有机相酶催化氨解反应拆分制备(R)-4-氯-3-羟基丁酸乙酯

通过脂肪酶催化的氨解反应拆分4-氯-3-羟基丁酸乙酯. 经过对脂肪酶及反应溶剂的筛选, 确定最佳脂肪酶及溶剂分别为Novozym435和二氧六环; 并在该反应体系中考察了温度、底物浓度、酶浓度与摇床转速对反应的影响. 综合考虑反应的反应速度和对映体选择率, 确定较佳的反应条件为: 温度30 ℃、底物浓度0.5 mol/L、酶量10 mg/mL、摇床转速200 n/min. 反应35 h后, ee可以达到99%以上, 此时转化率为57.7%.     

新型酰基供体用于酶法动力学拆分制备(R)-1-(2-萘基)乙胺的研究

首次成功实现了光学纯(R)-1-(2-萘基)乙胺的高效酶法动力学拆分制备,考察了脂肪酶种类、溶剂、酰基供体、底物浓度、反应温度等对拆分效果的影响,发现新型酰基供体——正戊酸对氯苯酯能够很好地抑制非酶促自催化酰胺化效应.在甲苯溶剂中,底物浓度300 mmol/L,40℃条件下,采用该供体在脂肪酶Novozym 435催化下,动力学拆分反应8 h转化率达到理论最佳值50%,eep>99%.     

有机相中α-氰基-3-苯氧基苄醇乙酯的酶促不对称醇解反应

研究了有机相中脂肪酶催化α-氰基-3-苯氧基苄醇乙酯(CPBAc)的不对称醇解反应,制备了S-α-氰基-3-苯氧基苄醇(S-CPBA).以脂肪酶Lipase AS 为催化剂,四氢呋喃为反应介质,甲醇为酰基受体,对反应过程的各种影响因素进行了研究.得到该酶反应的较适反应条件为:温度为35～45℃,脱水溶剂加水量为0%～1%,摇床转速大于200 r/min,酯醇摩尔比大于1:0.5,CPBAc为337.08mmol/L时需要10me/mL的酶量.然后对底物和产物抑制、产物稳定性以及酶的重复利用进行了研究.对酶催化反应过程的详细考察表明,在200g/L的底物浓度下反应依然可以高效进行,反应约33 h,S-CPBA转化率可达49%左右,ee大于98%,剩余底物R-CPBAc的ee也大于95%.最后进行了反应放大实验,取得了较好的实验结果.     

有机相中脂肪酶催化合成乳酸乙酯

 考察了在双底物抑制下脂肪酶催化合成乳酸乙酯,最佳溶剂为叔丁醇,在所选的几种脂肪酶中,固定化于大孔丙烯酸树脂的南极假丝酵母脂肪酶B (Novozym 435)的催化活性最好. 对反应条件进行了优化,当酸醇摩尔比为1∶8, 反应温度60 ℃, 酸浓度0.3 mol/L, 酶浓度45 g/mol, 摇床转速200 r/min时产率达到77%, 脂肪酶Novozym 435重复使用6次后产率仍然可达到60%.     

离子液体中脂肪酶催化拆分外消旋烯丙酮醇反应

 以离子液体为溶剂,考察了溶剂类型、水活度、温度、 pH值和共溶剂等因素对脂肪酶催化拆分外消旋烯丙酮醇(R,S)-4-羟基-3-甲基-2-(2-丙烯基)-2-环戊烯-1-酮反应的影响,并与常用于外消旋烯丙酮醇拆分的有机溶剂乙酸乙烯酯进行了比较. 结果表明,在离子液体［bmim］PF6中脂肪酶的催化性能较好,酶初始反应速率为18.48 μmol/(g·min), 半衰期为74.53 h, 高于在乙酸乙烯酯中的相应值(9.18 μmol/(g·min)和64.29 h). 但离子液体中拆分反应的转化率低于在乙酸乙烯酯中的转化率,可以通过向离子液体中补加酰基供体来提高外消旋烯丙酮醇的转化率. 两种反应介质中最佳酶反应条件均为水活度0.17, 温度40 ℃和pH=7, 但加入共溶剂后,离子液体中脂肪酶催化拆分外消旋烯丙酮醇的效率降低,而在乙酸乙烯酯中则有所提高.     

有机相中α-氰基-3-苯氧基苄醇乙酯的酶促醇解反应

研究了有机相中脂肪酶催化α-氰基-3-苯氧基苄醇乙酯的醇解化反应。制备α -氰基-3-苯氧基苄醇。考察了酶、溶剂、醇、醇用量、溶剂水含量以及底物浓度等 因素对反应的影响，结果表明Novozym435脂肪酶催化活性最高，经实验确定的最佳 条件为：脱水甲苯为溶剂，正辛醇为酰基受体，正辛醇、酯的摩尔比为1.5:1，酶 量为8 mg/mL时的最佳底物浓度为108.13 mmol/L，在上述条件下反应30 h酯的转化 率 > 96%。     

混合溶剂系统中固定化脂肪酶对酮基布洛芬的催化酯化反应

以硅藻土吸附的脂肪酶为催化剂,对外消旋酮基布洛芬[2-(3-苯甲酰苯基)丙酸]进行对映选择性酯化反应;考察了不同的脂肪酶制剂,固定化时所加缓冲液的体积与pH值,酰基受体(醇)的种类以及混合溶剂系统的组成等因素对酶活性的影响.结果表明,在所考察的7种脂肪酶中,以LipaseOF的酪化活性最高;用硅藻土吸附固定化酶时,缓冲溶液的最适pH为7.0左右,每克酶粉加1.0mL缓冲溶液为最佳;固定化酶催化酯化的活性比游离的脂肪酶高.在酮基布洛芬与不同酰基受体(醇)的酶促酯化反应中,以丙醇的反应速度为最快.在由一种主溶剂与一种助溶剂组成的混合溶剂系统中,酶促酯化的速度要比在单一的主溶剂或助溶剂系统中快.当以1gP值较大的环己烷或异辛烷等为主溶剂,甲苯为助溶剂时,脂肪酶催化酮基布洛芬酯化反应的活性最高.     

溶剂和酰基受体对α-氰基-3-苯氧基苄醇乙酯的酶促对映体选择性转酯化反应的影响

研究了在有机溶剂中固定化Alcaligenes sp.脂肪酶催化α-氰基-3-苯氧基苄醇乙酯的对映体选择性转酯化反应,考察了不同性质的溶剂和酰基受体对酶的催化活性和选择性以及对产物稳定性的影响.结果发现在弱极性溶剂如正己烷中酶具有较高的催化活性但产物e.e.%值低,而且容易分解;在四氢呋喃等溶剂中酶催化活性相对低,但产物e.e.%值高,也较为稳定;但反应时间太长,会导致产物分解及纯度下降;不同酰基受体对酶反应无显著影响,甲醇为最佳酰基受体,太多醇会导致反应速率下降;溶剂水含量大于2.0%时对酶活性和产物稳定性产生明显不利影响.在优化条件下,酶反应可得到(S)-α-氰基-3-苯氧基苄醇产率＞48%,纯度＞99%e.e.     

无溶剂系统中固定化脂肪酶催化废油脂转酯生产生物柴油

 探讨了无溶剂系统中固定化脂肪酶Novozym 435催化餐饮业废油脂转酯生产生物柴油. 反应副产物甘油可吸附在固定化酶载体表面,采用丙酮洗涤除去甘油可提高酶的稳定性. 适宜的醇/油摩尔比、酶用量、反应温度和摇床转速分别为1, 6.6 U/g, 35～40 ℃和150 r/min,不宜加水到反应体系中. 采用分步加入甲醇的方式可减轻甲醇对酶的毒害作用. 分别在反应进行到6和14 h时用丙酮除去酶表面的甘油,然后按醇/油摩尔比为1的比例加入甲醇继续反应,反应30 h后产物中的脂肪酸甲酯含量为88.6%. 连续反应300 h后,酶活性基本没有下降.     

有机相酶催化拆分制备(S)-2-氯-1-(2-噻吩)-乙醇

首次在有机相中对酶催化条件下的2-氯-1-(2-噻吩)-乙醇的反应进行了研究. 通过对不同来源酶的筛选, 找到了Novozym 435和Alcaligenes sp两种选择性较好的酶, 它们均对该反应具有较高的选择性和较快的反应速度, 在此基础上进一步通过对溶剂、温度、摇床转速以及酶用量的筛选, 确定了能够有效拆分2-氯-1-(2-噻吩)-乙醇的较佳反应条件. 当温度35 ℃, 酶量10 mg/mL, 反应72.5 h, 产物的ee值为98.5%时收率为48.6%.     

非水相中微生物脂肪酶催化转酯化拆分(R,S)-α-苯乙醇

研究了非水有机溶剂体系中脂肪酶不对称转酯化拆分(R,S)-α-苯乙醇反应,比较了15种不同微生物来源的脂肪酶,从中优选出催化活性及对映选择性较高的脂肪酶Lipase PS,系统考察了影响该酶催化不对称转酯化反应的关键因素,获得了优化的催化拆分工艺条件.结果表明,脂肪酶Lipase PS在非水反应体系中,以正己烷为反应介...     

Enzymatic Resolution of O‐(Methoxymethyl)‐Protected Tropane‐diols

A convenient synthetic route to enantiomerically pure tropane‐diol building blocks is described. The reaction sequence started from tropenone derivatives 1 , which were dihydroxylated to give 6,7‐dihydroxytropanone derivatives 2 . After introduction of the methoxymethyl (MOM) protecting group in diol 2a , a lipase‐mediated resolution of the resulting racemic mono‐MOM ether (±)‐ 5d with vinyl acetate and vinyl trifluoroacetate gave the acetates (?)‐ 6d and (?)‐ 6f , respectively, with 96–99% ee, and MOM ether (+)‐ 5d with up to 89% ee. Deacetylation of (?)‐ 6d afforded quantitatively MOM ether (?)‐ 5d with 99% ee, the absolute configuration of which was assigned via the modified Mosher method to be (R) at C(6). Enzymatic treatment of unprotected diol 2a with vinyl trifluoroacetate or alkoxycarbonylation resulted in the formation of C_s‐symmetrical products 9 and 12 rather than the desired desymmetrized derivatives.     

gem-Difluorocyclopropane as core molecule candidate for liquid crystal compounds

The synthesis of a novel chiral gem-difluorocyclopropane building block has been accomplished using chemo-enzymatic reaction protocol; the prochiral diol of 1,4-bis(2,2-difluoro-3-(hydroxymethyl)cyclopropyl)benzene (5) was converted to the corresponding chiral diacetate by Pseudomonas lipase (lipase SL-25, Meito)-catalyzed transesterification with vinyl acetate as acyl donor with >99% enantiomeric excess. Various types of diesters or dialkyl ether were prepared from the diol and their helical twisting power (HTP) was evaluated by addition of 1.0 wt% to a non-chiral nematic liquid crystal host; the HTP was significantly dependent on the structure of ester or ether moieties and diester of diol 5 with isopropylfumalic acid showed the largest HTP.     

Efficient lipase-catalyzed kinetic resolution of 4-arylmethoxy-3-hydroxybutanenitriles: application to an expedient synthesis of a statin intermediate

The kinetic resolution of 4-arylmethoxy-3-hydroxybutanenitriles was investigated by lipase-catalyzed transesterification in organic solvents. A high enantioselectivity was obtained via reaction with vinyl acetate in a mixed solvent (n-heptane/acetonitrile 1:1), which was catalyzed by the lipase from Artgribacter sp. A better selectivity was demonstrated when the number of substituents on the aryl ring increased. (S)-4-Arylmethoxy-3-hydroxybutanenitriles can be obtained with enantiomeric excesses of up to 98.0% by this method. Furthermore we have developed a novel route to synthesize tert-butyl (S)-6-benzyloxy-5-hydroxy-3-oxohexanoate, a key intermediate for the preparation of HMG-CoA reductase inhibitors (statins).     

A route to enantiomerically pure 5-(2′-hydroxyethyl)cyclopent-2-en-1-ol and its absolute configuration by Mosher esters

The (±)-5-(2′-hydroxyethyl)cyclopent-2-en-1-ol 1 was prepared in a one-pot procedure, and was resolved using lipase AK and vinyl acetate with high ee. This provides a readily available chiral synthon for the synthesis of a wide variety of biologically interesting molecules. Further, the absolute configuration of diol 1 was confirmed directly by the Mosher ester method.     

Resolution of 3-α-naphthoxy-1,2-propanediol using Candida antarctica lipase

The stereochemistry of the Candida antarctica lipase B (CALB) catalyzed resolution of diacetate 1 or diol 4 was analyzed. The primary and secondary acetate hydrolyses were studied separately using monoacetates 2 and 3. The enantioselectivity of CALB was found to be lower towards primary rather than secondary acetates/alcohols. The steric course of the process is discussed.     

The influence of microwave irradiation on lipase-catalyzed kinetic resolution of racemic secondary alcohols

The influence of microwave irradiation on the Novozyme 435^® (Candida antarctica lipase) catalyzed kinetic resolution of secondary alcohols with different functional groups was studied in comparison to the use of conventional heating at 60 °C. p-Chlorophenyl acetate was used as an acyl donor and toluene as the solvent. (±)-1-Phenyl-1-propanol 1, (±)-1-(4-bromophenyl)-propan-1-ol 3, (±)-1-phenylbut-3-en-1-ol 5 and (±)-3-bromo-2-(2-hydroxypropyl)-1,4-dimethoxynaphthalene 7 were successfully resolved into their (S)-alcohols and (R)-esters, respectively, in good enantiomeric excess. Resolution of (±)-ethyl-5-(4-methoxybenyloxy)-3-hydroxypentanoate 9 afforded its (R)-alcohol and (S)-ester using this method. In addition, microwave-assisted lipase transesterification of meso-symmetric diol 11 effected desymmetrization to ester 12 with high enantiomeric excess. In all cases studied, the conversion value for the microwave-assisted lipase kinetic resolution of secondary alcohols was higher than that obtained using conventional heating.     

Acyclic phenylalkanediols as substrates for the study of enzyme recognition: synthesis of substrates and enzymatic resolution via hydrolysis and transesterification

Different racemic or prochiral phenyl alkane (l,n)-diols were synthesized, and their resolution was carried out by two different strategies: enzymatic transesterification with vinyl acetate, or enzymatic hydrolysis of their corresponding diacetates, in both cases catalysed by porcine pancreatic lipase (PPL). The absolute configuration of the optically enriched reaction products was determined by formation of Mosher's esters or by the use of the Benzene Sector and Benzene Chirality Rules as obtained from the Circular Dichroism spectra.     

Syntheses of Enantiopure Aliphatic Secondary Alcohols and Acetates by Bioresolution with Lipase B from <em>Candida antarctica</em>

The lipase B from Candida antarctica (Novozym 435^?, CALB) efficiently catalyzed the kinetic resolution of some aliphatic secondary alcohols: (±)-4-methylpentan-2-ol (1), (±)-5-methylhexan-2-ol (3), (±)-octan-2-ol (4), (±)-heptan-3-ol (5) and (±)-oct-1-en-3-ol (6). The lipase showed excellent enantioselectivities in the transesterifications of racemic aliphatic secondary alcohols producing the enantiopure alcohols (>99% ee) and acetates (>99% ee) with good yields. Kinetic resolution of rac-alcohols was successfully achieved with CALB lipase using simple conditions, vinyl acetate as acylating agent, and hexane as non-polar solvent.     

Kinetic Resolution of (R,S)-2-Butanol Using Enzymatic Synthesis of Esters

Kinetic resolution of (R,S)-2-butanol using enzymatic synthesis of esters has been studied. (R,S)-2-Butanol is commonly found as a racemic mixture, and the products of its esterification are racemic mixtures too. This work is of great significance in the field of the enzymatic kinetic resolution due to the little information found in literature about the resolution of (R,S)-2-butanol as pure compound. So, this article is a contribution about the enzymatic resolution of (R,S)-2-butanol. The reaction here studied is the esterification/transesterification of (R,S)-2-butanol in organic media (n-hexane) using as biocatalyst the lipase Novozym 435?. The main target of this study is to analyze the influence of certain variables in this reaction. Some of these variables are acyl donor (acids and esters), concentration of substrates, enzyme/substrate ratio, and temperature. The main conclusions of this study are the positive effect of higher substrates concentration (1.5 M) and larger amount of enzyme (13.8 g mol(-1) substrate) on kinetic resolution rate but not a very noticeable effect on enantiomeric excesses. The longer the carboxylic acid chain is, the better results are obtained. Besides to achieve a satisfactory kinetic resolution, it is recommendable to select reaction times (180 min) at which the highest substrate enantiomeric excess is reached (~60%). The temperature has not an appreciable influence on the resolution in the range studied (40-60 °C). When an ester (vinyl acetate) is used as acyl donor, the resolution shows better results than when using a carboxylic acid as acyl donor (ee(s)?~90% at 90 min). Moreover, Michaelis-Menten parameters, v(max) and K(M), were determined, 0.04 mol l(-1) min(-1) and 0.41 mol l(-1), respectively.