二维液相色谱接口的改进及其在蛋白质组学研究中的应用

随着蛋白质组学、本草物质组学等组学概念的提出,所需分析的样品的成分越来越复杂,因此具有强大分离能力的多维液相色谱技术受到人们越来越多的关注。二维液相色谱中第二维的分离性能和速度是整个分离系统性能的关键。基于捕集柱模式,我们采用经特殊设计的流路系统,使得双捕集柱型接口具有预分离的功能。样品从第一维流出以后被富集在捕集柱1的柱头,经过脱盐后,正冲捕集柱,捕集柱1与第二维色谱柱联用对富集的样品进行分离,增加了第二维分离效率。当捕集柱上的样品全部被洗脱到第二维色谱柱上时,捕集柱2已经完成对第一维洗脱液中样品的捕集和脱盐,此时将阀进行切换,捕集柱2与第二维色谱柱直接相连进行洗脱。循环切换捕集柱1和捕集柱2,维持较高的阀切换频率,实现了第二维色谱柱的连续洗脱。因此保证了第二维分离具有较快速度,同时具有较高的分离效率。使用35 mm长捕集柱和十通阀为接口,以弱阴离子交换(WAX)色谱为第一维分离模式,以反相(RP)色谱为第二维分离模式,构建了WAX-RP二维液相色谱系统(2D-LC system)。以小鼠血清为样品对系统进行了初步评价。色谱流出曲线出现了明显的界面现象,这是由于捕集柱流动相中含有的较多盐分流出时的背景吸收造成的。同时,由于界面两侧的流动相黏度不同产生了黏性指进(VF)现象。当第二维色谱柱长度为50 mm时,理论上可将第二维分离效能提高70%。该接口可以应用于多种二维液相色谱模式,适用于蛋白质组学和本草物质组学研究中对于复杂样品的分离分析。     

在线单柱二维液相色谱法对蛋清中三种活性蛋白的快速分离纯化

基于一种新型的强阳离子交换/疏水色谱(SCX/HIC)双功能色谱柱构建了在线单柱二维液相色谱(2DLC-1C), 分离系统实现了自动控制, 可在线进行样品收集、二维进样和二维色谱分离. 采用SCX-HIC 2DLC-1C, 在120 min内可将8种标准蛋白完全分离, 并成功应用于鸡蛋清中三种活性蛋白质的分离纯化. 结果表明利用在线2DLC-1C技术可在70 min内完成对鸡蛋清中溶菌酶、卵清蛋白和卵转铁蛋白三种活性蛋白的快速分离纯化, 其纯度分别为95%、93%和97%. 该方法减少了样品的处理步骤, 对样品的污染小, 纯化速度快, 操作简单, 易于实现自动化和放大, 对活性蛋白的快速分离制备和工业化生产具有广阔的应用前景.     

基于高压制备液相的多维色谱技术在中药分离纯化中的应用

中药物质基础复杂,对其活性成分的分离一直是中药研究的难题.基于高压制备液相的多维色谱系统在高压制备液相色谱的基础上,结合了多种分离技术,极大地提高了色谱系统的分离性能和分离效率,更有利于对物质基础复杂的中药样品进行分离纯化.本文介绍了基于高压制备液相系统的多维色谱系统的基本原理、分离模式以及关键技术,并综述了其在中药分离纯化中的应用.     

全二维液相色谱(IEC/RP)的构建与评价

以IEC/RP模式构建了二维液相色谱系统,采用平行交替柱捕集分析的2位十通切换阀作接口,第一维洗脱产物按10:1的分流比分流后,得到IEC和RP切换谱图.以5个标准蛋白混合物的分离评价该系统,在单独一维模式中不能分离的样品在全二维液相色谱中得到了很好的分离.     

多维液相色谱-质谱用于酶解猪血蛋白中活性肽的研究

以强阳离子交换柱（SCX）为一维色谱柱，反相柱（RP）为二维色谱柱，采用在线捕集接口形式，通过10通阀连接一、二维色谱柱，构建了二维液相色谱分离系统。将该系统用于酶解猪血蛋白中对血管紧缩素Ⅰ转移酶（ACE）具有活性抑制作用的肽进行分离、鉴定，共检测出104个组分。收集一维馏分，离线注入LC—MS，鉴定出其中含有SAL、DKF、ESF、STVL及FESF5个小肽。     

中药物质基础的高效液相色谱分离分析方法研究

高效液相色谱方法已成为中药物质基础研究的重要手段．在中药质量控制、中药标准品制备、活性化合物发现等方面发挥着不可替代的作用．然而我们的实验数据表明,一个中药材可能包含上万个化合物．中药物质基础的复杂性对高效液相色谱方法提出了巨大挑战．本文针对液相色谱方法在中药物质基础分离分析中存在的问题与难点,结合红花、黄连、姜黄三味药材样品,从亲水色谱分离模式、新型色谱固定相、二维液相色谱分离系统和液相色谱质谱联用技术等方面讨论了液相色谱的分离分析方法和发展方向．结果表明,高效液相色谱新技术新方法在中药复杂体系的分离分析中具有很大的发展潜力和应用前景．     

在线单柱二维液相色谱法快速纯化牛胰腺中细胞色素C

用二维（弱阳,疏水）色谱柱首次完成了在线单柱二维液相色谱法快速纯化牛胰腺中的细胞色素C.在将牛胰腺粗提液进样到该二维色谱柱后,在弱阳离子交换模式下,以梯度洗脱方式进行一维色谱分离,并将分离得到的细胞色素C样品液收集到色谱仪的附加样品储液管内.然后将储液管中样品液全部排出,并二次进样到同一根二维色谱柱中,与此同时也完成了对该样品液的缓冲溶液交换,按疏水色谱（HIC）分离模式进行分离.最终对细胞色素C完成了第二维的HIC纯化.上述全部操作均为在线,在一具有正压的封闭体系中进行并可在52分钟内完成.细胞色素C的最终产品纯度高达94.7%（RSD=1.91%）,质量回收率为80.5%（RSD=2.20%）.预计此在线单柱二维液相色谱法也可能用于牛胰腺中其他功能蛋白的快速纯化,并可能将其放大到制备和生产规模.     

高温二维液相色谱系统的构建及其评价

在二维液相色谱中, 第二维的分离速度是制约其发展的重要因素. 升高色谱柱温度可以有效降低流动相粘度, 加快溶质在两相间的传质速率, 有效加快分析速度. 以离子交换色谱法(WAX)为第一维分离模式和反相色谱法(RP)为第二维分离模式, 十通阀和两个捕集柱为接口, 通过将第二维色谱柱温度升高到80 ℃和提高流量到3 mL/min, 构建了高温WAX/RP二维液相色谱系统. 以4种标准蛋白的酶解物为样品评价系统的分离性能, 第一维共有33个馏分被捕集并导入到第二维分析, 高温二维液相色谱系统识别出187个色谱峰.     

在线样品制备技术耦合液相色谱-质谱系统在食品危害物检测中的应用进展

食品安全检测具有重要意义,但食品样品基质复杂,测定其中危害物时,通常需要以下几个步骤：样品制备,即采用适合的样品前处理方法,在不同基质中将目标物分离出来;分离纯化,利用色谱系统进一步分离纯化目标物;定性定量分析,基于目标化合物的性质选择合适的检测器进行分析。其中样品制备是关键步骤之一,将样品制备过程与液相色谱系统耦合可以实现样品的在线自动化分析。与传统人工处理过程相比,在线分析不仅能够减少人工操作误差,保证良好的精密度和重复性,而且可以降低溶剂消耗,避免样品间交叉污染,同时节约分析时间,提高检测效率。本文主要介绍目前常用的在线样品制备技术,包括在线固相萃取(on-line SPE)、管内固相微萃取(in-tube SPME)、湍流色谱法(TFC),详细阐述了其基本原理和耦合设备。在线样品制备技术耦合液相色谱-质谱系统分为两个维度,主要依赖于阀切换技术,将样品制备(第一维度)和液相色谱系统(第二维度)之间建立物理连接,随后采用相应的检测器进行分析。第一维度的作用主要是去除样品杂质,净化分离目标物,为第二维度对目标物进行定性定量检测做准备。此外,文章对3种在线净化系统适用的不同净化填料进行...     

二维液相色谱(SCX/RP)系统的构建及对珠蛋白水解产物的研究

以十通阀为切换接口, 构建了SCX/RP常规柱二维液相色谱系统, 并以珠蛋白水解产物的分析对其加以评价. 样品首先由第一维阳离子交换色谱(Hypersil SCX, 100 mm×4.6 mm I.D.)在pH 4.0的磷酸盐缓冲体系中分离, 洗脱产物进入切换接口, 样品组分被富集在捕集柱(Hypersil BDS C18, 15 mm×4.6 mm I.D.)中, 进一步脱盐后被导入第二维反相色谱(Hypersil BDS C18, 250 mm×4.6 mm I.D.)分离分析. 阳离子交换色谱采用逐步增加盐浓度的12步台阶等度间断方式洗脱, 每次将洗脱产物捕集在捕集柱中进而由反相色谱分析, 实现对第一维洗脱产物的切割转移及第二维分析. 与一维色谱相比, 二维液相色谱系统的分辨率、峰容量也得到提高, 系统峰容量达到2280.     

IEX/RP二维液相色谱中弱保留组分收集模式的构建及系统评价

以十通阀和捕集柱接口形式,构建了弱阴离子交换/反相(WAX/RP)二维液相色谱分离系统.通过将第一维离子交换色谱分析中的前部集中洗脱出的弱保留组分收集后单独分析,剩余样品进一步采用二维液相色谱分析,可以有效避免第二维色谱柱对特殊样品局部集中流出导致的第二维分离超柱容量问题,提高了系统的整体分离能力.使用4种蛋白胰蛋白酶酶解后的多肽样品评价该系统,在不分流的系统中共检测到115个峰.对第一维分离的前15 min分流后得到的组分单独分析,共识别出58个峰,后续的二维分离中共得到78个峰.2种方法相比,第二种方法检测峰数增加了21个,一些低丰度的组分在弱保留组分收集后被识别.     

蛋白质高效分离两维色谱柱的选择优化

为了构建高效的离子交换/反相二维液相色谱(IEC/RPLC)分离平台系统,提高复杂蛋白质样品的分离效率,对色谱柱进行了评价与筛选。通过对实际人肝蛋白质样品的分离效果的比较,选择确定了TSKgel DEAE-5PW弱阴离子交换色谱柱(WAX)作为第一维色谱分离柱;考察了同一规格的10支代表性反相色谱柱(250 mm×4.6 mm, 5 μm, 30 nm, C4、C8或C18),通过评价其对尿嘧啶、硝基苯、萘和芴的分离性能以及对3种标准蛋白质样品的非特异性吸附、对人肝蛋白质样品的WAX馏分的分离效果,最终确定以Jupiter 300 C4反相色谱柱作为第二维色谱分离柱。对两维色谱柱的选择优化为蛋白质高效分离二维液相色谱平台的搭建提供了可靠基础。     

Isolation of oxidative degradation products of atorvastatin with supercritical fluid chromatography

The isolation of four oxidative degradation products of atorvastatin using preparative high‐performance liquid chromatography applying at least two chromatographic steps is known from the literature. In this paper it is shown that the same four impurities could be isolated from similarly prepared mixtures in only one step using supercritical fluid chromatography. The methods for separation were developed and optimized. The preparation of the mixtures was altered in such a way as to enhance the concentration of desired impurities. Appropriate solvents were applied for collection of separated impurities in order to prevent degradation. The structures of the isolated impurities were confirmed and their purity determined. The preparative supercritical fluid chromatography has proven to be superior to preparative HPLC regarding achieved purity of standards applying fewer chromatographic as well as isolation steps. Copyright © 2015 John Wiley & Sons, Ltd.     

Multidimensional capillary array liquid chromatography and matrix-assisted laser desorption/ionization tandem mass spectrometry for high-throughput proteomic analysis

A two-dimensional capillary array liquid chromatography system coupled with matrix-assisted laser desorption/ionization (MALDI) mass spectrometry (MS) was developed for high-throughput comprehensive proteomic analysis, in which one strong cation-exchange (SCX) capillary chromatographic column was used as the first separation dimension and 10 parallel reversed-phase liquid chromatographic (RPLC) capillary columns were used as the second separation dimension. A novel multi-channel interface was designed and fabricated for on-line coupling of the SCX to RPLC column array system. Besides the high resolution based on the combination of SCX and RPLC separation, the developed new system provided the most rapid two-dimensional liquid chromatography (2D-LC) separation. Ten three-way micro-splitter valves used as stop-and-flow switches in transferring SCX fractions onto RPLC columns. In addition, the three-way valves also acted as mixing chambers of RPLC effluent with matrix. The system enables on-line mixing of the LC array effluents with matrix solution during the elution and directly depositing the analyte/matrix mixtures on MALDI plates from the tenplexed channels in parallel through an array of capillary tips. With the novel system, thousands of peptides were well separated and deposited on MALDI plates only in 150min for a complex proteome sample. Compared with common 2D-LC system, the parallel 2D-LC system showed about 10-times faster analytical procedure. In combination with a high throughput tandem time of flight mass spectrometry, the system was proven to be very effective for proteome analysis by analyzing a complicated sample, soluble proteins extracted from a liver cancer tissue, in which over 1202 proteins were identified.     

Preparative isolation of flavonoid glycosides from Sphaerophysa salsula using hydrophilic interaction solid‐phase extraction coupled with two‐dimensional preparative liquid chromatography

An offline preparative two‐dimensional reversed‐phase liquid chromatography/hydrophilic interaction liquid chromatography coupled with hydrophilic interaction solid‐phase extraction method was developed for the preparative isolation of flavonoid glycosides from a crude sample of Sphaerophysa salsula . First, the non‐flavonoids were removed using an XAmide solid‐phase extraction cartridge. Based on the separation results of three different chromatographic stationary phases, the first‐dimensional preparation was performed on an XAqua C18 prep column, and 15 fractions were obtained from the 5.2 g target sample. Then, three representative fractions were selected for additional purification on an XAmide preparative column to further isolate the flavonoid glycosides. In all, eight flavonoid glycosides were isolated in purities over 97%. The results demonstrated that the two‐dimensional liquid chromatography method used in this study was effective for the preparative separation of flavonoid glycosides from Sphaerophysa salsula . Additionally, this method showed great potential for the separation of flavonoid glycosides from other plant materials.     

The development of an evaluation method for capture columns used in two-dimensional liquid chromatography

Capture columns are important interface tools for on line two-dimensional liquid chromatography (2D-LC). In this study, a systematic method was developed to evaluate and optimize the capture ability of capture columns by off-line method. First, the parameter Δt_R (Δt_R = t₂−t₁−t₀−W) was introduced to quantitatively represent the capture ability of the capture column by connecting a capture column behind the first dimensional column. Based on the value of Δt_R, an appropriate capture column was selected after the first dimensional column was fixed. Then, the capture ability of the selected column was promoted by adjusting the mobile phase of the first dimensional column. Capture ability was also optimized using complex sample analysis software system (CSASS) software. Second, the elution mode of the trapped compounds on the capture column was investigated by connecting the capture column before the second dimensional column. More specifically, in mode I, capture column was connected to the second dimension without changing the flow rate direction and the trapped compounds must pass through the capture column and be eluted into the second dimensional column. The contrary connection mode was mode II. It was found that mode I is more suitable method for 2D-LC. Finally, an off-line reversed-phase/hydrophilic interaction liquid chromatography two-dimensional liquid chromatography (RP/HILIC 2D-LC) system with a C18 capture column was developed to demonstrate the practical application of this method.     

Orthogonal strategy development using reversed macroporous resin coupled with hydrophilic interaction liquid chromatography for the separation of ginsenosides from ginseng root extract

Ginsenosides have been widely conceded as having various biological activities and are considered to be the active ingredient of ginseng. Nowadays, preparative high‐performance liquid chromatography is considered to be a highly efficient method for ginseng saponins purification and preparation. However, in the process of practical application, due to the complex and varied composition of natural products and relatively simple pretreatment process, it is likely to block the chromatographic column and affect the separation efficiency and its service life. In this work, an orthogonal strategy was developed; in the first‐dimension separation, reverse‐phase macroporous resin was applied to remove impurities in ginseng crude extracts and classified ginseng extracts into protopanaxatriol and protopanaxadiol fractions. In the second‐dimension separation, the obtained fractions were further separated by a preparative hydrophilic column, and finally yielded 11 pure compounds. Eight of them identified as ginsenoside Rh₁, Rg₂, Rd, Rc, Rb₂, Rb₁, Rg₁, and Re by standards comparison and electrospray ionization mass spectrometry. The purity of these ginsenosides was assessed by high‐performance liquid chromatography with UV detection.     

One-step multiple component isolation from the oil of Crinitaria tatarica (Less.) Sojak by preparative capillary gas chromatography with characterization by spectroscopic and spectrometric techniques and evaluation of biological activity

Gas chromatographic analysis revealed that the oil of Crinitaria tatarica was rich in sabinene (32.1%), β-pinene (8.8%), and two unknown (M+200) compounds (I) and (II) (21.4% and 3.4%). One-step multiple fractionation of the oil and separation of two unknown constituents were performed using preparative capillary gas chromatography connected to preparative fraction collector system. This combination allowed separation and recover of sufficient quantities of two unknown compounds with high purity from complex oil matrix. Separation conditions (column temperature, cooling temperature, flow rate, injection volume, cut time) were optimized to achieve the best isolation and successful collection. The target compounds were separated from the oil using a HP Innowax (Walt & Jennings Scientific, Wilmington, DE, USA) preparative capillary column in rapid one-step manner with 95.0% purity. Trapping of the isolated compounds in collector system was facilitated by cooling with liquid nitrogen. Structure determination was accomplished by spectral analysis including ultraviolet, nuclear magnetic rezonance, and high-resolution electrospray ionization mass spectrometry. Z- (I) and E-artemidin (II) were isolated for the first time from this species. Crinitaria tatarica oil and Z- (I) and E-artemidin (II) were evaluated for biological activity.     

An overview of techniques and strategies for isolation of flavonoids from the genus Erythrina

Plants in the genus Erythrina is a potential source of chemical constituents, one of which is flavonoids, which have diverse bioactivities. To date, literature on the flavonoids from the genus Erythrina has only highlighted the phytochemical aspects, so this review article will discuss isolation techniques and strategies for the first time. More than 420 flavonoids have been reported in the Erythrina genus, which are grouped into 17 categories. These flavonoid compounds were obtained through isolation techniques and strategies using polar, semi-polar, and non-polar solvents. Various chromatographic techniques have been developed to isolate flavonoids using column flash chromatography, quick column chromatography, centrifugally accelerated thin-layer chromatography, radial chromatography, medium-pressure column chromatography, semi-preparative high-performance liquid chromatography, and preparative high-performance liquid chromatography. Chromatographic processes for isolating flavonoids can be optimized using multivariate statistical applications such as response surface methodology with central composite design, Box–Behnken design, Doehlert design, and mixture design.