沉淀聚合法制备TNT分子印迹聚合物微球

以TNT为模板分子,丙烯酰胺为功能单体,二甲基丙烯酸乙二醇酯为交联剂,乙腈为溶剂,用沉淀聚合法制备了TNT分子印迹微球.紫外吸收光谱证实TNT与丙烯酰胺之间存在相互作用;平衡吸附实验结果表明,制备的分子印迹聚合物微球对TNT分子有较好的特异性吸附能力,能够选择性识别TNT分子.     

二茂铁甲酸分子印迹聚合物的制备和识别机理、结合特性

以二茂铁甲酸（FCA）为模板,选用不同的功能单体制备了一系列分子印迹聚合物,用平衡结合实验考察了它们对模板分子的结合性能。 结果表明,以甲基丙烯酸为功能单体制得的印迹聚合物P1对模板分子有很好的选择性,特异性吸附量ΔCP为23.18 μmol/g,印迹因子IF为2.33,竞争性结合实验结果表明,P1可以将模板分子从结构类似物中分离出来。 Scatchard方程研究表明,在研究的浓度范围内聚合物中形成了一类等价的结合位点,其对模板分子的平衡离解常数K=1.94 mmol/L,最大表观结合量Cpmax=92.33 μmol/g。 研究还表明,FCA的羧基是在聚合物的孔穴中产生识别位点的功能基,模板分子上的羧基与MAA的羧基形成双重氢键作用是分子识别的主要作用力。     

壬基酚表面印迹聚合物微球的合成及分子识别特性

采用表面分子印迹技术,在二氧化硅微粒表面通过乙烯基三甲氧基硅烷接枝,以壬基酚(NP)为模板、α-甲基丙烯酸为功能单体制备了壬基酚印迹聚合物。扫描电镜及比表面分析仪测试结果表明制备的印迹聚合物呈均匀分散的微球,具有较大的比表面积。采用红外光谱表征印迹聚合物微球制备过程中的化学结构变化情况,并用平衡吸附法研究了聚合物对NP的结合性能与分子识别特性。研究结果表明,聚合物对壬基酚具有良好的结合亲和性,最大结合量可达184.6 mg/g。印迹聚合物对NP的吸附量高于其结构类似物对特辛基酚和双酚A的吸附量,表现出较高的选择性识别能力。     

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.     

二茂铁甲酸分子印迹聚合物的制备、识别机理和结合特性

以二茂铁甲酸(FCA)为模板,选用不同的功能单体制备了一系列分子印迹聚合物,用平衡结合实验考察了它们对模板分子的结合性能。结果表明,以甲基丙烯酸为功能单体制得的印迹聚合物P1对模板分子有很好的选择性,特异性吸附量ΔCP为23.18μmol/g,印迹因子IF为2.33,竞争性结合实验结果表明,P1可以将模板分子从结构类似物中分离出来。Scatchard方程研究表明,在研究的浓度范围内聚合物中形成了一类等价的结合位点,其对模板分子的平衡离解常数K=1.94 mmol/L,最大表观结合量Cpmax=92.33μmol/g。研究还表明,FCA的羧基是在聚合物的孔穴中产生识别位点的功能基,模板分子上的羧基与MAA的羧基形成双重氢键作用是分子识别的主要作用力。     

内分泌干扰物雌酮分子印迹新型吸附功能材料的制备及其选择性能研究料

采用分子印迹本体聚合法,制备了对内分泌干扰物雌酮具有高选择识别能力的分子印迹聚合物。吸附动力学和选择性实验结果表明,与非印迹聚合物相比,印迹聚合物具有较高的吸附容量和吸附速率,对模板分子具有较高的选择性。聚合反应条件对印迹聚合物的吸附和识别性能有重要影响,以丙烯酰胺为功能单体,模板分子、功能单体和交联剂摩尔比为1：3：6,制备的印迹聚合物具有较高的选择和吸附性能。     

内分泌干扰物雌酮分子印迹新型吸附功能材料的制备及其选择性能研究

采用分子印迹本体聚合法,制备了对内分泌干扰物雌酮具有高选择识别能力的分子印迹聚合物。吸附动力学和选择性实验结果表明,与非印迹聚合物相比,印迹聚合物具有较高的吸附容量和吸附速率,对模板分子具有较高的选择性。聚合反应条件对印迹聚合物的吸附和识别性能有重要影响,以丙烯酰胺为功能单体,模板分子、功能单体和交联剂摩尔比为1:3:6,制备的印迹聚合物具有较高的选择和吸附性能。     

胆酸印迹聚合物的制备及在含水介质中的结合性能

为了在含水介质中进行有效印迹,本研究中以双甲基丙烯酰-β-环糊精（BMA-β-CD）和2-(二乙基胺基)乙基甲基丙烯酸酯(DEAEM)为功能单体制备了胆酸印迹聚合物MIP1,并用平衡结合实验研究了MIP1在含水介质中对模板分子的识别能力。结果表明,MIP1比单独以BMA-β-CD或DEAEM为功能单体制备的印迹聚合物MIP2和MIP3,显示出对模板分子更好的选择性结合能力。MIP1的特异性吸附量ΔCP为38.81μmol/g,印迹因子IF为2.46。研究表明,在含水介质中,利用模板分子与功能单体之间的疏水作用和离子作用是提高印迹聚合物分子识别能力的关键。研究还表明,在识别过程中,疏水作用在驱动分子进入印迹孔穴时起重要作用。     

红霉素分子印迹聚合物微球的制备及性能研究

以红霉素为模板分子,甲基丙烯酸为功能单体,乙二醇二甲基丙烯酸酯为交联剂,在水相中采用悬浮聚合法制备了红霉素分子印迹聚合物微球。利用扫描电镜对其表面形貌进行了表征,探讨了不同分散剂浓度、水油比、搅拌速度等参数对聚合物微球粒径及粒径分布的影响,重点对聚合工艺进行了优化,并将所得的聚合物用作吸附剂研究了其分子识别与选择性能。研究表明,该方法合成的聚合物微球平均粒径为40~130μm,对模板分子具有较高吸附性能和选择性识别能力,其分离因子达1.83,而动态吸附饱和吸附量则达到了42.59μmol/g。     

酚酞分子印迹聚合物的制备及特异吸附性能

以泻药酚酞为模板分子,4-乙烯基吡啶为功能单体制备了模板分子和功能单体不同比例的一系列酚酞分子印迹聚合物。利用扫描电镜对聚合物进行了表面形态分析,采用静态平衡实验法研究了聚合物对模板分子及其类似物的吸附行为和选择性识别能力。实验结果表明,所制备的分子印迹聚合物,吸附 3 h 后基本接近最大吸附量,其中模板分子、4-乙烯基吡啶和交联剂的摩尔比为 1∶6∶20的MIP2的印迹因子为 2.30,效果最佳。Scatchard 分析表明, 在所研究的浓度范围内,吸附过程存在两类结合位点,一类高亲和力结合位点的离解常数为Kd1= 0.63 mmol/L,最大表观结合量 Qmax1 = 25.4 umol/g,另一类低亲和力结合位点的离解常数为 Kd2 =3.5 mmol/L,最大表观结合量 Qmax2 = 61.9 umol/g,通过与酚酞类似物质在酚酞分子印迹聚合物上的吸附行为比较,表明对酚酞具有很好的选择性吸附。     

分子印迹纳米胶体阵列检测爆炸物的研究

以三硝基甲苯(TNT)为模板,丙烯酰胺为功能单体,采用乳液聚合法制备具有单分散性的TNT分子印迹胶体小球.通过垂直沉降法自组装,并用胶带将得到的具有蛋白石结构的分子印迹胶体阵列(MICA)固化.研究其在不同比例的甲醇/水溶液中的光学响应,并在最优检测环境下进行特异性吸附实验.实验表明,当甲醇/水的体积比为7∶3,TNT浓度为20 mmol/L时,反射峰红移近24 nm,为非印迹胶体阵列红移量的1.4倍,为TNT结构类似物的23倍.MICA在实现对光子晶体传感器制备简化的同时,提供了对TNT进行快速裸眼检测的可能性.     

Preparation of “dummy” l‐phenylalanine molecularly imprinted microspheres by using ionic liquid as a template and functional monomer

In this study, dummy imprinting technology was employed for the preparation of l‐ phenylalanine‐imprinted microspheres. Ionic liquids were utilized as both a “dummy” template and functional monomer, and 4‐vinylpyridine and ethylene glycol dimethacrylate were used as the assistant monomer and cross‐linker, respectively, for preparing a surface‐imprinted polymer on poly(divinylbenzene) microspheres. By the results obtained by theoretical investigation, the interaction between the template and monomer complex was improved as compared with that between the template and the traditional l‐ phenylalanine‐imprinted polymer. The batch experiments indicated that the imprinting factor reached 2.5. Scatchard analysis demonstrated that the obtained “dummy” molecularly imprinted microspheres exhibited an affinity of 77.4 M·10^?4, significantly higher that of a traditional polymer directly prepared by l‐ phenylalanine, which is in agreement with theoretical results. Competitive adsorption experiments also showed that the molecularly imprinted polymer with the dummy template effectively isolated l‐ phenylalanine from l‐ histidine and l‐ tryptophan with separation factors of 5.68 and 2.68, respectively. All these results demonstrated that the polymerizable ionic liquid as the dummy template could enhance the affinity and selectivity of molecularly imprinted polymer, thereby promoting the development of imprinting technology for biomolecules.     

Development of molecularly imprinted microspheres for the fast uptake of 4‐cumylphenol from water and soil samples

Molecularly imprinted microspheres containing binding sites for the extraction of 4‐cumylphenol have been prepared for the first time. The imprinted microspheres were synthesized by a precipitation method using 4‐cumylphenol as a template molecule, methacrylic acid as a functional monomer and divinylbenzene‐80 as a cross‐linker for polymer network formation. The formation and the morphology of molecularly imprinted microspheres were well characterized using infrared spectroscopy, thermogravimetric studies, and scanning electron microscopy. The Brunauer–Emmett–Teller analysis revealed the high surface area of the sorbent indicating formation of molecularly imprinted microspheres. The developed microspheres were employed as a sorbent for the solid‐phase extraction of 4‐cumylphenol and showed fast uptake kinetics. The sorption parameters were optimized to achieve efficient sorption of the template molecule, like pH, quantity of molecularly imprinted microspheres, time required for equilibrium set‐up, sorption kinetics, and adsorption isotherm. A standard method was developed to analyze the sorbed sample quantitatively at 279 nm using high‐performance liquid chromatography with diode array detection. It was validated by determining target analyte from synthetic samples, bottled water, spiked tap water, and soil samples. The prepared material is a selective and robust sorbent with good reusability.     

分子印迹胶体阵列检测对硝基苯酚

以对硝基苯酚(p-NP)为印迹模板,丙烯酰胺为功能单体,制备单分散的对硝基苯酚分子印迹胶体微球。通过垂直沉降法将分子印迹胶体微球自组装为分子印迹胶体阵列,采用胶带将分子印迹胶体阵列粘贴固定。固定于胶带上的分子印迹胶体阵列膜显示出良好的稳定性,而且对目标分子p-NP具有明显的光学响应。分子印迹微球吸附目标分子发生溶胀,引起胶体阵列溶涨,分子印迹胶体阵列(MICA)反射峰位置发生移动。实验结果显示,MICA随着p-NP浓度增加,反射峰红移近60 nm,MICA表面颜色由红色逐渐变为蓝紫色;而非印迹胶体阵列红移量只约40 nm。MICA简化了光子晶体凝胶传感材料的制备步骤,为开发新型高性能生化传感器材料提供了新思路。     

离子液体-水双相体系悬浮聚合法制备对苯二酚分子印迹聚合物微球

通过在[Bmim]PF6离子液体-水双相体系中,以对苯二酚为模板分子,甲基丙烯酸为功能单体,二甲基丙烯酸乙二醇脂为交联剂,采用悬浮聚合法制备得到对苯二酚印迹聚合物微球(MIMs-IL),并通过FTIR等测试技术对MIMs-IL进行了表征。对不同离子液体进行了选择,[Bmim]PF6介质中制备的MIMs-IL的识别性能最好。与从氯仿介质中制备的印迹聚合物微球(MIMs-Or)相比较,MIMs-IL的产率为70.8%,明显高于MIMs-Or的48.7%。采用静态吸附法考察其印迹识别能力的结果表明,MIMs-IL对水中的对苯二酚的识别能力大大强于MIMs-Or。对MIMs-IL识别吸附的热力学和动力学研究结果表明,12h时MIMs-IL及其非印迹聚合物微球(nMIMs-IL)均达到各自饱和吸附量,对于0.50g/L对苯二酚水溶液,MIMs-IL的饱和吸附量是nMIMs-IL的2.67倍。     

核-壳型白藜芦醇分子印迹微球研制及应用

以表面修饰乙烯基团的SiO2微球为基体,白藜芦醇为模板分子,丙烯酰胺(AA)为功能单体,乙二醇二甲基丙烯酸酯(EGDMA)为交联剂,采用表面印迹技术制备核-壳型白藜芦醇印迹微球。采用红外光谱(IR)、扫描电子显微镜(SEM)对该分子印迹微球进行表征,结果表明,SiO2表面成功接枝一层厚度为200nm的印迹聚合物,该印迹微球颗粒分散均匀。采用高效液相色谱技术对印迹微球的吸附性进行研究表明,此印迹微球具有良好的识别性能,利用Scatchard模型分析得出印迹微球的最大吸附量分别为Qmax1=9.087mg/g和Qmax2=13.80mg/g。此印迹微球成功用于分离虎杖提取液中白藜芦醇。     

核-壳型厚朴酚印迹聚合物的制备及性能研究

以表面修饰功能基团的SiO2微球为基体,以厚朴酚为模板分子,丙烯酰胺为功能单体,丙烯酸乙二醇二甲酯为交联剂,在SiO2微球表面制备对厚朴酚具有较好选择识别能力的核-壳型印迹聚合物.采用红外光谱及扫描电镜等技术表征聚合物的结构及形态.结果表明,该印迹聚合物表面成功制备了壳层厚度约为200nm的均匀印迹层.通过静态吸附、Scatchard分析法以及竞争吸附实验研究了该聚合物的吸附性能和选择性,结果表明,它对厚朴酚形成均一结合位点,离解常数为0.19mg/mL.     

鹅去氧胆酸分子印迹聚合物微球的制备及选择性分子识别

以鹅去氧胆酸(CDCA)为印迹分子, 甲基丙烯酸为功能单体, 丙烯酸乙二醇二甲基酯和三羟甲基丙烷三甲基丙烯酸酯为交联剂, 在氯仿中采用沉淀聚合法制得平均粒径为200~300 nm的分子印迹聚合物微球(MIPMS). 用红外光谱研究了印迹分子与功能单体之间的作用类型, 用透射电镜对聚合物的形貌进行了表征. 结果表明, 聚合物微球在合成过程中形成了两类结合位点, 该分子印迹聚合物对CDCA具有良好的特异吸附性能, 可用于胆汁酸的分离、纯化, 交联剂的种类可以影响分子印迹聚合物的形貌和吸附性能.     

Novel molecularly imprinted microsphere using a single chiral monomer and chirality-matching (S)-ketoprofen template

We designed and synthesized a cinchonine derivative to be used as a novel chiral monomer. It was employed in a dual role of functional monomer and cross-linking monomer, displaying multi-binding sites for the template (S)-ketoprofen. Monodisperse molecularly imprinted core-shell microspheres were prepared using surface imprinting method on silica gel. The results show a substantial synergistic effect in the enantioselective recognition, confirming our initial hypothesis. Computational simulation of the monomer and template pre-arrangement strongly supports our proposed chiral recognition mechanism for the imprinted microspheres.     

Preconcentration of Nicotinamide Using Molecularly Imprinted Microspheres for Solid-phase Extraction with Determination by High-performance Liquid Chromatography

The determination of target molecules in complicated matrices such as biological samples is largely dependent on sample pretreatment. Molecularly imprinted solid-phase extraction (SPE), using molecularly imprinted polymers as the adsorbent, has been demonstrated to be effective for the selective enrichment of target molecules in biological samples. In this study, molecularly imprinted polymeric microspheres were fabricated by two-step swelling polymerization using polystyrene particles as seeds, nicotinamide as the template, methacrylic acid as a functional monomer, and ethylene glycol dimethacrylate as a cross-linker. The molecularly imprinted polymeric microspheres were packed into empty SPE cartridges, and the spiked urine and serum samples were loaded separately. After an initial washing and elution step, the effluents were analyzed by high-performance liquid chromatography (HPLC) using 1:9 methanol/0.05% phosphoric acid. The obtained molecularly imprinted polymeric microspheres were uniform, and the spherical particles were well distributed. The established method was validated, and the results showed that the method was linear from 0.499 to 19.96?µg?mL^?1. The limits of detection and quantification for nicotinamide were 0.3 and 0.9?µg?mL^?1, respectively. The relative standard deviations were 1.55 and 2.86% in urine and serum, respectively. The spiked recoveries of nicotinamide were 86.0–98.8% and 87.0–96.8% in urine and serum, respectively. The molecularly imprinted SPE and HPLC methods in this study are useful for the pretreatment and determination of the target compounds in these matrices.