离子液体[Bmim]PF_6溶剂浮选分离富集-光度法测定环境中痕量四环素类抗生素的研究

建立了离子液体溶剂浮选四环素类(TCs)抗生素的新方法。以1-丁基-3-甲基咪唑六氟磷酸盐([Bmim]PF6)和乙酸乙酯(EA)的混合溶剂(V/V=1)为浮选剂,以Al(Ⅲ)为捕集剂,在pH=6.7条件下,分离富集环境水样中四环素(TC)、土霉素(OTC)、金霉素(CTC)三种四环素类抗生素,并用紫外-可见分光光度法测定总含量。方法线性范围为0.2~10.3μg.mL-1,表观摩尔吸光系数3ε80=3.8×105L.mol-1.cm-1,加标回收率达到94.5%~102.2%,相对标准偏差RSD3.76%(n=5)。该方法适合于环境水样中痕量TC、OTC、CTC抗生素总含量的分离分析。     

固相萃取-亲水作用色谱法测定废水中四环素类抗生素

建立了固相萃取(SPE)-亲水作用色谱法(HILIC)测定废水中金霉素(CTC)、强力霉素(DC)、四环素(TC)和土霉素(OTC) 4种四环素类抗生素(TCs)残留的新方法.水样经Oasis HLB固相萃取柱净化富集后, 采用以氨基色谱柱及高极性有机溶剂-水相缓冲溶液为流动相的亲水作用色谱法(HILIC)进行分析. 对流动相中缓冲溶液的类型和pH值、离子强度、 有机溶剂的浓度以及流速进行了优化, 确定了以V(乙腈)∶V(6.7 mmol/L柠檬酸铵缓冲溶液, pH 4.0)=85∶ 15混合液为流动相的最佳条件.本方法具有良好的线性关系(r> 0.999)和重现性(峰面积RSD<1.0%), 最低检出限(S/N=3)为12～30 μg/L, 4种四环素类药物添加水平在0.5～10 μg/L范围内的标准加入回收率为 90.6%～106.5%; 相对标准偏差为 2.5%～6.2%.本方法简便、准确、流动相离子强度低,适合于与质谱联用,用于屠宰场污水及医院污水等实际样品检测,结果满意.     

精氨酸的溶剂浮选分离技术及其分离机制

以表面活性剂十二烷基苯磺酸为捕收剂(DBSA),二(2-乙基己基)磷酸酯(P204)为萃取剂,正庚烷为有机溶剂,采用溶剂浮选法对水溶液中精氨酸进行分离富集,并与气浮络合萃取法、泡沫浮选法和溶剂萃取法进行了比较.结果表明,在常温下,0.09 g/L精氨酸水溶液250 mL、初始pH 7.0,DBSA浓度0.15 g/L,正庚烷体积10 mL, P204体积4.5 mL,气体流量200 mL/min,溶剂浮选法分离水溶液中精氨酸的富集比为16.2,回收率为97.2%.溶剂浮选法分离精氨酸的动力学实验结果表明,精氨酸的溶剂浮选过程阶段性明显,大致可分为3个阶段,第一阶段和第二阶段都符合一级动力学方程,第三阶段符合零级动力学方程,探索了溶剂浮选法分离精氨酸的分离机制.     

离子液体双水相溶剂浮选法分离/富集桑黄黄酮类成分

将亲水性离子液体氯化-1-丁基-3-甲基咪唑([C4mim]Cl)和K2HPO4形成的双水相体系与溶剂浮选结合,建立了分离/富集桑黄中总黄酮类成分的方法。考察了分相盐的种类和用量、样品量、溶液pH值、浮选时间和氮气流速对浮选效果的影响,并与双水相萃取进行比较。当浮选分相盐K2HPO4的质量浓度为50%、溶液pH=9.53、离子液体的用量为3 mL、浮选时间为50 min、氮气流速为30 mL/min时,浮选效率最佳,达到85.31%,富集倍数为8.59。离子液体双水相溶剂浮选法浮选效率高,富集倍数大,为中草药有效成分分离/富集提供了新方法。     

穿心莲内酯的溶剂浮选

应用溶剂浮选法对穿心莲乙醇提取液中的穿心莲内酯进行分离富集,优化了穿心莲内酯的浮选条件.实验表明:浮选溶剂为乙酸乙酯,水相与有机相体积比为2: 1,加入水相体积4%的乙醇,溶液pH 7,氮气流速200 mL/min,浮选时间40 min为最佳浮选条件.在最佳实验条件下,穿心莲内酯平均收率为94.1%; RSD为1.1%,平均标准加入回收率95.1%; 富集倍数为9.7倍.溶剂浮选法分离穿心莲内酯不仅能得到满意的回收率和富集倍数,并能有效地除去水溶性杂质,提高目标物纯度.与溶剂萃取法相比, 溶剂浮选法能节约有机溶剂和操作时间.     

离子液体-分散液液微萃取/高效液相色谱法用于猪肾脏中3种四环素类抗生素的检测

建立了分散液液微萃取(DLLME)技术进行样品前处理,高效液相色谱(HPLC)法测定猪肾脏中土霉素(OTC)、四环素(TC)、金霉素(CTC)3种四环素类抗生素(TCs)残留量的方法。考察了分散剂种类、离子液体用量、分散剂用量、样品溶液p H值、萃取时间、盐效应等因素对萃取效率的影响。优化后的实验条件为:以丙酮为分散剂,离子液体([BMIM]PF6)用量为50μL,分散剂用量为140μL,样品溶液p H值为3.0,萃取时间为15 min,不添加盐。该方法在0.1~10.0 mg/L范围内线性关系良好(r2≥0.999 5),土霉素、四环素和金霉素的相对标准偏差(RSD)为2.2%~3.1%,检出限(LOD)为54~93μg/L,富集倍数为7.0~27.8,且样品的加标回收率达99.5%~101.1%。该法准确度和精密度均满足分析方法的要求,实现了对猪肾脏中土霉素、四环素、金霉素3种四环素类抗生素残留量的快速、绿色、灵敏和准确检测。     

溶剂浮选分离-紫外分光光度法测定环境水样中罗红霉素残留量

采用溶剂浮选法分离富集环境水样中罗红霉素,并利用紫外分光光度法对罗红霉素进行测定。罗红霉素的最佳浮选条件为在磷酸氢二钾溶液中,以异丙醇作浮选溶剂,控制溶液pH为9.0,氮气流量15mL·min~(-1),浮选时间30min。罗红霉素的质量浓度在8.2～40.2mg·L~(-1)范围内与其吸光度呈线性关系,检出限(3S/N)为0.26mg·L~(-1)。在河水及湖水样品中分别加入3个浓度水平的罗红霉素标准溶液做方法的回收试验,测得平均回收率均超过90%。     

固相萃取-超高压液相色谱-串联质谱同时分析环境水样中四环素类和喹诺酮类抗生素

应用固相萃取及超高压液相色谱-质谱联用技术,建立了环境水样中4种四环素类和6种喹诺酮类抗生素的同时分析方法。样品经HLB固相萃取柱富集、净化后用甲醇洗脱,以超高压液相色谱-串联质谱仪多反应监测(MRM)离子模式定性、定量分析。以河水和海水为基质,卡巴氧为替代物进行回收率评价,4种四环素类抗生素在加标质量浓度分别为20.0 ng/L和100.0 ng/L时的回收率为94.0%～117.0%,相对标准偏差为2.0%～9.7%(n=4),方法的检出限均为20.0 ng/L;6种喹诺酮类抗生素在加标质量浓度分别为5.0 ng/L和20.0 ng/L时的回收率为63.6%～93.9%,相对标准偏差为1.6%～8.1%(n=4),方法的检出限为0.4 ng/L。结果表明,所建立的方法可成功地应用于近岸海域表层环境水样中目标抗生素残留的分析。     

溶剂浮选技术的研究现状与展望

溶剂浮选是一种被气泡传质效应强化的液-液萃取技术,具有高分离效率、高富集系数、传质温和、低有机溶剂消耗、操作简单等优点,广泛应用于仪器分析的样品前处理、水体中有机污染物的分离富集、天然产物中活性物质分离等领域。本文比较全面地综述了溶剂浮选技术的通用模式、分离参数、应用现状和理论研究进展;在此基础上,重点介绍了近些年溶剂浮选领域出现的一些新分离模式和应用领域:新的分离模式主要是"双水相浮选"和"气浮络合萃取",新的应用领域主要是样品前处理技术的新应用以及对天然产物提取液中活性物质的分离富集。     

溶剂浮选-高效液相色谱法测定水体中双酚A、辛基酚和壬基酚

以正辛醇为溶剂对水样中双酚A、辛基酚和壬基酚进行溶剂浮选分离和富集。水样溶液的适宜酸度为pH3,通入速率为60mL·min-1氮气浮选90min。浮选完成时,分取上层清液10μL供高效液相色谱分析用。上述3种环境激素的检出限(3s/b)依次为0.025,0.011,0.042μg.L-1。以不含上述化合物的水样作为基体,采用标准加入法对方法做回收试验,测得回收率在93.3%～102.0%之间,测定值的相对标准偏差(n=7)在1.3%～4.9%之间。     

Application and recovery of ionic liquids in the preparative separation of four flavonoids from Rhodiola rosea by on‐line three‐dimensional liquid chromatography

A novel on‐line three‐dimensional liquid chromatography method was developed to separate four main flavonoids from Rhodiola rosea. Ethyl acetate/0.5 mol/L ionic liquid 1‐butyl‐3‐methylimidazolium chloride aqueous solution was selected as the solvent system. In the first‐dimension separation, the target flavonoids were entrapped and subsequently desorbed into the second‐dimension high‐speed countercurrent chromatographic column for separation. In the third‐dimension chromatography, the residual ionic liquid in the four separated flavonoids was removed and the used ionic liquid was recovered. As a result, 35.1 mg of compound 1 , 20.4 mg of compound 2 , 8.5 mg of compound 3, and 10.6 mg of compound 4 were obtained from 1.53 g R. rosea extract. They were identified as rhodiosin, rhodionin, herbacetin, and kaempferol, respectively. The recovery of ionic liquid reached 99.1% of the initial amount. The results showed that this method is a powerful technology for the separation of R. rosea flavonoids and that the ionic‐liquid‐based solvent system has advantages over traditional solvent systems in renewable and environmentally friendly properties.     

一种难溶多金属氧酸盐配位聚合物的重构与表征

利用电沉积法将不溶于常规无机和有机溶剂的多金属氧酸盐基的配位聚合物1, [{La(H2O)5·(dipic)}{La(H2O)(dipic)}]2{Mo8O26}·10H2O溶解于离子液体[RMIM][HT]或[RMIM][HP]中, 在恒电位下电解, 得到多金属氧酸盐基的配位聚合物膜. 应用红外光谱、X射线光电子能谱和XRD粉末衍射等方法研究多金属氧酸盐基配位聚合物膜的结构, 发现其与多金属氧酸盐基配位聚合物有相同的结构. 实现了多金属氧酸盐基配位聚合物在电极上的重构设计以及多金属氧酸盐基的配位聚合物的二次加工成型.     

A Novel Ionic Liquid Based on Imidazolium Cation as an Efficient and Reusable Catalyst for the One‐pot Synthesis of Benzoxazoles,Benzthiazoles, Benzimidazoles and 2‐Arylsubstituted Benzimidazoles

A novel dicationic ionic liquid based on imidazolium cation is designed, synthesized and successfully used as catalyst for the one‐pot synthesis of benzoxazoles, benzthiazoles, benzimidazoles and 2‐arylsubstituted benzimidazoles. The remarkable feature of this new catalyst is its ethyleneoxy bridge which participates in dissolving organic compound in ionic liquid. The application of this ionic liquid is studied in a new one‐pot method for synthesis of heterocyclic compounds under solvent‐free conditions. Simple and convenient procedure, high conversion, reusability of catalyst, easy purification and shorter reaction time are the advantageous features of this method.     

A novel strategy to utilize ethylene glycol‐ionic liquids for the selective precipitation of polysaccharides

In the present work, three hydrophilic ionic liquids based on the combination between imidazolium cations attached with ethylene glycol polymers of various lengths and hexafluorophosphate anion were designed and synthesized for the separation of polysaccharides. By employing dextran 100 kDa as model compound, the effects of ionic liquid content, solvent/anti‐solvent volume, and temperature on its recovery efficiency were investigated systematically. The ability of these ionic liquids to precipitate dextran 100 kDa, increases with the elongation of ethylene glycol polymer chain. The established ionic liquid‐based precipitation system was successfully applied to selectively precipitate polysaccharides from water extracts of three traditional Chinese medicines and the precipitation could be achieved in about 15 min. In addition, the different precipitation responses of acidic, neutral, and basic polysaccharides in the ionic liquid‐based precipitation system and theoretical calculations both suggested that the selective precipitation of polysaccharides was probably mediated by interaction between ionic liquids and polysaccharides. The proposed strategy facilitated the isolation and purification of polysaccharides and may trigger a novel application of ionic liquids in carbohydrate research.     

Structural-dynamic properties of infinitely dilute ionic liquid–nonpolar compound systems

The effect of nonpolar solvents (argon, methane, and benzene) on the structural-dynamic properties of an ionic liquid (IL), dimethylimidazolium chloride, is studied at 400 K by the method of molecular dynamics using DL_POLY _4.05 software package. The energy and structural-dynamic parameters of infinitely dilute liquid ternary systems are calculated and analyzed. The pattern of motion of the molecules of dilute compound in the IL is described. It is demonstrated that increased size of a solvent molecule enhances the effect on the ionic liquid structure, which also influences the solubility of nonpolar compounds and IL.     

离子液体中微波促进的Knoevenagel缩合反应

以离子液体1-丁基3-甲基咪唑四氟硼酸盐为反应溶剂，氨基乙酸为催化剂，在微波辐射下，醛和活泼亚甲基类化合物发生的Knoevenagel缩合反应速度能被极大地提高，8种缩合产物被快速高收率地合成。     

Determination of triclosan by cuvetteless UV–vis micro-spectrophotometry following simultaneous ultrasound assisted emulsification–microextraction with derivatization: Use of a micellar-ionic liquid as extractant

Two ultrasound-assisted emulsification–microextraction procedures based on the use of a micellar ionic liquid as extractant are proposed for triclosan determination in troublesome matrices such as cosmetics and wastewaters. Microvolume UV–vis spectrophotometry was used in order to quantify the yellow azoderivative formed. This compound is polar and water-soluble and hence, it is not extractable into conventional organic solvents. Two imidazolium based ionic liquids were used as extractants. An improvement in the extraction of the derivative was achieved when SDS was mixed with the ionic liquid. The use of ultrasound energy allows a fast emulsification of the system. All the parameters related to the emulsification–microextraction were carefully optimized (i.e., ionic liquid type and volume, SDS concentration, sonication time and amplitude, salt addition, disperser solvent, cooling of ionic liquid and centrifugation time). Matrix effects were assessed and external calibration was used in all cases. Several advantages such as high sample throughput, simplicity and low reagent consumption can be emphasized.     

Preparation and evaluation of solid-phase microextraction fiber based on molecularly imprinted polymers for trace analysis of tetracyclines in complicated samples

Molecularly imprinted polymer (MIP) is widely used in many fields because of its characteristics of high selectivity, chemical stability and easy preparation. To enhance the selectivity and applicability of solid-phase microextraction (SPME), a novel MIP-coated SPME fiber was firstly prepared by multiple co-polymerization method with tetracycline as template. It could be coupled directly to high-performance liquid chromatography (HPLC) and used for trace analysis of tetracyclines (TCs) in complicated samples. The characteristics and application of the fibers were investigated. The electron microscope provided a crosslinked and porous surface, and the average thickness of the MIP coating was 19.5 microm. Compared with the non-imprinted polymer (NIP) coated fibers, the special selectivity to tetracycline and structure-similar oxytetracycline, doxycycline, chlortetracycline were discovered with the MIP-coated fibers. The adsorption and desorption of TCs with the MIP-coated fiber could be achieved quickly. A method for the fluorimetric determination of four TCs by the MIP-coated SPME coupled with HPLC was developed. The optimized extraction conditions such as extraction solvent, desorption solvent, and stirring speed were studied. Linear ranges for the four TCs were 5.00-200 microg/L and detection limits were within the range of 1.0-2.3 microg/L. The method was applied to simultaneous multi-residue analysis of four TCs in the spiked chicken feed, chicken muscle, and milk samples with the satisfactory recoveries.