表面印迹聚合物及其在微流控器件中的应用

分子印迹聚合物是通过在模板存在下固化交联的聚合物制备的.在固化过程中,聚合物和模板间形成非共价键.这些非共价结合位点被"冻结"在交联的聚合物中,即使移去模板后也依然维持他们的形状.余下的空穴与模板的尺寸和形状一致,并且可以选择性地从流过的混合物中俘获模板物质.在近几十年中,分子印迹的领域由选择性俘获小分子扩展到处理各种类型的样品.分子印迹聚合物(MIP)被用于分析种类繁多的样品,比如金属离子、药物分子、环境污染物、蛋白、病毒以至整个细胞.本文中我们综述相对较新的领域——表面印迹,这是一种可以用来生成相对较大的生物相关模板的印迹方法.传统的整体印迹法是直接在固化前将模板加入预聚体中,因而不适用于那些大到无法从固化后的聚合物中扩散出来的物质.要仅在表面上生成结合位点,必须要使用特别的方法,由此产生的表面印迹技术解决了分离科学以及化学和生物化学监测的重要问题.将印迹聚合物植入微流控芯片,大大扩展了微流体技术的适用性.本文叙述表面印迹最新的进展以及不同的实施手段,以及它们在微流控器件中的应用.     

Molecular Imprinting of Cyclodextrins Leading to Synthetic Antibodies

Molecularly imprinted cyclodextrins were applied to HPLC stationary phases forefficient recognition of nano-scaled guests in water. When cholesterol was usedas a template molecule, the imprinted polymer selectively retained this guest morestrongly and selectively than did non-imprinted polymer. The imprinting effect inthe retention behavior was consistent with previously reportedphysicochemical analyses.Immobilization of the imprinted cyclodextrin polymer on the surfaceof silica gel in water was also successful. The polymer-silica gel compositesobtained had sufficient physical strength, and were useful for HPLC stationary phases. Thesemolecularly imprinted polymers could recognize steroids, amino acid derivatives,dipeptides, and antibiotics. Moreover, we found that the enantio-selectivity towardthe template molecules was significantly promoted. This methodology has greatpotential for the recognition of large guest molecules in water, and can be analternative to affinity chromatography for the separation of bio-molecules.     

光接枝表面修饰法制备牛血红蛋白的分子印迹微球

聚苯乙烯球载体表面经引发转移终止剂修饰后, 采用光接枝表面印迹方法制备了以牛血红蛋白(BHb)为模板分子、丙烯酰胺为功能单体和N,N′-亚甲基双丙烯酰胺为交联剂的分子印迹聚合物微球(MIP). 进一步采用红外光谱(IR)、扫描电子显微镜(SEM)和元素分析对聚合物微球进行了表征, 证实了载体表面成功地接枝了分子印迹层, 并研究了其吸附性能和分子识别选择性能. 结果表明, 采用光接枝表面修饰法制备的分子印迹微球对模板分子有着很好的吸附容量和识别选择性.     

Bioimprinted QCM sensors for virus detection—screening of plant sap

Surface imprinting techniques on polymer-coated quartz-crystal microbalances (QCM) have been used to detect tobacco mosaic viruses (TMV) in aqueous media. Molecularly imprinted polymers (MIP), tailor-made by self organisation of monomers around a template (TMV), were generated directly on the gold electrodes. Imprinted trenches on the polymer surface mimicking the shape and surface functionality of the virus serve as recognition sites for re-adsorption after washing out of the template. The sensors are applicable to TMV detection ranging from 100 ng mL^–1 to 1 mg mL^–1 within minutes. Furthermore, direct measurements without time-consuming sample preparation are possible in complex matrices such as tobacco plant sap.Dedicated to Professor Dr. W. Fresenius on the occasion of his 90th birthday     

Preparation of bovine hemoglobin-imprinted polymer beads via the photografting surface-modified method

Molecularly imprinted polymers (MIPs), based on photografting surface-modified polystyrene beads as matrices, were prepared with acrylamide as the functional monomer, bovine hemoglobin as the template molecule and N, N′-methylene bisacrylamide as the crosslinker in a phosphate buffer. The results of IR, scanning electron microscope (SEM) and elemental analyses demonstrated the formation of a grafting polymer layer on the polystyrene-bead surface. Subsequent removal of the template left behind cavities on the surface of the polymer matrix with a shape and an arrangement of functional groups having complementary binding sites with the original template molecule. The adsorption studies showed that the imprinted polymers have a good adsorption capacity and specific recognition for bovine hemoglobin as the template molecule. Our results demonstrated that the polymer prepared via the photografting surface-modified method exhibited better selectivity for the template. Attempts to employ the new method in molecular imprinting techniques may introduce new applications for MIPs and facilitate probable protein separation and purification. __________ Translated from Chemical Journal of Chinese Universities, 2008, 29(1): 64–70     

基于银增强金标记物的阳极溶出伏安免疫分析用于补体第三成分的测定

分子印迹是制备对特定分子具有专一性结合能力的聚合物的技术,所制备的聚合物被称为分子印迹聚合物（Molecularly imprinted polymers,MIPs）,此类聚合物在分离提纯、模拟酶和传感器等方面均显示出广阔的应用前景,迄今,小分子化合物的印迹技术已经十分成熟。     

表面分子印迹聚合物纳米线用于蛋白质的特异性识别

手性配体交换色谱是拆分手性化合物,特别是氨基酸和羟基酸对映体的一种有效方法,通常以光活性氨基酸或其衍生物为手性选择子,可通过键合及涂渍制备手性固定相,也可作为流动相添加剂来实现手性配体交换色谱分离分析,配体交换键合固定相需要完成载体和手性选择子之间的偶联,键合量因受到载体和制备条件的影响而较难控制,且柱效较低。     

Preparation and application of hollow molecularly imprinted polymers with a super‐high selectivity to the template protein

Protein‐imprinted polymers with hollow cores that have a super‐high imprinting factor were prepared by etching the core of the surface‐imprinted polymers that used silica particles as the support. Lysozyme as template was modified onto the surface of silica particles by a covalent method, and after polymerization and the removal of template molecules, channels through the polymer layer were formed, which allowed a single‐protein molecule to come into the hollow core and attach to the binding sites inside the polymer layer. The adsorption experiments demonstrated that the hollow imprinted polymers had an extremely high binding capacity and selectivity, and thus a super‐high imprinting factor was obtained. The as‐prepared imprinted polymers were used to separate the template lysozyme from egg white successfully, indicating its high selectivity and potential application in the field of separation of protein from real samples.     

表面分子(离子)印迹硅胶/聚合物的制备及性能研究进展

分子印迹技术(MIT)是制备对模板分子具有专一识别能力聚合物的技术。目前,把识别位点建立在基质表面的表面印迹技术日益受到重视,它可以提高识别位点与印迹分子的结合速度,进一步加强印迹材料吸附分离效率,硅胶因其具有良好的机械稳定性和热稳定性,吸附选择性高等优点,作为表面印迹的基质显示出较大的优越性。本文详细综述了有机分子印迹硅胶/聚合物及金属离子印迹硅胶/聚合物的制备和性能的研究进展,并对印迹材料将来的应用进行了展望。     

模板结构与分子印迹效果间关系的研究

以一些分子量和体积都较小的简单化合物作为模板分子,合成分子印迹聚合物 。通过总结43种化合物的分子印迹聚合物的色谱数据,来研究模板分子的分子量、 作用位点数目、分子刚性等因素与印迹效果的关系。根据免疫学中免疫原性的定义 ,我们提出“印迹原性”的概念,即,化合物能够产生印迹效应的性质称为印迹原 性;具有印迹原必的化合物称为印迹原;并讨论了具有较强选择性的印迹原的化学 基础。所得到的结论将有助于对分子印迹聚合物的识别机理的进一步理解,并且对 于根据模板分子性质预测MIP分子识别能力将具有一定的指导意义。     

表面分子印迹材料和技术在分离分析中的应用进展

复杂体系的高选择性分析对分离新材料和新方法提出了迫切需求。分子印迹聚合物（MIPs）以其特异性高、化学稳定性好、制备简单且成本低等优点,在高选择性分离分析中展现出巨大的应用前景。但以本体聚合为代表的传统合成方法获得的MIPs存在识别位点位于聚合物内部难以识别、模板分子洗脱不彻底、传质速率慢、结合容量低等问题。表面印迹技术制备的核-壳型表面分子印迹材料是解决上述难题的有效途径。通过核体和壳层结构的设计和构建,表面分子印迹材料还可具备多功能、多响应的特性,适于现代分离分析对快速、高效、高选择性的要求。该文主要综述了近几年表面分子印迹技术在样品前处理、化学/生物传感分析及靶向药物递送领域的应用进展。     

Comparison of three cross‐linking agents for imprinting diethylstilbestrol in solid‐phase extraction

Molecularly imprinted polymer (MIP) has been heavily studied for years. However, most efforts focused on functional monomer and particular study of cross‐linking agents on imprinting effect and pore structure is rare. In this paper, diethylstilbestrol (DES) imprinted polymers cross‐linked by three types of agents and their imprinting effects in solid‐phase extraction (SPE) were discussed. Evolution of UV spectral and simulation of cross‐linking agents or monomer mixed with DES revealed that there was a particular interaction between divinylbenzene and DES. Clear imprinting effects towards DES showed for divinylbenzene made imprinted polymer (DM), with imprinting factors up to 16.02 (STD = 2.20), while the other two imprinted polymers showed limited effects with imprinting factors of 4.95 (STD = 0.45) and 1.63 (STD = 0.54). Specific surface areas, pore volumes, and pore size distributions of the particles also confirmed that DM showed distinguished structure, and the average pore size of it was just fit the size of DES and bisphenol A (BPA), while no pore was found in divinylbenzene made blank polymer. Other imprinted and non‐imprinted polymers showed no pore or big pores relatively. These results show that the cross‐linking monomer is not merely an inert component for the MIPs, it could play a positive role in promoting interactions with the template to afford molecular recognition in imprinting DES. Copyright © 2011 John Wiley & Sons, Ltd.     

Electrochemistry of molecular imprinting of large entities

Molecularly imprinted polymer (MIP) is a well-known approach, in which cavities with specific affinity are formed. These functional materials are used mostly for the separation, sensing, and catalysis of small molecules. In the last two decades, the MIP concept has been expanded for the imprinting of large entities such as nanoparticles, viruses, and cells. In this emerging field termed surface imprinted polymers (SIPs), a thin matrix imprints only part of the entity to enable its easy removal and rebinding.In this review, we focus on the different recent imprinting strategies for nanoparticles, viruses, and cells in conjunction with electrochemistry and describe their applications in the fields of biology, analytical chemistry, and medicine.     

Preparation of molecularly imprinted polymers with thiourea group for phosphate

Molecularly imprinted polymers selective for phosphate were prepared with the two types of functional monomers, 1-allyl-2-thiourea and N-methyl-N′-(4-vinylphenyl)-thiourea, and the binding abilities of the polymers were evaluated. Phenylphosphonic acid or diphenyl phosphate were used as the template molecules and the imprinted polymers prepared with 1-allyl-2-thiourea as functional monomer showed high binding ability to phosphate in aqueous media and nearly 90% of phosphate could be recovered. Also, the imprinted polymer prepared with N-methyl-N′-(4-vinylphenyl)-thiourea as functional monomer had a high binding ability and specific interaction with phosphate in acetonitrile solution and over 90% of phosphate-derivatives could be recovered selectively.     

Synthesis and binding properties of a noncovalent molecularly imprinted testosterone-specific polymer

In this study, molecular imprinting was used to develop a method based on noncovalent interactions for synthesis of a testosterone-specific polymer. The effect of the different template–monomer ratios, the particle sizes of polymers, and chromatographic mobile phases on steroid–polymer interactions are discussed. The polymer obtained was found to interact specifically with testosterone, while other steroids under study were eluted close to the void volume in the HPLC experiments. Batch rebinding studies in acetonitrile were undertaken to quantitatively evaluate the affinity of the polymer for testosterone. During this experiment, the testosterone concentration was measured in two ways: spectrophotometrically and by HPLC on a column with testosterone-specific imprinted polymer synthesized by us. Both methods resulted in similar values of association constants and the number of binding sites. However, the second method has obvious advantages when the analyzed solution contains a mixture of optically dense compounds. The results obtained focus on the two-point binding nature of the imprinted polymer–testosterone interaction and the significant role of hydrogen bonds between the OH group of testosterone and carboxy group of methacrylic acid residues inside specific recognition sites of the imprinted polymer. © 1998 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 36: 1725–1732, 1998     

Sulfonamide imprinted polymers using co-functional monomers

Molecular imprinted polymers (MIPs) prepared using combination of acrylamide (ACM) and 4-vinylpyridine (4-Vpy) as co-functional monomers exhibited efficient recognition properties in both organic and aqueous media as HPLC stationary phase. The results indicate that amide and pyridine groups in functional monomers formed strong hydrogen-bonding interaction with the template molecule, and specific recognition sites were created within the polymer matrix during the imprinting process. When sulfamethoxazole (SMO) was used as template, a MIP prepared in a polar organic solvent (acetonitrile) using the combination of ACM and 4-Vpy showed better recognition of template than the polymer prepared in the same solvent using the combination of acidic monomer (methacrylic acid) and basic monomer 4-Vpy. On the contrary, when sulfamethazine (SMZ) was used as template, a MIP prepared using the combination of methacrylic acid (MAA) and 4-Vpy showed better recognition of template than the polymer prepared using the combination of ACM and 4-Vpy. Our results indicate that in organic media the degree of retention of the sample molecules on the imprinted polymers was controlled by the hydrogen-bonding interaction between the sample molecules and the polymer, while in aqueous media it was determined to a considerable extent by hydrophobic interactions. In both media the shape, size and the electronic structure of the template molecule were all-important factors in the recognition process.     

Factors Affecting Preparation of Molecularly Imprinted Polymer and Methods on Finding Template-Monomer Interaction as the Key of Selective Properties of the Materials

Molecular imprinting is a technique for creating artificial recognition sites on polymer matrices that complement the template in terms of size, shape, and spatial arrangement of functional groups. The main advantage of Molecularly Imprinted Polymers (MIP) as the polymer for use with a molecular imprinting technique is that they have high selectivity and affinity for the target molecules used in the molding process. The components of a Molecularly Imprinted Polymer are template, functional monomer, cross-linker, solvent, and initiator. Many things determine the success of a Molecularly Imprinted Polymer, but the Molecularly Imprinted Polymer component and the interaction between template-monomers are the most critical factors. This review will discuss how to find the interaction between template and monomer in Molecularly Imprinted Polymer before polymerization and after polymerization and choose the suitable component for MIP development. Computer simulation, UV-Vis spectroscopy, Fourier Transform Infrared Spectroscopy (FTIR), Proton-Nuclear Magnetic Resonance (¹H-NMR) are generally used to determine the type and strength of intermolecular interaction on pre-polymerization stage. In turn, Suspended State Saturation Transfer Difference High Resolution/Magic Angle Spinning (STD HR/MAS) NMR, Raman Spectroscopy, and Surface-Enhanced Raman Scattering (SERS) and Fluorescence Spectroscopy are used to detect chemical interaction after polymerization. Hydrogen bonding is the type of interaction that is becoming a focus to find on all methods as this interaction strongly contributes to the affinity of molecularly imprinted polymers (MIPs).     

Cost‐effective imprinting combining macromolecular crowding and a dummy template for the fast purification of punicalagin from pomegranate husk extract

The combination of molecular crowding and virtual imprinting was employed to develop a cost‐effective method to prepare molecularly imprinted polymers. By using linear polymer polystyrene as a macromolecular crowding agent, an imprinted polymer recognizable to punicalagin had been successfully synthesized with punicalin as the dummy template. The resulting punicalin‐imprinted polymer presented a remarkable selectivity to punicalagin with an imprinting factor of 3.17 even at extremely low consumption of the template (template/monomer ratio of 1:782). In contrast, the imprinted polymer synthesized without crowding agent, did not show any imprinting effect at so low template amount. The imprinted polymers made by combination of molecular crowding and virtual imprinting can be utilized for the fast separation of punicalagin from pomegranate husk extract after optimizing the protocol of solid‐phase extraction with the recovery of 85.3 ± 1.2%.     

基于N-异丙基丙烯酰胺的温敏型分子印迹聚合物

温敏型分子印迹技术是近几年来分子印迹技术新的发展。温敏型分子印迹聚合物以低交联度为特征,对模板分子的吸附容量和选择性随温度变化而改变。本文总结并评述了基于N-异丙基丙烯酰胺的温敏型MIP分子印迹聚合物及其制备方法,指出了温敏型分子印迹技术发展中需要解决的问题。     

分子印迹聚合物在抗生素残留测定中的应用

抗生素的滥用及残留对生物体和环境造成极大危害,其含量低、种类多、基质复杂,通常需要进行样品前处理结合色谱分析以实现灵敏测定。分子印迹聚合物（MIPs）能选择性识别、有效富集目标分析物并消除干扰,已广泛用于抗生素的样品前处理中。该文对MIPs制备中面临的挑战进行了总结;对2016年以来抗生素MIPs的固相萃取应用进行了综述和展望,主要包括固相萃取、分散固相萃取、磁固相萃取、基质固相分散萃取、固相微萃取、搅拌棒吸附萃取。此外,该文重点介绍了抗生素MIPs的印迹新策略,如多模板、多功能单体、虚拟模板、刺激响应、亲水性印迹等。最后,该文对抗生素MIPs的制备和前处理应用进行了展望。