液晶分子印迹整体柱的制备及其分子识别热力学

液晶分子印迹聚合物(MIPs)因刚性液晶单体的加入而在超低交联度水平下也能印迹和识别模板分子,有效解决了传统MIPs因高交联度造成的位点包埋、结合容量低、传质慢等问题。尽管液晶MIPs具有如此独特的优势,但却面临着由于交联度的大幅度降低而导致印迹效果下降的问题。为了研究液晶MIPs的结合特性,制备具有良好印迹效果的低交联液晶MIPs,该文通过二次接枝聚合,制备了一系列不同交联度的液晶分子印迹整体柱,用高效液相色谱法研究了聚合参数与印迹整体柱亲和性的关系。实验中选用三羟甲基丙烷三甲基丙烯酸酯(TRIM)为交联剂,以甲苯和十二醇为致孔剂合成整体柱骨架,并在此基础上以(S)-萘普生为模板,加入液晶单体4-氰基苯基单环己基乙烯(CPCE)进行二次聚合接枝。实验中系统考察了流动相中乙腈比例及缓冲液pH值对色谱保留的影响,结果发现液晶单体的加入使得MIPs对萘普生保留控制机制由原来的氢键作用变为了疏水作用;通过动态吸附实验得到的突破曲线经前沿分析及对吸附等温线Langmuir、Freundlich和Scatchard分析拟合,发现交联度为15%时液晶MIPs印迹因子最大(3.78)、非均一性最强,且特异性吸附量高于非特异性吸附量。液晶MIPs的计量置换模型(SDM-R)分析表明,液晶印迹整体柱对模板分子的总亲和力(ln A=0.645)明显高于其类似物;而从空间匹配程度看,与液晶印迹整体柱空间匹配程度最高的是酮洛芬而非模板分子,但液晶印迹整体柱对酮洛芬的总亲和力(ln A=0.242)不及模板分子的一半,表明在本低交联液晶印迹系统中,空间效应不是决定印迹系统识别能力的主要因素。进一步的分离热力学研究发现,低交联液晶印迹柱的|ΔΔH|<T|ΔΔS|,而交联度为70%的非液晶MIPs柱的|ΔΔH|>T|ΔΔS|,表明液晶MIPs的分离过程是一个熵控制过程,而常规无液晶MIPs的分离过程是一个焓控制过程。上述结果表明,液晶单体的加入改变了MIPs的识别机制,适当的低交联度可显著提高液晶MIPs的识别性能,因此液晶MIPs这些特质有望使其成为新一代的MIPs。     

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。     

S-布洛芬印迹聚合物微球的制备及应用

以S-布洛芬为模板,丙烯酰胺（AM）为功能单体,二乙烯基苯（DVB）为交联剂,在甲苯-乙腈的混合溶剂中,采用沉淀聚合法制得粒径为3~6μm的印迹聚合物微球。将印迹聚合物微球用作高效液相色谱（HPLC）固定相,以乙腈为流动相,通过拆分外消旋布洛芬及分离其类似物,评价分子印迹聚合物的特异识别性能;研究了流动相中乙酸含量、流速对拆分能力的影响;通过测定分离过程中焓变、熵变及自由能的变化,对分子印迹聚合物的分离过程做了详细的解释。     

分子印迹整体柱在高效液相色谱和电色谱手性分离中的应用

在常规不锈钢色谱管中以甲基丙烯酸为功能单体，采用原位聚合法制备了(5S,11S)-特罗格尔碱(S-TB)的印迹整体柱。考察了流动相中添加不同量的醋酸和水对分离的影响,结合台阶梯度洗脱模式在S-TB整体柱上实现了对TB消旋体的快速分离。另外,以碱性单体2-二甲基乙基胺甲基丙烯酸酯(DAMA)为功能单体，在毛细管中采用原位聚合法制备了毛细管分子印迹整体柱,用于在毛细管电色谱（CEC）中对消旋体1,1′-联-2-萘酚(BNL)进行手性分离。结果表明，以AMA为功能单体可以制备其他酸性模板的分子印迹聚合物,从而扩大了分子印迹聚合物MIP）在CEC分离中的应用范围。     

分子印迹手性分离过程的热力学研究

以丙烯酰胺为功能单体, 以二甲基丙烯酸乙二醇酯为交联剂, 在模板分子N-叔丁氧羰酰-L-色氨酸(N-Boc-L-Trp)和N-叔丁氧羰酰-L-酪氨酸(N-Boc-L-Tyr)的存在下, 分别采用光引发聚合和热引发聚合制备了N-Boc-L-Trp和N-Boc-L-Tyr的分子印迹聚合物(MIPs), 进行分子印迹手性分离过程的热力学研究. 测定了分离过程的熵变、焓变和自由能变化. 结果显示, 在流动相中添加异丙醇或甲醇等强氢键竞争性溶剂时, 熵变对分离起到了主要作用, 而且分离过程中的溶剂化对分离的影响也非常大. 分子印迹聚合物对印迹分子和非印迹分子进行分子识别的主要作用是印迹聚合物与印迹分子匹配的三维空间结构.     

谷胱甘肽分子印迹聚合物的制备及其性能研究

采用新型光源高压汞灯制备了三肽分子谷胱甘肽的分子印迹聚合物(MIPs), 反应时间缩短, 制备条件温和. 对MIPs做了一系列的静态吸附实验, 结合荧光测定法研究了不同单体-模板比例下MIPs表现出来的吸附性能. 对最佳比例制备的MIPs进行了一系列性能研究, 包括吸附等温线的测定、Scatchard分析以及薄层色谱分离实验等. 结果表明, 所合成的MIPs对GSH具有良好的吸附和选择识别能力,最大吸附量为45.4 mg/g, 特异因子达到了4.98.     

谷胱甘肽分子印迹聚合物的制备及其性能研究

采用新型光源高压汞灯制备了三肽分子谷胱甘肽的分子印迹聚合物(MIPs),反应时间缩短,制备条件温和.对MIPs做了一系列的静态吸附实验,结合荧光测定法研究了不同单体-模板比例下MIPs表现出来的吸附性能.对最佳比例制备的MIPs进行了一系列性能研究,包括吸附等温线的测定、Scatchard分析以及薄层色谱分离实验等.结果表明,所合成的MIPs对GSH具有良好的吸附和选择识别能力,最大吸附量为45·4mg/g,特异因子达到了4·98.     

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。     

分子印迹技术在毛细管电色谱中的应用

分子印迹技术是制备具有分子识别功能聚合物，即分子印迹聚合物（MIPs)的一种新技术；毛细管电色谱（CEC）是一个具有发展前途的色谱新技术。将分子印迹技术和毛细管电色谱两种新技术相结合，优势互补，具有极大的发展潜力。本文对分子印迹技术在毛细管电色谱中的应用，以及各类MIPs-CEC毛细管柱的制备方法进行了较为全面的综述，引用文献52篇。     

分子印迹聚合物拆分消旋体酮洛芬

以(S) 酮洛芬为印迹分子利用分子印迹技术合成能识别(S) 酮洛芬的聚合物。聚合物作为高效液相色谱的固定相,消旋体酮洛芬在固定相能分开,同时聚合物还能将酮洛芬和布洛芬的混合物分开。     

分子烙印手性固定相分离过程热力学研究

考察了温度对分子烙印固定相手性分离的影响,计算了手性分离过程中的热力学参数。结果表明,分子烙印手性固定相的分离过程为焓控制过程,随着温度的升高,样品的容量因子降低,手性选择因子α减小。２与分子烙印固定相的作用力包括非特异作用力和特异作用力,只有特异作用力的差值才是手性分离的本质,分子烙印产生的空穴对热力学参数有较大的影响,烙印分子与烙印空穴的匹配性最好,烙印空穴对烙印分子的结合的能量和构型上都是有     

Synthesis and Molecular Recognition of Molecularly Imprinted Polymer with Ibuprofen as Template

Ibuprofen and ketoprofen are chemically similar non‐steroidal anti‐inflammatory drugs widely used in the treatment of arthritis. Using a molecular imprinting technique, a simple and rapid method was developed for the simultaneous separation and determination of ibuprofen and ketoprofen. Molecular imprinting introduces artificial binding sites into a synthetic polymer matrix, allowing it to exhibit selective rebinding of template molecules. Imprinted polymers can be regarded as an HPLC stationary phase, important for pharmaceutical analysis. Most molecularly imprinted polymers (MIPs) are synthesized by free radical polymerization of functional monomers, resulting in an excess of crosslinking monomers. In this study, MIPs have been prepared with a ibuprofen template, which can form intramolecular hydrogen bonds. Methacrylic acid (MAA) and ethyleneglycol dimethacrylate (EGDMA) were used as the functional monomer and cross‐linker, respectively. Bulk polymerization was carried out at 4 °C under UV radiation. The resulting MIP was ground into 25?44 μm particles, which were slurry‐packed into analytical columns. Template molecules were removed by methanol‐acetic acid (9:1, v/v). We evaluated the template binding performance of the MIP using HPLC, with ultraviolet (UV) detection at 234 nm. Chromatographic resolution of ibuprofen and ketoprofen on the MIPs were appraised using buffer/acetonitrile (45/55, v/v) as the mobile phase. Results show that the MIPs prepared using ibuprofen as the template had a significant molecular imprinting effect. The method was successfully applied to the separation and analysis of ibuprofen and ketoprofen in pharmaceuticals.     

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.     

Enantioselective analysis of ibuprofen, ketoprofen and naproxen in wastewater and environmental water samples

A highly sensitive and reliable method for the enantioselective analysis of ibuprofen, ketoprofen and naproxen in wastewater and environmental water samples has been developed. These three pharmaceuticals are chiral molecules and the variable presence of their individual (R)- and (S)-enantiomers is of increasing interest for environmental analysis. An indirect method for enantioseparation was achieved by the derivatization of the (R)- and (S)-enantiomers to amide diastereomers using (R)-1-phenylethylamine ((R)-1-PEA). After initial solid phase extraction from aqueous samples, derivatization was undertaken at room temperature in less than 5 min. Optimum recovery and clean-up of the amide diastereomers from the derivatization solution was achieved by a second solid phase extraction step. Separation and detection of the individual diastereomers was undertaken by gas chromatography-tandem mass spectrometry (GC-MS/MS). Excellent analyte separation and peak shapes were achieved for the derivatized (R)- and (S)-enantiomers for all three pharmaceuticals with peak resolution, R(s) is in the range of 2.87-4.02 for all diastereomer pairs. Furthermore, the calibration curves developed for the (S)-enantiomers revealed excellent linearity (r(2) ≥ 0.99) for all three compounds. Method detection limits were shown to be within the range of 0.2-3.3 ng L(-1) for individual enantiomers in ultrapure water, drinking water, surface water and a synthetic wastewater. Finally, the method was shown to perform well on a real tertiary treated wastewater sample, revealing measurable concentrations of both (R)- and (S)-enantiomers of ibuprofen, naproxen and ketoprofen. Isotope dilution using racemic D(3)-ibuprofen, racemic D(3)-ketoprofen and racemic D(3)-naproxen was shown to be an essential aspect of this method for accurate quantification and enantiomeric fraction (EF) determination. This approach produced excellent reproducibility for EF determination of triplicate tertiary treated wastewater samples.     

Chiral separation of ketoprofen on an achiral NH<Subscript>2</Subscript> column by HPLC using vancomycin as chiral mobile phase additive

A high-performance liquid chromatographic method for chiral separation of ketoprofen racemate was developed. (R)- and (S)-ketoprofen enantiomers were separated on a LiChrosorb NH₂ column (250 mm × 4.6 mm, i.d 5 µm) at 20 °C, using 2-propanol/potassium dihydrogen phosphate buffer (pH 6.0, 0.05 M) (50:50 v/v). Containing vancomycin as the mobile phase, at a flow rate of 0.8 ml min^?1 and detection wavelength of UV, the detector was set at 310 nm. Under these conditions, ketoprofen enantiomers could be separated with a selectivity factor (α) of 2.172 and a resolution (Rs) of 4.78 using extremely low concentrations of the vancomycin chiral additive.     

蛋白质分子印迹

分子印迹技术是一种新型的高效分离技术，具有空间选择性识别特性。本文介绍了分子印迹技术在蛋白质大分子上的应用和发展，包括蛋白质分子印迹选用的单体和交联剂、印迹方法、印迹机理、蛋白质分子印迹技术的应用以及存在的一些问题。     

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%.     

萘普生分子印迹拆分及亲和吸附平衡常数的测定

分子印迹 (Molecular imprinting)是一种新的、很有发展潜力的分离技术 [1～ 3 ] .该技术已成功地用于氨基酸、糖类及其衍生物和药物的手性分离 .萘普生是一种重要的非甾体消炎、解热和镇痛药 ,为了减少给药量和对人体产生的毒副作用 ,必须对其进行手性拆分 . Mosbach等 [4 ] 曾以 4-乙烯基吡啶为功能单体 ,利用分子印迹对外消旋萘普生进行了手性拆分 ,但 4-乙烯基吡啶使用前需经过减压蒸馏 ,使用不便 . Haginaka等 [5～ 7] 也采用 4-乙烯基吡啶为功能单体 ,以 (S) -萘普生为模板制得了均一粒径的分子印迹介质 .尽管分子印迹分离技术发展…     

Enantiomeric purity determination of ketoprofen by capillary electrophoresis: development and validation of the method

A simple, fast capillary electrophoresis method for determining the total ketoprofen content in an oral pharmaceutical formulation is proposed. The addition of 75 mM of heptakis(tri- O-methyl)-beta-cyclodextrin to the background electrolyte allows the quantitation of the enantiomeric impurity of ( R)-(-)-ketoprofen contained in the formulation. A relative limit of detection is proposed as a measure of the lowest detectable enantiomeric impurity and the results show that the method can detect the minor enantiomer at levels as low as 0.04% in ( S)-(+)-ketoprofen. The chiral method was validated following ICH recommendations and the quality parameters obtained show the suitability of the proposed method. The analysis of samples examined during the course of a stability study under chiral and achiral conditions revealed that the total ketoprofen content did not change significantly with time and the enantiomeric impurity range was 0.1-0.4%.