Displacement chromatography of chemotactic peptides

Displacement chromatography was successfully used to separate a binary peptide mixture, n-formyl-Met–Phe and n-formyl-Met–Trp, on a reversed-phase column. Displacement parameters such as choice of displacer, displacer concentration, mobile phase organic level, and flow-rate were critically examined in the context of maximizing productivity. Since the feed composition was limited by solubility, optimal productivity was sought as a function of feed volume. The impurities contained in the commercial displacers used in this study did not seem to affect the overall separation quality. In most cases the final pattern of contiguous rectangular bands was not attained; nevertheless, separations of high productivity were achieved using benzethonium chloride and tris[2-(2-methoxyethoxy)ethyl]amine as displacers. In some cases further increase in productivity was not possible only because of solubility constraints. Loading of feed at low initial organic modulator level coupled with displacements at higher modulator level was found to give efficient separations.     

Displacement chromatography of biomolecules

Displacement chromatography was used for the preparative-scale separation of peptides, antibiotics, and proteins. The feed components were both purified and concentrated during the separation processes. The components of a peptide mixture were separated on a reverse-phase analytical column using 2-(2-butoxyethoxy) ethanol as the displacer. The use of organic modifiers in the carrier along with an elevated column temperature of 45 degrees C enabled the efficient separation of relatively hydrophobic peptides by displacement chromatography. In addition, the throughput of the process was significantly increased by carrying out the separation at an elevated flow-rate with no adverse effect on product purity. The antibiotic cephalosporin C was isolated from impurities in a fermentation broth using 2-(2-butoxyethoxy)ethanol as the displacer along with a step change in column temperature. The proteins cytochrome c and lysozyme were purified on a weak cation-exchanger column using cationic polymers as the displacers. While polymers of 60 and 20 kilodaltons were both found to be good displacers for these proteins, only the lower molecular weight polymer was readily removed from the column by standard regeneration techniques.     

Displacement chromatography of proteins on hydrophobic charge induction adsorbent column

Displacement chromatography of protein mixtures is proposed on hydrophobic charge induction chromatography (HCIC). We have used an HCIC medium, MEP-Hypercel as the stationary phase and a quaternary ammonium salt, benzethonium chloride, as the displacer. It was found that the multiple interactions between proteins/displacer and the HCIC sorbent, i.e. hydrophobic interaction and charge repulsion, enabled a greater flexibility for the design of displacement processes and ease of column regeneration by adjustment of pH. The capacity factors of proteins and displacers were used to predict their performances in column displacement, and the experimental results agreed well with the prediction. An isotachic displacement train of lysozyme and alpha-chymotrypsinogen A was formed with benzethonium chloride as the displacer at pH 5.0 with good yields and purities of the two proteins. Column regeneration was efficiently achieved by charge repulsion between the displacer and the adsorbent at lower pH values (pH 3 and 4). The results indicate that the displacement chromatography on HCIC is a good alternative to traditional hydrophobic displacement chromatography.     

Salt effects in anion exchange displacement chromatography: Comparison of pentosan polysulfate and dextran sulfate displacers

Summary Experimental studies were carried out to investigate the utility of pentosan polysulfate as a low molecular weight polyelectrolyte displacer for the purification of proteins in anion-exchange displacement systems. In addition, the influence of mobile phase salt concentration on displacer efficacy, protein-protein resolution, and displacement development were studied for several anionic displacers. It was found that while large polyelectrolytes (50 kd dextran sulfate) were efficient displacers for a wide range of salt concentrations, relatively small polyelectrolytes (3 kd pentosan polysulfate) were seen to act as an efficient displacer only under conditions of high salt micro-environments. In addition, for proteins exhibiting similar affinities, zone mixing at the protein-protein boundary was found to be quite sensitive to the salt concentration. Finally, displacement chromatography was successfully implemented for the separation of proteins from milk whey.     

Rapid displacement chromatography of melittin on micropellicular octadecyl-silica.

Rapid high-performance liquid chromatographic analysis and displacement purification of melittin and its variants were carried out by reversed-phase chromatography. High speed of separation was achieved by the use of columns packed with a micropellicular stationary phase consisting of a thin C18 hydrocarbonaceous layer on the surface of 2-microns fluid-impervious silica microspheres at elevated temperature. In the case of melittin from bee venom or its synthetic variants the plots of the logarithmic retention factor against acetonitrile concentration in the eluent were straight lines whereas the van't Hoff plots in the temperature range from 20 to 80 degrees C were non-linear. Purification of melittins by displacement was carried out with benzyldimethylhexadecyl ammonium chloride as the displacer. In a 20-min displacement run at 40 degrees C about 5 mg of highly pure melittin were isolated from 10 mg of synthetic mixture by using a 105 x 4.6 mm column. The results demonstrate that columns packed with micropellicular sorbents not only facilitate rapid high-performance liquid chromatographic analysis but are also suitable for fast peptide purification with high recovery.     

The effect of feed composition on the behavior of chemically selective displacement systems

In this paper we examine whether adding a more retained protein to the feed will mitigate displacer–protein interactions in the column, thus affecting the displacement modality that occurs (chemically selective vs. traditional displacement chromatography). STD-NMR experiments were carried out to probe displacer–protein interactions for the chemically selective displacer chloroquine diphosphate and the results indicated that this displacer only had measurable interactions with the protein α-chymotrypsinogen A. For a two component feed mixture containing ribonuclease A and α-chymotrypsinogen A, the separation resulted in the displacement of ribonuclease A, with the more hydrophobic α-chymotrypsinogen A remaining on the column. On the other hand, when the experiment was repeated with cytochrome c added to the feed, all three feed proteins were displaced. Column simulations indicated that the combination of sample self-displacement occurring during the introduction of the feed, along with the dynamics of the initial displacement process at the column inlet was responsible for this behavior. These results indicate that for this class of hydrophobic-based selective displacers, in order for the protein to be selectively retained, the protein should be the most strongly retained feed component.     

Mass influences in the performance of oligomeric poly(diallyldimethylammonium chloride) as displacer for cation-exchange displacement chromatography of proteins

A novel type of linear polyelectrolyte, namely poly-DADMAC [poly(diallyldimethylammonium chloride)], was prepared and studied as a displacer for cation-exchange displacement chromatography of proteins. In contrast to the commercially available polymers of that chemistry, the novel type of poly-DADMAC introduced here is characterized by a homogeneous linear structure, a narrow distribution of the (adjustable) molar mass as well as by a defined and homogeneous affinity for the stationary phase. Five poly-DADMACs of different size (17900 to 88000 g/mol) were prepared and compared with regard to their stationary phase affinity and protein separation potential, taking a mixture of basic proteins, namely lysozyme, cytochrome C, and ribonuclease A (from bovine pancreas), as an example. The steric mass action model was employed to aid method development. Under the chosen conditions (low ionic strength of the mobile phase guaranteeing strong binding of both the proteins and the displacer) the poly-DADMAC with the lowest molar masses proved to be the most efficient displacers for the basic proteins with a stationary phase affinity constant of 5.3 x 10(16) and a steric factor of 224. Using this substance as displacer, a sample mixture containing up to three proteins was separated and the proteins recovered at high yields (80-97%) and in high purity and concentration.     

Tandem use of carboxypeptidase Y reactor and displacement chromatograph for peptide synthesis

A packed-bed enzyme reactor with immobilized carboxypeptidase Y was used in tandem with a displacement chromatograph for the preparation of N-benzoyl-L-arginyl-L-methioninamide, from N-benzoyl-L-arginine and L-methioninamide. The pumps and valves of the coupled enzyme reactor and displacement chromatograph were controlled by a microprocessor. The enzyme was immobilized on microparticulate amino-silica by glutaraldehyde and packed into a 60 X 4.6 mm I.D. column. The packed-bed reactor was used in the recirculating mode and components of the reaction mixture were subsequently separated by displacement chromatography on a 250 X 4.6 mm octadecyl-silica column using butoxyethoxyethanol as the displacer. Unreacted L-methioninamide was returned to the reaction mixture. Both the progress of the reaction and the extent of separation by displacement chromatography were monitored by high-performance liquid chromatographic analysis. The system was designed so that enzymatic peptide synthesis, separation by displacement chromatography, and column regeneration were carried out simultaneously by using two identical columns in parallel. An amount of 460 mg of N-benzoyl-L-arginyl-L-methioninamide having purity greater than 99% could be obtained in 24 h with this system. The tandem operation of the enzyme reactor and liquid chromatograph operated in the displacement mode offers a means for the synthesis and purification of peptides.     

High performance displacement chromatography of proteins: Separation of β-Lactoglobulins A and B

Summary β-Lactoglobulins A and B were separated by high performance displacement chromatography on an anion-exchanger column with chondroitin sulfate as the displacer. A sample of 100 mg containing a mixture of the two β-lactoglublins was separated on a column of 75×7.5 mm in a single chromatographic run. The separation process followed the rules of the classical displacement development: the two proteins formed contiguous rectangular bands and their concentrations were dependent on the displacer concentration. The results demonstrate that high performance displacement chromatography is a useful technique for the separation of proteins in preparative amounts with columns and instrumentation typically used in analytical HPLC. Furthermore, it has the potential to become the method of choice in large scale separation of proteins.     

Thermosensitive copolymers of N-vinylimidazole as displacers of proteins in immobilised metal affinity chromatography

Synthetic copolymers of N-vinylcaprolactam (VCL) and N-vinylimidazole (VI) were studied as thermosensitive, reusable displacers for immobilised metal affinity chromatography (IMAC) of proteins. The copolymer with weight-average molecular mass of 11700 g/mol prepared by free radical polymerisation at a 9:1 monomer molar ratio was separated into several fractions by IMAC and thermal precipitation. The fraction with an average VI content of 8.5% was most efficient as a reusable displacer for IMAC of ovalbumin, lysozyme and other proteins of egg white on Cu2+-IDA-Sepharose. The displacer exhibited a sharp breakthrough curve and binding capacity of 16-20 mg/ml gel, depending on the flow-rate. The recovery of egg white proteins in the course of displacement chromatography was >95%. The displacer could be removed quantitatively from the protein fractions by thermal precipitation at 48 degrees C. Co-precipitation of lysozyme with the displacer was minimal in the presence of 3% (v/v) acetonitrile, while the lysozyme enzymatic activity in the supernatant was completely retained. Addition of free imidazole to the mobile phase increased the rate of protein desorption and allowed better separation of egg white proteins and the displacer in the course of chromatography. The displacement profile of the egg white extract consisted of three zones with different distributions of individual proteins characterised by SDS-PAGE. Regeneration of the column was easily performed with 0.02 M EDTA in 0.15 M sodium chloride, pH 8.0, followed by washing with distilled water and reloading with Cu2+. The displacer could also be regenerated by thermal precipitation at 48 degrees C and subsequent dialysis against dilute hydrochloric acid (pH 2.5).     

Preparative purification of Plasmodium falciparum circumsporozoite protein synthetic polypeptides by displacement chromatography

Displacement chromatography was used for the preparative purification of a synthetic polypeptide that is a promising malaria vaccine. It was prepared by solid-phase synthesis and contains two important epitopes of circumsporozoite (CS) protein of Plasmodium falciparum sporozoite. With apparatus typically employed in analytical high-performance liquid chromatography (HPLC) and on a 250 x 4.6 mm I.D. reversed-phase column, up to 50 mg of crude polypeptide were purified in a single run and with a yield higher than 95%. The results demonstrate that displacement chromatography is suitable for the isolation of several milligrams of a pure polypeptide from a complex mixture that is difficult to separate even by analytical HPLC. In such a preparative application, displacement appears to be superior to elution chromatography as used traditionally.     

Investigation of operating parameters in high-performance displacement chromatography

The effect of operational parameters of displacement chromatography was examined in the separation of various mixtures such as that of the main hydrolysis products of methylfurylbutyrolactone, a potential anticancer drug, the diastereoisomers benzoyl-D- and benzoyl-L-phenylalanyl-L-alanyl-L-proline, as well as polyethylene glycol homologues containing 1-10 ethylene oxide units. The chromatograph was assembled from modules generally used in analytical high-performance liquid chromatography (HPLC) and the column effluent was analyzed by an on-line HPLC unit at 30-sec intervals. Octadecyl-silica was used throughout as the stationary phase. Derivatives of ethylene glycol and propylene glycol as well as tetrabutylammonium bromide and n-butanol were used as displacers. The throughput was used as the measure of efficiency. In the absence of axial dispersion, for a given separation various displacers are expected to yield the same efficiency if the slope of the operating line is kept the same by appropriate adjustment of displacer concentrations. In practice, however, the optimum slope of the operating line has to be determined experimentally as most available chromatographic systems depart from ideal behavior. The dependence of the throughput on the flow-rate and feed load also indicated the presence of non-equilibrium phenomena and the optimum value of these parameters was established experimentally. In most cases water was used as the carrier solvent but the separation of poorly soluble peptides required the use of hydro-organic carriers. Results obtained with octadecyl-silicas of different origin and a given displacer were found to vary significantly suggesting that even for stationary phases of the same type the selection of displacer requires special consideration. Most experiments were carried out with columns having dimensions customary in analytical HPLC. Increasing the inner diameter of the column did not result in the expected increase in throughout probably due to poor distribution of the sample at the column entrance. Therefore scaling-up the process requires careful engineering of inlet conditions. Throughput can be increased by connecting a small inner diameter column to the outlet of a large diameter preparative column. As theoretical predictions for ideal displacement chromatography do not hold in practice when axial dispersion is significant, optimization of the process requires experimental support. The results obtained in the separation of a variety of mixtures shed light on the most important operational aspects of displacement chromatography and suggest approaches to find optimum conditions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ion-exchange displacement chromatography of proteins Dextran-based polyelectrolytes as high affinity displacerss

Dextran-based polyelectrolyte displacers were successfully employed for the displacement purification of proteins in ion-exchange displacement systems. The effect of molecular mass was investigated by examining the efficacy of DEAE-dextran and dextran sulfate displacers of various molecular masses in cation- and anion-exchange systems, respectively. Induced salt gradients produced during these displacement experiments were measured in order to study their effect on the protein separations. The unique characteristics of these displacements were well predicted by simulations obtained from a steric mass action (SMA) ion-exchange model. These displacements differ from the traditional vision of displacement chromatography in several important ways: the isotherm of the displacer does not necessarily lie above the feed component isotherms; the concentration of the displaced proteins can sometimes exceed that of the displacer; higher-molecular-mass displacers are not necesarily more efficacious than lower-molecular-mass compounds; and the salt gradients induced by the adsorption of the displacer produce different salt micro-environments for each displaced protein.     

Efficient purification of paclitaxel from yews using high-performance displacement chromatography technique

Paclitaxel was purified using high-performance displacement chromatography (HPDC) technique, but not by the mechanism of HPDC. On small scale, paclitaxel was extracted with methanol from dry needles of Taxus canadensis and was enriched by extracting with chloroform after removing water-soluble hydrophilic components and hexane-soluble hydrophobic components. Then, 93-99% purity of paclitaxel was obtained using the HPDC technique. On large scale, taxanes were enriched by solvent partitioning between acetic acid/MeOH/H(2)O and hexane and extracted with CH(2)Cl(2). Taxanes except paclitaxel were further removed by extracting with methanol-water-trifluoroacetic acid (1.0:98.9:0.1, v/v/v). Applying HPDC technique to water-insoluble substances is problematic as this method requires a highly aqueous solvent system. In order to overcome this incompatibility, a system was set up where paclitaxel, although in low concentration, was extracted by methanol-water-trifluoroacetic acid (10.0:89.9:0.1, v/v/v). Recycling the extracting solvent to ensure minimal volume, the extracted paclitaxel was adsorbed on a C(18) trap column. A C(18) column of 4.6mm internal diameter was then connected to the trap column. The HPDC technique was thus carried out using an isocratic acetonitrile-water-trifluoroacetic acid (30.0:69.9:0.1, v/v/v) mobile phase consisting of a displacer cetylpyridinium trifluoroacetate (3mg/mL). Paclitaxel was co-eluted with the displacer and spontaneously crystallized. The crystal (114mg) showed 99.4% purity and only 10% of paclitaxel in the starting crude extract was lost during the enrichment/purification processes. This large scale purification method was successfully applied to purify paclitaxel from Chinese yew in small scale, suggesting general applicability of the method. This is the first report of purifying a water-insoluble natural product using HPDC technique.     

Applying Aluminum Oxide Column Chromatography Purify Extracts of Cathuranthus Roseus and Simultaneous Determination of the Indole Alkaloids by HPLC

Indole alkaloid of Cathuranthus roseus was purified by applying aluminum oxide column chromatography and an HPLC method was established to determine it. Applying aluminum oxide column chromatography produced a high purified monomer of alkaloids; the extracts of indole alkaloid were then loaded on the neutral aluminum oxide column chromatography and washed with an organic solvent (a mixture of chloroform, ether, and petroleum ether). Effect of purification was the best when the proportion of chloroform, ether, and petroleum ether was 10:10:1. To determine the content of vindoline, vinblastine, and cathuranthine exactly, the mobile phase of HPLC was water (containing 0.005 mol·L^?1 ammonium hydrogen phosphate), methanol (containing 0.67% triethylamine), and acetonitrile, the proportion of each was nonlinear.     

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%).     

The Role of Spacers in Displacement Thin-Layer Chromatography

Abstract

Displacement chromatography generates highly concentrated bands which migrate closely to each other along the stationary phase bed.

Spacer-displacement thin-layer chromatography is a planar method improving the observable resolution by inserting odd compounds (spacers) among the members of displacement train to be separated.

Substances were chromatographed by displacement mode of development using silica plates, chloroform carrier and triethanolamine displacer.

Resolution formula valid for elution chromatography has been adapted to the displacement type of developments. Explanation for the numerical value of required separation is given for various cases of displacement thin-layer chromatography.

Equations are suggested in order to calculate yield, loss and efficiency of displacement chromatography.     

Preparative Liquid Chromatography and Centrifugal Partition Chromatography for Purification of New Anticancer Precursors

In organic synthesis, the purification of reactional intermediates or final products is generally carried out by normal phase flash chromatography. However, for dihydrodipyridopyrazines, a new family of antitumor agents, the efficiency of this technique is too low to achieve the purification of the isomer mixture. Purification of the DHDPP isomer mixture has therefore been studied using preparative liquid chromatography. With the stationary phase used in flash chromatography, PLC provides greater efficiency and allows to increase the mobile phase flow rate. A complete study of preparative purification was performed, including that of compounds solubility and analytical optimization. This work has allowed to lower the overlap between the two DHDPP isomers, to greatly reduce the total duration of the process, to increase the purified quantity per run and consequently to greatly improve the throughput of the purification. In addition, this technique can be easily and totally automated. Concurrently, another purification method (centrifugal partition chromatography ), based on acidic constants difference of the two components in two immiscible liquids, was developed. CPC has demonstrated its ability to separate the two DHDPP isomers. Finally, the economic aspects of PLC and CPC results are compared.     

Fractionation of low-molecular-mass heparin by centrifugal partition chromatography in the ion-exchange displacement mode

Centrifugal partition chromatography in the ion-exchange displacement mode allowed a preparative and efficient fractionation of low-molecular-mass heparins from enoxaparin sodium. Amberlite LA2--a lipophilic liquid secondary amine--was chosen as a weak anion exchanger. The biphasic system methyl isobutyl ketone-water was selected. Protonated LA2 (10%, v/v) was added to the organic stationary phase. Hydroxide (Na+, OH-) was chosen as a displacer in the aqueous mobile phase. The observed pH and concentration profiles are typical of displacement chromatography, as supported by numerical simulation. The Dubois test for the analysis of sugar content and an analysis of sulfur content (and consequently sulfatation rate) were carried out to monitor the effectiveness of the procedure. Moreover, the fractions were analyzed by high-performance size-exclusion chromatography and the 1H NMR spectra confirmed the fractionation of the sample of enoxaparin sodium.