固相合成寡糖的进展

固相法是一种非常有前途的合成寡糖的方法。本文综述了固相法合成寡糖的进展。论述了固相合成寡糖的原理、所用的聚合物载体、合成过程的检测、偶联和拆解的方法等。     

微波合成对SrAl2O4:Eu2+, Dy3+晶相和铕的价态的影响

为了在较低温度下合成性能优良的SrAl2O4：Eu^2＋,Dy^3＋（SAO—ED）发光材料,采用溶胶-凝胶-微波法在900℃烧结30min合成SAO—ED发光材料。产品的发光性能优于传统高温固相法1400℃烧结3h制备的产品。根据Henderson和Taylor提出的公式对SrAl2O4的XRD数据进行了量化,计算出单斜晶系（M）和六方晶系的比例;结果表明,溶胶-凝胶-微波法制备的产品中只有单斜晶系存在,而高温固相法制备的产品中有六方晶系存在,六方晶系不发光。另外,产品采用XANES表征了Eu离子存在的价态,发现溶胶一凝胶微波法制备的产品中残留的Eu^3＋的比例远低于传统高温固相法制备的产品。以上两种原因导致了产品的发光性能优于高温固相法制备的产品。     

近红外水溶性不对称吲哚方酸菁染料的合成

以吲哚啉季铵盐为原料, 分别采用两步法和固相法合成了3种水溶性不对称吲哚方酸菁染料. 两步法为将不同N-烷基取代的2,3,3-三甲基-3H-吲哚-5-磺酸季铵盐与方酸反应, 再与另一种吲哚啉季铵盐反应制备不对称菁染料. 固相法是用对氨基苯甲酸做桥连物, 将方酸化学键连到高分子固相载体聚乙二醇上, 然后与吲哚啉季铵盐杂环母核缩合制得带有固相高分子载体的半菁, 再与另一吲哚啉季铵盐杂环母核反应切掉载体, 合成不对称菁染料. 产品用C-18反相柱进行分离提纯, 通过核磁共振氢谱和质谱对产品结构进行了表征, 测试了产品的光谱性能. 比较而言, 固相法合成不对称染料效果更好, 产率接近传统两步法的二倍, 是一种更适合的合成水溶性不对称吲哚方酸菁染料的方法.     

液相组合化学

综述了液相组合化学的研究进展，重点介绍了液相组合合成中的分离纯化方法和合成方法策略，基本分离纯化方法包括利用固相载体协助分离纯化法，相萃取分离纯化法和色谱法，主要合成方法策略有平行合成策略和索引合成策略。     

溶胶-凝胶法合成Li_4SiO_4

Li4SiO4具有有利于离子传导的结构,为锂离子导体理想的基质材料[1].在硅酸盐体系中,硅的聚合态很复杂,难以得到纯相,鉴于固相法操作简单,在已有的文献中,合成方法多为固相法,但固相法不易保证成份的准确性、均匀性且合成温度较高.溶胶-凝胶法是近几年来发展起来的湿化学合成方法,用此法合成离子导体具有纯度高、均匀性好、颗粒小、反应过程易于控制等优点[2],而通常的溶胶-凝胶法是用金属醇盐与有机盐为前驱物,这样成本较高,且易造成污染.本文用金属醇盐及无机盐为前驱物,用溶胶-凝胶法合成了Li4SiO4纯相,并同一般固相法相比较,对合成的…     

组合化学在功能材料合成方面的应用

组合化学方法是当今材料科学和化学领域的研究热点。组合化学方法首先在新药的合成领域得到应用, 很快就以其合成周期短、合成的样品数量大、节约经费等诸多优点而拓展到功能材料的合成等其它领域。组合化学的方法有许多种, 按照反应相的不同可以分为液相中的组合合成法和固相中的组合合成法, 固相组合合成又可以根据所选用的掩模方式的不同而分为二分阴影掩模法、四分阴影掩模法、可移动百叶窗式掩模法等几种, 可以根据材料合成的实际需求加以选择。     

固相载体法合成低聚糖

固相载体法合成低聚糖;固相载体;合成;低聚糖;偶联剂     

糖肽的固相合成

综述了固相法合成糖肽的最新进展，论述了合成策略和所用聚合物载体，这是一种很有前途的合成糖肽的方法，参考文献４２篇。     

溶胶-凝胶法制备YAl3(BO3)4粉末

使用溶胶-凝胶法、XRD与SEM等方法,研究了YAl3(BO3)4的合成参数.相对于固相合成YAl3(BO3)4需要温度1200 ℃才能形成纯相,溶胶-凝胶法当灼烧温度为900 ℃时,YAl3(BO3)4主相已经形成,当温度升至1100 ℃,可制得纯相,其粒径大约为1 μm.但其中存在晶粒大小不均问题,需进一步研究.     

DNA微阵列原位合成中的氧化剂体系改进

DNA芯片的制备方法主要有离片合成法和在片合成法．离片合成是用点样法将DNA探针固定在基片上;在片合成是在基片表面直接原位合成寡核苷酸探针阵列．目前国外已有多种DNA芯片原位合成方法的报道,但其中仅Fordor等提出的光脱保护DNA固相原位合成技术已商品化,该方法制备成本高,     

A study on size effect of carboxymethyl starch nanogel crosslinked by electron beam radiation

The formation of carboxymethyl starch (CMS) nanogel with 50 nm less particle size was carried out through a radiation crosslinked process on the electron beam (EB) linear accelerator. Changes of intrinsic viscosities and weight averaged molecular weight in the CMS concentration, which ranged from 3 to 10 mg ml^?1 in absorbed doses were investigated. There were some new peaks in the ¹H NMR spectra of CMS nanogel compared with those of CMS polymer. These results were anticipated that the predominant intramolecular crosslinking of dilute CMS aqueous solution occurred while being exposed to a short intense pulse of ionizing radiation. Hydrodynamic radius (often called particle size, R_h) and distribution of particle size were measured by a dynamic light scattering technique. The radiation yield of intermolecular crosslinking of CMS solution was calculated from the expression of G_x (Charlesby, 1960, Jung-Chul, 2010). The influence of the “size effect” was demonstrated by testing culture of Lactobacillus bacteria on MRS agar culture medium containing CMS nanogel and polymer. Results showed that the number of Lactobacillus bacteria growing on nanogel containing culture medium is about 170 cfu/ml and on polymer containing culture medium is only 6 cfu/ml.     

Synthesis and Evaluation of Thiol Polymers

Thiol polymer, which is known as a reactive and functional polymer, is synthesized and evaluated quantitatively by the modified Ellman method. The synthesis was accomplished by 1) hydrolysis of an isothiouronium salt that is the adduct of 4‐chloromethylstyrene (CMS) homopolymer or CMS‐styrene (St) copolymer with thiourea; 2) hydrolysis of a precursor copolymer made from 4‐vinylbenzyl N‐ethyldithio‐carbamate (VBEC) and St or N‐vinyl‐2‐pyrrolidone (NVP); 3) solvolysis of an iminium salt polymer obtained from the reaction of CMS‐NVP copolymer with N,N‐dimethylthioformamide (TDMF). When a higher thiol content is desired, more severe hydrolysis conditions are required which however, also increase the loss of thiol. Hence, it is clear that the best synthesis of thiol polymers is Method 3. A quantitative yield of functional thiol polymer is obtained by this method, and the product is soluble in DMSO, DMF, and CHCI_3.     

Starch derivatives of high degree of functionalization 9: carboxymethyl starches

This paper describes the synthesis of carboxymethyl starch (CMS) ID various alcohols (methanol, ethanol, isopropyl alcohol) as slurry media and with different starch types. The products were investigated regarding their degree of substitution (DS), their reaction efficiency (RE), and their pattern of functionalization. The highest DS obtained ID a one-step procedure was 1.40 with a RE of 82%, applying isopropyl alcohol as slurry medium. Moreover, by using the synthesis concept via a reactive microstructure, CMS samples with high DS values can be achieved ID a one-step synthesis as well. A multi-step carboxymethylation ID methanol, on the other hand, leads to maximal DS values of 2.3 after 10 conversions, dependent on the amylose content of the starch. ¹H NMR spectroscopic investigations show a reactivity ID the order O-2 > O-6 O-3 for the samples prepared ID alcoholic slurry media. ID contrast, the CMS synthesized via reactive microstructure reveals a preferred substitution ID position 6 and a non-statistic distribution of the carboxymethyl groups along the chain. A significant amount of 2,3,4,6-tetra--functionalization, caused by the branched structure of starch, was found.     

Synthesis of core-shell type polystyrene monodisperse particles with chloromethyl groups

The synthesis of core-shell type polystyrene monodisperse particles with surface chloromethyl groups was carried out by a two-step emulsion polymerization process at different reaction temperatures. In a first step, the core was synthesized at 90 °C by means of batch emulsion polymerization of styrene (St), and in the second step, the shell was polymerized by batch emulsion copolymerization of St and chloromethylstyrene (CMS) using the seed obtained previously. With the aim of optimizing the production of these core-shell type polystyrene monodisperse particles with surface chloromethyl groups, the reaction temperature in the second step, the purification or not of the functionalized monomer (CMS), the amount and type of the redox initiator system used, and the type of addition of the initiator system to the reactor were studied.     

Adsorption behavior of carboxymethyl starch on titanium dioxide surfaces

The adsorption of carboxymethyl starch (CMS) on titanium dioxide surface from aqueous solution of electrolyte was investigated by adsorption and electrokinetics mobility measurements. Zeta potential measurements showed that the addition of CMS resulted in a shift of isoelectric point to the more acidic region, indicating the adsorption of CMS from the aqueous solution onto titanium dioxide surface. The positively charged and hydrophilic surface sites of titanium dioxide favor the adsorption of CMS molecules. The adsorption capacity of CMS on titanium dioxide surface was found to be controlled by the number of functional group on CMS that promotes surface charge CMS adsorption in agreement with Langmuir isotherm. For the adsorption of CMS, the pseudo-second-order kinetics of chemical reaction provides the best correlation of the experimental data.     

Electrospinning of carboxymethyl starch/poly(L‐lactide acid) composite nanofiber

Carboxymethyl starch (CMS) is a natural polymer derived from sago starch that is obtained from sago palm (Metroxylon spp.). Herein, CMS was used as a polysaccharide source in preparations of composite nanofibers with poly(L‐lactide acid) (PLLA). The incorporation of CMS with PLLA in nanofiber form has great potential to be used in biomedical applications. The composite PLLA/CMS nanofibers were fabricated by electrospinning technique at various ratios of CMS, which were 5, 10, 15, and 20% vol/vol. The composite nanofibers were characterized according to their physical morphology, chemical interaction, wettability, water uptake, and thermal and mechanical behaviors. The result showed that uniform and bead‐free nanofibers were produced at the low ratio of CMS while fractal and discontinuing fiber was observed at a high ratio of CMS. A better mechanical strength was obtained at low CMS ratio as compared with higher one. Fourier transform infrared results showed that there was an interaction between CMS and PLLA after electrospinning. The surface hydrophilicity and water uptake increased with increasing ratio of CMS. The results from the differential scanning calorimeter analysis showed the decrease of the glass transition (T_g) and cold crystallization temperature (T_cc) of the nanofiber after addition of CMS in PLLA.     

SnNi-deposited carbonaceous mesophase spherule as anode material for lithium ion batteries

Carbonaceous mesophase spherule (CMS) is a commercial anode material for rechargeable lithium batteries. A composite anode material of SnNi deposited carbonaceous mesophase spherule was prepared by co-precipitation method. The structural and electrochemical characterization of the SnNi/CMS composite anode material was studied. According to the measurement of its electrochemical characterization, the prepared SnNi/CMS composite anode material shows much better electrochemical performance than CMS. The first discharge capacity of 360 mA h g⁻¹ was obtained for the SnNi/CMS composite anode material, and its discharge capacity maintained at 320–340 mA h g⁻¹ in the following cycles. It indicates that the modification of CMS with SnNi alloy can further improve the intercalation performance of CMS. SnNi/CMS composite material shows a good candidate anode material for the commercial rechargeable lithium batteries.     

Spontaneous liquid-gas imbibition for characterization of carbon molecular sieves

Spontaneous liquid-gas imbibition at 293.2K and 0.1 MPa was conducted to assess the micropore size and size-exclusion property of carbon molecular sieves (CMS). The CMS were firstly saturated with N(2) and then immersed into water. The volume of gas recovered by the water imbibition was measured and applied to evaluate the density of the N(2) adsorbed in the CMS. The micropore size of the CMS was determined by comparing the N(2) density from the water-N(2) imbibition with that calculated by grand canonical simulation. The micropore size evaluated by the liquid-gas imbibition coincides with that obtained by N(2) adsorption at ambient temperature. The size-exclusion property of the CMS was estimated through comparing the N(2) recovery by imbibition of liquids with increasing molecular dimensions, that is, water, benzene, and cyclohexane. The amount of N(2) recovered from benzene imbibition is dramatically less than that from the water imbibition, showing that the dominated micropore size of the CMS is smaller than 0.37 nm. Furthermore, the effect of chemical vapor deposition treatment on the porous texture of the CMS was revealed by the liquid-gas imbibition.     

Electrochemical Analysis of Liposome-encapsulated Colistimethate Sodium

In this study, the neutral and cationic liposomal formulations of Colistimethate sodium (CMS), an antibiotic for multi-drug resistant gram-negative bacteria, were prepared and electrochemical quantification of CMS from these liposomes were achieved. This is the first study of the electrochemical detection of CMS released from liposomes. First, the electrochemical properties of CMS were analysed, then the encapsulation efficiency, and the release kinetic of CMS from liposomes were determined with Differential Pulse Voltammetry (DPV) measurements. In addition, Cyclic Voltammetry were applied to determine oxidation signal of CMS. A higher encapsulation efficiency was found in the cationic liposome compared to the neutral liposome. Moreover, CMS was controlled released from liposomes with zero-order drug release kinetics.     

Thymine‐functionalized polystyrenes for applications in biotechnology. III. Increasing the thymine loading via a new synthetic pathway

In this article, we report an efficient method for the synthesis of thymine‐functionalized polystyrene microspheres. First, poly(styrene‐co‐4‐chloromethylstyrene) copolymers slightly crosslinked with divinylbenzene were synthesized in batch free‐radical emulsion copolymerization. Microspheres with a particle size of ～40–70 nm were obtained with greater than 99% conversion. The chloromethylstyrene (CMS) groups were then converted into thymylmethylstyrene (TMS) in a two‐phase system with greater than 80% efficiency, and up to a 45 mol % thymine loading was achieved. The functionalized microspheres were characterized by elemental analysis, Fourier transform infrared, and X‐ray photoelectron spectroscopy. The analyses revealed partial hydrolysis of the CMS functionalities, yielding hydroxymethyl functional groups in addition to the thymine functionalities. These copolymers have potential applications in biotechnology. © 2005 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 43: 5545–5553, 2005