凝胶色谱用微粒硅胶NWG

研制成功 NWG硅胶,粒度分别为 3—5μ和 5—10μ。经测试渗透极限为聚苯乙烯分子量4×10~4—7×10~6,分离容量V_i/V_0不低于0.6,柱效在 1×10~4塔板/米以上。可在10分钟内作分子量100—3×10~6样品的全分离。硅胶在不同流速下的行为符合物料平衡方程理论的预见。     

A simplex optimization of the experimental parameters in preparative liquid chromatography

Summary A study of the optimization of the experimental conditions for the purification or extraction of pure compounds by liquid chromatography is presented. Optimum values of the parameters of overloaded elution are derived for maximum production rate, using a Simplex algorithm and the procedure previously described for the simulation of the elution profiles of binary mixtures. The mobile phase flow velocity and the sample size have been optimized together in a first step, simulating the procedure followed in practice, when a column is available. In a second part, the influence of the column length and the average particle size of the packing material on the column performance as well as the trade-offs between the production rate and the yield are discussed.There are three major conclusions in this work. First, the optimum experimental conditions are often very different, depending whether one is primarily interested in the first or in the second eluted component of a mixture. Second, the column efficiency under analytical conditions is very important: it is traded-off for high flow rates, hence short cycle time and increased production rate. Third, the production rate depends strongly on the maximum pressure at which the equipment can be operated. Finally, the optimum production rate varies rather smoothly with the mobile phase velocity and the sample size, so a high yield (70% or more) can usually be obtained with a limited loss in production rate (30 to 60%).     

Axial development and radial non-uniformity of flow in packed columns

Flow inhomogeneity and axial development in low-pressure chromatographic columns have been studied by magnetic resonance imaging velocimetry. The columns studied included (a) an 11.7-mm I.D. column packed with either 50 microm diameter porous polyacrylamide, or 99 or 780 microm diameter impermeable polystyrene beads, and (b) a 5-mm I.D. column commercially packed with 10 microm polymeric beads. The packing methods included gravity settling, slurry packing, ultrasonication, and dry packing with vibration. The magnetic resonance method used averaged apparent fluid velocity over both column cross-sections and fluid displacements greater than one particle diameter and hence permits assessment of macroscopic flow non-uniformities. The results confirm that now non-uniformities induced by the conical distributor of the 11.7-mm I.D. column or the presence of voids at the column entrance relax on a length scale of the column radius. All of the 11.7-mm I.D. columns examined exhibit near wall channeling within a few particle diameters of the wall. The origins of this behavior are demonstrated by imaging of the radial dependence of the local porosity for a column packed with 780 microm beads. Columns packed with the 99-microm beads exhibit reduced flow in a region extending from ten to three-to-five particle diameters from the wall. This velocity reduction is consistent with a reduced porosity of 0.35 in this region as compared to approximately 0.43 in the bulk of the column. Ultrasonicated and dry-packed columns exhibit enhanced flow in a region located between approximately eight and 20 particle diameters from the wall. This enhancement maybe caused by packing density inhomogeneity and/or particle size segregation caused by vibration during the packing process. No significant non-uniformities on length scales of 20 microm or greater were observed in the commercially packed column packed with 10 microm particles.     

C18‐bound porous silica monolith particles as a low‐cost high‐performance liquid chromatography stationary phase with an excellent chromatographic performance

Ground porous silica monolith particles with an average particle size of 2.34 μm and large pores (363 Å) exhibiting excellent chromatographic performance have been synthesized on a relatively large scale by a sophisticated sol–gel procedure. The particle size distribution was rather broad, and the d(0.1)/d(0.9) ratio was 0.14. The resultant silica monolith particles were chemically modified with chlorodimethyloctadecylsilane and end‐capped with a mixture of hexamethyldisilazane and chlorotrimethylsilane. Very good separation efficiency (185 000/m) and chromatographic resolution were achieved when the C₁₈‐bound phase was evaluated for a test mixture of five benzene derivatives after packing in a stainless‐steel column (1.0 mm × 150 mm). The optimized elution conditions were found to be 70:30 v/v acetonitrile/water with 0.1% trifluoroacetic acid at a flow rate of 25 μL/min. The column was also evaluated for fast analysis at a flow rate of 100 μL/min, and all the five analytes were eluted within 3.5 min with reasonable efficiency (ca. 60 000/m) and resolution. The strategy of using particles with reduced particle size and large pores (363 Å) combined with C₁₈ modification in addition to partial‐monolithic architecture has resulted in a useful stationary phase (C₁₈‐bound silica monolith particles) of low production cost showing excellent chromatographic performance.     

Investigation of sample preparation for high temperature gel permeation chromatography using a low solvent consumption method

The study explored the optimum conditions for sample preparation of polyolefins for high temperature gel permeation chromatography (GPC) recommended by ASTM D 6474, and the potential for reducing solvent consumption by using columns with reduced internal diameter. A polypropylene sample with high crystallinity and high molecular weight was selected, because this is one of the most difficult polyolefins to analyze by GPC. Sequences of injections covering 20 h showed that, at 160 °C, 2 h is enough to dissolve this sample, and that the antioxidant concentration is the critical parameter in obtaining reproducible GPC results. By using one column with an internal diameter (ID) of 4.6 mm and a flow rate of 0.3 mL/min, instead of the classical set of 3 columns of 7.5 mm ID and a flow rate of 1 mL/min, the solvent consumption can be reduced to about 10%.     

Steric exclusion and lateral diffusion in gel-permeation chromatography

The peak separation in gel-permeation chromatography (GPC) is attributed to the contributions of the steric exclusion and the lateral diffusion processes. The advantage of using the distribution coefficient K_GPC of the solute molecule in interpreting the GPC separation mechanism is assessed. The physical significance of K_GPC and its relation to measurable GPC parameters are examined in detail. A simple mixing experiment for determining the exclusion effect is described. The results of this experiment, as well as those of the flow rate study, show that the exclusion effect plays the primary role in GPC peak separation. For a column packed with Bio-Rad porous glass of 200 Å designation, the diffusion effect does not contribute significantly to peak separation. However, for the case of a Waters Associates column packed with polystyrene gel of 10⁴ Å designation, both the exclusion and the diffusion effects are shown to be important. A diffusion theory which includes the concept of a restricted diffusion coefficient is proposed to interpret the diffusion effect observed in the polystyrene gel column. The results of the theoretical calculation are found to agree with the observed flow rate dependence of the calibration curve.     

Optimization of HPLC-ECD conditions for determination of catechins with precision and efficiency based on the FUMI theory.

A chemometric tool based on the Function of Mutual Information (FUMI) theory can provide a relative standard deviation (RSD) without repetitive measurements in high-performance liquid chromatography with electrochemical detection (HPLC-ECD). Two parameters: precision (= information content) phi and efficiency (= information content/time) theta, which were calculated from predicted RSD based on the FUMI theory, were used to optimize HPLC-ECD conditions, such as applied potential, flow rate, column length, and size of ODS porous packing. We selected catechins as analytes, and found that the most optimum applied potential and flow rate were +600 mV vs. SCE and 0.9 mL/min, respectively, because they gave the largest phi and theta values. Buffer concentration in mobile phase is less effective for giving large phi and theta values. Since the FUMI theory makes it possible to predict RSD without repetitive measurements, the present method saves considerable amounts of chemicals and experimental time, and was found to be useful for the optimization of experimental conditions for determination by HPLC-ECD.     

Parameters affecting the separation of intact proteins in gradient-elution reversed-phase chromatography using poly(styrene-co-divinylbenzene) monolithic capillary columns

An experimental study was performed to investigate the effects of column parameters and gradient conditions on the separation of intact proteins using styrene-based monolithic columns. The effect of flow rate on peak width was investigated at constant gradient steepness by normalizing the gradient time for the column hold-up time. When operating the column at a temperature of 60 °C a small C-term effect was observed in a flow rate range of 1–4 μL/min. However, the C-term effect on peak width is not as strong as the decrease in peak width due to increasing flow rate. The peak capacity increased according to the square root of the column length. Decreasing the macropore size of the polymer monolith while maintaining the column length constant, resulted in an increase in peak capacity. A trade-off between peak capacity and total analysis time was made for 50, 100, and 250 mm long monolithic columns and a microparticulate column packed with 5 μm porous silica particles while operating at a flow rate of 2 μL/min. The peak capacity per unit time of the 50 mm long monolithic column with small pore size was superior when the total analysis time is below 120 min, yielding a maximum peak capacity of 380. For more demanding separations the 250 mm long monolith provided the highest peak capacity in the shortest possible time frame.     

Effects of column length, particle size, gradient length and flow rate on peak capacity of nano-scale liquid chromatography for peptide separations

The effects of the column length, the particle size, the gradient length and the flow rate of a nanoLC system on peptide peak capacity were investigated and compared. Columns packed with 1.7 microm and 3 microm C(18) materials into pieces of 75 microm capillary tubing of various lengths were tested with different gradient lengths and flow rates. While increasing the length of a column packed with the 1.7 microm material helped improve peptide peak capacity at the whole range of the tested gradient lengths (24-432 min), little improvement in peak capacity was observed with the increase of the length of a column packed with the 3 microm material unless a gradient longer than 50 min was carried out. Up to 30% of peak capacity increase was observed when a column's length is doubled, with little reduction in the throughput. In most cases, more than 50% of the increase in peak capacity was obtained with the reduction in the particle size from 3 microm to 1.7 microm. With the same backpressure generated, a shorter 1.7-microm-particle column outperformed a longer column packed with the 3 microm material. In a flow rate range of 100-700 nl/min, increasing the flow rate improved peak capacity for columns packed with 1.7 microm and 3 microm materials.     

Fast liquid chromatography separation and multiple‐reaction monitoring mass spectrometric detection of neurotransmitters

We describe here the fast LC‐MS/MS separation of a mixture of neurotransmitters consisting of dopamine, epinephrine, norepinephrine, 3,4‐dihydroxybenzylamine (DHBA), salsolinol, serotonin, and γ‐aminobutyric acid (GABA). The new UltiMate® 3000 Rapid Separation system (RSLC) was successfully coupled to the 4000 QTRAP mass spectrometer operating in multiple‐reaction monitoring (MRM) mode. The separation was attained using a 100 mm length, 2.2 μm particle size Acclaim column at a flow rate of 0.5 mL/min. The column back pressure was 350 bar, while the total run time including column re‐equilibration was 5.2 min. The peak resolution was minimally affected by the fast separation. The RSLC‐MRM separation was found to have a precision range based on peak area for 50 replicate runs of 2–5% CV for all analytes, and the reproducibility of the retention time for all analytes was found to range from 0–2% CV. The described method represents an almost seven times shorter analysis time of neurotransmitters using LC/MRM which is very useful in screening large quantities of biological samples for various neurotransmitters.     

Packing density of slurry-packed capillaries at low aspect ratios

The average interparticle voidage or porosity (epsilon(inter)) in cylindrical capillaries is studied in dependence on the column diameter (d(c)) to particle diameter (d(p)) ratio for 5 < d(c)/d(p) < 50. Using optimized slurry and packing solvents, high pressure and ultrasonication, 5 mum-sized porous C18-silica particles were slurry-packed into fused-silica capillaries having ids from 30 to 250 mum. Packing densities are assessed by a polystyrene standard which is size-excluded from the intraparticle pore space of the packings. For d(c)/d(p) > 35 densely packed beds are realized (epsilon(inter) = 0.36-0.37), while for decreasing aspect ratios an exponential increase in epsilon(inter )is observed reaching epsilon(inter ) approximately 0.47 at d(c)/d(p) = 5. This behaviour is ascribed to a combination of the geometrical wall effect operating in the direct vicinity of the column wall, caused by the inability of the particles to form a dense packing against the hard surface of the column wall, and particle characteristics like the size distribution, shape and surface roughness. Results are compared with the literature data to address also the importance of absolute particle size in studying structure-transport relations in packed beds in dependence on the aspect ratio d(c)/d(p).     

High Performance Size Exclusion Chromatography Using Porous Glass Packing Materials

Abstract

Porous glass packing materials of average particle diameter 5 μm have been packed into a 7.2 mm i.d. x 25 cm column by viscousslurry packing parocedure. Average pore diameters of porous glasses were 170 Â, 500 Â, 1000 A, and 2000 A. The numbers of theoretical plates were between 7000 and 8000 per a column for porous glasses of pore diameters of 170, 500, and 1000 A, and 5000 for that of 2000 A. The retention volumes of narrow molecular weight-distribution polystyrene standards have been determined using tetrahydrofuran as mobile phase for the construction of calibration curves. Separations of polystyrene over molecular weight ranges of 1000 and 4,000,000 have been obtained by combining all four porous glass columns in series. Molecular weight averages of NBS 706 polystyrene have been measured and compared with the values determined with polystyrene gel columns. Both results were equivalent to the manufacturer's data. Porous glasses thus appear to be a useful packing materials for HPSEC.     

Automated in-line gel filtration for native state mass spectrometry

Characterization of protein-ligand complexes by nondenaturing mass spectrometry provides direct evidence of drug-like molecules binding with potential therapeutic targets. Typically, protein-ligand complexes to be analyzed contain buffer salts, detergents, and other additives to enhance protein solubility, all of which make the sample unable to be analyzed directly by electrospray ionization mass spectrometry. This work describes an in-line gel-filtration method that has been automated and optimized. Automation was achieved using commercial HPLC equipment. Gel column parameters that were optimized include: column dimensions, flow rate, packing material type, particle size, and molecular weight cut-off. Under optimal conditions, desalted protein ions are detected 4 min after injection and the analysis is completed in 20 min. The gel column retains good performance even after >200 injections. A demonstration for using the in-line gel-filtration system is shown for monitoring the exchange of fatty acids from the pocket of a nuclear hormone receptor, peroxisome proliferator activator-delta (PPARdelta) with a tool compound. Additional utilities of in-line gel-filtration mass spectrometry system will also be discussed.     

Recycling in preparative liquid chromatography

Summary Chromatographic recycling is used to allow the scale up of an analytical separation made on a 7 mm ID microparticle GPC column to a multi-gram separation on a 25 mm ID preparative column, filled with conventional particle size GPC gel.     

A Study of Mechanical Degradation of Polymer in High Performance GPC

Abstract

Four narrow distribution polystyrene samples (M = 2.7 × 10⁶, 6 × 10⁶, 6.5 × 10⁶, 7 × 10⁶) were dissolved in tetrahydrofuran and the solutions were passed through a Shodex A-80M column at a concentration of approximately 1 × 10^?3 g/ml, injection volume of 500 microliters, and a flow rate of 2 ml/min (i.e., maximun flow rate allowable for this column). Molecular weights of eluants were then determined by viscosity and laser light scattering methods; concentrations were determined by ultra-violet spectrophotometry. From the results of analysis of the eluate, it was shown that no significant degradation was detectable for all four samples in this colulmn which was packed with a cross-linked polystyrene gel. When a silica gel (irregular shaped) column was used, under same operating conditions, only sample PS-4, with a molecular weight of M = 7 × 10⁶ underwent degradation up to 15%. High pressure exerted on the column is believed to be the main cause of the degradation.     

Semimicro Size Exclusion Chromatography For Oligomers. I. Column Packing Procedure

Abstract

Polystyrene gels of a particle diameter 10 ± 2 μm for the use in oligomer separation were packed into 1.5 mm i.d. × 25 cm length columns by the balanced density slurry-packing technique under a constant flow rate of 500 μL/min. The slurry solvent was a mixture of toluene and chloroform (50.5/49.5, v/v). The example of the number of theoretical plates (N) of these columns was 8600 plates/25 cm (HETP = 29.1 μm) at flow rate of 40 μL/min by injecting 1 μL of 0.5% benzene solution. Sixteen columns were connected and the overall value of N was 103000 plates/4 m. A typical example of oligomer separation was demonstrated. A constant-flow technique is preferable to a constant-pressure technique. When two or three column blanks were packed together, the columns located at the outlet of the packer-column assembly had higher values of N. Optimum flow rate of the slurry solvent when three column blanks were packed together lay between 400 and 500 μL/min. The packing efficiency, that is, the probability of getting valid columns was about 60%. Viscous slurry solvents were not effective to get efficient columns. To pack gels in the less swollen state gave sometimes efficient columns. Pressure monitoring in progress of packing was very effective to foresee the column efficiency.     

Evaluation of The Peak Capacity of Various RP-Columns for Small Molecule Compounds in Gradient Elution

Peak capacity is the commonly used measure of separation efficiency in gradient elution. This study focuses on the effect of column characteristics (particle size and column length) and operating parameters (gradient time and flow rate) on the peak capacity for small molecule compounds in gradient elution. The goal of this study is to develop a practical strategy to maximize the separation efficiency (i.e., peak capacity) under different constraints (analysis time or pressure limit). Using both experimental data and theoretical modeling, the current study reveals that the peak capacity increases with both gradient time and column length in a non-linear fashion. Marginal peak capacity is proposed to characterize the non-linear increase of peak capacity over the gradient time and column length. This study also attempts to understand the maximum peak capacity achievable under certain pressure limits using Neue’s peak capacity model. The results of this study provide a better understanding of the UPLC technology, and can also help to develop practical strategies to maximize the separation efficiency in gradient elution to meet the separation needs.     

Optimization of extraction chromatography separations of trace levels of actinides with ICP-MS detection

The separation of trace level actinides has been evaluated on extraction chromatography columns. Detection of the actinides was achieved through the use of an inductively coupled plasma MS (ICP-MS). The columns that we tested were prepared from a commercial TRU resin. The separation of the actinides was optimized for several parameters including particle size, column length, packing pressure, and eluent flow rate. We also examined the possibility of reducing or eliminating oxalic acid in the eluents in order to improve the performance of the mass spectrometer. We were able to separate a mixture of five actinides ((232)Th,( 238)U,( 237)Np, (239)Pu,( 243)Am) in less than 4 min. This work has application to rapid bioassay as well as for automated separations of actinide materials.     

The size exclusion chromatography calibration of ‘Mixed-A’ and ‘Mixed-D’ columns using various polymers and compounds: An application to coal-derived materials

This work attempts to obtain the calibration curves of two different size exclusion chromatography (SEC) columns operating with 1-methyl-2-pyrrolidinone (NMP) as eluent by using various standards. Polystyrene (PS) and polymethylmethacrylate (PMMA) standards were used for obtaining calibration curves, and checked against polysaccharide (PSAC) standards, some small aromatic polycyclic standards and miscellaneous polymers. Polystyrenes and polymethylmethacrylates gave identical calibrations while polysaccharides and miscellaneous polymers lay within 1 or 2 min of the polystyrene calibration. Small molecules of mass less than 1000 units lay on or near to the polystyrene calibration lines, with a shift to late elution for the smallest molecules. This shift may be caused by the interaction with the column packing. A sample has been examined by analytical size exclusion chromatography, which was calibrated using polystyrene and polymethylmethacrylate standards. Molecular mass (MM) distributions of the sample have been examined in terms of these calibrations.     

Evaluation of gel permeation chromatography to Fourier transform infrared spectrometric detection using a modified thermospray for analysis of polystyrene samples

A heated gas flow modified thermospray was used to couple gel permeation chromatography (GPC) to Fourier transform infrared spectrometry (FTIR) for the analysis of the standard polystyrene samples. Effluents from the GPC column were evaporated and the solutes were deposited as a series of spots on the surface of a moving stainless steel belt (0.025 mm thickness × 13 mm width). The belt continuously transferred the spots into the diffuse reflectance (DRIFT) accessory of the FTIR spectrometer, enabling identification of the deposited solutes by measurement of the diffuse reflectance IR spectrum. The IR spectra of the separated components showed excellent agreement of the spectral features to those of standard FTIR spectra and no thermal degradation was observed.