首页 | 本学科首页   官方微博 | 高级检索  
相似文献
 共查询到18条相似文献,搜索用时 156 毫秒
1.
采用薄层层析─紫外分光光度法测定不同地区黄花蒿中的青蒿素含量,并对照测定野生与人工栽培样品,结果人工栽培的黄花蒿中青蒿素含量较野生高。  相似文献   

2.
以来源于重庆、广西、湖南、广东、江苏、陕西等省区的72分种质资源为试验材料,研究不同产地与类型及采收方法对黄花蒿中青蒿素含量的影响,为良种的选育和药材的采收提供科学的依据。结果表明:(1)早熟型与中、晚熟型青蒿素含量的差异显著,其顺序为:中熟型>晚熟型>早熟型;(2)在同一管理条件下不同茎秆颜色的青蒿素含量之间差异显著,其顺序为:白杆型>黄绿秆型>紫秆型>绿秆型;(3)不同产地的黄花蒿青蒿素含量动态变化规律一致,青蒿素含量最高时期为孕蕾期,是最佳采收期;(4)不同部位之间青蒿素含量差异显著,以叶片的青蒿素含量最高。  相似文献   

3.
黄花蒿是一种治疗痢疾的特效中药,植物体中含有丰富的精油,但其应用和生产中常有种类混杂现象,严重影响了黄花蒿为原料的药材质量。为实现黄花蒿药材快速鉴定与评价,该研究利用FTIR技术和GCMS分别对黄花蒿及其近缘种叶片原药材及挥发油成分进行了检测和鉴定。结果表明:挥发油以黄花蒿含量最高(1.86%),其次是南牡蒿、茵陈蒿、青蒿、牡蒿和艾蒿。FTIR分析结果表明,黄花蒿及其近缘种一维图谱相似,酰胺类、芳香类以及萜类化合物种类较多且含量丰富;二阶导数图谱中,黄花蒿青蒿素成分振动吸收明显增强,可以明显将黄花蒿与其混淆中区分开。GC-MS分析显示,黄花蒿与其近缘种的挥发油成分中共检测出17个共有峰,28种化学成分,均含有较高樟脑、á-杜松烯、Crocetane、植烷、2,4-二叔丁基苯酚,但不同种间成分含量差异很大,植烷在黄花蒿中含量明显高于其它近缘种,龙脑成分只能在黄花蒿叶片中检测出,然而á-雪松烯在青蒿、南牡蒿、茵陈蒿均较高,而在黄花蒿,艾蒿,牡蒿中含量均较低。最后通过聚类分析探讨了黄花蒿与其近缘种挥发油成分差异性,6种材料明显聚为2类。其中,黄花蒿与牡蒿、艾蒿聚为一类,青蒿与茵陈蒿和南牡蒿聚为一类。该研究结果为黄花蒿药材的真伪鉴别及其药材质量评价提供了快速而有效的分析手段。  相似文献   

4.
本研究运用FTIR技术,对栽培和野生黄花蒿不同部位化学成分的红外光谱特征进行指认,并比较分析两者不同部位青蒿素含量差异.结果显示:酰胺、芳香类物质均以栽培黄花蒿茎和叶片中多;可溶性多糖和糖苷类物质,栽培与野生黄花蒿茎中含量相近,但是,叶片中含量以栽培黄花蒿高;纤维素类物质,栽培茎少于野生茎,而两种黄花蒿叶片的纤维素含量相近.与青蒿素标准品比较,栽培和野生黄花蒿不同部位青蒿素含量有一定差异,其中栽培叶最高,其次是野生叶,栽培茎的含量最低.所以,运用FTIR技术可以快速判断栽培和野生型黄花蒿主要化学成分的差异,本研究对黄花蒿的引种驯化和良种选育工作有一定指导意义.  相似文献   

5.
柱前衍生-RP-HPLC法测定青蒿中青蒿素的含量   总被引:17,自引:0,他引:17  
采用柱前衍生-RP-HPLC法测定10个不同产地的青蒿药材中青蒿素的含量.采用Lichrospher 100 RP-18e(250 mm×4.6 mm,5μm,Merck KgaA,Germany)色谱柱,甲醇-0.01 mol/L醋酸钠-醋酸缓冲液(pH 5.8)(体积比62:38)为流动相;检测波长:260 nm;流速:0.5 mL/min;柱温:25℃.结果表明该法准确重现性好,可以为青蒿质量标准的制订提供科学依据.  相似文献   

6.
目的:建立快速简便检测青蒿素的超高效液相-紫外(UPLC-UV)法,并对不同产地青蒿中青蒿素的含量进行检测。方法:色谱柱Agilent Eclipse Plus C18(2.1 mm×50 mm,1.8μm),流动相乙腈/水(45/55),流速1.0mL/min,柱温28℃,波长200 nm。结果:该方法对青蒿素的分离度较好,保留时间缩短为1.5 min。并且,整个分析过程可以在2 min内完成。线性范围0.101 17~10.117μg,进样量与峰面积线性相关,A=109.4C+6.7026,R2=0.9 993(n=9),加样回收率为99.3%(RSD=2.6%,n=6)。结论:UPLC-UV法分析时间短、样品前处理简单、精密度、稳定性、加样回收率等符合分析检测要求,对于青蒿中青蒿素的含量能进行快速准确的分析。  相似文献   

7.
通过对采收后的黄花蒿植株进行适当的处理及干燥温度和贮藏时间对比试验,采用HPLC法测定,探讨提高青蒿素含量的加工新方法。结果表明:整株立式阴晾一定时间后晒干的处理随着阴晾时间的增加青蒿素含量呈抛物线状变化,4~5d最高,达显著水平,之后逐渐下降;随着干燥温度的升高青蒿素含量呈下降趋势,40℃时叶片青蒿素含量较高;随着贮藏时间的延长青蒿素含量逐渐下降,贮藏100 d后下降明显。采收后整株立式阴晾4~5 d后再晒干方法能提高黄花蒿叶片的青蒿素含量。40℃的干燥温度能使叶片中青蒿素含量损耗较少。黄花蒿叶片的保质贮藏时间约90 d。  相似文献   

8.
青蒿素是迄今为止治疗疟疾的有效成分,主要从青蒿(黄花蒿)中提取获得。然而黄花蒿中青蒿素的含量很低,难以满足临床用药需求。本文归纳并总结了近年来用于提高青蒿素产量的生物技术方法,包括提高野生青蒿中青蒿素产量、使用转基因手段提高青蒿素产量以及青蒿素在其他生物中合成等方面的研究进展,为青蒿素合成相关研究提供理论依据,开拓研究思路。  相似文献   

9.
调查和分析测定同一产区不同土壤类型的黄花蒿土壤和植株不同部位的养分含量及青蒿素含量,并对其进行相关分析和因子分析,结果表明,青蒿素含量与土壤Ca的含量有显著的正相关关系,与根N、茎N素含量以及植株地下部和地上部的N素含量比有显著的负相关关系,与茎部和叶部的N素含量比有极显著负相关关系;黄花蒿植株叶片的N含量与土壤P含量有显著的正相关关系;影响青蒿素含量的主要因子是黄花蒿植株体内的养分含量,其次是土壤的养分含量以及土壤和植株等综合因子。通过施肥、适当补充土壤中的Ca和P素营养,改善土壤养分状况等各种途径来调节植株体内的养分,降低地下部和地上部的N素含量比值,茎叶部N素含量比值,提高青蒿素的含量,增施K肥,有利于黄花蒿的生长。  相似文献   

10.
不同土壤环境对黄花蒿生长和青蒿素含量的影响研究   总被引:1,自引:1,他引:0  
通过田间小区试验,比较研究了施肥与不施肥条件下,4种土壤环境(沙土、旱地土、水稻土和棕色石灰土)对黄花蒿的生长、生物量分配和青蒿素含量的影响。结果表明:黄花蒿对土壤养分的适应性较强,在沙土、旱地土、水稻土和石灰土上均能生长发育,养分水平低时,分配更多的生物量到根,根生物量分数和根/冠比增大;养分水平高时,分配更多的生物量到叶,叶生物量分数增加。黄花蒿的生长和青蒿素含量显著受土壤养分的影响,不施肥时,石灰土和水稻土栽培黄花蒿的株高、地径、总生物量、叶生物量和青蒿素含量显著大于旱地土,而旱地土又显著大于沙土。但在施肥条件下,以上参数不同土壤间无显著差异,且显著高于不施肥。因此,只要根据土壤养分状况合理施肥,黄花蒿在不同养分土壤栽培均能获得较高的青蒿素产量。  相似文献   

11.
Artemisinin is a novel effective antimalarial drug extracted from the medicinal plant Artemisia annua L. Owing to the tight market and low yield of artemisinin, there is great interest in enhancing the production of artemisinin. In the present study, farnesyi diphosphate synthase (FPS) was overexpressed in high-yield A. annua to Increase the artemisinin content. The FPS activity in transgenic A. ennue was twoto threefold greater than that In non-transgenic A. annua. The highest artemisinin content in transgenic A. annua was approximately 0.9% (dry weight), which was 34.4% higher than that in non-transgenic A. annua. The results demonstrate the regulatory role of FPS in artemisinin biosynthesis.  相似文献   

12.
促进黄花蒿发根青蒿素合成的内生真菌诱导子的制备   总被引:7,自引:0,他引:7  
应用酸解法对黄花蒿(ArtemisiaannuaL.)内生胶孢炭疽菌(Colletotrichumgloeosporioides)菌丝体进行提取,在黄花蒿发根培养系统中比较了各制备提取物的青蒿素诱导活性。活性提取物经过SephadexG25层析后,部分纯化的内生菌寡糖提取物(MW<2500)可显著促进发根青蒿素的合成,培养23d的发根经诱导子(0.4mg/mL)处理4d后,青蒿素产量可达13.51mg/L,比同期对照产量提高51.63%,诱导作用与诱导子浓度、作用时间相关。内生菌寡糖诱导子的制备和使用,在青蒿素生物技术生产研究中为首次应用。  相似文献   

13.
Hairy root cultures of Artemisia annua L were cultivated in four different culture systems: a flask, a bubble column, a modified bubble column and a modified inner-loop airlift bioreactor. The artemisinin contents of hairy root cultures in the bubble column and the modified inner-loop airlift bioreactor were higher than that in the modified bubble column. The growth rate and hairy root distribution in the modified inner-loop airlift bioreactor were better than those in other bioreactors, and dry weight and artemisinin production reached to 26.8 g/L and 536 mg/L after 20 days.  相似文献   

14.
In this study, a liquid chromatography/diode array detector-atmospheric pressure chemical ionization/mass spectrometry (LC/DAD-APCI/MS) was successfully developed to identify and characterize the main flavonoids and caffeoylquinic acids (CQAs) of three common Compositae plants (Chrysanthemum morifolium Raman, Artemisia annua, and Chrysanthemum coronarium) which have been used as herbal medicine. Identifications were performed by comparing the retention time, UV and mass spectra of samples with standards or/and earlier publications. The crude methanolic extracts of these plants were assayed directly using LC/MS without any further pretreatment. The proposed method is rapid and reproducible and is useful for characterization and evaluation of different plant flavonoids and CQAs. A total of 41 different flavonoids and 6 CQAs were identified and confirmed by APCI-MS. The main components of three Compositae plants were also compared. Although there exist some similarities in the flavonoidic content of the leaf and flower of C. morifolium, significant variations in their varieties and concentrations were observed. Artemisia annua processes substantial amount of alkylated derivatives of flavones and Chrysanthemum coronarium contains only CQAs. These findings suggest that although all the plants studied are from the same Compositae family, their flavonoids and phenolic compositions are markedly different. The proposed method is useful for further chromatographic fingerprinting of plant flavonoids.  相似文献   

15.
氮对黄花蒿生长、光合特性和青蒿素含量的影响   总被引:2,自引:2,他引:0  
对不同氮处理黄花蒿生长、生物量分配、青蒿素含量和光合特性进行测定,结果表明:(1)供氮量在0~0.4g.kg-1之间,黄花蒿叶片单位重量的氮含量、最大净光合速率、光饱和点和表观量子效率均随供氮量的增大而增加,之后开始下降。在较大范围内,环境氮含量越高,黄花蒿的光合能力越强,能够利用的光强也更高;(2)黄花蒿根生物量分数和根冠比均随供氮量的减少而显著增大,低氮时分配更多的生物量到养分吸收器官,有利于减少氮素对生长的限制,供氮量在0.1~0.6g.kg-1之间,黄花蒿叶生物量分数随供氮量的增加而增大,高氮时更多的生物量投入到碳同化器官,提高了植株的竞争能力;(3)无论以最大净光合速率、地径、叶片生物量还是以总生物量来衡量,均以0.4g.kg-1氮处理的植株生长得最好,0.2g.kg-1氮处理的青蒿素含量最高,生产中推荐使用0.2g.kg-1剂量的氮更经济。  相似文献   

16.
青蒿提取物抗单纯疱疹病毒活性研究   总被引:5,自引:1,他引:4  
用细胞病变效应(CPE)法证明了青蒿水提物具有抗单纯疱疹病毒Ⅱ型(HSV—2)活性,通过初步分离纯化得到抗HSV—2活性的有效成分。用MTT法研究了青蒿水提物和有效成分的细胞毒性和抗HSV—2活性,CC50分别为5.29mg/ml和4,94mg/ml,IC50分别为1.45mg/ml和0.128mg/ml,TI分别为3.65和38.6。以0.5mg/ml的无环鸟苷(ACV)作为阳性对照,结果显示有效成分在体外可以明显抑制HSV—2的致细胞病变作用,效果与ACV相当。  相似文献   

17.
不同种源黄花蒿生长及生物量分配   总被引:1,自引:0,他引:1  
对都安、崇左、阳朔和融安县四个不同种源黄花蒿的生长发育状况和生物量分配进行比较,结果表明:黄花蒿的生长旺盛期是在5月底至7月初,6月中旬为生长的高峰期,这段时期内应施以重肥;不同种源黄花蒿各功能构件生物量平均值具有相同的规律:茎构件>叶构件>根构件;都安种源的叶构件生物量和青蒿素含量均比其它种源的高,综合表现最优,是引种栽培的好种源。  相似文献   

18.
A simple TLC-densitometric technique has been developed for the rapid and accurate analysis of artemisinin in a large number of Artemisia annua plantlets cultured in vitro. This new analytical method is based on the structural conversion of artemisinin on a silica gel layer by ammonia vapour to form 10-azadesoxyartemisinin, a chromophore-containing compound (lambdamax 320 nm) that can be detected by UV-based TLC densitometry. The TLC system was evaluated quantitatively in terms of product stability, precision, accuracy and calibration. Good linearity was obtained in the range of 0.01-0.12 microg artemisinin. The technique appeared to be accurate and sensitive as compared with the complicated pre-column reaction-HPLC technique. Among 90 samples of A. annua plantlets, the artemisinin content in the leaves appeared to be highly variable, ranging from 0.02 to 0.67% w/w dry weight. These results demonstrate that densitometric TLC can be a cheap and simple technique for the accurate screening of high-artemisinin-producing plants.  相似文献   

设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号