由2',4'-二氢-6'-甲氧基-3',5'-二甲基查耳酮合成新黄酮

在DMSO/ I2的氧化作用下,由2',4'-二氢-6'-甲氧基-3',5'-二甲基查耳酮可合成一种全新结构的黄酮:7-羟基-5-甲氧基-6,8-二甲基黄酮(产率91%),而在HCl/MeOH作用下则得到了两种黄烷酮:7-羟基-5-甲氧基-6,8-二甲基黄烷酮 (产率70%) 和 5,7-二羟基-6,8-二甲基黄烷酮 (产率20%).     

由2′,4′-二氢-6′-甲氧基-3′,5′-二甲基查耳酮合成新黄酮

在DMSO/I2的氧化作用下,由2′,4′-二氢-6′-甲氧基-3′,5′-二甲基查耳酮可合成一种全新结构的黄酮:7-羟基-5-甲氧基-6,8-二甲基黄酮(产率91%),而在HCl/MeOH作用下则得到了两种黄烷酮:7-羟基-5-甲氧基-6,8-二甲基黄烷酮(产率70%)和5,7-二羟基-6,8-二甲基黄烷酮(产率20%)。     

细穗玄参的化学成分

细穗玄参(Scrofella chinensis Maxim)为玄科细穗玄参属独种植物,它是我国特有种,被用作传统中药.从细穗玄参全草中分离并鉴定了7个化合物.利用光谱(MS、NMR、UV)和化学方法分别鉴定为对苯酚(t),对甲氧基苯甲酸(2),5,7,3＇-三羟基-4-甲氧基黄酮(3),3,7-二羟基5,4＇-二甲氧基黄酮(4),5,6,7-三羟基-4＇-甲氧基黄酮(5),熊果甙(6),玉叶金花糖甙酸(7).7个化合物均为首次从该植物中发现.     

铁杆蒿化学成分研究

从铁杆蒿中分离并经光谱方法鉴定出17种化合物,其中5,8,3',5'-四羟基双氢黄酮(1)、5,8,2'-三羟基-5'-甲氧基双氢黄酮(2)、5,7,4'-三羟基-3',5'-二甲氧基双氢黄酮(3)和3-(3-羟基苯氧基)-2-丙烯醛(6)为新化合物.     

黄酮类化合物研究(Ⅷ)——7-取代黄酮及2'''',4-二羟基-3-甲氧基-4''''-取代查尔酮的合成

3,4′,7-三羟基黄酮和3,3′,4′,7-四羟基黄酮是中草药舒冠通糖浆的主要成份,该药对冠心病、心绞痛、胸闷有一定疗效。为系统研究黄酮类化合物的构效关系,我们在前文基础上又合成了5个新的4′-羟基-7-取代黄酮及5个3′-甲氧基-4′-羟基-7-取代黄酮。在此过程中,又合成了4个新的2′,4-二羟基-3-甲氧基-4′-取代查尔酮。其合成路线如下:     

5，3’，4’—三羟基—6，7—二甲氧基黄酮的另法全合成

从两个易得原料3，4，5—三甲氧基苯甲酸和3，4-二羟基苯甲醛出发，分别合 成出2—羟基4，5，6—三甲氧基苯乙酮和3，4-二苄氧基苯甲酰氯，随后采用相转 移催化法成功地全合成了5，3’，4’—三羟基—6，7—二甲氧基黄酮。     

大叶桉化学成分的研究 - 大叶桉酚乙和其它成分的分离和鉴定

从大叶桉叶的乙醇提取物中分离并鉴定出九种已知成分:5-羟基-4',7-二甲氧基6,8-二甲基黄酮,4',5-二羟基-7-甲氧基6,8-二甲基黄酮,3β-羟基-乌索-11-烯-28,13β-内酯,13β-乙酰氧基-乌索-11-烯-28,13β-内酯;3β,28-二羟基-乌索-12-烯,β-谷甾醇,2-甲基5,7-二羟基-苯骈吡喃酮-7β-葡萄糖苷,正卅烷醇和正卅烷酸,另外,分得一种新的酰基间苯三酚类成分,命名为大叶桉酚乙,其结构为2-甲氧基-4,6-二羟基异丁酰基苯,并进行化学合成确证,大叶桉酚乙在管碟法中对金黄色葡萄球菌和枯草杆菌有抑菌作用。     

高效液相色谱-电喷雾质谱联用测定黄芪黄酮苷酶解产物

高效液相色谱-电喷雾质谱(HPLC-ESI-MS)联用分析黄芪中的黄酮类化合物结果表明黄芪黄酮提取物主要包含毛蕊异黄酮-7-O-β-D-葡萄糖苷、芒柄花苷、9, 10 -二甲氧基紫檀烷-3-O-β-D-葡萄糖苷以及2'-羟基-3',4'-二甲氧基异黄烷-7-O-β-D-葡萄糖苷等黄酮苷,黄芪黄酮提取物经过β-葡萄糖苷酶(1 IU/mL)粗酶液酶解后,HPLC-ESI-MS分析酶解生成产物主要为黄酮苷元毛蕊异黄酮、芒柄花素、3-羟基-9,10 -二甲氧基紫檀烷以及7, 2'-二羟基-3',4'-二甲氧基异黄烷.其中前两种主要的黄酮苷酶解率均达90%以上.酶解后所得产物对DPPH自由基清除率是酶解前的1.4倍.因此,通过β-葡萄糖苷酶水解可以有效地将黄芪黄酮转化为相应的黄酮苷元,大大提高黄芪黄酮提取物的抗氧化活性.     

天然产物Combretastatin A-1和Combretastatin B-1的合成

基于Perkin反应策略合成了具有强效抗肿瘤、抗血管活性的天然产物Combretastatin A-1(CA1)和Combretastatin B-1(CB1).以2,3,4-三羟基苯甲醛(1)为起始物, 经单甲基化反应得到2,3-二羟基-4-甲氧基苯甲醛(2), 再经酚羟基保护得到2,3-二异丙基-4-甲氧基苯甲醛(3), 该化合物与3,4,5-三甲氧基苯乙酸(4)发生Perkin反应分离得到E-2-(3,4,5-三甲氧基苯基)-3-(2',3'-二异丙氧基-4'-甲氧基)丙烯酸(E-5), 经脱羧反应得到Z-3,4,4',5-四甲氧基-2',3'-二异丙氧基二苯乙烯(6), 最后经脱保护反应得到CA1.另外, 将E-2-(3,4,5-三甲氧基苯基)-3-(2',3'-二异丙氧基-4'-甲氧基)丙烯酸(E-5)脱去保护基得到E-2-(3,4,5-三甲氧基苯基)-3-(2',3'-二羟基-4'-甲氧基)丙烯酸(7), 该化合物经脱羧-异构化反应得到E-3,4,4',5-四甲氧基-2',3'-二羟基二苯乙烯(E-CA1), 最后经催化氢化得到CB1.     

诱导根癌农杆菌vir区基因表达水稻代谢物的分离,鉴定和生物活性研究

从孕穗期至开花期水稻(oryza sative L. cv. lndia IR 72)的茎叶提取液中, 筛选并分离出二种能高效诱导根癌农杆菌(Agrobacterium tumfaciens) vir 区基因表达的信号分子,这两种信号分子的化学结构分别是5,7,4'-三羟基-3'-5'-二甲氧基黄酮和5,4'-二羟基-3',5'-二甲氧基-7-β-D-葡萄糖氧基黄酮.     

Active Chemical Constituents from Sauropus androgynus

This paper describes the chemical investigation on BuOH-soluble EtOH extract from the aerial part of Sauropus androgynus. This study led to the characterization of six bioactive ingredients including three nucleosides—adenosine (1), 5′-deoxy-5′-methylsulphinyl-adenosine ( 2 ), and uridine ( 3 ), two flavonol dioside — 3-O-β-D-glucosyl-7-O-α-L-rhamnosyl-kaempferol ( 4 ), 3-O-β-D-glucosyl-(1→6)-β-D-glucosyl-kaempferol ( 5 ), and one rare flavonol trioside — 3-O-β-D-glucosyl-(1→6)-β-D-glucosyl-7-O-α-L-rhamno-syl-kaempferol ( 6 ). Their structures were determined on the basis of spectral analysis.     

A new isorhamnetin glycoside and other phenolic compounds from Callianthemum taipaicum

A new flavonol glycoside together with five known phenolic compounds were isolated from the whole herb of Callianthemum taipaicum. The compounds were identified as isorhamnetin-3-O-α-L-arabinoside-7-O-β-D-glucoside (1), isorhamnetin-3-O-β-D-glucoside (2), dibutyl phthalate (3), (+)-1-hydroxylpinoresinol-4'-β-D-glucoside (4), pinoresinol-4'-O-β-D-glucoside (5) and 2-phenylethyl-β-primeveroside (6). Compound 1 was identified as a new flavonol glycoside. The compound 6 was isolated for the first time as natural product. All compounds were isolated for the first time from the Callianthemum genus. Furthermore, the 2D-NMR data of the four known compounds 2-5 are given for the first time in this paper. All the structures were identified on the basis of detailed spectral analysis. The compounds 1 and 4 exhibited certain antifungal activity.     

Inhibitory effects of constituents from Euphorbia lunulata on differentiation of 3T3-L1 cells and nitric oxide production in RAW264.7 cells

A new flavonol galactopyranoside, myricetin 3-O-(2',3'-digalloyl)-β-D-galactopyranoide (1), and 23 known constituents, including myricetin 3-O-(2'-galloyl)-β-D-galactopyranoide (2), myricitrin (3), myricetin (4), quercetin 3-O-(2', 3'-digalloyl)-β-D-galactopyranoide (5), quercetin 3-O-(2'-galloyl)-β-D-galactopyranoide (6), hyperin (7), isoquercetrin (8), quercetin (9), kaempferol (10), apigenin (11), luteolin (12), 3-O-methylquercetin (13), 5,7,2',5'-tetrahydroxyflavone (14), 1,3,4,6-tetra-O-galloyl-β-D-glucose (15), 1,2,6-tri-O-galloyl-β-D-glucose (16), 1,3,6-tri-O-galloyl-β-D-glucose (17), gallic acid (18), protocatechuic acid (19), 3,4,5-trimethoxybenzoic acid (20), 2,6-dihydroxyacetophenone (21), 3,3'-di-O-methylellagic acid (22), ellagic acid (23) and esculetin (24) were isolated from Euphorbia lunulata Bge. Their structures were determined by spectroscopic analysis. Isolated hydrolysable tannins, flavonoids, and flavonol galactopyranoside gallates showed significant inhibition of the differentiation of 3T3-L1 preadipocytes and triglyceride accumulation in maturing adipocytes, and nitric oxide production in RAW 264.7 cells.     

Cochinchin from Dracaena cochinchinensis

A new compound, Cochinchin (1), together with 7,4‘-dihydroxyflavone (2), 7-hydroxy-4‘-methoxyflavane (3),7-hydroxy-3-(4-hydroxybenzyl)chroman (4), 4‘-hydroxy-2,4-dirnethoxydihydrochalcone (5) and 4‘-hydroxy-2,4,6-trimethoxydihydrochalcone (6) was isolated from the resin (trivial name, “dragon‘s blood“) of Dracaena cochinchinensis (Lour.) S. C. Chert. The structure of 1 was elucidated on the basis of spectroscopic data as (2,3-trans)-6-allyl-2-(3,5-dimethoxyphenyl)-3-(4-hydroxyphenyl)-2,3-dihydrobenzo[1,4]dioxin which is a natural product possessing a new framework.     

STRUCTURAL STUDY OF GORGOSTEROL FROM SOFT CORAL

<正> The title compound was isolated from the Lobophytum Chevalieri soft coral of the South China Sea and identified by X-ray diffraction to be (22R,23R,24R)-22,23-methylene-23,24-dimetylcholest-5-en- 3β - ol. The crystal is monoclinic space group P21, a=9. 666(3) ,b=7. 503(2),c= 37. 108(4) A ,β=91. 30(2)°,V = 2690. 7 A3,Z = 4,and Dc= 1. 076gcm-3. The structure was solved by direct methods and refined to R=0. 084 for 4147 observed MoKa reflections. There are two independent molecules in each asymmetric unit which have the same orientation. The intermolecular hydrogen bonds between water molecule and hydroxy as well as between hydroxy groups link the molecules into infinite double layers which are parallel with the (001) plane.     

A study of the claisen rearrangement of 7-cinnamyloxy benzo-γ-pyrones

The Claisen rearrangement of 7-O-cinnamyl noreugenin (2) yields 4′,5′ - dihydro - 5 - hydroxy - 2,4′ - dimethyl - 5′ - phenyl - furo (2′,3′: 7,8) chromone (6) as established by its NMR spectrum, whereas that of 7-cinnamyloxyflavone (10a) and 5 - hydroxy - 7 - cinnamyloxy - 2 - methylisoflavone (10b) afford the corresponding furo derivatives (12a and 12b respectively). All these rearrangements are symmetry-allowed but are accompanied by further reactions of thermal cyclisation via 3-membered cyclic intermediate (5) and/or dehydrogenation.     

Structural characterization of flavonol 3,7-di-O-glycosides and determination of the glycosylation position by using negative ion electrospray ionization tandem mass spectrometry

Flavonol 3,7-di-O-glycosides were investigated by negative ion electrospray ionization tandem mass spectrometry using a quadrupole linear ion trap (LIT) mass spectrometer. The results indicate that the fragmentation behavior of flavonol 3,7-di-O-glycosides is substantially different from that of their isomeric mono-O-diglycosides. In order to characterize a flavonoid as a flavonol 3,7-di-O-glycoside, both [Y3(0) - H]-* and [Y(0) - 2H]- ions should be present in [M - H]- product ion spectrum. The MS(3) product ion spectra of Y3(0)-, [Y3(0) - H]-* and Y7(0)- ions generated from the [M - H]- ion provide sufficient structural information for the determination of glycosylation position. Furthermore, the glycosylation positions are determined by comparing the relative abundances of Y3(0)- and Y7(0)- ions and their specific fragmentation patterns with those of flavonol mono-O-glycosides. In addition, a [Y3(0) - H]-* ion formed by the homolytic cleavage of 3-O glycosidic bond with high abundance points to 3-O glycosylation, while a [Y(0) - 2H]- ion formed by the elimination of the two sugar residues is consistent with glycosylation at both the 3-O and 7-O positions. Investigation of negative ion ESI-MS(2) and MS(3) spectra of flavonol O-glycosides allows their rapid characterization as flavonol 3,7-di-O-glycoside and their differentiation from isomeric mono-O-diglycosides, and also enables their direct analysis in crude plant extracts.     

细枝岩黄芪根部中的三个新的异戊烯基呋喃异黄酮

岩黄芪属植物中的多序岩黄芪作为传统中药“红芪”有着广泛的药用价值,而同属的红花岩黄芪也报道具有良好的药用活性。我们对该属中的细枝岩黄芪根部的化学成份进行了研究,从中分离得到了三个新的异戊烯基呋喃异黄酮,分别为：5-羟基-7-(2-羟基异丙基)-4′-甲氧基-9-苯并呋喃[3,2-g]异黄酮(1),5-羟基-4′-甲氧基-9-苯并呋喃[3,2-g]异黄酮(2),5-羟基-7-(2-羟基异丙基)-4′-甲氧基-7-苯并呋喃[2,3-h]异黄酮(3),并对这三个新化合物的清除自由基能力进行了测试。     

Synthesis of the metabolites of oxapadol,a new non-narcotic analgesic agent

Different metabolites (2-7) of oxapadol 1 were carried out from 3 by known methods. Their acidic hydrolysis provided compounds 4 in which the dioxolane moiety was opened. The reaction of glycerol with compounds 3 gave the dioxolane derivatives 5 which have a hydroxymethyl group and which (R = H) gave by oxidation the carboxylic acid 7. From 3 (R = H), the hydroxy acid 6 has been also prepared.     

Flavonol glycosides from Epimedium pubescens

Five new flavonol glycosides (1, 3, 5-7) were isolated from the aerial parts of Epimedium pubescens Maxim., along with two known compounds, sagittasine C (2) and 4',5-dihydroxyl-8-(3,3-dimethylallyl)-flavonol 3-O-[β-D-xylopyranosyl(1→3)-4-O-acetyl-α-L-rhamnopyranoside]-7-O-β-D-glucopyranoside (4). The structures were elucidated on the basis of their 1D-, 2D-NMR, MS, UV and IR spectra data.