引发剂对酶促开环聚合ε-己内酯的影响

通过脂肪酶Novozym 435催化的ε-己内酯开环聚合反应,在无溶剂体系中研究了聚己内酯的合成及末端官能化。以醇类为引发剂,研究了引发剂对聚合过程单体转化率、产物结构和相对分子质量的影响。结果表明,在引发剂存在的条件下,反应速率提高,产物相对分子质量降低。无引发剂时单体转化率为79.32%,乙醇和乙二醇为引发剂时分别为97.43%和89.90%。产物相对分子质量在无引发剂时为5 393,乙醇和乙二醇为引发剂时分别下降到2 127和1 851。另外,产物的红外光谱和1H NMR谱图显示,引发剂的加入实现了聚合物的末端官能化。     

聚酯网的缝接及其对复合血管形态结构的影响

本研究对生物——人工复合血管制备过程中聚酯网的缝接及其对复合血管形态结构的影响进行了探讨,作者通过对复合血管聚酯网缝接处的肉眼、LM和SEM观察,认为聚酯的缝接对复合血管形态结构的影响甚微,同时介绍了聚酯网缝接的原则和方法。     

基于噁唑烷酮的不对称催化合成构建多官能化手性氨基酸类化合物

多官能化手性氨基酸及其衍生物是一类重要的手性药物以及合成手性药的关键中间体,如现在大量用于临床的左甲状腺素、赖诺普利、阿莫西林、缬沙坦、头孢氨苄以及青霉素等。进行多官能化手性氨基酸类化合物的不对称催化合成,可为新型化学药的设计与发现开辟新的视野。噁唑烷酮(Azlactone)被证明是合成四取代氨基酸衍生物的优秀底物。可通过不对称催化手段向其中引入需要的基团,再经多取代的噁唑烷酮直接开环得到一系列的目标化合物。本文主要综述了近年来基于恶唑烷酮的不对称催化反应构建四取代氨基酸类化合物的研究。     

生物技术打造低成本聚酯

荷兰Avantium技术公司宣布现已成功研发出一项用于生产生物基聚酯产品的突破性技术,采用该技术制造的生物基聚酯产品与传统聚酯产品相比性价比更高。     

用筐架式填充床生物反应器高密度培养工程细胞

用圆盘型聚酯载体筐架式填充床内作为细胞生长分裂的支持物,通过笼状唧筒生物反应器连续培养能合成和分泌ｒｔＰＡ的工程细胞,经２８ｄ连续灌注培养,细胞密度达４.７×１０^７／ｍｌ,ｒｔＰＡ浓度最高达９.９μｇ／ｍｌ,ｒｔＰＡ活性最高达４０６８ＩＵ／ｍｌ。     

聚苹果酸及其衍生物的制备与应用研究进展

摘要：天然和合成聚合物因优良的特性引起了越来越多研究者的兴趣,并已被广泛用于人类的日常生活中。聚苹果酸（Polymalic acid,PMLA）一种天然的高分子聚酯材料,具有良好的生物相容性和完全生物降解性,其衍生物同样具有优异的生物学性能,被广泛应用于众多领域中。本文就聚苹果酸及其衍生物的结构、性质和合成方法进行了概述,并全面总结了其在制药和其他领域的应用研究现状,最后对未来发展方向进行了展望。     

生物法合成3-羟基丙酸的研究进展

从3-羟基丙酸的性质出发,介绍了生物法合成3-羟基丙酸以及它在生物体内的五种代谢途径,此外还简要介绍了3-羟基丙酸在合成生物聚酯、抗植物病虫害上的一些应用。     

官能化聚烯烃改性塑木复合材料的研究

采用官能化的聚烯烃树脂代替传统的未改性的聚烯烃树脂,提高了基体树脂的流动性和树脂与木粉之间的界面粘结,从而增强了塑木复合材料的性能。结果表明该材料的性能指标可以通过调整官能化聚烯烃的种类(如PE、PP等)和含量而方便调节。     

代谢工程技术调控3-羟基丁酸与3-羟基己酸共聚酯PHBHHx的微生物合成

3-羟基丁酸和3-羟基己酸共聚酯(PHBHHx)是一种新型生物可降解材料,其性能与3-羟基己酸(3HHx)在共聚物中的摩尔百分含量密切相关。本研究在两株嗜水性气单孢菌Aeromonas hydrophila WQ和Aeromonas hydrophila 4AK4中分别引入了编码酯酰辅酶A脱氢酶的yafH基因和编码合成3-羟基丁酸-CoA的phbA和phbB基因,将A.hydrophila WQ合成的PHBHHx中的3HHx的摩尔含量由3％—5％提高到20％以上;而A.hydrophila 4AK4合成的PHBHHx中的3HHx摩尔含量则由15％左右降低到3％-12％。成功地实现了对PHBHHx单体组成的调控。     

利用Y-RACE法进行棉花胚珠cDNA末端快速扩增

在YADE(Y shapedadaptordependentextension)方法的基础上 ,设计了一种新的cDNA末端快速扩增方法 ,称为Y RACE法 .利用该方法只需一次cDNA合成就能进行多个基因的 3′和 5′末端的扩增 .分别利用Y RACE方法和RACE试剂盒 (TaKaRa)扩增了一个棉花胚珠cDNA片段F0 2 7的末端序列 .序列比较表明 ,用Y RACE方法扩增的末端序列较试剂盒所得序列在最末端稍短 ,但同样能进行正确拼接并获得全长编码序列 .对Y RACE法的优缺点和可能的改进作了进一步讨论 .     

Lipase-catalyzed synthesis of aromatic polyesters

The enzymatic synthesis of aromatic polyesters by direct polyesterification between a diacid and a diol is described. The effects of the type of substrate, type and quantities of lipase, temperature, vacuum, and reaction time on the synthesis of aromatic polyesters were studied in detail. Among three lipases investigated, only Novozym 435 worked well for aromatic polyester synthesis. Temperature and vacuum played an important role in obtaining a high molar mass of the aromatic polyesters. Furthermore, with isophthalic acid and 1,6-hexanediol as substrates, the mass average molar mass of the polyester obtained increased with an increase in the lipase quantity up to 0.375 g (11.7%, w/w of total reactor contents). The mass average molar mass of the polyester was as high as 50000 g mol⁻¹ in 168 h, with a polydispersity of PD ≈ 1.4. Received 27 January 1998/ Accepted in revised form 19 May 1998     

Enzymatic Synthesis of Various Aromatic Polyesters in Anhydrous Organic Solvents

Lipases and proteases from various sources were tested in aromatic polyester synthesis in organic solvents. A commercial protease from Bacillus licheniformis efficiently catalyzed the transesterifica-tion of a diester of terephthalic acid and 1,4-butanediol in anhydrous tetrahydrofuran (THF). This protease was used as a catalyst in the synthesis of aromatic polyesters in THF. Oligomers with average molecular weights from 400 to 1000 daltons were obtained using various diols and aromatic diesters.     

Metabolic engineering for the synthesis of polyesters: A 100-year journey from polyhydroxyalkanoates to non-natural microbial polyesters

As concerns increase regarding sustainable industries and environmental pollutions caused by the accumulation of non-degradable plastic wastes, bio-based polymers, particularly biodegradable plastics, have attracted considerable attention as potential candidates for solving these problems by substituting petroleum-based plastics. Among these candidates, polyhydroxyalkanoates (PHAs), natural polyesters that are synthesized and accumulated in a range of microorganisms, are considered as promising biopolymers since they have biocompatibility, biodegradability, and material properties similar to those of commodity plastics. Accordingly, substantial efforts have been made to gain a better understanding of mechanisms related to the biosynthesis and properties of PHAs and to develop natural and recombinant microorganisms that can efficiently produce PHAs comprising desired monomers with high titer and productivity for industrial applications.Recent advances in biotechnology, including those related to evolutionary engineering, synthetic biology, and systems biology, can provide efficient and effective tools and strategies that reduce time, labor, and costs to develop microbial platform strains that produce desired chemicals and materials. Adopting these technologies in a systematic manner has enabled microbial fermentative production of non-natural polyesters such as poly(lactate) [PLA], poly(lactate-co-glycolate) [PLGA], and even polyesters consisting of aromatic monomers from renewable biomass-derived carbohydrates, which can be widely used in current chemical industries.In this review, we present an overview of strain development for the production of various important natural PHAs, which will give the reader an insight into the recent advances and provide indicators for the future direction of engineering microorganisms as plastic cell factories. On the basis of our current understanding of PHA biosynthesis systems, we discuss recent advances in the approaches adopted for strain development in the production of non-natural polyesters, notably 2-hydroxycarboxylic acid-containing polymers, with particular reference to systems metabolic engineering strategies.     

Analysis of the aliphatic monomer composition of polyesters associated with Arabidopsis epidermis: occurrence of octadeca-cis-6, cis-9-diene-1,18-dioate as the major component

Although the surface waxes from Arabidopsis thaliana leaves and stems have been thoroughly characterized, the monomer composition of the polyesters of the cuticular membrane has not been analyzed. Delipidated Arabidopsis leaves or stems, when depolymerized under conditions to cleave polyesters, produced typical omega-hydroxy fatty acid cutin monomers such as 16-hydroxy-palmitate, 10,16-dihydroxy-palmitate and 18-hydroxy-9,10-epoxy-stearate. However, the major monomer was octadeca-cis-6, cis-9-diene-1,18-dioate, with lesser amounts of octadec-cis-9-ene-1,18-dioate and hexadeca-1,16-dioate. These dicarboxylates were found predominantly in epidermal peels from Arabidopsis stems and are therefore likely to be associated with the cuticular membrane. They were also found in analyses of canola leaves but were absent in tomato and apple fruit cutins. In the fad2-1 mutant line of Arabidopsis, which has reduced levels of linoleate and linolenate and elevated oleate in cytosolic phospholipids, the amount of octadeca-cis-6, cis-9-diene-1,18-dioate was 50% reduced, with a concomitant increase in octadec-cis-9-ene-1,18-dioate. In a fatb-ko line of Arabidopsis, where the availability of cytosolic palmitate is impaired, there was an 80% loss of C16 monomers and a compensating increase in C18 monomers. The presence of substantial amounts of dicarboxylates in cuticular membranes is unexpected. High amounts of aliphatic dicarboxylates are usually considered as an indicator of suberin, and are reported only as very minor components of cutin. The high level of polyunsaturation is also unusual in cuticles; saturated fatty acid monomers usually predominate, with lesser amounts of monounsaturates. These novel findings for Arabidopsis demonstrate that a broad range of monomer compositions are possible for polyesters of the epidermis.     

Lipase/esterase-catalyzed synthesis of aliphatic polyesters via polycondensation: A review

Over the last decade, there has been an increasing interest in lipase/esterase-catalyzed polycondensation as an alternative to metal-based catalytic process, because the former can proceed under mild reaction conditions and does not cause undesirable side reactions or produce trace metallic residues. In this review, the in vitro synthesis of aliphatic polyesters by polycondensation using lipases or esterases is systematically summarized, especially for the synthesis of complex and well-defined polyesters. The polycondensation of diols with diacids or their activated esters, including alkyl, haloalkyl and vinyl esters, through esterification and transesterification polycondensation reactions is discussed. In addition, three or more monomers can also be polymerized simultaneously, which provides a new route for preparing functional polymers. Self-polycondensation with respect to hydroxyl and mercapto acids or their esters is another reaction mode discussed in the review. Finally, concurrent enzymatic ring-opening polymerization and polycondensation has been developed to construct novel polyesters with tailor-made structures and properties. Overall, the review demonstrates that lipase/esterase-catalyzed synthesis of polyesters via polycondensation provides an effective platform for conducting “eco-friendly polymer chemistry”.     

Synthesis of poly(L-lactide) and polyglycolide by ring-opening polymerization

This protocol describes the synthesis of poly(L-lactide) by ring-opening polymerization of L-lactide using tin(II) 2-ethylhexanoate catalyst as well as the synthesis of polyglycolide by ring-opening polymerization of glycolide. Ring-opening polymerization of cyclic diesters synthesized from alpha-hydroxycarboxylic acids gives high-molecular-weight polyester in high yield. Tin(II) 2-ethylhexanoate catalyst is the most common catalyst for ring-opening polymerization of diesters owing to its high reactivity and low toxicity. Purity of monomers and the amount of water and alcohol in the reaction system are significant factors for increasing molecular weight and conversion of polyesters. The molecular weight of the polyesters is also dependent on reaction temperature and reaction time. This protocol can be completed in 3 d for the synthesis of poly(L-lactide) and 2 d for the synthesis of polyglycolide.     

Biocatalytic polyester synthesis: analysis of the evolution of molecular weight and end group functionality

The enzymatic synthesis of polyesters from activated diesters and diols has been investigated. Differences between enzymatic synthesis and traditional chemical condensation processes are discussed. The disappearance of monomers during the initial phase of reaction indicates that enzyme has a higher specificity for transesterification of ester-terminated oligomers. During the intermediate phase, enzymatic polymerization involves a competition between diol and enzyme-bound water for the nucleophilic attack of the acyl enzyme intermediate. Competition between enzymatic transesterification and hydrolysis at different stages of polymerization in nonaqueous media is responsible for termination of polyesters with acid end-groups and also for limiting the polymer molecular weight. The resulting oligoester consists of chains that are either terminated with - OH groups and/or - COOH groups. We have used Matrix Assisted Laser Desorption/Ionization - Time of Flight Mass spectroscopy (MALDI-TOF) along with colorimetric titration techniques to determine the acidity of enzyme-synthesized polyesters. This paper addresses how the enzymatic polymerization proceeds, and compares our results to the growing literature in this field. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 55: 227-239, 1997.     

Multi-modular engineering of 1,3-propanediol biosynthesis system in Klebsiella pneumoniae from co-substrate

Applied Microbiology and Biotechnology - 1,3-Propanediol (1,3-PDO) is a monomer for the synthesis of various polyesters. It is widely used in industries including cosmetics, solvents, and...     

Enzymatic and whole-cell synthesis of lactate-containing polyesters: toward the complete biological production of polylactate

The importance of polylactic acid, a representative bio-based polyester, has been established on a worldwide scale in response to emerging global environmental problems such as green house gas emission and limited petroleum consumption. The current methods for generating this bio-based polymer involve biological synthesis and lactic acid (LA) fermentation, followed by chemical ring-opening polymerization. Among the research community working on polyhydroxyalkanoate polyesters, the prospect of direct biological synthesis of LA into a polymeric form is very attractive from the academic and industrial perspectives. In 2008, this challenge was met for the first time by the discovery of an “LA-polymerizing enzyme”. Using this novel enzyme, the metabolic engineering approach outlined here provided an entirely new, single organism generation of the polymer. This is a major breakthrough in the field. In this review, we provide an overview of the whole-cell synthesis of LA-containing polyesters in comparison with conventional lipase-catalyzed polymer synthesis in terms of both the concepts and strategies of their synthetic processes.     

Water-soluble degradable hyperbranched polyesters: novel candidates for drug delivery?

A novel approach to hyperbranched polymers is presented in this work. Hyperbranched polyesters with a large amount of terminal hydroxyl groups are prepared by a one-pot synthesis from commercially available AB-type and CD(n)-type monomers (n >/= 2). In this paper, Michael addition of diethanolamine (CD(2)) or N-methyl-d-glucamine (CD(5)) to methyl acrylate (AB) generates dominantly AD(n)-type intermediates. Further self-condensation of intermediates at higher temperature and in the presence of catalyst gives hyperbranched polyesters. Because of the tertiary amino groups in the backbone and the hydroxyl groups in the linear and terminal units, the resulting hyperbranched polyester is highly soluble in water. Furthermore, the hyperbranched polymer is degradable because of its ester units. So, the water-soluble hyperbranched polyesters might be applied as a novel material for drug delivery.