大叶黄杨叶、茎、果中挥发油萃取部位成分差异明显,有特定抗病毒活性。 相似文献
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The volatile constituents of Valeriana jatamansi Jones and V. hardwickii Wall. (Valerianaceae) collected from the Khasi Hills of north-east India were analyzed by GC and GC/MS. Twenty-seven and twenty-one compounds were characterized and identified from V. jatamansi and V. hardwickii samples, representing 90.6% and 82.7% of the total oil, respectively. Sesquiterpenes were shown to be the main constituents in both the oil samples. Maaliol (26.1%), patchouli alcohol (9.3%) and a-gurjunene (8.7%) were the major components of V. jatamansi oil, whereas valeracetate (21.3%), methyl linoleate (14.1%), bornyl acetate (13.8%) and cuparene (7.1%) were the main constituents of V. hardwickii oil. Both Indian valerian essential oils were studied for their antioxidant activities using the free radical-scavanging activity (DPPH) and ferric reducing antioxidant power (FRAP) assays. V. hardwickii oil exhibited a higher antioxidant capacity than V. jatamansi in both assays. For both the valerian oil samples, there was a concentration-dependent increase in free radical scavenging activity and ferric reducing capacity. Both valerian oils and their ingredients are potential sources of natural antioxidants. 相似文献
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分析野生和栽培羌活药材挥发油含量及其组分的变化,为羌活药材的引种栽培及进一步的开发利用提供了依据。采用水蒸气蒸馏法提取羌活药材中的挥发油,通过GC-MS对挥发油成分进行分析鉴定;利用聚类分析对测定结果进行分类;通过相关分析研究海拔对羌活药材挥发油含量的影响。6份药材样品挥发油含量范围为1.60~7.98 mL/100g,6份羌活药材挥发油成分经GC-MS分析,共鉴定出57个化合物,共有成分12个;基于挥发油成分种类及相对含量的聚类分析显示了羌活药材挥发性成分种类及含量的种间差异;相关分析结果表明,海拔高度与挥发油含量存在显著正相关。野生和栽培羌活药材挥发油含量存在差异,总体上野生羌活药材的挥发油含量高于栽培种;羌活药材挥发油含量随海拔升高而增加。 相似文献
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The relative proportions of chemical classes (hydrocarbons, oxides, alcohols/ethers, aldehydes/ketones, acids/esters/lactones) in the essential oil of lavender (Lavendula angustifolia Mill., family Lamiaceae) and bitter fennel (Foeniculum vulgare Mill. subsp. vulgare var. vulgare (Mill.) Thellung, family Apiaceae) and in the volatile fraction of infusion extracts were examined and showed remarkable differences. The volatile compounds of infusions were isolated by hydrodistillation and solid phase extraction (SPE). Their qualitative and semiquantitative compositions were compared with the essential oil isolated by hydrodistillation directly from the plant material and analyzed by GC-MS. Furthermore, quantification of the major constituents of lavender oil and of the volatile fraction obtained by hydrodistillation of the infusion was performed. Comparison of the total essential oil yield quantified by hydrodistillation of the lavender infusion (0.7% v/w, corresponding to plant material) with the essential oil yield of the blossoms (5.1% v/w) revealed that only 13.9% of the initial oil could be extracted by infusion. The main constituents of the volatile fraction of the lavender infusion were (hydrodistillation/SPE): linalool (39.3%/28.2%), 1,8 cineole (24.8%/18.9%), cis-linalool oxide (furanoid) (5.8%/8.0%), trans-linalool oxide (furanoid) (4.1%/7.1%), camphor (5.3%/4.0%) and alpha-terpineol (4.0%/3.0%). The major constituents of lavender essential oil were linalool (28.8%), 1,8-cineole (18.05%), linalyl acetate (13.9%) and alpha-terpineol (4.0%). Most intriguing, in the volatile fraction of lavender infusion a significant proportional decrease of linalyl acetate and an increase of linalool oxides was recognized. The essential oil yield of fennel fruits was 12.5% v/w, whereas 1.8% v/w volatile fraction (corresponding to plant material) was obtained by hydrodistillation of the fennel infusion, which is equivalent to 14.5% of the initial fennel essential oil. The main constituents of the volatile fraction of the fennel infusion were (hydrodistillation/SPE): trans-anethole (56.4%/54.8%), fenchone (36.2%/39.5%) and estragole (2.5%/2.2%), which were also the major compounds of the genuine bitter fennel essential oil. In infusions, the proportion of ethers vs. ketones was shifted significantly towards a higher proportion of the latter compared with the essential oil obtained from the fruits. 相似文献
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