乳丝的加工、性能及其应用

乳丝学名为聚乳酸纤维,是一种可生物降解的新型绿色纤维,目前制备方法主要有熔融纺丝、溶液纺丝和静电纺丝等3种方法。作为一种新型的可降解纤维材料,其环保性、吸湿性、透气性、生物相容性以及优良的力学性能决定了其在生物医用、织物面料、非织造材料(如一次性卫生用品、过滤材料等)等很多方面都将得到广泛应用。     

5-氨基乙酰丙酸的生物合成及其应用

5-氨基乙酰丙酸是一种新型农药,由于其在环境中易降解,无残留,对人蓄无毒性,所以是一种无公害的绿色农药而倍受关注,在农业领域应用非常广泛,主要应用于植物生长调节剂、绿色除草剂、杀虫剂等方面,还可以应用到医学、有机合成等方面。本文主要综述了生物合成五氨基乙酰丙酸的途径,同时还介绍了五氨基乙酰丙酸作为一种调节剂、新型农药、杀虫剂的研究进展及在医学领域的发展。以期为科研和生产提供指导。     

国外动态

美国开发出新型有机物制氢催化剂开发出低成本的制氢工艺是氢能源普及的关键一环 ,科研人员对于如何利用植物等生物材料制氢一直颇为关注。美国科学家研制出一种含有镍、铝和锡成分的催化剂 ,在将造纸厂、食品和谷物加工厂的有机废物中所含葡萄糖等转化为氢的过程中 ,新型催化剂能降低制氢的成本。美国威斯康星大学的一个研究小组对 30 0多种合金催化剂进行筛选后发现 ,由镍、铝和锡按一定比例构成的一种新型催化剂 ,不仅制氢效率与目前使用的铂催化剂相当 ,而且成本大大降低。新型催化剂能够在 2 2 5℃这一相对较低的温度下工作 ,其工作时…     

Biosynthesis and Application of 5-Aminolevulinic Acid

5-氨基乙酰丙酸是一种新型农药,由于其在环境中易降解,无残留,对人蓄无毒性,所以是一种无公害的绿色农药而倍受关注,在农业领域应用非常广泛,主要应用于植物生长调节剂、绿色除草剂、杀虫剂等方面,还可以应用到医学、有机合成等方面.本文主要综述了生物合成五氨基乙酰丙酸的途径,同时还介绍了五氨基乙酰丙酸作为一种调节剂、新型农药、杀虫剂的研究进展及在医学领域的发展.以期为科研和生产提供指导.     

一种新型淀粉酶的鉴定及其产酶菌株的筛选*

对筛选到的菌株ZX99产生的一种新型淀粉酶 (异麦芽低聚糖酶 )进行了分析鉴定。ZX99菌株能产生一种胞外淀粉酶 ,该酶能催化淀粉的降解产生异麦芽低聚糖。对原产酶菌株ZX99多次进行紫外线照射诱变后 ,获得了优良、稳定的变异菌株BS3.232 ,其产酶水平为原株的160 %。产物薄层层析证明 ,该酶能催化淀粉的降解 ,产生异麦芽糖、潘糖、异麦芽三糖和异麦芽四糖等低聚糖 ,但对普鲁兰基本不起作用 ,由此证明它是一种不同于新型普鲁兰酶 (neopullulanase)和传统淀粉酶 (amylase)的一种新型     

新型隐球酵母非编码小RNAs的研究进展

新型隐球酵母是一种担子菌病原真菌,主要感染免疫功能缺陷的人群,例如HIV-1感染病人,最终会引起致命隐球菌性脑膜炎。非编码小RNAs一般指长度为20-30nt的小RNAs,具有调节功能。新型隐球酵母能够产生大量的小RNAs,但是其生成（biogenesis）过程以及生物学功能尚未完全阐述。本文就新型隐球酵母中小RNAs的特征和产生、以及在新型隐球酵母中的生物学作用和机制进行综述。     

精制原代地鼠肾细胞狂犬病疫苗制备工艺的研究

通过ａＧ 株病毒在金黄地鼠肾细胞中培养,而制备的一种新型灭活狂犬病精制疫苗已获成功。该纯化方法包括醋酸锌沉淀和Ｓｅｐｈａｒｏｓｅ ４ＦＦ柱层析,所生产的疫苗质量完全达到新型狂犬病疫苗的要求。该工艺方法简单,成本低廉,是一种理想的狂犬病疫苗生产方法。     

苏联的生物工程

象其他工业型国家一样,苏联也把生物工程视为一种新型工业,是改进国家的农业和医疗卫生体系的一种新型工具。这二者对于劳动集约的苏联经济极为重要,同时,这二者又需要良好的技术基础。三、四十年代的苏联生物学,特别是遗传学,受到了拉马克主义的遗传学家李森科教条主义的约束。     

Nature Works推出优化注塑的生物聚合物

美国明尼苏达MINNETONKA消息，NatureWorks公司推出了一种新型改善的注塑生物聚合物-Ingeo 3251D。这种新型Ingeo产品被设计用于电子产品、化妆品、家用器具、玩具和传统模制产品中。     

DNA植物技术公司出售真菌病害现场检测工具箱

DNA Plant Technology公司在农业诊断业务方面的联合商业经营公司,即Agri-Diagnostics Associates公司,已经开始出售一种牌名为ALERT的新型检测工具箱。用这种工具箱能够快速地现场检测大豆和其它作物上发生的真菌病害。联营公司还推销另一种新型的,即REVEAL牌的工具箱,它能在十分钟之内检测草皮上的真菌病害。 Agri-Diagnostics公司正在直接向病虫害防治顾问、作物顾问、农药经销商和种子经     

Applications of dendrimers in bio-organic chemistry

Dendrimers represent a new class of highly branched polymers whose interior cavities and multiple peripheral groups facilitate potential applications in biomedicine and bio-organic chemistry. Major advances in the past year were made in the synthesis and study of new carbohydrate, nucleic acid, and peptide dendrimers, as well as in the use of dendrimers as magnetic resonance imaging contrast agents, as agents for cellular delivery of nucleic acids, and as scaffolds for biomimetic systems.     

Glycopeptide dendrimers. Part II.

Glycopeptide dendrimers are regularly branched structures containing both carbohydrates and peptides. Various types of these compounds differing in composition and structure are mentioned, together with their practical use spanning from catalysis, transport vehicles to synthetic vaccines. This Part II (for Part I see JeZek J, et al., J. Pept. Sci. 2008; 14: 2-43) covers linear oligomers with variable valency (brush dendrimers, comb dendrimers), sequential oligopeptide carriers SOCn-I and SOCn-II, chitosan-based dendrimers, and brush dendrimers. Other types of glycopeptide dendrimers are self-immolative dendrimers (cascade release dendrimers, domino dendrimers), dendrimers containing omega-amino acids (Gly, beta-Ala, gamma-Abu and epsilon-aminohexanoic acid), etc. Microwave-assisted synthesis of dendrimers and libraries of glycopeptides and glycopeptide dendrimers are also included. Characterization of dendrimers by electromigration methods, mass spectrometry, and time-resolved and nonlinear optical spectroscopy, etc. plays an important role in purity assessment and structure characterization. Physicochemical properties of dendrimers including chirality are given. Stability of dendrimers, their biocompatibility and toxicity are reviewed. Finally, biomedical applications of dendrimers including imaging agents (contrast agents), site-specific drug delivery systems, artificial viruses, synthetic antibacterial, antiviral, and anticancer vaccines, inhibitors of cell surface protein-carbohydrate interactions, intervention with bacterial adhesion, etc. are given. Glycopeptide dendrimers were used also for studying recognition processes, as diagnostics and mimetics, for complexation of different cations, for therapeutic purposes, as immunodiagnostics, and in drug design.     

Nanomaterials for ocular drug delivery

Efficient drug delivery to the eye remains a challenging task for pharmaceutical scientists. Due to the various anatomical barriers and the clearance mechanisms prevailing in the eye, conventional drug delivery systems, such as eye drop solutions, suffer from low bioavailability. More invasive methods, such as intravitreal injections and implants, cause adverse effects in the eye. Recently, an increasing number of scientists have turned to nanomaterial-based drug delivery systems to address the challenges faced by conventional methods. This paper highlights recent applications of various nanomaterials, such as polymeric micelles, hydrogels, liposomes, niosomes, dendrimers, and cyclodextrins as ocular drug delivery systems to enhance the bioavailability of ocular therapeutic agents.     

Glycopeptide dendrimers. Part I.

Glycopeptide dendrimers are branched structures containing both carbohydrates and peptides. Various classes of these compounds differing in composition and structure are mentioned, together with their practical use spanning from catalysis, transport vehicles to synthetic vaccines. The main stress is given to glycopeptide dendrimers, namely multiple antigen glycopeptides (MAGs). In MAGs, the core, branches or both are composed of amino acids or peptides. Other classes of glycodendrimers (PAMAM, polypropylene imine, cyclodextrin, calixarene, etc.) are mentioned too, but to a smaller extent. Their syntheses, physicochemical properties and biological activities are given with many examples. Glycopeptide dendrimers can be used as inhibitors of cell surface protein-carbohydrate interactions, intervention with bacterial adhesion, for studying of recognition processes, diagnostics, imaging and contrast agents, mimetics, for complexation of different cationts, as site-specific molecular delivery systems, for therapeutic purposes, as immunodiagnostics and in drug design. Biomedical applications of glycopeptide dendrimers as drug and gene delivery systems are also given.     

Peptide dendrimers: applications and synthesis

Peptide dendrimers are radial or wedge-like branched macromolecules consisting of a peptidyl branching core and/or covalently attached surface functional units. The multimeric nature of these constructs, the unambiguous composition and ease of production make this type of dendrimer well suited to various biotechnological and biochemical applications. Applications include use as biomedical diagnostic reagents, protein mimetics, anticancer and antiviral agents, vaccines and drug and gene delivery vehicles. This review focuses on the different types of peptide dendrimers currently in use and the synthetic methods commonly employed to generate peptide dendrimers ranging from stepwise solid-phase synthesis to chemoselective and orthogonal ligation.     

Peptide and glycopeptide dendrimers and analogous dendrimeric structures and their biomedical applications

The size of information that can be stored in nucleic acids, proteins, and carbohydrates was calculated. The number of hexamers for peptides is 64,000,000 (20⁶) and seems to be impressive in comparison with 4,096 (4⁶) hexanucleotides, but the number of isomers of hexasaccharides is 1.44 × 10¹⁵. Carbohydrates are therefore the best high-density coding system. This language has been named glycocode resp. sugar code. In comparison with peptide dendrimers, the amount of information carried by glycopeptide dendrimers or glycodendrimers is therefore much higher. This is reflected by the variability of structures and functions (activities). This review is about the broad area of peptide and glycopeptide dendrimers. The dendrimeric state and physicochemical properties and general consequences are described, together with a cluster effect. The impact of cluster effect to biological, chemical, and physical properties is discussed. Synthesis of dendrimers by convergent and divergent approaches, “Lego” chemistry, ligation strategies, and click chemistry is given with many examples. Purification and characterization of dendrimers by chromatographic methods, electromigration methods, and mass spectrometry are briefly mentioned. Different types of dendrimers with cyclic core, i.e. RAFTs, TASPs and analogous cyclic structures, carbopeptides, carboproteins, octopus glycosides, inositol-based dendrimers, cyclodextrins, calix[4]arenes, resorcarenes, cavitands, and porphyrins are given. Dendrimers can be used for creation of libraries, catalysts, and solubilizing agents. Biocompatibility and toxicity of dendrimers is discussed, as well as their applications in nanoscience, nanotechnology, drug delivery, and gene delivery. Carbohydrate interactions of glycopeptide dendrimers (bacteria, viruses, and cancer) are described. Examples of dendrimers as anti-prion agents are given. Dendrimers represent a fast developing area which partly overlaps with nanoparticles and nanotechnologies.     

Enhanced delivery of antisense oligonucleotides with fluorophore-conjugated PAMAM dendrimers

PAMAM dendrimers are cationic polymers that have been used for the delivery of genes and oligonucleotides to cells. However, little is known about the behavior of dendrimer–nucleic acid complexes once they reach the cell interior. To pursue this issue, we prepared dendrimers conjugated with the fluorescent dye Oregon green 488. These were used in conjunction with oligonucleotides labeled with a red (TAMRA) fluorophore in order to visualize the sub-cellular distribution of the dendrimer–oligonucleotide complex and of its components by two-color digital fluorescence microscopy. The 2′-O-methyl antisense oligonucleotide sequence used in these studies was designed to correct splicing at an aberrant intron inserted into a luciferase reporter gene; thus effective delivery of the antisense agent results in the expression of the reporter gene product. The dendrimer–oligonucleotide complex remained associated during the process of uptake into vesicular compartments and eventual entry into the nucleus. Since the pharmacological activity of the antisense compound was manifest under these conditions, it suggests that the dendrimer–oligonucleotide complex is functionally active. A surprising result of these studies was that the Oregon green 488-conjugated dendrimer was a much better delivery agent for antisense compounds than unmodified dendrimer. This suggests that coupling of relatively hydrophobic small molecules to PAMAM dendrimers may provide a useful means of enhancing their capabilities as delivery agents for nucleic acids.     

Low‐generation asymmetric dendrimers exhibit minimal toxicity and effectively complex DNA

Conventional dendrimers are spherical symmetrically branched polymers ending with active surface functional groups. Polyamidoamine (PAMAM) dendrimers have been widely studied as gene delivery vectors and have proven effective at delivering DNA to cells in vitro. However, higher‐generation (G4‐G8) PAMAM dendrimers exhibit toxicity due to their high cationic charge density and this has limited their application in vitro and in vivo. Another limitation arises when attempts are made to functionalize spherical dendrimers as targeting moieties cannot be site‐specifically attached. Therefore, we propose that lower‐generation asymmetric dendrimers, which are likely devoid of toxicity and to which site‐specific attachment of targeting ligands can be achieved, would be a viable alternative to currently available dendrimers. We synthesized and characterized a series of peptide‐based asymmetric dendrimers and compared their toxicity profile and ability to condense DNA to spherical PAMAM G1 dendrimers. We show that asymmetric dendrimers are minimally toxic and condense DNA into stable toroids which have been reported necessary for efficient cell transfection. This paves the way for these systems to be conjugated with targeting ligands for gene delivery in vitro and in vivo. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Effect of size, surface charge, and hydrophobicity of poly(amidoamine) dendrimers on their skin penetration

The barrier functions of the stratum corneum and the epidermal layers present a tremendous challenge in achieving effective transdermal delivery of drug molecules. Although a few reports have shown that poly(amidoamine) (PAMAM) dendrimers are effective skin-penetration enhancers, little is known regarding the fundamental mechanisms behind the dendrimer-skin interactions. In this Article, we have performed a systematic study to better elucidate how dendrimers interact with skin layers depending on their size and surface groups. Franz diffusion cells and confocal microscopy were employed to observe dendrimer interactions with full-thickness porcine skin samples. We have found that smaller PAMAM dendrimers (generation 2 (G2)) penetrate the skin layers more efficiently than the larger ones (G4). We have also found that G2 PAMAM dendrimers that are surface-modified by either acetylation or carboxylation exhibit increased skin permeation and likely diffuse through an extracellular pathway. In contrast, amine-terminated dendrimers show enhanced cell internalization and skin retention but reduced skin permeation. In addition, conjugation of oleic acid to G2 dendrimers increases their 1-octanol/PBS partition coefficient, resulting in increased skin absorption and retention. Here we report that size, surface charge, and hydrophobicity directly dictate the permeation route and efficiency of dendrimer translocation across the skin layers, providing a design guideline for engineering PAMAM dendrimers as a potential transdermal delivery vector.     

Stimuli-responsive nanocarriers for intracellular delivery

The emergence of different nanoparticles (NPs) has made a significant revolution in the field of medicine. Different NPs in the form of metallic NPs, dendrimers, polymeric NPs, carbon quantum dots and liposomes have been functionalized and used as platforms for intracellular delivery of biomolecules, drugs, imaging agents and nucleic acids. These NPs are designed to improve the pharmacokinetic properties of the drug, improve their bioavailability and successfully surpass physiological or pathological obstacles in the biological system so that therapeutic efficacy is achieved. In this review I present some of the current approaches used in intracellular delivery systems, with a focus on various stimuli-responsive nanocarriers, including cell-penetrating peptides, to highlight their various biomedical applications.