Green and Functional Aerogels by Macromolecular and Textural Engineering of Chitosan Microspheres

Tremendous interest was recently devoted to the preparation of porous and functional materials through sustainable route, including primarily the use of renewable biopolymers instead of petroleum‐sourced synthetic chemicals. Among the biopolymers available in enormous quantity, chitosan – obtained by deacetylation of chitin – stands as the sole nitrogen‐containing cationic amino‐sugar carbohydrate. This distinctively provides chitosan derivatives with plenty of opportunities in materials science. Particularly, its pH switchable solubility allowed the preparation of three‐dimensional entangled nanofibrillated self‐standing microspheres. These porous hydrogels behave as nano‐reactors to confine exogenous nanoobjects within the polysaccharide network, including sol‐gel metal alkoxide species, organometallic derivatives and isotropic and oriented nanoparticles. Besides, the interfacial interplay of chitosan with lamellar clay and graphene oxide allowed the penetration of the biopolymer inside of the galleries, which result in a complete delamination of the layered nanomaterials. The preserved gelation memory of chitosan in these formulations provides a way to access porous microspheres entangling exfoliated nanometric sheets. CO₂ supercritical drying of functional hydrogel beads enabled efficient removal of water and other liquid solvents without wall collapsing, allowing large‐scale preparation of millimetric hydrocolloidal microspheres with an open macroporous network. These functionalized lightweight biopolymer aerogels find applications in heterogeneous catalysis, sensing, adsorption, insulation and for the design of other sophisticated porous nanostructures. Beyond their tailorable molecular and textural‐engineering, the possibility for macroscopic shaping of these intriguing nanostructures opens many new opportunities, especially in additive‐manufacturing for soft and hybrid robotics.     

Rapid measurements of curcumin from complex samples coupled with magnetic biocompatibility molecularly imprinted polymer using electrochemical detection

Curcumin widely exists in food, and rapid selective and accurate detection of curcumin have great significance in chemical industry. In this experiment, a new magnetic biocompatibility molecularly imprinted polymer was prepared with nontoxic and biocompatible Zein to adsorb curcumin selectively. The polymer has high biocompatibility, good adsorption capacity, and specific adsorption for curcumin. Combined with portable electrochemical workstations, the polymer can be used to detect curcumin rapidly and cost‐effectively. Using curcumin as a template and Zein as the crosslinking agent, the polymers were synthesized on the surface of Fe₃O₄ particles for solid phase extraction. The experimental results showed that the polymer reached large adsorption capacity (32.12 mg/g) with fast kinetics (20 min). The adsorption characteristic of the polymer followed the Langmuir isotherm and pseudo‐second‐order kinetic models. Hexacyanoferrate was used as electrochemical probe to generate signals, and the linear range was 5–200 µg/mL for measuring curcumin. The experimental analysis showed that the polymer was an ideal material for selective accumulation of curcumin from complex samples. This approach has been successfully applied to the determination of curcumin in food samples with electrochemical detection, indicating that this is a feasible and practical technique.     

磁性微珠的制备及其在生物样品分离富集中的应用

磁性微珠作为一种新型的功能材料,广泛应用于磁性材料、生物医学、细胞学、生物工程及分离工程等诸多领域,并显示出强大的生命力。本文对磁性微珠的结构、性质、制备方法及其在生物样品的分离富集等方面的应用,进行了总结和评述,引用文献62篇。     

Preparation of crosslinked epoxy microparticles via phase inversion

Differential scanning calorimetry (DSC) and scanning electron microscopy (SEM) studies have been performed to reveal a crosslinked epoxy nature of the spherical particles formed in cured epoxy/DDS/PMMA blends. An interesting phase inversion phenomenon was observed in cured DGEBA/DDS/PMMA blends, which occurred at a relatively low thermoplastic composition of 20 phr PMMA in blends. A unique method of preparing crosslinked epoxy spheres of controlled sizes based on cure-induced phase inversion is described in this report. Several factors have been found to affect the geometry of the formed epoxy spheres. The volume fraction of PMMA in the blends strongly dominates the influence. With the increase of PMMA volume fraction in the blends, the spheres not only become smaller in sizes, but also more regular in the spherical geometry due to less impingement. The crosslinking density (DDS phr in the blends) has been found to influence the average sizes of the spheres. The cure temperature has relatively limited effects only when the PMMA loadings in the blends are relatively small. Various potential applications for the epoxy microspheres may be investigated in future studies. © 1996 John Wiley & Sons, Inc.     

PREPARATION OF POLYMER MICROSPHERES WITH PYRIDYL GROUP AND THEIR STABILIZED GOLD METALLIC COLLOIDS

Narrow disperse poly(ethyleneglycol dimethacrylate-co-4-vinylpyridine)(poly(EGDMA-co-4-VPy))microspheres were prepared by distillation-precipitation copolymerization of ethyleneglycol dimethacrylate(EGDMA)and 4-vinylpyridine (4-VPy)with 2,2'-azobisisobutyronitrile(AIBN)as initiator in neat acetonitrile.The polymer microspheres containing pyridyl group were then utilized as stabilizer for gold metallic colloids with the diameter around 7 nm,which were prepared by the in situ reduction of gold chloride trihydrate with sodium borohydride through the coordination of the pyridyl group on the gel layer and surface of the microsphere with the gold metallic nano-particles.The catalytic properties of the pyridyl- functionalized microsphere-stabilized gold metallic colloids and the behavior of the stabilized-catalyst for the recycling were investigated with reduction of 4-nitrophenol to 4-aminophenol as a model reaction.     

Pd/PdO纳米复合微球的合成及催化性能

采用甲基丙烯酸锌加速还原氯化钯(PdCl₂) 溶液中的钯离子(Pd ²⁺)为钯(Pd) 纳米微球, 进而用得到的钯纳米微球直接制备钯/氧化钯(Pd/PdO) 纳米复合微球. 通过扫描电子显微镜(SEM)、 透射电子显微镜(TEM)、 粉末X射线衍射分析(XRD)及X射线光电子能谱分析(XPS) 等方法对 Pd/PdO 纳米复合微球进行表征, 结果表明, 制备的纳米复合微球为表面粗糙、 大小均一的纳米微球. 采用紫外-可见吸收光谱(UV-Vis) 等方法考察了 Pd/PdO 纳米复合微球在对硝基苯酚(4-NTP) 还原反应中的催化性能, 发现其具有良好的催化活性和循环稳定性.     

以橡子为碳源制备的空心磁性碳纳米球及其吸附性能

以橡子为碳源,通过高温煅烧法制备了粒径均匀的磁性空心碳纳米球(MHCNS)。经过HCl浸泡处理可得MHCNS-1,再经HNO_3和NH_3·H_2O处理得MHCNS-2。MHCNS-2粒径均匀,直径为20～40 nm,球壁厚度为3～5 nm。MHCNS-2的尺寸可通过改变镍离子与氢氧化钾的添加量和比例进行调控。通过X射线粉末衍射、扫描电镜、透射电镜、振动样品磁强计等方法对制备的产物进行了表征,进而分析了其生长机制。MHCNS-2对于有机染料亚甲基蓝(MB)的吸附性能的实验结果表明,MHCNS-2具有强吸附性能,当MB溶液浓度为100 mg·L~(-1)时,吸附量可以达到185 mg·g~(-1)。MHCNS对布洛芬的载药释药实验结果表明,MHCNS-2载药率可达44%,释药率达70%,有着良好的载药与释药能力。     

在CPS微球表面固载氨基酚型双齿席夫碱氧钒(Ⅳ)配合物及其催化氧化性能

使乙醛酸(GA)与氯甲基化交联聚苯乙烯(CMCPS)微球发生酯化反应,将醛基(AG)引入交联聚苯乙烯(CPS)微球表面,得到改性微球CPS-AG;再以间氨基苯酚(MAP)为试剂,使微球CPS-AG表面的AG发生席夫碱反应,制得了表面键合有氨基酚型双齿席夫碱配基的功能微球CPS-AGAP;最后,使微球CPS-AGAP与硫酸氧钒发生配位螯合反应,获得了表面固载有氨基酚型双齿席夫碱氧钒(Ⅳ)配合物的固体催化剂微球CPS-[VO(AGAP)2]。重点考察了主要因素对GA与CMCPS微球的酯化反应的影响。采用红外光谱(FT-IR)、固体紫外(UV)及扫描电子显微镜(SEM)对催化剂微球进行了充分表征。分别将微球CPS-[VO(AGAP)2]用于环己醇和乙苯的分子氧氧化过程,考察其催化活性。实验结果表明,溶剂的极性有利于GA与CMCPS微球之间的酯化反应,极性较强的N,N-二甲基乙酰胺为适宜的反应溶剂,90℃为适宜的反应温度。在适宜的反应条件下,CMCPS微球的氯甲基转化率可以达到82%。在分子氧氧化环己醇和乙苯的过程中,非均相催化剂CPS-[VO(AGAP)2]微球均表现出良好的催化活性。     

Preparation and characterization of imprinted microspheres for clopyralid

In this work, the molecularly imprinted polymers (MIPs) and non-imprinted polymers (NIPs) for clopyralid (3,6-DCP) were successfully synthesized via precipitation polymerization using methacrylic acid (MAA) as functional monomer, ethylene glycol dimethacrylate (EGDMA) as crosslinker and a mixture of butanone (MEK) and n-heptane as porogen under the existence of azobisisobutyronitrile (AIBN). The morphologies, particle sizes, structures, adsorption properties and selective recognitions of polymers were investigated systematically. The average particle sizes of MIP3 and NIP3 were 2.76 μm and 2.15 μm. The apparent maximum binding amount (Q_max) of MIP3 and NIP3 were 67.50 mg·g^?1 and 65.02 mg·g^?1 in Scatchard analysis. Langmuir isotherm displayed that the Langmuir constant (K_l) of MIP3 and NIP3 were 0.015 L·mg^?1 and 0.0065 L·mg^?1, the saturation adsorption capacity (Q_max) of MIP3 and NIP3 were 63.23 mg·g^?1 and 58.17 mg·g^?1. Lagergren pseudo-second-order kinetic plot described that the adsorption process of MIP3 was visualized as chemical absorption. Selectivity analysis revealed that MIP3 possessed highly specific recognition for 3,6-DCP.