猪去氧胆酸化学 8:锇催化不对称双羟化合成 (24R,25R)-24,25,26-三羟基胆固醇

本文报道应用锇催化不对称双羟化对甾体化合物侧链三取代双键的反应合成得光学纯3a和3b,(3a∶3b=6.5:1),收率分别为71％和11％.从3a经五步反应合成新的维生素D_3类似物的关键中间体(24R,25R)-243 25,26-三羟基胆固醇(10).     

猪去氧胆酸化学 8:锇催化不对称双羟化合成 (24R,25R)-24,25,26-三羟基胆固醇

本文报道应用锇催化不对称双羟化对甾体化合物侧链三取代双键的反应合成得光学纯3a和3b,(3a:3b=6.5:1),收率分别为71%和11%.从3a经五步反应合成新的维生素D~3类似物的关键中间体(24R,25R)-24,25,26-三羟基胆固醇(10).     

1α,25-双羟基维生素D_3的合成研究——从猪去氧胆酸甲酯合成25-羟基胆固醇

25-羟基维生素D_3(1)和1α,25-双羟基维生素D_3(2)是维生素D_3(3)在体内的两个重要代谢产物。2是目前所知生理活性最强的维生素D.1和2可治疗软骨病,特别用于对肝脏、肾脏功能不全的维生素D缺乏症。最近日本Kureha公司报道,它们还具有抑制白血病细胞和骨髓肿瘤细胞生长的作用。25-羟基胆固醇(4)是合成1和2的关键中间体。文献已有许多关于它的合成报道。     

甾体植物生长促进剂合成的研究VII: 从猪去氧胆酸合成Zα, 3α-双羟基-7-氧杂-6-酮-23,24-双失碳-B-高碳-5α-胆甾酸和2α, 3α-双羟基-7-氧杂-6-酮-24-失碳-B-高碳-5α-胆甾醇

从猪去氧胆酸经一系列化学反应制得两个油菜甾醇内酯类似物.2α, 3α-双羟基-7-氧-6-酮-23,24,-双失碳B-高碳-5α-胆烷酸和2α, 3α-双羟基-6-酮-24-失碳-B-高-7-氧-5α-胆烷酸.     

25-羟基胆固醇的合成及路线优化

以猪去氧胆酸为起始原料,经酯化、上保护、还原、氧化、缩合、水解、酯化、环氧化、还原等九步反应,制备25-羟基胆固醇,总收率30%。目标产物结构经¹HNMR和¹³CNMR鉴定。     

1,3-双[3-(1-甲氧基-2-羟基丙氧基)丙基]封端聚硅氧烷的合成

以1,3-双[3-(1-甲氧基-2-羟基丙氧基)丙基]四甲基二硅氧烷和八甲基环四硅氧烷(D4)为原料,通过阳离子催化开环聚合制备了1,3-双(3-(1-甲氧基-2-羟基丙氧基)丙基)封端聚硅氧烷,研究了反应温度,反应时间,催化剂种类及加入量对于聚合反应的影响,结果表明,最佳反应条件为:反应温度65℃,反应时间24h,浓硫酸作为催化剂加入量为反应物质量的0.3%,此时反应拥有最高的转化率。通过红外光谱与核磁共振光谱对产物进行了表征。     

(R)-3,3-二甲基-2-羟基-4-氧代丁酸乙酯的不对称合成

研究了异丁醛与乙醛酸乙酯不对称羟醛缩合反应合成(R)-3,3-二甲基-2-羟基-4-氧代丁酸乙酯,考察了催化剂种类及用量、反应时间、反应溶剂对羟醛缩合反应的影响。确定较佳反应条件为:L-组氨酸作催化剂,用量为乙醛酸乙酯物质的量的30%,乙二醇为溶剂,反应时间24h。(R)-3,3-二甲基-2-羟基-4-氧代丁酸乙酯的收率达75%,ee值为73%。产物结构经1H NMR,GC-MS进行了表征。     

从(-)-莽草酸出发合成(3R,5R)-3,4,5-三苯甲酰氧基环己酮

报道了一种合成手性中间体(3R,5R)-3,4,5-三羟基环己酮的新方法。首次以(-)-莽草酸为起始原料,经苯甲酰化、双键氢化、选择性还原甲酯、羟基碘代、碘代烃消除、双键双羟化、片哪醇断裂等步骤,以44.9%的总收率合成了(3R,5R)-3,4,5-三苯甲酰氧基环己酮,所有化合物的结构经¹H NMR、 ¹³C NMR、 IR及MS等确证。      

液相色谱-串联质谱法检测干血点样本中25-羟基维生素D2和25-羟基维生素D3

建立了一种高通量液相色谱-串联质谱技术检测干血点(DBS)样本中25-羟基维生素D2[25(OH)D2]和25-羟基维生素D3[25(OH)D3]的方法.以DBS为样本,以4-苯基-1,2,4-三唑啉-3,5-二酮(PTAD)为试剂进行分析物衍生化,所需样本量仅约相当于6μL全血当量的DBS样本;使用甲醇直接超声提取分析物,避开了通常情况下DBS样本前处理中的全血复溶和蛋白质沉淀等繁琐步骤;整个前处理过程使用自动化液体处理平台实现自动化操作和高检测通量;以25(OH)D2-D6和25(OH)D3-D3为同位素内标,消除基质效应的影响.前处理后的样本进行LC-MS/MS分析,使用C18柱进行分离,流动相为甲醇(含5 mmol/L甲酸铵)-水(含5 mmol/L甲酸铵)(75:25,V/V),洗脱时间为4 min,使用多反应监测模式(MRM)定量.结果表明:25(OH)D2和25(OH)D3的检出限为0.12 ng/mL(S/N=3),定量限为0.94 ng/mL(S/N=10).25(OH)D2和25(OH)D3在0.94~120.00 ng/mL范围内线性关系良好,日内相对标准偏差(RSD)分别为1.4%~8.6%和3.7%~15.5%,日间RSD分别为4.0%~5.3%和3.8%~14.9%,平均回收率分别为91.7%±7.9%~108.5%±6.5%和94.8%±6.8%~101.3%±2.9%.DBS样本在不同温度(-20℃,22℃,37℃)下储存不同时间(0,1,2,3,5,7,14天)后的稳定性实验显示样本总体RSD°15%.以25(OH)D参考物质NIST SRM 972a中的Level 3制备标准DBS样本,25(OH)D2和25(OH)D3的回收率分别为110.3%和103.0%.     

25,26,27-三失碳-B-高-7-氧-6-酮-5α-胆甾-3α,24-二醇的合成

本文报道以3α-羟基-6-羰基-5α-胆烷酸甲酯(3)为原料经六步反应合成了油菜甾醇类似物25,26,27-三失碳-B-高-7-氧-6-酮-5α-胆甾-3α,24-二醇(9a).总产率14%.9a的促进植物生长作用是24-表油菜甾醇内酯的60%.     

Catalytic rearrangement of 1,2-orthoacetates of α-D-glucose and 20(S), 24(R)-epoxydammarane-3,12β,25-triols. I

The catalytic rearrangement of 20(S),24(R)-epoxydammarane-3,12β,25-triol 3-mono and 3,12-di(α-D-glucose 1,2-orthoacetate)s leads to the formation of the corresponding 12-mono- and 12,25-diglucosides. The anomalous regioselectivity of the catalytic rearrangements of orthoesters of 20(S),24(R)-epoxydammarane-3,12β,25-triols is evidently due to the influence of strong intramolecular hydrogen bonds. Details of the IR, PMR, and¹³C NMR spectra, and also the physicochemical constants, of the newly obtained compounds are given.     

从(-)-α-蒎烯合成(IR,3R)-(+)-反式菊酸甲酯

报道了以(-)-α-蒎烯为主要成分的松节油作原料,通过十四步反应合成了(1R,3R)-(+)-反式菊酸甲酯,每步反应的得率都在60%以上,总得率10.8%.反应操作方便,条件温和,对合成路线中的有些反应作了一些比较和讨论.化合物3-9都是新化合物.     

C-24 stereochemistry of marine sterols: (22E)-24-(isopropenyl)-22-dehydrocholesterol and 24-isopropenylcholesterol

The C-24 configuration of (22E,24xi)-24-isopropenyl-22-dehydrocholesterol (1), which was recently isolated from the Colombian Caribbean sponge, Topsentia ophiraphidites, was investigated. Synthesis of the stereodefined (24R)- and (24S)-(22E)-24-isopropenyl-22-dehydrocholesterols (1a, 1b) followed by (1)H- and (13)C-NMR data comparison of these sterols established the (24R)-configuration of 1. In addition, (24R)- and (24S)-24-isopropenylcholesterols (2a and 2b) were also synthesized and their NMR data are provided. The C-24 configurations of the samples of 24-isopropenylcholesterol reported previously are discussed.     

Glycosylation of triterpenoids of the dammarane series I. 20(S),24(R)-epoxydammarane-3α-12β,25-triol 25-O-β-D-glucopyranoside

The glycosylation of 3,12-diacetoxy-20(S),24(R)-epoxydammaran-25-ol with -acetobromoglucose under the conditions of Helferich's modification and with D-glucose tert-butyl orthoacetate under the conditions of the orthoester method gives a high yield (60–64%) of the hexacetate of the -D-glucoside at the tertiary hydroxy group of 20(S),24(R)-epoxydammarane-3,12,25-triol (III) with mp 207–209°C (ethanol), [] _D ²⁰ -20.9 (c 1.0, CHCl₃). Saponification with 10% KOH in methanol gives the free 20(S),24(R)-epoxydammarane-3,12,25-triol 25-O--D-glucoside (V) (yield 90%) with mp 275–279°C (methanol), [] _D ²⁰ +11.4° (c, 1.0, C₅H₅). The results of IR and¹H and¹³C NMR spectroscopy and of elementary analysis are given.Pacific Ocean Institute of Bioorganic Chemistry of the Far Eastern Scientific Center, Academy of Sciences of the USSR, Vladivostok. Translated from Khimiya Prirodnykh Soedinenii, No. 2, pp. 205–208, March–April, 1980.     

Syntheses of the C(1-6) and C(19-24) fragments of lituarines A, B, and C

[structure: see text] Lituarines A-C are marine natural products comprising a tricyclic spiroacetal bridged at C(8) and C(18) by a functionalized ester linkage conceptually obtained from a C(19-24) alcohol and a C(1-6) carboxylic acid whose oxidation level varies at C(4) and C(5). Stereoselective routes are described to compounds 26 and 27, fully functionalized ester fragments of lituarine A and lituarines B and C, respectively.     

Glycosylation of triterpenoids of the dammarane series. IX. β-D-glucopyranosides of 20(S),24(R)-epoxydammarane-3α,12β,17α,25-tetraol 25-tetraol

Glycosides have been synthesized from 20(S),24(R)-epoxy-dammarane-3α,12β,17α, 25-tetraol, which was isolated from the leaves ofBetula costata. Exhaustive glycosylation of betulafolienetetraol oxide with α-acetobromoglucose in the presence of mercury cyanide gave an acetylated 3,12,25-triglucoside (yield 61%), while glycosylation in the presence of insoluble silver compounds led to the formation of 3- and 12-mono- and 3,12- and 12,25-diglucopyranosides (total yield 57–82%). The structures of the glucosides obtained have been established on the basis of the results of IR and¹H and¹³C NMR spectroscopy.     

Determination of (S)-(-)-cathinone and its metabolites (R,S)-(-)-norephedrine and (R,R)-(-)-norpseudoephedrine in urine by high-performance liquid chromatography with photodiode-array detection.

A high-performance liquid chromatographic (HPLC) procedure with photodiode-array detection (DAD) is described for the determination of (S)-(-)-cathinone (S-CA) and its metabolites (R,S)-(-)-norephedrine (R-NE) and (R,R)-(-)-norpseudoephedrine (R-NPE) in urine. Extraction and clean-up of 1-ml urine samples were performed on a cyano-bonded solid-phase column using (+/-)-amphetamine as internal standard. The concentrated extracts were separated on a 3-microns ODS-1 column with acetonitrile-water-phosphoric acid-hexylamine as the mobile phase. Peak detection was done at 192 nm. The detection limits for S-CA and R-NE/R-NPE in urine were 50 and 25 ng/ml, respectively. The differentiation of the enantiomers of cathinone and norephedrine was achieved by derivatization with (S)-(-)-1-phenylethyl isocyanate to the corresponding diastereomers followed by HPLC-DAD on a 5-microns normal-phase column. The R and S enantiomers of norpseudoephedrine were determined by gas chromatography-mass spectrometry after on-column derivatization with (S)-(-)-N-trifluoroacetylprolyl chloride. Following a single oral dose of 0.5 mg/kg of S-CA, the concentrations found in urine ranged from 0.2 to 3.8 micrograms/ml of S-CA, from 7.2 to 46.0 micrograms/ml of R-NE and from 0.5 to 2.5 micrograms/ml of R-NPE.     

Alpha-hydroxylation at C-15 and C-16 in cholesterol: synthesis of (25R)-5alpha-cholesta-3beta,15alpha,26-triol and (25R)-5alpha-cholesta-3beta,16alpha,26-triol from diosgenin

[reaction: see text] (25R)-5alpha-cholesta-3beta,16alpha,26-triol 7b and (25R)-5alpha-cholesta-3beta,15alpha,26-triol 10b were synthesized, via (25R)-5alpha-cholesta-3beta,16beta,26-triol 5a, from diosgenin 3 in 52% yield over six steps and 47% yield over eight steps, respectively. An efficient method for inversion of a C-16beta hydroxyl to the C-16alpha position and a short method for transposition of a C-16beta hydroxyl to the C-15alpha position via the unexpected beta-reduction of a C-15 ketone in a steroid are reported.     

合成(R)-2-异戊氧基丙醇的新方法

以(R)-1,2-丙二醇为原料,经伯醇羟基保护、仲醇O-异戊基取代、脱羟基保护三步反应合成了手性醇(R)-2-异戊氧基丙醇,其结构经NMR和MS确证.