加芯毛细管填充柱的理论研究

 从速率方程和柱压降两个方面对加芯毛细管填充柱的柱效和渗透性进行了探讨，并详细讨论了柱直径、芯直径、芯根数和柱压降的关系。综合考虑柱压降、板高和拉制柱子时颗粒在柱内的镶嵌状况可知最佳柱型是３芯的毛细管填充柱。     

IgG adsorption on a new protein A adsorbent based on macroporous hydrophilic polymers: II. Pressure–flow curves and optimization for capture

Pressure–flow curves are obtained for a new protein A adsorbent matrix based on macroporous hydrophilic polymer beads with average diameter of 57 μm and a narrow particle size distribution. Experimental data are obtained in a 1 cm diameter laboratory column and in preparative scale columns with diameters of 20, 30, and 45 cm. The results are consistent with a model that assumes a linear relationship between bed compression and relative flow velocity. Surprisingly, the packing compressibility is essentially independent of column diameter for the preparative columns. As a result, after accounting for the variation in extraparticle porosity caused by compression, the column pressure drop is accurately predictable using the Carman–Kozeny equation. A model is also developed to predict productivity for IgG capture as a function of operating conditions based on dynamic binding capacity data presented in Part I of this work. For typical conditions, the model predicts maximum productivity at low residence times, between 1 and 1.5 min, when the dynamic binding capacity is at about 70–80% of the maximum. Combining the two models for column pressure and for dynamic binding capacity allows the design of preparative scale columns that maximize productivity while meeting specified pressure constraints.     

Impact of a pressure drop on a monolithic capillary column on the efficiency and separation ability of the column

The impact of inlet and outlet column pressures on column separation properties was investigated for monolithic capillary column in gas chromatography. It was demonstrated that the classical Van Deemter equation does not allow us to make a clear choice of the optimal separation conditions. More relevant data can be obtained from the dependence of the height equivalent to a theoretical plate (HETP) on the inlet and outlet column pressures. The dependence ensures that the minimum HETP value can be achieved at high values of inlet and outlet column pressures, but the ratio of the pressures must approach 1. The efficiency of the column under these optimal conditions can exceed by 25–35% the column efficiency under the optimal conditions found using the classical Van Deemter plot. It was shown that a decrease in inlet and outlet column pressures even at a relative pressure close to 1 leads to an increase in HETP and the loss of column separation ability.     

Säulen zur bestimmung kleiner probemengen (10−10 g) in der flüssigkeits-chromatographie

The dilution of the sample in liquid chromatographic columns increases with the square of the internal diameter of the tube if all other parameters are kept constant. If the mass or the volume of the sample is extremely small the separated peaks become undetectable. Irregularly packed capillary columns with an internal diameter of less than 1 mm seem to be the best solution. Unfortunately the mass of the stationary phase per unit column volume is then very small (low k′-values and long hold-up times) and consequently the analysis time is increased, the dilution of the sample in the column becomes high and the instrumental problems are not negligible. The equipment and methods for packing glass columns with internal diameters between 1.3 and 2.0 mm are described. The columns are packed with silica gel or with reversed-phase packing (particle size ～ μm), and h/d_p values between 2.5 and 4 are achieved. This ratio is more or less independent of the stationary phase and of the eluent (n-heptane or methanol). The cis- and trans-isomers of abscisinic acid are separated and detected even when the sample size is only 10^?10g, thanks to the high molar absorptivities.     

The effect of column characteristics on the minimum analyte concentration and the minimum detectable amount in capillary gas chromatography

The need for faster and more efficient separations of complex mixtures of organic compounds by gas chromatography has led to the development of small inner diameter open tubular columns. Owing to their decreased plate height, extremely narrow peaks are obtained. When differently sized columns with equal plate numbers are compared, injection of a fixed amount of a solute will give the highest detector signals for the smallest bore columns. When P is defined as the ratio of the column inlet and outlet pressures, it can be seen from theory that under normalized chromatographic conditions the minimum detectable amount (Q_º) for a mass flow sensitive detector increases proportionally to the square of the column diameter for P = 1. In the situation of greater interest in the practice of open tubular gas chromatography where P is large, a linear relationship is derived between Q_º and the column diameter. It is a widespread misunderstanding, however, that narrow bore capillary columns should be used for this reason in trace analysis. If a fixed relative contribution of the injection band width to the overall peak variance is allowed, a decreased plate height drastically restricts the maximum sample volume to be injected. It is shown that the minimum analyte concentration in the injected sample (C_º) is inversely proportional to the column inner diameter when a mass flow sensitive detector is used. For actual concentrations less than C_º, sample preconcentration is required. The effect of peak resolution and selectivity of the stationary phase in relation to C_º and Q_º will be discussed as well. The validity of the given theory is experimentally investigated. Minimum analyte concentrations and minimum detectable amounts are compared using columns with different inner diameter.     

Revue et discussion à propos des diverses techniques de préparation des colonnes pour la chromatographie en phase liquide à haute performance

Résumé L'emploid de colonnes remplies de particules de petites dimensions (5 à 20 m de diamètre) s'est généralisé en chromatographie en phase liquide ces dernières années à cause des remarquables performances qu'elles permettent d'atteindre. Ces colonnes ne peuvent pas être remplies selon les méthodes classiques par voie sèche au cours desquelles les petites, particules s'agglomèrent entre elles. Il est alors nécessaire d'avoir recours à des méthodes de remplissage par voie humide utilisant une suspension des particules dans un liquide. Ces méthodes sont décrites et classées en fonction des moyens pris pour stabiliser la suspension et éviter la sédimentation des particules. Les différentes méthodes d'imprégnation in situ de phases stationnaires pour la chromatographie liquide-liquide sont également exposées.

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Review and discussion of the various techniques of packing of columns for high performance liquid chromatography

Summary The use of columns packed with small particles (diameters between 5 and 20 m) has become widespread in liquid chromatography. These columns allow the achievement of remarkably high performances. They cannot be packed by the old conventional, dry-packing methods because the small particles agglomerate to larger ones, which has a catastrophic effect on the efficiency. It becomes necessaryto use wet packing methods which all use a slurry of the stationary phase. The various techniques are described and discussed. They differ mainly in the technique used to keep the particles in suspension in the solvent, and to prevent their sedimentation. The various methods of coating a liquid stationary phase on the support for use in liquid-liquid chromatography, are also discussed.

     

Comparison of nonporous silica-based ion exchangers and monolithic ion exchangers in separations of inorganic anions

Low capacity anion exchangers for IC have been prepared by modification of nonporous uniformed silica MICRA microbeads and by modification of the organic polymeric monolithic matrixes prepared in situ in quarz capillary. Due to the small particle size (1.5 microm) high-performance adsorbents were prepared allowing to obtain up to 190,000 tp/m. However, the column possesses a very high back-pressure and can be used in a short length up to 50 mm only to meet the requirements of conventional chromatographic equipment. An analysis of a test mixture of seven anions was completed within 3 min with a back column pressure of about 350 bar (HETP of about 5.5 microm, where HETP is the height equivalent to the theoretical plate). Monolithic capillary columns provide lower efficiency per column unit length than MICRA columns; however, they can be used at a longer length because of their low flow resistance. Monolithic column of ca. 40 cm length has workable pressure below 10 bar and allows separation of a five anions test mixture within less than 10 min. A better efficiency of monolithic column (HETP approximately 75 microm) can be achieved at reduced flow rates when the analysis time is not a critical parameter.     

Optimization of capillary parameters for gas chromatography

An HETP equation for the capillary column is developed that takes into account the dependence of gaseous diffusion on pressure, the compressibility of the mobile phase, together with the unique relationship between mobile phase velocity, and the resistance to mass transfer in the stationary phase. The equation is used to develop a procedure for column optimization and expressions are derived that allow the optimum column radius and optimum column length to be calculated for a given fixed inlet pressure. It is shown that fast, simple separations are optimally achieved using relatively short small diameter columns. Conversely, optimum performance for the separation of complex mixtures requiring higher efficiencies requires the use of long columns with relatively large diameters.     

Spherical Versus Irregular-Shaped Silica Gel Particles in HPLC

Abstract

With optimised packing procedures, spherical shaped silica gel particles produce 1.5 to 2 times more plates in HPLC than irregular shaped silica gel particles. The lowest reduced plate height obtained by us so far is for 5 μm ROSiL-C₁₈-HL-D and is h: 1.62 for k': 4.5. It is suggested to transform h into 100/h% and to name this the “Chromatographic efficiency”, or a % of the ideal 100% limit. This limit would be an h value equal to the mean particle diameter. Spherical and irregular silica gel particles of 5 and 10 μm particle diameter and with similar physical characteristics have the same permeability in HPLC columns.

Whether a correct column packing procedure is used can be shown by the constancy of plate number and column permeability in function of different packing pressures.     

Influence of the degree of coverage of C18-bonded stationary phases on the mass transfer mechanism and its kinetics

The influence of the degree of coverage of a silica surface with bonded C18 alkyl chains on the mass transfer mechanism in RPLC was investigated. Five packing materials were used, prepared with the same batch of silica particles (5 microm diameter, 90 A average pore size): one column was packed with the silica derivatized by trimethylchlorosilane (TMS) (C1, 3.92 micromol/m2), and the other four with the silica first derivatized with octadecyl-dimethyl-chlorosilane (C18, 0.42, 1.01, 2.03, and 3.15 micromol/m2), and then endcapped with TMS. A solution of methanol and water (25/75, v/v) was used as the mobile phase. The experimental HETP curves were acquired for each column by measuring the first moment and the second central moment of phenol and correcting them for the influence of the temperature increase due to the heat generated by the friction of the stream against the bed. The different kinetic parameters of the mass transfer in these packed chromatographic columns were identified (longitudinal diffusion, eddy diffusion, film mass transfer, and transparticle mass transfer) and quantified by fitting the experimental data to a new general HETP equation recently derived [F. Gritti, G. Guiochon, Anal. Chem., in press (AC-060203R).]. The agreement was excellent and allowed the comparison of the kinetic parameters among the six columns used. The highest column efficiency measured at conventional or fast flow rates (>0.5 ml/min) is obtained for the most retentive column, which has a surface coverage of 2.03 micromol/m2. The smallest HETP measured is as low as 10 microm, only twice the average particle diameter dp, due to the large contribution of surface diffusion (90%) to the particle effective diffusivity. However, no significant difference was observed between the efficiencies of the columns packed with C1 and C18 derivatized silica.     

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.     

On the optimization of the solid core radius of superficially porous particles for finite adsorption rate

Packed chromatographic columns with the superficially porous particles (porous shell particles) guarantee higher efficiency. The theoretical equation of the Height Equivalent to a Theoretical Plate (HETP), for columns packed with spherical superficially porous particles, was used for the analysis of the column efficiency for finite rate of adsorption-desorption process. The HETP equation was calculated by the application of the moment analysis to elution peaks evaluated with the General Rate (GR) model. The optimal solid core radius for maximum column efficiency was estimated for a wide spectrum of internal and external mass transfer resistances, adsorption kinetic rate and axial dispersion. The separation power of the shell adsorbent for two component mixture, in analytical and preparative chromatography, was discussed. The conditions of the equivalence between the solutions of the General Rate model with slow adsorption kinetic and the Lumped Kinetic Model (LKM) or the Equilibrium Dispersive (ED) model were formulated.     

Experiences with the development and operation of a large-scale preparative gas chroamtograph

Summary A large-scale preparative gas chromatograph containing a 3 m long 100 mm l. D. column was built to investigate the application of preparative gas chromatography for the separation and production of various organic compounds. In this paper some experiences are reported concerning the operation of this large-scale preparative unit. In particular the efficiency of the receivers, the method of sample introduction as well as the stability of column packing were investigated.     

Packing capilllary electrochromatography columns using vacuum--a preliminary study

This paper introducesa novel method for packing Capillary Electrochromatography Columns (CEC). Using vacuum packing methodology, silica particles as small as 1 microm were successfully packed into the capillary columns with 75 microm inner diameter. The columns are verystable and show no noticeable loss in efficiency after 200 sample injections. The performance of these vacuum packed capillary columns was evaluated with a mixture of aromatic and non-aromatic compounds. A 24 cm long capillary column can produce peak efficiencies of around 45,000 plates for benzene.     

Performance of open tubular columns as a function of tube diameter and liquid phase film thickness

Summary Wall-coated, open-tubular (capillary) columns prepared from different diameter tubing, with different liquid phase film thickness, are compared with each other and with packed and support-coated open-tubular columns. The comparison is based on the variation of the phase ratio and the capacity factor, and includes column efficiency (HETP, theoretical plate number), resolution, retention time, and sample capacity. Problems associated with the evaluation of the sample capacity are outlined. The influence of temperature on column performance is discussed in detail. Finally, the possibilities of short, wide-bore open-tubular columns prepared with a thick liquid-phase film are demonstrated.Parts of this paper were presented at the 35th Pittsburgh Conference on Analytical Chemistry and Applied Spectroscopy, Atlantic City NJ, March 5–9, 1984, and at the 20th International Symposium on Advances in Chromatography, New York NY, April 16–18, 1984.     

筛板对台锥形制备液相色谱柱流型和柱效的影响

制备液相色谱柱柱头筛板的选择直接影响到样品在柱头的分配情况及色谱柱柱效的高低。 利用柱后可见-紫外检测,比较了采用多孔聚四氟乙烯材料和多孔烧结不锈钢材料作为台锥形制备液相色谱柱柱头筛板材料时的柱效;用柱上可视化方法研究了柱头筛板的直径对流型的影响。结果表明,多孔聚四氟乙烯的变形使得采用该材料做柱间筛板的色谱柱柱效比使用多孔不锈钢筛板的色谱柱柱效低约40%;样品流经直径小于柱入口内径的筛板导致样品在柱头分配不均,而流经直径与柱入口内径相同的筛板时因受到的阻力相同,可以实现柱塞状进样。还观察到不同直径的筛板     

Ultrahigh-pressure liquid chromatography using a 1-mm id column packed with 1.5-microm porous particles

The evolution of chromatography has led to the reduction in the size of the packing materials used to fabricate HPLC columns. The increase in the backpressure required has led to this technique being referred to as ultrahigh-pressure liquid chromatography (UHPLC) when the column backpressure exceeds 10000 psi (approximately 700 bar). Until recently, columns packed with sub-2-microm materials have generally fitted into two classes; either short (less than 5 cm) columns designed for use on traditional HPLC systems at pressures less than 5000 psi (350 bar), or capillary columns (inner diameters less than 100 microm). By using packing materials with diameters <2 microm to fabricate UHPLC columns, there is an increase in efficiency and a decrease in the analysis time that are directly proportional to the size of the packing material. In order to realize and exploit the increase in efficiency, however, the columns must maintain lengths typically associated with analytical columns (15-25 cm). We have packed 1 mm diameter, 150 mm in length columns with 1.5 microm packing material, and evaluated their performance in UHPLC. The pressure required to achieve optimum linear velocities in plots of plate height versus linear velocity was in the vicinity of 1104 bar (16000 psi). The 1.5 microm particle-packed column was compared with the more traditional 150 mm long analytical columns packed with 3 microm materials. This column showed an efficiency that was approximately twice that observed with the 3 microm packed column and a concomitant reduction in the analysis time, theoretically predicted.     

Characteristics of elution profile in radial chromatography under linear conditions

Radial chromatography is one of the most efficient tools for the fast analytical and preparative separation of complex samples. Compared to conventional axial liquid chromatography, it has obvious advantage espe- cially in the preparation of biological sa…     

Studies on column size scale-up and flow profile in conical shape liquid chromatographic column of 10° by visualization method

An improved visualization device made of polymethyl methacrylate (PMMA) was used to study the 3D flow profile inside conical columns of a 10° opening angle packed with C₁₈ phase. The outside wall of the conical columns was rectangular in shape in order to improve the transparency property of the column wall and reduce the deformation of the image for better observation of the flow profiles of colored solutes inside the column. The influence of flow rate, particle size and shape on the flow profile of a colored band were studied on a 5-cm-long column and a scaled-up column of four fold in volume. It was found that the flow rates of the mobile phase had little influence on the flat flow profile of the iodine band while the properties of the stationary phase had a certain influence on them. We observed that the flow profiles of the scaled-up column were flat during the whole chromatographic process, and the efficiency and resolution of the column were also increased in accordance with theoretical prediction. The experimental results proved that the 10° conical columns can be proportionally scaled up while still keeping the flat flow profile, sample load per unit volume of packing material, and column efficiency, which are superior to the conventional column. __________ Translated from Chemical Journal of Chinese Universities, 2006, 27 (1) (in Chinese)     

Hydrodynamic impact of particle shape in slurry packed liquid chromatography columns

We report on a series of flow velocity and efficiency profiles, which were measured across the cross section of preparative chromatographic columns packed with different stationary phase materials using computed tomography. It is shown that this non-invasive technique is very useful for visualization of the inner part of a packed column and measurement of the spatial resolved column packing properties. For evaluation of the influence of the particle shape on the velocity distribution and column performance, irregular and spherical reversed phases were studied in detail. The results showed a decreasing velocity towards the column wall most certainly due to a lower permeability. This effect was much less pronounced in the case of spherical particles, indicating a more homogenous packing structure. The influence of the column packing pressure, as a possible measure for improvement of the packing homogeneity was also studied. It was shown that under the same packing conditions spherical particles always lead to a more homogeneous packing. The overall results of this work contribute to the origin of the fact that spherical material is superior to irregular one from the hydrodynamic point of view.