乙二胺二琥珀酸功能化硅胶材料的制备及特性研究

以乙二胺二琥珀酸（EDDS）为配体、3-缩水甘油基氧基丙基三甲氧基硅烷（γ-GLDP）为间隔臂、硅胶（Silica）为基质,制得一种新型多功能改性材料—EDDS-Silica。采用X射线光电子能谱（XPS）和酸碱电位滴定对EDDS-Silica分别进行了定性和定量表征,证明EDDS-Silica已成功制备,且当Silica与EDDS用量比为1.5∶3.0(m/m)时单位硅胶基质上EDDS的键合量最高,为39.82μmol/g。通过蛋白质色谱实验以及金属离子吸附实验分别对EDDS-Silica的阳离子交换特性和金属螯合特性进行了考察。结果表明,EDDS-Silica既可作为色谱固定相用于带电荷物质的分离与纯化,又可作为金属螯合吸附剂用于金属离子的吸附研究。EDDS-Silica优良的离子交换和金属螯合特性,使得该配体改性材料具有更为广阔的应用前景。     

柱温对胆固醇键合固定相分离黄酮苷的影响及其热力学分离机理研究

柱温属于高效液相色谱(HPLC)的可调参数之一,但在实际操作过程中,柱温对溶质保留行为的影响通常被忽略,不作为色谱条件优化参数.本研究分别以甲醇-0.02 mol/L乙酸(30∶70,V/V)及甲醇-0.02 mol/L乙酸(25∶75,V/V)为流动相,讨论了柱温对6种黄酮苷在一种新型色谱固定相-胆固醇键合固定相以及C18键合固定相上分离的影响.结果表明,随着柱温升高,不同于十八烷基键合固定相,黄酮苷在胆固醇键合固定相上的分离效果得到改善,且峰形变好.同时,拟合了25℃～55℃温度范围内的van't Hoff方程,从热力学角度比较了黄酮苷在胆固醇键合固定相和十八烷基键合固定相上的保留机理.结果表明,黄酮苷在两种色谱柱上的van't Hoff方程均具有良好的线性关系(R2 ＞0.99),且拟合参数相近(△H0＜0,△S0＜0),表明这些物质在胆固醇键合固定相上的保留机理与在十八烷基键合固定相上相似,以单一的疏水性保留机理为主导,均属于焓驱动过程.本实验证实,在使用胆固醇键合固定相时,柱温可作为一项重要调节参数,参与色谱优化过程,从而使液相色谱从两变量调节方式(流动相种类和流动相比例)变为三变量调节方式(流动相种类、比例和柱温),从而为色谱条件优化提供了更多选择.     

α-氨基酸在L-脯氨酸手性配体交换色谱固定相上的分离

合成了L-脯氨酸硅胶键合手性配体交换色谱固定相，并用于α-氨基酸的直接光学分离，详细考察了流动相pH值、金属离子浓度、流速、柱温以及进样量等因素对分离效果的影响，从而进一步优化了色谱分离条件。     

多壁碳纳米管键合硅胶固定相的保留机理研究

制备了3种不同键合量的多壁碳纳米管键合硅胶固定相。以芳香族化合物为目标分析物,甲醇-水为流动相,分别考察了其在不同流动相比例、流速、柱温条件下,酸性、中性、碱性化合物的色谱保留行为,并通过计算分离过程中焓变、熵变和吉布斯自由能等热力学参数,探讨了色谱柱的保留机理。结果表明,碳纳米管键合硅胶与未键合的硅胶固定相分离对氨基苯磺酸和尿嘧啶时,因碳纳米管的加入增强了其疏水作用,保留机理与反相色谱柱相似。而分离中性化合物时,因加入的碳纳米管引入π-π作用,增强了对化合物的保留,有效地提高了色谱柱的柱效。碳纳米管的加入使溶质分子在固定相上的保留增强,溶质分子从杂乱无序排列转为有序排列,且溶质分子在不同碳纳米管键合量的色谱柱上的保留并非由单一机理支配,而是由多种作用相互协同的结果,这使碳纳米管键合硅胶固定相在分离和固相萃取领域展现出良好的应用前景。     

一种手性中间体在键合型和涂覆型纤维素手性固定相上的拆分

制备了涂覆型和键合型纤维素-(3, 5-二甲基苯基氨基甲酸酯)固定相, 分别在制备的纤维素手性固定相上成功地拆分了一种手性中间体, 通过考察流动相中的改性剂(醇、四氢呋喃、三氯甲烷)对手性拆分的影响, 优化了手性中间体在两种手性固定相上的色谱分离条件, 并比较了手性中间体在涂覆和键合型纤维素手性固定相上的拆分. 结果表明, 涂覆型和键合型手性固定相对这种手性中间体均有较好的拆分效果, 在150 mm的色谱柱上, 这两种手性固定相对这种手性中间体的拆分能力相差不大, 但键合型固定相上可选择的流动相范围更广.     

硅胶键合手性配体交换色谱固定相拆分α-氨基酸

用简易的方法制备了铜(Ⅱ)—L—羟脯氨酸键合手性固定相；在所制备的手性固定相上，用配体交换色谱法研究了pH值、温度、中心离子浓度及流速对α—氨基酸对映体拆分的选择性和分离度的影响，选择了合理的色谱分离条件；结果表明，该固定相在配体交换模式下，可对部分常见氨基酸进行良好分离。     

C_(60)键合硅胶液相色谱固定相的合成及其性能评价

 以γ－（乙二胺基）丙基三乙氧基硅烷为偶联剂合成了Ｃ６０键合硅胶固定相；用元素分析法测定得到该固定相的Ｃ６０键合量为５７．５７μｍｏｌ／ｇ。考察了多环芳烃和杯芳烃在Ｃ６０键合硅胶固定相上的分离，多环芳烃在该固定相上的洗脱顺序与ＯＤＳ固定相相似；杯芳烃的洗脱顺序为杯［８］、杯［４］和杯［６］芳烃。     

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。     

流动相组成、浓度和pH对蛋白质在金属螯合柱上的保留特性的影响

 系统研究了流动相中盐的性质和浓度、溶液 pH以及竞争配体对蛋白质在金属螯合色谱中保留值的影响。导出了描述蛋白质在金属螯合色谱中保留特征的数学表达式 ,提出用洗脱强度指数ε表征盐溶液的洗脱能力。根据不同色谱条件下蛋白质的保留特性 ,发现蛋白质在金属螯合色谱中的保留是配位、静电和疏水的协同作用。对与蛋白质强结合的金属螯合柱 ,以配位作用为主 ,静电作用为辅 ;对弱结合的金属柱 ,以静电作用为主 ,配位作用为辅。在流动相中加入高浓度非成络盐 ,可增强蛋白质和固定相间的疏水作用。     

十二烷基键合氧化锆固定相的制备与性能评价

以自制5μm球形氧化锆为基质，制备了十二烷基键合氧化锆HPLC固定相，考察了正烷基取代苯、稠环芳烃、苯胺及吡啶衍生物、苯酚和硝基苯酚异构体等不同性质化合物在固定相上的保留行为，并与十二烷基键合硅胶固定相进行了比较。结果表明：中性和碱性化合物在固定相上主要为反相色谱保留机理；酸性化合物在固定相上以反相色谱保留机理为主，但是氧化锆表面的Lewis酸性中心对溶质也存在一定程度吸附作用，导致色谱峰拖尾。     

金属离子与氨羧类螯合配体的键合特性研究

利用前沿色谱法,通过Cu2+、Ni2+和Co2+与螯合配体IDA 键合的准确度(R2>0.98)与精密度(RSD <5%)实验,研究了前沿色谱法同时测定络合稳定常数KML与总键合位点数Λ0值的可行性.为了进一步证明前沿色谱法的普适性,以Cu2+、Ni2+和Co2+为代表,在3种键合缓冲体系(NaAc-HAc、Na-PB、Tris-HCl)中,考察了金属离子在3种氨羧类螯合配体(IDA、Asp、Glu)上络合稳定常数KML的变化规律.结果表明,螯合配体对金属离子键合强度遵循IDA>Asp>Glu;金属离子对螯合配体键合强度遵循Cu2+>Ni2+>Co2+;3种键合缓冲体系中,NaAc-HAc键合效果最好.按照M06/6-311++G (d, p) 方法对螯合配体与金属离子的结合能(ΔE)与吉布斯自由能(ΔG)进行相关的量子计算.根据ΔE 与ΔG 的大小,从理论上推测出螯合配体与金属离子的键合规律,此规律与上述实验结果基本相符.本研究为金属离子与螯合配体间键合参数的求取提供了有效的方法和手段,从而为今后提高IMAC柱的稳定性,解决固定金属亲和柱在应用过程中尤其是竞争洗脱过程中金属离子的流失问题奠定了良好的基础.     

Analysis of Nonionic Surfactants by High Performance Liquid Chromatography

Abstract

This review discusses the principles of immobilized metal ion affinity chromatography (IMAC) and its applications to protein separations. IMAC functions by binding the accessible electron-donating pendant groups of a protein - such as histidine, cysteine, and tryptophan - to a metal ion which is held by a chelating group covalently attached on a stationary support. A common chelating group is iminodiacetate. The ions commonly used are of borderline or soft metals, such as Cu²⁺, Ni²⁺, Co²⁺, and Zn²⁺. Protein retention in IMAC depends on the number and type of pendant groups which can interact with the metal. The interaction is affected by a variety of independent variables such as pH, temperature, solvent type, salt type, salt concentration, nature of immobilized metal and chelate, ligand density, and protein size. Proteins are usually eluted by a decreasing pH gradient or by an increasing gradient of a competitive agent, such as imidazole, in a buffer. There are still several unresolved issues in IMAC. The exact structures of protein-immobilized metal complexes need to be known so that retention behavior of proteins can be fully understood and sorbent structures can be optimized. Engineering parameters, such as adsorption/desorption rate constants, sorbent capacities, and intraparticle diffusivities, need to be developed for most protein systems. Engineering analysis and quantitative understanding are also needed so that IMAC can be used efficiently for large scale protein separations.     

Selectivity behaviour of a bonded phosphonate--carboxylate polymeric ion exchanger for metal cations with varying eluent compositions

The chromatographic behaviour of a commercially available ion-exchange stationary phase (the Dionex IonPac CS12A column) is described for a wide range of transition and heavy metal ions with nitric acid eluents containing chloride and nitrate potassium salts. The separation selectivity was found to arise from simultaneous ion-exchange interactions and chelation with the attached carboxylic and phosphonic acid groups. These interactions were investigated by altering the ionic strength and pH of the eluent and also the column temperature. Strong affinity of the stationary phase towards heavy metal ions, in particular bismuth and the uranyl ion was observed at low pH under chelating ion-exchange conditions, with high efficiency separations of other ions including cadmium and lead being possible with short analysis times (approximately 5-15 min). Examples are given of separations obtained using 4-(2-pyridylazo)resorcinol or Arsenazo III as the post-column chromogenic reagents, demonstrating the potential versatility and utility of this stationary phase for heavy metal ion analysis.     

Use of phage display methods to identify heptapeptide sequences for use as affinity purification 'tags' with novel chelating ligands in immobilized metal ion affinity chromatography

This study describes the screening of a peptide phage display library for amino acid sequences that bind with different affinities to a novel class of chelating ligands complexed with Ni2+ ions. These chelating ligands are based on the 1,4,7-triazacyclononane (TACN) structure and have been chosen to allow enhanced efficiency in protein capture and decreased propensity for metal ion leakage in the immobilized metal ion affinity chromatographic (IMAC) purification of recombinant proteins. Utilising high stringency screening conditions, various peptide sequences containing multiple histidine, tryptophan, and/or tyrosine residues were identified amongst the different phage peptide sequences isolated. The structures, and particularly the conserved locations of these key amino acid residues within the selected heptapeptides, form a basis to design specific peptide tags for use with these novel TACN ligands as a new mode of IMAC purification of recombinant proteins.     

蛋白质在合成阳离子交换剂上的色谱特性研究

用国产材料按间接法合成了螯合型弱阳离子交换剂,详细研究了合成填料的色谱性能,并与商品柱的分离效能进行了比较;在宽温度范围内研究了蛋白质在弱阳离子交换系统中的色谱热力学,测定了蛋白质在色谱过程变性时的热力学参数 (△H0和△S0) 和补偿温度β,提出用标准熵变△S0判断蛋白质的构象变化和用△H0与△S0的补偿关系鉴定蛋白质各变体在色谱系统保留机理的同一性。考察了螯合型弱阳离子交换剂与金属离子的作用,研究了蛋白质在金属螯合色谱中的保留机理。     

Refolding and simultaneous purification of recombinant human proinsulin from inclusion bodies on protein‐folding liquid‐chromatography columns

Protein‐folding liquid chromatography (PFLC) is an effective and scalable method for protein renaturation with simultaneous purification. However, it has been a challenge to fully refold inclusion bodies in a PFLC column. In this work, refolding with simultaneous purification of recombinant human proinsulin (rhPI) from inclusion bodies from Escherichia coli were investigated using the surface of stationary phases in immobilized metal ion affinity chromatography (IMAC) and high‐performance size‐exclusion chromatography (HPSEC). The results indicated that both the ligand structure on the surface of the stationary phase and the composition of the mobile phase (elution buffer) influenced refolding of rhPI. Under optimized chromatographic conditions, the mass recoveries of IMAC column and HPSEC column were 77.8 and 56.8% with purifies of 97.6 and 93.7%, respectively. These results also indicated that the IMAC column fails to refold rhPI, and the HPSEC column enables efficient refolding of rhPI with a low‐urea gradient‐elution method. The refolded rhPI was characterized by circular dichroism spectroscopy. The molecular weight of the converted human insulin was further confirmed with SDS–18% PAGE, Matrix‐Assisted Laser Desorption/ Ionization Time of Flight Mass Spectrometry (MALDI‐TOF‐MS) and the biological activity assay by HP‐RPLC. Copyright © 2014 John Wiley & Sons, Ltd.     

固定金属离子亲和色谱--蛋白质分离的方法、原理、特性和应用

介绍了固定金属离子亲和色谱法(IMAC)的方法原理、金属螯合柱的制备、固定金属离子与蛋白质的相互作用以及影响这些作用的因素、不同色谱条件下各种作用力对蛋白质保留值的贡献、蛋白质的洗脱原理和IMAC在蛋白质分离纯化中的应用,论述了IMAC的特点、不足、克服的方法和今后应解决的问题。     

Properties and Application of a Chelating Sorbent Prepared by Modification of LiChroprep-NH<Subscript>2</Subscript> with Calcon

A new chelating sorbent for metal ions was prepared by modification of chemically modified silica – LiChroprep-NH₂ with Calcon. The molecular mechanism of binding this reagent to the surface of the applied carrier is presented. The properties of this sorbent were compared to analogous sorbents with a plain silica carrier and chemically modified silicas – LiChroprep-RP containing Calcon. The advantages of the new sorbent compared to the silica and LiChroprep-RP chelating sorbents are demonstrated. The sorbent obtained was applied as stationary phase in solid-phase extraction (SPE) for separations of some chosen mixtures of metal ions and for additional purification of aqueous solutions of salts of alkali metals from trace amounts of heavy metals. The multiple use of the sorbent based on LiChroprep-NH₂ in sorption-desorption processes of metal ions without deterioration of its sorption capacity is demonstrated.     

Towards multimodal HPLC separations on humic acid-bonded aminopropyl silica: RPLC and LEC behavior

In the present study, metal binding property of humic acid (HA) was successfully adapted to the ligand-exchange concept, and metal-loaded immobilized humic acid was used as a ligand exchanger stationary phase for separation of some nucleosides. Humic-acid bonded aminopropyl silica (EC-HA-APS) was turned into ligand exchanger forms by loading aqueous solutions of Cu²⁺, and Co²⁺ to the column (4.6 × 150; as mm) packed with EC-HA-APS. Metal ion solutions were loaded to the column in a stepwise manner where the concentration of metal ion solution being loaded to the column was increased gradually between 5 and 100 mM. The progress of metal loading process was monitored via the breakthrough curves propagated stepwise. Ligand-exchange chromatography (LEC) studies were performed on an HPLC system, and chromatographic behaviors of the studied nucleosides (i.e. uridine, Urd; thymidine, Tyd; cytidine, Cyd; adenosine, Ado; and guanosine, Guo) were investigated on Cu²⁺ and Co²⁺ loaded forms of the EC-HA-APS (Cu-EC-HA-APS and Co-EC-HA-APS). Effect of mobile phase composition, temperature, and the type of metal ion loaded to the column on the retentive behaviors of the compounds was studied, in detail. The studied solutes exhibited mixed-mode RPLC/LEC behavior on the stationary phase. Metal-loaded column (M-EC-HA-APS) was easily regenerated into its original form, EC-HA-APS, with 98 ± 2% metal recoveries, by using aqueous mixture of EDTA + NH₃ at pH = 7.5. Thus, the stationary phase exhibited a high flexibility between RPLC and LEC modes. This property, also, made it possible to convert the stationary phase into various ligand exchanger forms by loading different metal ions. Hence, capacity and selectivity of the stationary phase towards the studied species was manipulated easily by loading different metal ions to the stationary phase. Baseline separation for the studied species was achieved on Cu-EC-HA-APS and Co-EC-HA-APS and some differentiations were observed in capacity and selectivity, depending on the type of metal loaded. Thus, being as the first endeavor on usability of immobilized HA as a ligand exchanger stationary phase, the present study is believed to be useful to understand multifunctional character of HA-based solid/stationary phases.     

Ion chromatographic investigation of the ion-exchange properties of microdisperse sintered nanodiamonds

The possibility of using sintered diamonds as a stationary phase in ion chromatography has been evaluated. Bare sintered synthetic nanodiamonds demonstrated the properties of a weak cation-exchanger. The observed ion-exchange selectivity is similar to carboxylic type cation-exchangers. The regularities of retention of alkali, alkaline-earth and transition metal ions on a column packed with sintered nanodiamonds in dilute nitric acid were studied and the occurrence of chelating properties was noted. For the first time chromatographic separations of model mixtures of cations on diamonds have been obtained.