脂肪酶催化缩聚法合成可完全降解的聚羟基丙酸酯(英文)

以3-羟基丙酸甲酯为聚合单体,建立了以固定化脂肪酶Novozym 435为催化剂的酶催化缩聚反应体系,合成可完全降解的高分子聚酯聚羟基丙酸酯,考察了反应条件和介质对反应性能的影响,结果表明,纯度大于95%的单体即可在温和条件下合成聚羟基羧酸酯;降低反应压力可有效提升产物产率和分子量.通过选择合适的有机溶剂介质和表面活性剂,可使产物分子量提升至13000(Mw)以上.脂肪酶催化剂重复利用能力优异,经6批次反应后,其相对活性保持在95%以上.     

镍催化转移缩聚合成全氟环丁基芳基醚聚合物

研究了通过镍催化转移缩聚的方法来合成全氟环丁基芳基醚聚合物.首先,我们以对溴苯酚和1,2-二溴四氟乙烷为起始原料,通过两步反应得到对溴三氟乙烯基芳基醚,进一步加热环化二聚得到单体1,2-二(4-溴苯氧基)六氟环丁烷.该二聚物再与异丙基格氏试剂发生镁交换反应,生成格氏试剂中间体,在催化剂Ni(dppe)Cl2的存在下发生镍催化转移缩聚生成聚合物.研究了反应时间、温度和单体投料比对催化缩聚反应的影响.     

淀粉与丙烯酰胺的接枝共聚

本文以木薯淀粉为骨架,以丙烯酰胺为单体,进行淀粉—丙烯酰胺接枝共聚的研究。对接枝共聚过程中引发剂浓度、单体浓度、反应温度、反应时间、介质酸浓度及淀粉糊化温度等因素的影响进行了讨论,寻找接枝共聚的最佳反应条件。     

钯催化合成新型聚合物聚亚胺酮

以二溴化芳香酮和芳香二胺为单体,通过钯催化的胺化缩聚反应合成了新型聚合物——聚亚胺酮,其结构经1HNMR,IR和元素分析确认。     

AB_3型超支化聚(酰胺-酯)的合成及缩聚动力学研究

采用丁二酸酐、三羟甲基氨基甲烷为主要原料 ,在冰水浴条件下 ,合成AB3型单体 ,然后进行熔融缩聚制得超支化聚 (酰胺 酯 ) ,没有出现凝胶现象 .采用Fourier变换红外谱仪 (FTIR)、粘度测试、端基分析等方法对其结构、特性粘数进行了表征 .同时对AB3型超支化聚 (酰胺 酯 )的缩聚反应动力学进行了研究 ,得出了130℃、14 0℃和 15 0℃时的缩聚反应速率常数 ,并进一步得出了缩聚反应活化能 .实验结果证明缩聚过程为自催化过程 ,且为三级反应     

辣根过氧化物酶催化水溶性聚对苯二胺-对氨基苯磺酸的合成及表征

以辣根过氧化物酶(HRP)为催化剂,H2O2为氧化剂,催化对苯二胺与对氨基苯磺酸共聚,合成了聚对苯二胺-对氨基苯磺酸(PAn-I)。利用紫外光谱、红外光谱、XPS、GPC、循环伏安、热重分析等方法对合成的PAn-I进行了结构表征与分析,测定了其电导率、电活性和热稳定性等。结果显示,合成的PAn-I不仅具有一定的电活性和热稳定性,且在水溶液中具有良好的溶解性。合成过程中采用去离子水作为反应介质,避免了使用有机溶剂,反应条件温和,酶的用量也较少。     

新型茂钛催化剂用于St/Bd嵌段共聚物的合成

先用五甲基茂基三苄氧基钛 /甲基铝氧烷催化苯乙烯预聚 ,再与丁二烯进行嵌段共聚合。考察预聚时间、催化剂浓度、苯乙烯浓度等条件对嵌段共聚合反应的影响。共聚产物经沸丁酮、沸甲苯、沸四氢呋喃、沸氯仿连续抽提后 ,嵌段共聚物主要存在于氯仿的可溶级分中。随着预聚时间的增加 ,共聚反应催化效率增加 ,共聚产物中丁二烯含量下降 ;随着催化剂浓度增加 ,共聚催化效率增加 ,[Ti]为 2 .0× 1 0 -4 mol/L时 ,共聚活性达到最大值 ( 1 7.78× 1 0 3 gP/gTi) ,随着催化剂浓度进一步增加 ,共聚催化效率下降 ,共聚产物中丁二烯含量变化亦存在峰值。     

双金属氰化络合物催化环氧丙烷和邻苯二甲酸酐共聚

采用双金属氰化络合物 (DMC)催化环氧丙烷 (PO)和邻苯二甲酸酐 (PA)共聚 ,探讨了共聚合特征 ,并用IR、1 H NMR和GPC对共聚物的结构和分子量进行了表征 .发现DMC催化剂对该共聚反应速度快 ,转化率高 ,是该反应的有效催化剂 ,催化剂浓度为 6 0mg kg时 ,90℃下 ,以THF作溶剂共聚反应 3h ,转化率可达94 0 % .聚合速度甚至比DMC催化PO均聚还快 .该共聚反应可在多种溶剂中进行 ,极性溶剂更有利于共聚合 ,溶液聚合温度比本体共聚低 ,合适的溶液共聚温度在 90～ 10 0℃之间 .共聚产物的分子量受催化剂用量、反应温度和体系中水份含量的影响 ,数均分子量在数百至数千之间 .考察该共聚体系的动力学表明 ,该共聚反应速率对单体浓度呈一级关系     

Zn-MOFs催化合成聚丁二酸乙二醇酯和碳酸二甲酯的研究

采用溶剂热法和直接混合法合成了3种金属有机骨架材料(Zn-MOFs),研究了其在碳酸乙烯酯(EC)与丁二酸二甲酯(DMSu)耦合反应制聚丁二酸乙二醇酯(PES)和碳酸二甲酯(DMC)反应中的催化性能,并对工艺条件进行了考察.采用X射线粉末衍射法(XRD),扫描电子显微镜(SEM),傅里叶转化红外光谱法(FTIR)和原子发射光谱法(ICP-AES)对Zn-MOFs进行了表征,对聚合物PES进行了FTIR和核磁共振(~1HNMR和~(13)C-NMR)测试.结果表明,既具有MOF-5结构,又含有较多Zn O的纳米Zn-MOF-L催化活性最好.在Zn-MOF-L催化下,最优反应条件如下:预缩聚反应温度215℃,预缩聚反应时间4 h,缩聚反应温度220℃,缩聚压力小于300 Pa,n(EC)/n(DMSu)=2,催化剂用量为1 wt%.最优反应条件下,DMC的收率可达到65.08%,PES的特性黏数[η]可达到0.572 d L/g,数均相对分子质量M_n为2.1×104,相对分子质量分布PDI为2.21.     

二醚型 Ziegler-Natta 催化剂催化丙烯与极性单体共聚

 以三乙基铝 (TEA) 为保护剂, 研究了 TiCl4/MgCl2/芴二醚/Al(C2H5)3 体系催化丙烯与十一烯醇或十一烯酸的共聚反应. 结果表明, 在极性单体存在下, 聚合反应活性随极性单体加入量的增加而降低, 但可保持丙烯均聚活性的一半以上, 反应活性衰减较小. 同时, 随着极性单体加入量的增加, 极性单体在共聚物中的含量增加. 与十一烯酸相比, 十一烯醇共聚具有更高的共聚活性和共单体含量. 随着共聚物中极性单体含量的增加, 聚合物的熔点和结晶温度都有所降低. 反应温度对丙烯和十一烯醇共聚的反应活性和共单体含量影响较小.     

Polyesters from Macrolactones Using Commercial Lipase NS 88011 and Novozym 435 as Biocatalysts

The demand for environmentally friendly products allied with the depletion of natural resources has increased the search for sustainable materials in chemical and pharmaceutical industries. Polyesters are among the most widely used biodegradable polymers in biomedical applications. In this work, aliphatic polyesters (from globalide and ω-pentadecalactone) were synthesized using a new commercial biocatalyst, the low-cost immobilized NS 88011 lipase (lipase B from Candida antarctica immobilized on a hydrophobic support). Results were compared with those obtained under the same conditions using a traditional, but more expensive, commercial biocatalyst, Novozym 435 (lipase B from C. antarctica immobilized on Lewatit VP OC). When NS 88011 was used in the polymerization of globalide, longer reaction times (240 min)—when compared to Novozym 435—were required to obtain high yields (80–90 wt%). However, higher molecular weights were achieved. When poly(ω-pentadecalactone) was synthesized, high yields and molecular weights (130,000 g mol^?1) were obtained and the enzyme concentration showed strong influence on the polyester properties. This is the first report describing NS 88011 in polymer synthesis. The use of this cheaper enzymatic preparation can provide an alternative for polyester synthesis via enzymatic ring-opening polymerization.     

A lipase catalyzed condensation reaction with a tricyclic diketone: yet another example of biocatalytic promiscuity

Novozym 435 (a commercially available immobilized form of Candida antarctica lipase B) was found to catalyze a condensation reaction of 5-hydroxy-endo-tricyclo[5.2.1.0^2,6]deca-4,8-dien-3-one with acetaldehyde (enzymatically produced from vinyl acetate in situ) under low water conditions, in presence of 10% organic co-solvent (N,N-dimethyl formamide or pyridine), to form a bis-adduct. Even though the condensation reaction occurred with pyridine (acting as a base catalyst) in the presence of acetaldehyde and in the absence of enzyme, the reaction was very slow as compared to the enzymatic process. Thus, while the non-enzymatic process took 4 days to achieve 100% conversion; in presence of enzyme it was possible within 4 h.     

Enzymatic polyesterification in organic media. Enzyme-catalyzed synthesis of linear polyesters. I. Condensation polymerization of linear hydroxyesters. II. Ring-opening polymerization of ϵ-caprolactone

With the object to synthesize polyesters by enzymatic catalysis in organic media, two directions have been investigated: (1) the condensation polymerization of linear ω-hydroxyesters and (2) the ring-opening polymerization of lactones. The commercially-available crude porcine pancreatic lipase (PPL), suspended in organic solvents, was the preferred enzyme for the reactions. In order to determine the optimal conditions for the condensation polymerization, the bifunctional methyl 6-hydroxyhexanoate was used as a model compound to study the influence of the following parameters: type of the enzymecatalyst, kind of solvent, concentration, temperature, duration, size of the reaction mixture, and stirring. Film-forming polyesters with a degree of polymerization (DP) up to about 100 were obtained from linear aliphatic hydroxyesters in n-hexane at reflux temperature (69°C). Yet concurrently with the intermolecular condensation polymerization, macrolactones were also formed by intramolecular reaction. Two aromatic hydroxyesters did not react under these conditions. For the ring-opening polymerization of lactones the reaction of ?-caprolactone with methanol as the preferred nucleophile, was studied. Polyesters with a DP of up to 35 were obtained in n-hexane at temperatures between 25 and 40°C. The degrees of polymerization of the polyesters were determined by comparative analyses of the end groups in the ¹H-NMR spectra and by determination of molecular weights either by vapor phase osmometry, gel permeation chromatography, or intrinsic viscosity. © 1993 John Wiley & Sons, Inc.     

超支化聚合物结构和形貌的表征与分析

用固定化酶Novozyme435(NV435)催化2,2-二羟甲基丁酸(BHB)与ε-己内酯(ε-CL)开环缩聚得到端基中一端带有一个羧基,另一端带有多个羟基的超支化共聚酯。利用核磁共振分析(NMR)、傅立叶红外(FTIR)、凝胶渗透色谱仪(GPC)对超支化聚合物进行结构表征,用扫描电子显微镜(SEM)分析了聚合物的表面形貌。     

One‐step synthesis of polycarbonates bearing pendant carboxyl groups by lipase‐catalyzed ring‐opening polymerization

The ring‐opening polymerization of a monomer containing a free carboxylic acid group is reported for the first time. The monomer, 5‐methyl‐5‐carboxyl‐1,3‐dioxan‐2‐one (MCC), was copolymerized with trimethylene carbonate (TMC) in an enzymatic ring‐opening polymerization conducted in bulk at 80 °C. The low‐melting TMC comonomer also solubilized the high‐melting MCC monomer, allowing for solvent‐free polymerizations. Six commercially available lipases were screened, and Candida antarctica lipase‐B (Novozym‐435) and Pseudomonas cepacia lipase were selected to catalyze the copolymerization because of their higher monomer conversions. Higher molecular weight polymers (weight‐average molecular weight = 7800–9200) were prepared when Novozym‐435 was used, with less MCC incorporated into the copolymer than used in the monomer feed. However, Pseudomonas cepacia lipase showed good agreement between the molar feed ratios and the molar composition, but the molecular weights (weight‐average molecular weight = 3600–4800) were lower than those obtained when Novozym‐435 was used. ¹³C NMR spectral data were used for microstructural analysis, which suggested the formation of random, linear, and pendant carboxylic acid groups containing polycarbonates with hydroxyl groups at both chain ends. © 2002 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 40: 1267–1274, 2002     

Investigation on lipase-catalyzed solution polymerization of cyclic carbonate

In this study, 26-membered macrocyclic carbonate, cyclobis(decamethylene carbonate) [(DMC)₂] was attempted to undergo ring-opening polymerization by lipase catalysis in toluene. Novozym-435 exhibited even higher catalytic activity towards (DMC)₂ polymerization compared with SnOCt₂ while high molecular weight (M_n) of 5.4 × 10⁴ and yield of 99% was still achieved at ultra-low enzyme/substrate (E/S) weight ratio of 1/200. ¹H NMR spectra demonstrated the existence of terminal hydroxyl group. Solid phase polymerization in the absence of toluene unexpectedly took place at the temperature lower than (DMC)₂’s melting point of 110 °C. Compared with solvent-free case, the addition of toluene solvent resulted in marked increase in reaction rate. As to the polymerization during 48 h with the E/S weight ratio of 1/100, a region existed at around toluene/carbonate (vol/wt, ml/g) ratio of 1∼2 where the polymerizations gave optimal results in terms of both higher molecular weight and monomer conversion. It was found that much higher molecular weight polymers may be obtained by decreasing enzyme concentrations. Plots of ln{[M]₀:[M]_t} versus reaction time were in linear agreement, indicating no chain termination, and monomer consumption follows a first-order rate law. The Novozym-435 catalyzed polymerization of (DMC)₂ in toluene presented pseudo-living characteristic. Compared with 6-membered trimethylene carbonate, much lower reaction activity of large-sized (DMC)₂ is observed, which is opposite to the result concerning the enzymatic polymerization of lactones with different ring-size.     

Studies of lipase-catalyzed polyesterification of an unactivated diacid/diol system

Preliminary enzymatic polymerization studies in the simple stoichiometric adipic acid/butane-1,4-diol system using lipase B from Candida antarctica, immobilized as Novozym 435®, suggest that in solvent-free conditions a step-growth mechanism operates involving the sequential addition of an AB synthon by esterification mode only. Conversely, in toluene as solvent there is a change to the more facile transesterification mode in line with the conventional polyesterification procedure, pointing to a change in specificity of the lipase. Evidence is drawn from qualitative studies using a series of synthetic intermediates, enabling authentication of product mixtures together with an indication of the comparative reactivity of species along the proposed reaction pathway. © 1998 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 36: 2069–2080, 1998     

Iterative tandem catalysis of secondary diols and diesters to chiral polyesters

The well-known dynamic kinetic resolution of secondary alcohols and esters was extended to secondary diols and diesters to afford chiral polyesters. This process is an example of iterative tandem catalysis (ITC), a polymerization method where the concurrent action of two fundamentally different catalysts is required to achieve chain growth. In order to procure chiral polyesters of high enantiomeric excess value (ee) and good molecular weight, the catalysts employed need to be complementary and compatible during the polymerization reaction. We here show that Shvo's catalyst and Novozym 435 fulfil these requirements. The optimal polymerization conditions of 1,1'-(1,3-phenylene) diethanol (1,3-diol) and diisopropyl adipate required 2 mol% Shvo's catalyst and 12 mg Novozym 435 per mmol alcohol group in the presence of 0.5 M 2,4-dimethyl-3-pentanol as the hydrogen donor. With these conditions, chiral polyesters were obtained with peak molecular weights up to 15 kDa, an ee value up to 99% and with 1-3 % ketone end groups. Also with the structural isomer, 1,4-diol, a chiral polyester was obtained, albeit with lower molecular weight (8.3 kDa) and slightly lower ee (94%). Aliphatic secondary diols also resulted in enantio-enriched polymers but at most an ee of 46 % was obtained with molecular weights in the range of 3.3-3.7 kDa. This low ee originates from the intrinsic low enantioselectivity of Novozym 435 for this type of secondary aliphatic diols. The results presented here show that ITC can be applied to procure chiral polyesters with good molecular weight and high ee from optically inactive AA-BB type monomers.     

Preparation and characters of hyperbranched polyester‐based organic‐inorganic hybrid material compared with linear polyester

To compare the properties of hyperbranched polymers with linear oligomers for preparing organic‐inorganic hybrids, hyperbranched aliphatic polyester (Boltorn^TM H20) and linear polyester hexa‐acrylate (EB830) were selected as organic components for preparing UV‐curable transparent hybrid materials using 3‐(trimethoxysilyl) propylmethacrylate as a coupling agent via a sol‐gel process. The prehydrolyzed product of tetraethoxysilane was used as an inorganic component. The effects of inorganic content on the morphologies, thermal behaviors, photopolymerizaiton kinetics and mechanical properties of the hybrids were investigated. The results show that for hyperbranched polyester‐based hybrids, the organic phase shows much better compatibility with inorganic phase even at high inorganic component content due to its special spheral shape and plenty of functional end groups, compared with linear EB830‐based hybrids. Copyright © 2004 John Wiley & Sons, Ltd.