壳聚糖载药阿司匹林复合纤维的制备及其释药性能

为研制具有缓释效果的解热镇痛材料,以阿司匹林(Asp)为模型药剂、壳聚糖(CS)为纺丝基材、聚丙烯酸钠(PAAS)为助纺高分子,采用静电纺丝和热处理制备了Asp-CS/PAAS复合纤维材料;研究了热处理温度对复合纤维微观形貌、化学结构、力学性能以及体外释药行为的影响。结果表明:以10wt%的聚丙烯酸钠作为共纺高分子可以形成直径约886 nm的纤维,热处理温度的提高可以提高纤维的耐溶剂性能,但会降低纤维的拉伸强度;进一步的研究结果表明简单的热处理可以调控纤维的溶胀性能,从而实现调节阿司匹林药物的释放速率,缓释曲线符合Higuchi模型。     

高分子复合物纤维的研究进展

功能化和智能化是纤维发展的趋势.单一组分纤维难以满足日益发展的需求,而多组分纤维能够集中不同组分的特点,实现性能的集成与优化.通过非共价相互作用,高分子聚集而形成多组分均相体系,称为高分子复合物.利用高分子复合物的形成过程使纤维成型;或者直接利用高分子复合物进行纺丝而得到的纤维称为高分子复合物纤维.高分子复合物纤维,各组分可以达到分子层面上的相容性,给我们提供了一个功能纤维和智能纤维设计开发的平台.本文详细阐述了各类高分子复合物纤维的研究现状,并展望高分子复合物纤维的未来发展.     

无规聚丙烯腈纤维热处理过程相转变行为的同步辐射研究

使用在线同步辐射广角X射线衍射(WAXD)和原位变温傅里叶红外(FTIR)研究了无规聚丙烯腈(at-PAN)纤维热处理过程中晶区的相转变行为.研究发现,WAXD图像中由(110)晶面衍射形成的衍射弧在加热过程中其q值随温度的变化速率不完全一致,在110℃存在突变点,此温度下晶区的热膨胀率从4.15×10-4nm/K(α1)突变为1.13×10-3nm/K(α2),同时DSC曲线在110℃附近出现放热峰,说明发生了晶胞结构转变.通过升温FTIR测试发现1230 cm-1和1250 cm-1处吸收峰的相对强度随热处理过程也发生变化,两峰峰强分别对应纤维中31螺旋构象与平面锯齿构象的相对含量,通过C=I1250/I1230与热处理温度的关系发现C值在110℃突然急剧减小,说明at-PAN纤维晶区分子链在110℃附近发生了平面锯齿构象向31螺旋构象的剧烈转变,而正是由于这种转变导致晶区层间距的变化使得WAXD图像中衍射弧的位置随温度变化速率不一致,即相转变行为是由分子链构象的变化引起的.     

多组分高分子复合物纤维的制备与性能调控

多组分是实现纤维性能提升和调控的有效手段.利用传统方法制备的多组分纤维,不同高分子之间很难达到分子层面相容.高分子复合物是不同高分子高度相容的聚集组装体系.本工作研究聚氧化乙烯(PEO)、聚乙烯醇(PVA)和聚丙烯酸(PAA) 3种组分制备复合物纤维.利用红外光谱、X射线衍射、示差扫描量热、扫描电子显微镜和力学拉伸等方法分别表征氢键复合、纤维的聚集态结构和力学性质.研究结果表明,PEO/PVA/PAA纤维不同组分高度相容,通过改变纤维中组分的含量,可以实现对多组分复合物纤维的性能调控.纤维中柔性PEO组分含量增加,可以实现由塑性到弹性的转变,并且纤维在湿度场下表现出形状记忆与可修复行为.     

聚丙烯腈电纺纤维的功能化

聚丙烯腈是一种性能优异、应用广泛的成纤聚合物,静电纺丝技术则可用于制备聚丙烯腈纳米纤维,本文对聚丙烯腈纳米纤维的功能化进行了综述.通过表面仿生修饰、碳纳米管填充等方法改性的聚丙烯腈电纺纤维被尝试作为酶固定化的载体材料,在显著提高载酶量的同时,能大幅度提高酶活性.糖基功能化的纳米纤维对特定的蛋白质具有较高的识别效率,可望用于蛋白质的分离与纯化.卟啉化的聚丙烯腈电纺纤维则在显示出荧光特性的同时,在催化、传感等方面具有潜在的应用前景.     

最高强度的高分子材料

日本研究出强度最高的高分子材料。这种新材料是聚丙烯酸酯类的一种。直径拉伸到0.12mm的纤维,其断裂强度达9500kg/mm~?。在高强度材料中,著名的产品是杜邦公司生产的芳纶-Ⅱ(Kelvlar)。本发明的新材料有可能产生超强度纤维,从而使杜邦公司失去垄断地位。聚丙烯酸酯具有如下优点:由于它在300℃左右是可溶的,所以拉伸成丝的成型加工简单,而且不仅可以将其加工成纤维,还可制成管材和板材。     

中国化学会第17届反应性高分子学术讨论会征文启事

正经中国化学会批准,中国化学会第17届反应性高分子学术讨论会定于2014年7月18~21日在常州大学召开,欢迎您报名参加,并欢迎您就下列内容踊跃投稿:1.离子交换材料、吸附材料、高分子催化剂、高分子试剂2.生物医用高分子材料3.新型反应性高分子(如高分子膜、纤维等分离材料)4.反应性高分子的合成、应用及表征论文摘要要求具有创新性、指导性,凡已在国内外学术会议上报     

基于苯乙烯和苯并噻二唑共聚场效应发光高分子材料的设计合成及性能研究

共轭高分子材料由于其优异的光电性能和可溶液加工等特性在有机光电器件中具有重要应用.本工作采用Stille偶联和Suzuki聚合反应,合成了两个由经典发光基元苯乙烯片段和共轭吸电子结构基元苯并噻二唑共聚的高分子材料聚（1,2-双（2,5-双（异辛氧基）亚苯基亚乙烯基-2,1,3-苯并噻二唑））（PVBT）和聚（1,2-双（2,5-双（正辛氧基）亚苯基亚乙烯基-2,1,3-苯并噻二唑））（nPVBT）.通过凝胶渗透色谱（GPC）、元素分析及差式扫描量热法（DSC）对PVBT和nPVBT两种高分子材料的结构及热稳定性进行表征,结果表明它们均具有良好的热稳定性,分解温度约380℃.由于烷氧基链的存在,两个材料具有良好的溶解性及成膜加工性.PVBT和nPVBT均表现出优异的发光特性,最大发射波长在590~605 nm范围,溶液下荧光量子产率为23%~35%,固态薄膜下量子产率为12%~20%.以这两个高分子材料薄膜作为活性层,所制备的顶栅-底接触型有机场效应晶体管器件显示出典型的p型电荷传输性能,空穴迁移率可达1.1×10^-4 cm²·V^-1·s^-1,开关比为10³~10⁴.本研究为发展高性能光电集成高分子材料提供了新思路,有望推动有机光电集成器件的研究.     

高分子-过渡金属络合物在2-氯-4-硝基甲苯还原中的催化作用

本文研究了高分子-过渡金属(钯、铂和镍)络合物在2-氯-4-硝基甲苯的硝基还原反应中的催化活性及选择性.实验结果表明:高分子-金属络合物具有较高的稳定性,高分子-钯和铂络合物在常压和低温下具有较高的催化活性,高分子-镍络合物在较高温度(100～140℃)和较高压力(3～10MPa)下具有一定的的活性.对于本体系,催化剂活性顺序为:PMS-Pd,PMV-Pd,PAA-AN-Pd>PAM-Pt>PAA、VPy-Pd>高分子镍络合物.与Raney Ni相比,高分子-铂和镍络合物具有较高的选择性,其顺序为:PVP-Ni;N-l-Ni;PMV-Ni>=PAM-Pt>Raney NI>>PMS-Pd,PMV-Pa,PAA-AN-Pd,PAA-VPy-Pd.此外还初步地探讨了取代基、压力和温度对催化活性的影响     

聚乙烯醇缩丁醛/氧化铝杂化高分子材料的研究

由异丙醇铝与乙酰丙酮反应制备铝 乙酰丙酮螯合物 ,由此通过控制水解制备Al2 O3 溶胶 .该溶胶与聚乙烯醇缩丁醛分子上残存的羟基发生交联生成有机 无机溶胶 (OIS) .OIS经成型和干燥后即可方便地形成耐溶剂性的有机 无机杂化高分子材料 ,如透明薄膜和高弹纤维 .将OIS涂覆在碳纤维束丝上 ,热处理无机化后 ,可得到非常均匀致密的无定形氧化铝 -碳涂层 .该涂层可明显提高碳纤维的耐高温氧化性和表面特性     

STUDIES ON PAN MACROMOLECULAR SEMICONDUCTING FIBER 1. PREPARATION OF PAN CONDUCTING FIBER TREATED BY STANNIC CHLORIDE AND ITS SEMICONDUCTING BEHAVIOUR

The PAN fiber treated by Lewis acid (e.g. stannic chloride) could be transformed into a macromolecular conducting fiber by further thermal treatment. Depending on thermal treatment condition the resistance of the fiber varied from 10~3 to 10~(12) Ωand kept stable after hydrolysis. The fiber has enough strength to be processed by various means. This is a new kind of macromolecular semiconducting fiber having some characteristics similar to those of organic semiconductors.     

浸润性可调的导电聚苯胺/聚丙烯腈同轴纳米纤维

聚苯胺(PANI)因其具有可调的导电性、优异的化学稳定性、简单的制备方法等特点, 在化学电源、抗静电涂层、电磁屏蔽材料、抗腐蚀、传感器等领域具有广泛的应用前景[^1~4]. 由于聚苯胺的刚性分子链使得聚苯胺几乎不溶不熔, 难以加工应用, 因此, 将导电聚合物直接制成纳米纤维一直是合成纤维界所希望的目标之一. 此外, 由于材料尺度的减小, 使纳米材料的表面与界面性质,尤其是表面浸润性变得更为突出.浸润性是固体表面的重要特征之一, 它主要由表面的化学组成和微观结构共同决定^[5,6]. 可调的浸润性在超疏水材料、药物传输、仿生材料和微流体等领域具有重要的应用价值^[7~10] , 引起人们广泛关注.     

Low Temperature Preparation of Titania Coated PAN Fiber and Its Photocatalytical Property

Titania thin film was deposited successfully on polyacrylonitrile (PAN) fiber by the sol‐gel process with the assistance of tetraethyl silicate (TEOS) at low temperature. It was found that the densification and crystallization of the film was a result of the post‐treatment in boiling water because of the hydrolysis of the Si‐O‐Ti bonds and dissolution of the silica component formed in the film. XRD patterns revealed the existence of anatase phase in the continuous titania layer. The product, titania coated polyacrylonitrile fiber (TiO₂/PAN), showed a high photocatalytic property and good repetition on the photodegradation of methylene blue (MB). The proposed method is expected to be used for the preparation of novel photo‐catalysts based on thermally sensitive substrates.     

The 140-GHz (D-band) saturation transfer electron paramagnetic resonance studies of macromolecular dynamics in conducting polymers

The high-field/high-frequency (5 T, 140 GHz) saturation transfer electron paramagnetic resonance (ST-EPR) method was used for the study of superslow librational macromolecular dynamics in various conducting polymers. It was shown that the increase of the electron precession frequency allows separate determination of spin relaxation and dynamics differently affecting effective ST-EPR spectra. Higher microwave frequency increases significantly the spectral resolution of the method and its sensitivity to the anisotropic macromolecular motion in conducting polymers. This broadens the interval of correlation time measured, thereby extending the slow-motion limit for ST-EPR by at least 2 orders of magnitude compared with convenient waveband EPR.     

Modification of wool fiber using steam explosion

Wool fiber was modified by steam explosion in this study. SEM results show that some scales on the fiber surface were cleaved and tiny grooves generated during the explosion. FTIR results suggest no evident changes in the chemical composition of the fiber after the explosion treatment. However, the crystallinity of the fiber decreased slightly as the steam pressure increased based on the X-ray results. In the thermal analysis, DSC results show that the temperature corresponding to vaporization of absorbed water and cleavage of disulfide bonds respectively decreased as the steam pressure increased. The reduction in thermal decomposition energy of the treated fiber indicates that steam explosion might have destroyed some crystals and crosslinks of macromolecular chains in the fiber. The treatment also led to some alterations of the fiber properties, including reduction in strength, moisture regain and solubility in caustic solution.     

Characterization of macromolecular orientation in κ-carrageenan fibers using polarized Fourier-transform infrared spectroscopy

In the current study, polarized infrared (IR) microspectroscopy was employed to characterize the macromolecular orientation in wet-spun and stretched κ-carrageenan fibers. The fibers were shown to be well oriented by X-ray diffraction, suggesting that the κ-carrageenan molecules were generally aligned along the fiber axis direction. Longitudinal fiber pieces of about 10 μm thick were obtained by focused ion beam (FIB) micromilling. The fiber pieces were examined by polarized IR in transmission mode. Several bands, including those characteristic of κ-carrageenan at 845 and 930 cm⁻¹, were polarization-dependent, demonstrating polarized IR as a useful tool to evaluate macromolecular orientation in carrageenan fibers. Band assignments were discussed by considering the general alignment of molecules and the polarization dependence of vibration modes, and our results agreed well with band assignments from previous reports.     

Preparation of MnO2 Loaded Hydrothermal Carbon-coated Electrospun PAN Fiber Membranes for Highly Efficient Adsorption and Separation of Cationic Dye

Hydrothermal carbonaceous materials and MnO₂ have been proved to be promising adsorbents to remove organic dyes from wastewater. In this study, flexible MnO₂ loaded hydrothermal carbon-coated electrospun poly-acrylonitrile(AC/MnO₂/PAN) fiber membranes were fabricated by a facile one-step hydrothermal method and activated by NaOH solution. The composite fibers exhibited large adsorption capacity toward cationic dyes and excellent mechanical properties. The adsorption performance can be fitted well with pseudo-second-order model and Langmuir isotherm model. The maximum adsorption for methylene blue(MB), methyl violet(MV) and malachite green(MG) are 1173.27,1106.31 and 1129.89 mg/g, respectively, according to Langmuir fitting. The AC/MnO₂/PAN fiber membrane also showed satisfactory performances for selective adsorption and recyclability. In addition, based on selective adsorption, the AC/MnO₂/PAN fiber membranes that are repulsive to the anionic dye methyl orange(MO) can separate the MB/MO mixture solution by dynamic filtration. Thus, this work not only provides a facile strategy to fabricate large capacity adsorbents, but also demonstrates the potential applications in the dye wastewater treatment field.     

Evolution of the composition and structure of PAN carbon fiber during preoxidation

Using scanning electronic microscope, X-ray diffraction analysis, PYR-GCMS and IR etc., we studied the evolving process of the composition and structure of PAN carbon fiber during preoxidation. In the initial stage of preoxidation, PAN filament tows disappear and become semi-thaw. At first, reactions happen between the copolymers and esters disappear. The molecules annularly crosslink and the index of cyclation slowly increases. It is easy to fix the structure and form defects during the initial and the medium stages, which are most reactive. More traction is advised in these stages to minimize the structural deficiencies. In the medium stage of preoxidation, the fiber was reshaped into new sheet stacks and gradually changed to sheet sectors, and this structure tends to be stable in the final stage. Induced by acid and ester copolymer, PAN fiber forms a very stable cycle structure in the final stage. Besides, monomer, dimmer and trimer obviously decrease. In the final stage of the preoxidation, there exi     

Sisal fibers coated with conducting polyaniline: Property and structural studies

Sisal (Agave sisalana) fiber was extracted by manual process. These fibers were subjected to surface coating with conducting polyaniline, through in situ oxidative polymerization. The polyaniline modified sisal fibers were characterized by thermal, spectroscopic and microscopic techniques. It was shown that the fiber was coated with polyaniline through in situ oxidative polymerization and the latter had a smoothing effect on the surface as compared to uncoated sisal fiber. Besides, it was confirmed that polyaniline was deposited in conductive form of emeraldine salt. This in turn verified the introduction of active functionalities to the system, which is helpful to tune up surface chemistry of polyaniline for water treatment applications.     

Process optimization and empirical modeling for electrospun polyacrylonitrile (PAN) nanofiber precursor of carbon nanofibers

Ultrafine fibers were spun from polyacrylonitrile (PAN)/N,N-dimethyl formamide (DMF) solution as a precursor of carbon nanofibers using a homemade electrospinning set-up. Fibers with diameter ranging from 200 nm to 1200 nm were obtained. Morphology of fibers and distribution of fiber diameter were investigated varying concentration and applied voltage by scanning electric microscopy (SEM). Average fiber diameter and distribution were determined from 100 measurements of the random fibers with an image analyzer (SemAfore 5.0, JEOL). A more systematic understanding of process parameters was obtained and a quantitative relationship between electrospinning parameters and average fiber diameter was established by response surface methodology (RSM). It was concluded that concentration of solution played an important role to the diameter of fibers and standard deviation of fiber diameter. Applied voltage had no significant impact on fiber diameter and standard deviation of fiber diameter.