[1]Leo P. A method of producing ingenol-3-angelate:WO,2012010172[P]. 2012-01-26.
[2]李彦赟,杨昱,孙传腾,等. 巨大戟醇甲基丁烯酸酯有关物质的合成[J]. 天津药学,2022,34(4):1-5.
[3]Rosen R H,Gupta A K,Tyring S K. Dual mechanism of action of ingenol mebutate gel for topical treatment of actinic keratoses:rapid lesion necrosis followed by lesion-specific immune response[J]. Journal of the American Academy of Dermatology,2012,66(3):486-493.
[4]Jrgensen L,McKerrall S J,Kuttruff C A,et al. 14-Step synthesis of (+)-ingenol from (+)-3-carene[J]. Science,2013,341(6148):878-882.
[5]Chen M X,Tian M,Liu F,et al. Distribution of ingenol derivatives in Euphorbia plants and UV-dependent promotion of ingenol production in greenhouse-grown Euphorbia plants[J]. Industrial Crops and Products,2021,173:114111.
[6]中国科学院中国植物志委员会. 中国植物志:第四十四卷第三分册[M]. 北京:科学出版社,1997:58-60.
[7]张笑宇,陈恩慧,李瑞,等. 铁海棠药学研究概况[J]. 安徽农业科学,2014,42(2):383-384,386.
[8]Kamurthy H,Dontha S,Rajani K.Phytochemical screening on Euphorbia milii Red flowers isolation of terpenoids,flavone and phenols[J]. American Journal of Ethnomedicine,2015,2(6):322-332.
[9]Yu H F,Cheng Y C,Wu C M,et al. Diverse diterpenoids with α-glucosidase and β-glucuronidase inhibitory activities from Euphorbia milii[J]. Phytochemistry,2022,196:113106.
[10]Liu S N,Hu J Y,Tan S H,et al. ent-Rosane diterpenoids from Euphorbia milii showing an Epstein-Barr virus lytic replication assay[J]. RSC Advances,2017,7(74):46938-46947.
[11]Kupchan S M,Uchida I,Branfman A R,et al. Antileukemic principles isolated from Euphorbiaceae plants[J]. Science,1976,191(4227):571-572.
[12]Nascimento B A,Zani C L.A simple high pressure liquid chromatographic method for the quantitative determination of the molluscicide milliamine L in the latex of Euphorbia splendens[J]. Phytochemical Analysis,1999,10(2):93-96.
[13]Shi J X,Li Z X,Nitoda T,et al. Three antinematodal diterpenes from Euphorbia kansui[J]. Bioscience,Biotechnology,and Biochemistry,2007,71(4):1086-1089.
[14]翁颖妮,朱婧,王琴波,等. 黄花倒水莲毛状根诱导及其愈伤组织总皂苷的测定[J]. 中药材,2020,43(9):2099-2102.
[15]陈宇,董瑜,张楷燕,等. 白英毛状根的培养与薯蓣皂苷元的测定[J]. 中草药,2016,47(7):1199-1203.
[16]姚庆收,陈向明,马玉娥,等. 蒙古黄芪毛状根的高效诱导及毛状根生物量和总黄酮含量的比较分析[J]. 中药材,2017,40(8):1753-1757.
[17]卢虹玉,刘敬梅,张海超,等. 甘草毛状根诱导培养及其黄酮含量检测的研究[J]. 中国药学杂志,2011,46(11):814-818.
[18]吴顺,孙建春,周凯,等. 钩藤毛状根的诱导及其钩藤碱含量的测定[J]. 北方园艺,2019(15):49-54.
[19]包京姗,张海弢,徐大卫,等. 王不留行毛状根培养体系建立及其黄酮苷的测定[J]. 中草药,2016,47(1):138-142.
[20]何凤发,田恬,王贵学,等. 不同理化因子对绞股蓝毛状根诱导的影响[J]. 中药材,2010,33(11):1675-1677.
[21]贾春秋,赵雪. 苦参毛状根的诱导培养及氧化苦参碱含量的测定[J]. 人参研究,2014,26(3):39-42.
[22]薛雯心,刘立业,袁金月,等. 党参毛状根诱导条件研究[J]. 安徽农业科学,2017,45(10):121-123,146.
[23]向倩倩,杨佳瑶,侯梓淇,等. 三叶青毛状根的诱导及其液体培养体系的研究[J]. 林业科技,2019,44(4):5-9.
[24]王丽,刘琪,宁明明,等. 龙葵毛状根诱导条件的研究[J]. 北方园艺,2015(4):107-111.
[25]刘连旺,张永清,祁建军,等. 地黄毛状根的诱导及条件优化[J]. 山东农业科学,2015,47(1):47-50.
[26]林志豪,邓钰宏,赵静. 黄瓜‘中国龙’毛状根诱导体系的建立[J]. 中国瓜菜,2016,29(2):6-9,19,3.
[27]胡菊,毛美琴,杨君,等. 4种发根农杆菌对朱砂根组培无菌叶片毛状根诱导的影响[J]. 西北植物学报,2016,36(2):411-418.
[28]李云芳. 三七细胞及毛状根液体培养的研究[D]. 大连:大连工业大学,2014:45.
[29]高帅,王洪峰,侯丽丽,等. 不同培养条件对金铁锁毛状根生长的影响[J]. 广东林业科技,2012,28(2):16-21.
[30]张弘弛,刘瑞,高志慧,等. 恒山黄芪毛状根遗传转化体系的建立及活性成分含量测定[J]. 北方园艺,2022(9):93-99.