加速溶剂萃取快速洗脱印迹聚合物中的模板分子

通过优化实验条件,选择洗脱温度80℃、加热时间5min、萃取压力10.4MPa、洗脱溶剂为300mL的甲醇/乙酸(90∶10,V/V),静态萃取时间8min、吹扫时间100s,对1.000g尼古丁印迹聚合物中的模板分子进行连续6次的萃取洗脱,洗脱效率达94.2%,模板渗漏量仅为9.8μg/L,萃取时间<70min。将2000mg洗脱后的印迹聚合物颗粒装填于3mL的聚丙烯固相萃取小柱中,用10mL甲醇/乙酸(90∶1,V/V)淋洗小柱,用高效液相色谱检测淋洗液中的尼古丁,获得模板的渗漏量为9.8μg/L。     

分子印迹-固相萃取-高效液相色谱法测定鱼肉中的孔雀石绿

以本体聚合法制备孔雀石绿(MG)分子印迹聚合物,并以此为填料,制作针对孔雀石绿的分子印迹固相萃取小柱。鱼肉样品经乙腈超声提取,提取液过分子印迹固相萃取小柱,用甲醇-乙酸(9+1)混合液洗脱,洗脱液采用Eclipse Plus C18色谱柱分离,以50mmol·L-1乙酸盐缓冲溶液-乙腈(4+6)混合液为流动相进行洗脱,检测波长为620nm。孔雀石绿的线性范围为1.00~50.0μg·L-1,检出限(3S/N)为0.62μg·kg-1。对空白鱼肉样品进行加标回收试验,回收率在86.6%~95.4%之间,测定值的相对标准偏差(n=5)在3.6%~6.8%之间。     

赛庚啶-分子印迹聚合物的制备及其固相萃取研究

以赛庚啶为模板分子,甲基丙烯酸为功能单体,乙二醇二甲基丙烯酸酯为交联剂,通过优化致孔剂、单体及模板与单体摩尔比等因素,合成了对赛庚啶具有高选择性的分子印迹聚合物,其表面积达24.9 m2/g。制备的印迹聚合物固相萃取小柱(MISPE)依次以甲醇和水活化小柱,水溶液上样,水和甲醇依次洗涤,氨化甲醇(5∶95,V/V)洗脱,赛庚啶在制备MISPE小柱上的回收率为94.0%,而非分子印迹小柱(NISPE)的回收率仅为38.9%;MISPE结合赛庚啶的容量达8.8 mg/g,印迹因子约为2.32。在优化的固相萃取条件下,10 mg/L赛庚啶、阿米替林、磺胺嘧啶和甲氧苄啶混合标准溶液上样,进行选择性实验。以0.05%戊烷磺酸钠溶液和乙腈为流动相,梯度洗脱,在MISPE小柱上,与CYP化学结构差异较大的磺胺嘧啶和甲氧苄啶回收率均小于10%,结构相似的阿米替林回收率达70%,赛庚啶回收率大于90%;4种分析物在NISPE小柱上的回收率均小于30%。制备的MISPE小柱应用于畜禽饮用水样中赛庚啶的分离富集和分析测定,方法回收率为80.5%~97.7%,检出限达0.01 mg/L。     

洛克沙胂分子印迹聚合物的制备及其固相萃取研究

以阿散酸为虚拟模板分子,2-乙烯吡啶为功能单体,乙二醇二甲基丙烯酸酯为交联剂,合成了对洛克沙胂具有高选择性的分子印迹聚合物。通过考察致孔剂、单体及交联剂等因素对合成聚合物性能的影响,获得优化聚合配方为:阿散酸、2-乙烯吡啶、乙二醇二甲基丙烯酸酯、甲醇-乙腈(1∶1,V/V)及偶氮二异丁腈之比为1 mmol∶4 mmol∶20 mmol∶6 mL∶60 mg。合成印迹聚合物对洛克沙胂的最大吸附量为0.93 mg/g,作为固相萃取填料分离、富集洛克沙胂的优化萃取条件为:水和乙腈活化平衡,乙腈上样,水和甲醇依次淋洗,5%甲酸甲醇溶液洗脱。洛克沙胂在分子印迹固相萃取柱上的回收率达到95%以上,而非分子印迹固相萃取柱的回收率仅为43.1%。制备小柱应用于池塘水中洛克沙胂的净化富集,检测限可达0.05 mg/L。     

印迹分子聚合物结合低共熔溶剂用于山楂中咖啡酸的固相萃取

在相同的实验条件下,分别合成了以咖啡酸为模板的印迹分子聚合物和无模板分子聚合物。使用场发射扫描电镜法和吸附实验表征这两种聚合物材料的孔状结构和选择性吸附性能。然后利用印迹分子聚合物、无模板分子聚合物、C₁₈萃取小柱这3种材料结合固相萃取法纯化山楂提取物中的咖啡酸,提取率分别为3.46、1.01、1.17 μg/g。为了优化固相萃取过程,实验研究了不同洗脱剂的影响。分别利用用氯化胆碱和甘油、氯化胆碱和尿素(摩尔比均为1:2)合成出两种低共熔溶剂。甲醇与这两种低共熔溶剂分别以不同的体积比混合作为洗脱剂,用于优化咖啡酸的固相萃取过程。实验结果表明,印迹分子聚合物是一种良好的固相萃取材料;当甲醇和甘油基低共熔溶剂在体积比为3:1混合时,表现出最好的洗脱能力,得到咖啡酸的回收率为82.32%。     

分子印迹在线固相萃取分离奥克托今合成反应中间体

采用分子印迹在线固相萃取和液相色谱-质谱联用技术建立了奥克托今合成反应中间体1,3,5,7-四乙酰基-1,3,5,7-四氮杂环辛烷(TAT)与1,3,5-三乙酰基-1,3,5-三氮杂环己烷(TRAT)的分离鉴定方法。固相萃取填料采用TAT分子印迹聚合物,液相色谱分离检测采用亲水色谱柱。首先以乙腈为固相萃取柱上样溶剂,流速为0.1 mL/min,然后以乙酸乙酯淋洗萃取柱,用甲醇洗脱,并以甲醇为流动相对洗脱溶液进行液相色谱分离,与质谱仪联用鉴定各分离组分。在上述条件下,TAT回收率在79％~93％,检出限为1.8 mg/L (3σ),线性范围为6.0~500.0 mg/L,富集倍数400倍。     

咖啡因分子印迹固相萃取柱的制备及应用

以咖啡因作为模板分子,α-甲基丙烯酸为功能单体,乙二醇二甲基丙烯酸酯为交联剂,制备了咖啡因分子印迹聚合物(MIP)。与非印迹聚合物(NIP)相比,MIP对咖啡因具有更高的吸附容量和选择性,MIP和NIP对咖啡因的最大静态吸附量分别为28.1和16.5mg/g,相对选择因子为1.25。以咖啡因分子印迹聚合物为固相萃取填料,结合高效液相色谱(HPLC),建立了茶水中咖啡因浓度及人饮茶后血清中咖啡因浓度的检测方法。考察了洗脱剂种类和用量对咖啡因回收率的影响。当萃取柱依次以2mL水活化,水溶液上样,2mL水淋洗,6mL甲醇-乙酸(9∶1,V/V)洗脱,咖啡因在MIP固相萃取柱上的回收率达到97.5%,而在NIP柱上的回收率仅为54.9%。     

印迹分子聚合物结合低共熔溶剂用于山楂中咖啡酸的固相萃取（英文）

在相同的实验条件下,分别合成了以咖啡酸为模板的印迹分子聚合物和无模板分子聚合物。使用场发射扫描电镜法和吸附实验表征这两种聚合物材料的孔状结构和选择性吸附性能。然后利用印迹分子聚合物、无模板分子聚合物、C18萃取小柱这3种材料结合固相萃取法纯化山楂提取物中的咖啡酸,提取率分别为3.46、1.01、1.17μg/g。为了优化固相萃取过程,实验研究了不同洗脱剂的影响。分别利用用氯化胆碱和甘油、氯化胆碱和尿素(摩尔比均为1∶2)合成出两种低共熔溶剂。甲醇与这两种低共熔溶剂分别以不同的体积比混合作为洗脱剂,用于优化咖啡酸的固相萃取过程。实验结果表明,印迹分子聚合物是一种良好的固相萃取材料;当甲醇和甘油基低共熔溶剂在体积比为3∶1混合时,表现出最好的洗脱能力,得到咖啡酸的回收率为82.32%。     

固相萃取-气相色谱/质谱法同时测定涂料中的8种有机锡

建立了一种固相萃取（SPE）前处理、气相色谱-质谱（GC-MS）法同时测定涂料中8种有机锡的方法。样品采用阳离子交换固相萃取小柱净化,最佳固相萃取条件为：固相萃取小柱分别用5mL甲醇、7mL洗脱液（氯化铵、甲醇、冰乙酸的混合溶液）预洗,10mL甲醇活化;将用甲醇稀释的涂料样品上样后,用5mL甲醇淋洗,抽干2min,7mL乙酸-氯化铵甲醇溶液（10：90,V／V）洗脱溶液洗脱。洗脱液用四乙基硼化钠溶液衍生后,气相色谱-质谱法进行定性定量分析。结果表明：以标准加入法计算回收率,在1.68％-16.84%添加范围内,平均回收率在85％-105％之间,相对标准偏差均小于12％。     

替米考星分子印迹聚合物的制备及其固相萃取研究

以泰乐菌素为虚拟模板分子,甲基丙烯酸为功能单体,乙二醇二甲基丙烯酸酯为交联剂,合成了对替米考星具有高选择性的分子印迹聚合物。考察了二甲基甲酰胺、甲醇、丙酮和氯仿4种致孔剂对合成聚合物性能的影响。通过正交实验优化的聚合配方为:1.0mmol泰乐菌素,8.0mmol甲基丙烯酸,20.0mmol乙二醇二甲基丙烯酸酯,6.0mL氯仿,20.0mg偶氮二异丁腈。研究了将该聚合物作为固相萃取填料分离、富集替米考星的萃取条件和萃取性能。当萃取柱依次用甲醇和水(pH9.0)活化,乙腈溶液上样,甲醇和氯仿分别洗涤,3mL氨化甲醇(95:5,V/V)洗脱时,替米考星在分子印迹固相萃取柱上的回收率达到90%以上,而非分子印迹固相萃取柱的回收率仅为32%。     

Computer‐assisted design and synthesis of molecularly imprinted polymers for the simultaneous determination of six carbamate pesticides from environmental water

The computer‐assisted design and synthesis of molecularly imprinted polymers for the simultaneous capture of six carbamate pesticides from environmental water are reported in this work. The quantum mechanical computational approach was employed to design the molecularly imprinted polymers with carbofuran as template. The interaction energies between the template molecule and different functional monomers in various solvents were calculated to assist in the selection of the functional monomer and porogen. The optimised molecularly imprinted polymer was subsequently used as a class‐selective sorbent in solid‐phase extraction for pre‐concentration and determination of carbamates from environmental water. The parameters influencing the extraction efficiency of the molecularly imprinted solid‐phase extraction procedure were systematically investigated to facilitate the class‐selective extraction. For the proposed method, linearity was observed over the range of 2–500 ng/mL with the correlation coefficient ranging from 0.9760 to 1.000. The limits of detection ranged from 0.2 to 1.2 ng/mL, and the limit of quantification was 4 ng/mL. These results confirm that computer‐assisted design is an effective evaluation tool for molecularly imprinted polymers synthesis, and that molecularly imprinted solid‐phase extraction can be applied to the simultaneous analysis of carbamates in environmental water.     

利用分子印迹技术预处理生物样品中头孢药物的研究

优化了头孢硫脒分子印迹聚合物的合成条件,探讨了分子印迹技术和固相萃取联用对血浆中头孢硫脒的分离富集,发现用4-乙烯基吡啶作功能单体合成的分子印迹聚合物作为固相萃取填充料,能定量吸附血浆中的头孢硫脒,并初步研究了其吸附机理。     

Preparation of l‐phenylalanine‐imprinted solid‐phase extraction sorbent by Pickering emulsion polymerization and the selective enrichment of l‐phenylalanine from human urine

A novel l‐ phenylalanine molecularly imprinted solid‐phase extraction sorbent was synthesized by the combination of Pickering emulsion polymerization and ion‐pair dummy template imprinting. Compared to other polymerization methods, the molecularly imprinted polymers thus prepared exhibit a high specific surface, large pore diameter, and appropriate particle size. The key parameters for solid‐phase extraction were optimized, and the result indicated that the molecularly imprinted polymer thus prepared exhibits a good recovery of 98.9% for l‐ phenylalanine. Under the optimized conditions of the procedure, an analytical method for l‐ phenylalanine was well established. By comparing the performance of the molecularly imprinted polymer and a commercial reverse‐phase silica gel, the obtained molecularly imprinted polymer as an solid‐phase extraction sorbent is more suitable, exhibiting high precision (relative standard deviation 3.2%, n = 4) and a low limit of detection (60.0 ± 1.9 nmol·L^?1) for the isolation of l‐ phenylalanine. Based on these results, the combination of the Pickering emulsion polymerization and ion‐pair dummy template imprinting is effective for preparing selective solid‐phase extraction sorbents for the separation of amino acids and organic acids from complex biological samples.     

Preparation and selective recognition of a novel solid‐phase microextraction fiber combined with molecularly imprinted polymers for the extraction of parabens in soy sample

A prepared molecularly imprinted polymer with ethyl p‐hydroxybenzoate as template molecule was applied for the first time to a homemade solid‐phase microextraction fiber. The molecularly imprinted polymer‐coated solid‐phase microextraction fiber was characterized by scanning electron microscopy and thermogravimetric analysis. Various parameters were investigated, including extraction temperature, extraction time, and desorption time. Under the optimum extraction conditions, the molecularly imprinted polymer‐coated solid‐phase microextraction fiber exhibited higher selectivity with greater extraction capacity toward parabens compared with the nonimprinted polymer‐coated solid‐phase microextraction fiber and commercial fibers. The molecularly imprinted polymer‐coated solid‐phase microextraction fiber was tested using gas chromatography to determine parabens, including methyl p‐hydroxybenzoate, ethyl p‐hydroxybenzoate, and propyl p‐hydroxybenzoate. The linear ranges were 0.01–10 μg/mL with a correlation coefficient above 0.9943. The detection limits (under signal‐to‐noise ratio of 3) were below 0.30 μg/L. The fiber was successfully applied to the simultaneous analysis of three parabens in spiked soy samples with satisfactory recoveries of 95.48, 97.86, and 92.17%, respectively. The relative standard deviations (n=6) were within 2.83–3.91%. The proposed molecularly imprinted polymer‐coated solid‐phase microextraction method is suitable for selective extraction and determination of trace parabens in food samples.     

Recent advances and applications of molecularly imprinted polymers in solid‐phase extraction for real sample analysis

Sample pretreatment is essential for the analysis of complicated real samples due to their complex matrices and low analyte concentrations. Among all sample pretreatment methods, solid‐phase extraction is arguably the most frequently used one. However, the majority of available solid‐phase extraction adsorbents suffer from limited selectivity. Molecularly imprinted polymers are a type of tailor‐made artificial antibodies and receptors with specific recognition sites for target molecules. Using molecularly imprinted polymers instead of conventional adsorbents can greatly improve the selectivity of solid‐phase extraction, and therefore molecularly imprinted polymer‐based solid‐phase extraction has been widely applied to separation, clean up and/or preconcentration of target analytes in various kinds of real samples. In this article, after a brief introduction, the recent developments and applications of molecularly imprinted polymer‐based solid‐phase extraction for determination of different analytes in complicated real samples during the 2015‐2020 are reviewed systematically, including the solid‐phase extraction modes, molecularly imprinted adsorbent types and their preparations, and the practical applications of solid‐phase extraction to various real samples (environmental, food, biological, and pharmaceutical samples). Finally, the challenges and opportunities of using molecularly imprinted polymer‐based solid‐phase extraction for real sample analysis are discussed.     

Preparation of a stoichiometric molecularly imprinted polymer for auramine O and application in solid‐phase extraction

We describe a stoichiometric approach to the synthesis of molecularly imprinted polymers specific for auramine O. Using the stoichiometric interaction in molecular imprinting, no excess of binding sites is necessary and binding sites are only located inside the imprinted cavities. The free base of the template was obtained to facilitate the interaction with the monomers. Itaconic acid was selected as the functional monomer, and stoichiometric ratio of the interaction with the free base was investigated. The molecularly imprinted polymer preparation conditions such as cross‐linker, molar ratio, porogen were optimized as divinylbenzene, 1:2:20 and chloroform/N,N‐dimethylformamide, respectively. Under the optimum conditions, a good imprinting effect and very high selectivity were achieved. A solid‐phase extraction method was developed using the molecularly imprinted polymers as a sorbent and extraction procedure was optimized. The solid‐phase extraction method showed a high extraction recovery for auramine O in its hydrochloride form and free form compared to its analogues. The results strongly indicated that stoichiometric imprinting is an efficient method for development of high selectivity molecularly imprinted polymers for auramine O.     

分子印迹固相萃取—高效液相色谱法同时测定鸡血浆中环丙氨嗪和三聚氰胺残留

建立了基于分子印迹固相萃取-高效液相色谱同时测定鸡血浆中环丙氨嗪和三聚氰胺残留方法.以环丙氨嗪为模板分子,甲基丙烯酸为功能单体,合成了对环丙氨嗪和三聚氰胺具有高选择性的分子印迹聚合物.作为固相萃取填料,评价和优化了其分离、富集环丙氨嗪和三聚氰胺的固相萃取条件.血浆用1％三氯乙酸沉淀蛋白,分子印迹固相萃取净化.在辛烷磺酸...     

Preparation of five high‐purity iridoid glycosides from Gardenia jasminoides Eills by molecularly imprinted solid‐phase extraction integrated with preparative liquid chromatography

Five iridoid glycosides were prepared using molecularly imprinted solid‐phase extraction combined with preparative high‐performance liquid chromatography. Hydrophilic molecularly imprinted polymers were synthesized using α‐1‐allyl‐2‐N‐acetyl glucosamine, which introduced an abundance of hydrophilic groups into the polymers. Using molecularly imprinted solid‐phase extraction as the sample pretreatment procedure, five iridoid glycosides, gardenoside, geniposide, shanzhiside, geniposidic acid, and genipin‐1‐O‐gentiobioside, were selectively enriched from Gardenia fructus extracts. Preparative high‐performance liquid chromatography then provided iridoid glycosides with a purity >98%. The structures were elucidated by using nuclear magnetic resonance spectroscopy, optical rotation and melting point measurements, and mass spectrometry. The results demonstrate that molecularly imprinted solid‐phase extraction combined with preparative high‐performance liquid chromatography was an efficient, rapid, and economical method for the preparation of bioactive compounds from natural products.     

Innovative method for the enrichment of high‐polarity bioactive molecules present at low concentrations in complex matrices

Ginsenoside Rg1 is a valuable bioactive molecule but its high polarity and low concentration in complex mixtures makes it a challenge to separate Ginsenoside Rg1 from other saponins with similar structures, resulting in low extraction efficiency. The successful development of effective Rg1 molecularly imprinted polymers that exhibit high selectivity and adsorption may offer an improved method for the enrichment of active compounds. In this work, molecularly imprinted polymers were prepared with two different methods, precipitation polymerization or surface imprinted polymerization. Comparison of the adsorption abilities showed higher adsorption of the surface molecularly imprinted polymers prepared by surface imprinted polymerization, 46.80 mg/g, compared to the 27.74 mg/g observed for the molecularly imprinted polymers prepared by precipitation polymerization. Therefore, for higher adsorption of the highly polar Rg1, surface imprinted polymerization is a superior technique to make Rg1 molecularly imprinted polymers. The prepared surface molecularly imprinted polymers were tested as a solid‐phase extraction column to directionally enrich Rg1 and its analogues from ginseng tea and total ginseng extracts. The column with surface molecularly imprinted polymers showed higher enrichment efficiency and better selectivity than a C₁₈ solid‐phase extraction column. Overall, a new, innovative method was developed to efficiently enrich high‐polarity bioactive molecules present at low concentrations in complex matrices.     

分子印迹固相萃取及其应用

系统地介绍了分子印迹固相萃取的原理、特点、发展现状及其发展趋势，并重点对分子印迹固相萃取技术在环境和生物样品前处理中的应用作了较详细的综述。共引用文献100篇。