Preparative Purification of Peptides by Countercurrent Chromatography on the Ito Coil Planet Centrifuges

Abstract

For the purification of up to 1000 mg of synthetic peptides by countercurrent chromatography, the coil planet centrifuges have proven useful in the research laboratory. Besides the earlier described horizontal flow-through coil planet centrifuge which chromatographs substances in all solvent systems at room temperature, the multi-layer coil planet centrifuge affords more rapid chromatography. However, separations using n-butanol, especially suited for peptides, have to be conducted at elevated temperatures. A new machine that has characteristics of both of the foregoing instruments is the compact horizontal flow-through coil planet centrifuge which promises rapid chromatography with full retention of the stationary phase.     

Chromatography of AC-ASP-TYR-MET-GLY-TRP-MET-ASP-NH2 on the Horizontal flow-Through Coil Planet Centrifuge and the High-Speed Multi-Layer Coil Planet Centrifuge

Abstract

The peptide Ac-Asp-Tyr-Met-Gly-Trp-Met-Asp-NH₂ was purified by countercurrent chromatography in the horizontal flow-through coil planet centrifuge. The solvent system used was ammonium acetate, pH 8.5 and n-butanol (1:1 by volume). The high pH served to maintain the peptide in solution. When the upper phase was utilized as the mobile phase better separation of the peptide from impurities resulted. The peptide was also chromatographed in a new apparatus, the high-speed multi-layer coil planet centrifuge. With the lower phase mobile and at a higher temperature, the peptide was fractionated very rapidly in 30 min compared to 7 hr on the other instrument.     

Rapid Purification of Synthetic Bombesin by Countercurrent Chromatography on the Multi-Layer Coil Planet Centrifuge

Abstract

A temperature-controlled multi-layer coil planet centrifuge rapidly yields highly efficient preparative separations of polar compounds. Capability of the method was demonstrated on a one-step purification of crude synthetic bombesin with a two-phase solvent system composed of n-butanol/dichloroacetic acid/water (100:1:100). Under an elevated temperature at 45°C to 50°C, the bombesin peak was eluted within two hours. Reversed phase HPLC analysis of the bombesin fractions showed over 98% purity. The method may be applicable to many other peptides and polar compounds.     

High-speed counter-current chromatography of apple procyanidins

Apple procyanidins were separated by high-speed counter-current chromatography using a type-J multilayer coil planet centrifuge. Several two-phase solvent systems with a wide range of hydrophobicities from a non-polar hexane system to polar n-butanol systems were evaluated their performance in terms of the partition coefficient and the retention of the phase. The best separation of procyanidins B and C was achieved with a two-phase solvent system composed of n-butanol-methyl tert.-butyl ether-acetonitrile-0.1% trifluoroacetic acid (2:4:3:8) using the lower phase as a mobile at a flow-rate of 1.0 ml/min.     

Separations of hydrophobic synthetic peptides in counter-current chromatography

Synthetic peptides with many aromatic, aliphatic and especially acidic amino acid residues are not very soluble and require strong solvents for useful partitioning. A chloroform-methanol-acidic solvent system fractionates neutral and basically charged 26-mers to provide high yields. An insoluble 15-mer with 5 Trp residues and 60% overall hydrophobic amino acid content was purified in pyridine-acetic acid and in another basic t-butyl methyl ether-n-butanol-acetonitrile solvent system with high recovery. Two instruments were used, the eccentric-multi-layer hybrid coil planet centrifuge and the new spiral disk planet centrifuge that were able to retain the stationary phase of these solvent systems, some of which have low interfacial tension.     

Countercurrent Chromatography Using a Toroidal Coil Planet-Centrifuge: A Comparative Study of the Separation of Organelles Using Aqueous Two-Phase Partition

Abstract

A toroidal coil planet centrifuge is described and compared with other countercurrent chromatography (CCC) and countercurrent distribution (CCD) techniques. The basis of separation is partition in aqueous two-phase polymer systems, with each method assessed by fractionating rat liver organelles. The size and ease of operation of the toroidal coil planet centrifuge gave significant advantages over conventional CCD systems achieving equivalent resolution in a fraction of the time.     

Experimental observations of the hydrodynamic behavior of solvent systems in high-speed counter-current chromatography. I. Hydrodynamic distribution of two solvent phases in a helical column subjected to two types of synchronous planetary motion

Hydrodynamic distribution of two-phase solvent systems in a rotating helical column subjected to centrifugal fields produced by two different types of synchronous planetary motion has been studied by the use of the combined horizontal flow-through coil planet centrifuge. With continuous elution of the mobile phase, the simpler type of motion resulted in low retention of the stationary phase in the column whereas a more complex motion, which produces a quasi-radial centrifugal field varying in both intensity and direction, yielded high stationary phase retention for commonly used solvent systems having a wide range of hydrophobicity. These solvent systems display highly complex modes of hydrodynamic interaction in the coil according to their particular physical properties.     

High-Speed Countercurrent Chromatography of Dipeptides on a Polar Two-Phase Solvent System

Abstract

The performance of the high-speed countercurrent chomatograph was evaluated by separating dipeptide samples on a polar biphasic solvent composed of n-butanol-acetic acid-water (4:1:5, v/v/v). Best results were obtained with a set of multilayer coils of small helical diameter by eluting with the upper nonaqueous phase in a head to tail direction at a flow rate of 1 or 2 ml/min. Four components were completely resolved in 5 to 11 hours. Other types of coiled columns such as a multilayer coil with large helical diameter (in a commercial model) and eccentric dual-layer coil assemblies mounted on a horizontal coil planet centrifuge also yielded satisfactory separations.     

Large-scale preparative countercurrent chromatography for separation of polar compounds

Gram quantity separations of polar compounds (tryptophyl-leucine and valyl-tyrosine) have successfully been accomplished with the use of a horizontal coil planet centrifuge. Two columns of different length fluorinated ethylene propylene tubing but of same internal diameter (0.55 cm) were coaxially coiled around a holder 7.5 cm or 15 cm in diameter and used to assess the preparative capabilities of the apparatus in terms of stationary phase retention and sample peak resolution. Optimal operating conditions derived from preliminary studies with the short column were applied to a column 7 times in length and volume. Volume capacities were 114 ml and 750 ml respectively. A hydrophilic solvent system of n-butanol, acetic acid and water (4:1:5) was used with both the aqueous and non-aqueous phases being used as the mobile phase. Preliminary studies revealed that the hydrodynamic distribution of the two phases was independent of the helical diameter while peak resolution was sensitive to both helical diameter and rpm setting.     

New angle rotor coil planet centrifuge for counter-current chromatography. II. Design of the apparatus and studies on phase retention and partition capability

A new angle rotor coil planet centrifuge (psi = 25 degrees), which produces a Type J-L synchronous planetary motion, has been constructed to examine its capability in terms of stationary phase retention and solute partitioning. Studies on phase distribution diagrams obtained from various two-phase solvent systems indicated that the present system can be adapted to a wide variety of solvent systems by adjusting the centrifugal conditions. Excellent partition capability of the apparatus was successfully demonstrated in separations of dinitrophenyl amino acid samples with chloroform-acetic acid-0.1 N hydrochloric acid (2:2:1).     

Large-Scale Preparative Counter-Current Chromatography with a Coil Planet Centrifuge

Abstract

Development of the large-scale preparative countercurrent chromatographic schemes has been continued by increasing the diameter of the separation column. A 0.55 cm i.d. FEP tube was coaxially coiled around the holder (7.5 cm, 10 cm or 15 cm in diameter) of a horizontal flow-through coil planet centrifuge (15 cm revolutional radius). Performance of each column was evaluated on the separation of dinitrophenyl amino acid samples with a two-phase solvent system composed of chloroform, acetic acid, and 0.1N hydrochloric acid (2:2:1) by using both aqueous and nonaqueous phases as the mobile phase. Experiments with the short preliminary columns (114 ml capacity) revealed that the hydrodynamic distribution of the two solvent phases was sensitively affected by the helical diameter of the column. However, by choosing the proper elution mode of the mobile phase, satisfactory results were obtained with the helical diameters of 7.5 cm and 15 cm at a high flow rate of 500 ml/h under a moderate revolutional speed of 300 rpm. With the long coiled columns (750 ml capacity), the preparative capability of the present scheme was successfully demonstrated on separations of the 1g-quantity sample mixture under optimized operational conditions. Overall results indicated that the sample-loading capacity of the present scheme can be further increased by the use of longer and/or larger-diameter columns.     

Large-scale separation of salvianolic acid B from the Chinese medicinal plant Salvia miltiorrhiza by pH-zone-refining countercurrent chromatography

pH-Zone-refining countercurrent chromatography was successfully applied to the separation of salvianolic acid B from the Chinese medicinal plant, Salvia miltiorrhiza Bunge, using a multilayer coil planet centrifuge. A 2.0 g quantity of sample was separated using the following two-phase solvent system: methyl tert-butyl ether (MtBE)-water, 10 mM TFA in organic stationary phase and 10 mM ammonia in aqueous mobile phase. The obtained fractions were analyzed by HPLC and ESI-MS. The separation yielded 572 mg of the main component of salvianolic acid B with a purity of 94.1%.     

Optimization of Solvent Mixture Compositions for High Speed Countercurrent Distribution

Abstract

Seven solvents considered appropriate for use with relatively sensitive biosynthetic products undergoing separation by multilayer coil planet centrifuge high speed countercurrent distribution (HSCCD) have been evaluated in a new and systematic procedure for optimal solvent selection. the new method was illustrated by a complete HSCCD separation of five closely related dipeptides.     

Evaluation of Analytical Countercurrent Chromatographs: High-Speed Countercurrent Chromatograph-4000 Vs. Analytical Toroidal Coil Centrifuge

Abstract

Performance of two countercurrent chromatographic models, high speed countercurrent chromatograph (HSCCC-4000) and analytical toroidal coil centrifuge (TCC), is evaluated in terms of theoretical plate number, resolution factor and separation time to assess their analytical capability. A series of experiments was conducted to investigate the effects of internal diameter and length of the coiled column, and flow rate of the mobile phase on the separation of indole auxins in two-phase solvent systems composed of n-hexane-ethyl acetate-methanol-water at different volume ratios. The three components of indole auxins were completely resolved in 16 min with a HSCCC system equipped with a multilayer coil of a 0.55 mm I.D. PTFE tube with theoretical plates ranging from 1290 to 829. Similar separation was achieved in 24 min with a TCC systems equipped with a 0.3 mm I.D. PTFE tube with theoretical plates ranging from 1811 to 969. It is concluded that both systems have comparable analytical capability at the present stage of development.     

New small-scale cross-axis coil planet centrifuge. Partition efficiency and application to purification of bullfrog ribonuclease

The new small-scale cross-axis coil planet centrifuge (X-axis CPC) previously designed and fabricated in our laboratory has a distinctive feature such that four separation columns of similar weight are mounted symmetrically around the rotary frame to achieve stable balancing of the centrifuge under a high revolution speed. In this column layout, neighboring columns must be rotated in the opposite direction if viewed from the center of the centrifuge to avoid twisting the interconnecting flow tubes. The effect of rotational direction of the columns on the partition efficiency was evaluated with separation of a set of test samples such as cytochrome c, myoglobin, and lysozyme using an aqueous-aqueous polymer phase system composed of 12.5% (w/w) polyethylene glycol (PEG) 1000 and 12.5% (w/w) dibasic potassium phosphate under 1000 rpm of column revolution. A series of experiments was performed using a set of two diagonally located columns (connected in series) each consisting of five coiled layers of 1 mm I.D. with a total capacity of 27.0 mL. Both right- and left-handed coils were tested each under the optimized conditions for choice of mobile phase and direction of the column rotation so that the satisfactory volume of the mobile phase was retained in the column by the aid of Archimedean screw effect. The results of these studies showed that one particular combination of handedness of the coil and direction of the rotation yielded the best peak resolution for each mobile phase. In order to demonstrate the capability of the apparatus, the purification of ribonuclease (RNase) from the extract of bullfrog egg, sialic acid binding lectin (cSBL), was carried out using both organic-aqueous and aqueous-aqueous polymer phase systems. When using the 16.0% (w/w) PEG 1000-6.3% (w/w) dibasic potassium phosphate-6.3% (w/w) monobasic potassium phosphate system, cSBL was successfully separated from other proteins present in the extract while commercial RNase A was eluted at near the solvent front by the lower phase mobile. The cSBL retained its native RNase activity. The overall results demonstrated that the present new small-scale X-axis CPC is useful for the purification of bioactive compounds without loss of their native activities.     

Use of pH-Zone Refining Countercurrent Chromatography for Preparative Separation of Fangchinoline and Tetrandrine from Stephania tetrandra

pH-Zone-refining countercurrent chromatography with a multilayer coil planet centrifuge has been successfully used for separation of fangchinoline and tetrandrine from crude extracts of Stephania tetrandra. The two target compounds were completely resolved by use of the two-phase solvent system petroleum ether (60–90 °C)–ethyl acetate–methanol–water 5:5:1:9 (v/v), with 10 mm triethylamine in the organic stationary phase and 5 mm hydrochloric acid in the aqueous mobile phase. Separation of 3.5 g sample yielded 126 mg fangchinoline (LC purity >93%) and 249 mg tetrandrine (LC purity >95%). The structures of the compounds were confirmed by use of electrospray ionization mass spectrometry and ¹H NMR.     

PH-Zone-refining counter-current chromatography of lappaconitine from Aconitum sinomontanum nakai I. Separation of prepurified extract

pH-Zone-refining counter-current chromatography was applied to the separation of diterpenoid alkaloids from a crude sample from a crude prepurified sample containing lappaconitine at about 90% purity using a multilayer coil planet centrifuge. The experiment was performed with a two-phase solvent system composed of methyl tert.-butyl ether-tetrahydrofuran-distilled water (2:2:3, v/v) where triethylamine (10 mM) was added to the upper organic stationary phase as a retainer and hydrochloric acid (10 mM) to the aqueous mobile phase as an eluter. The separation of 10.5 g of the sample yielded 9.0 g of lappaconitine at a high purity of over 99% as determined by HPLC.     

Improved partition efficiency with threaded cylindrical column in vortex counter-current chromatography

Type-I coil planet centrifuge produces a uniformly circulating centrifugal force field to produce vortex motion of two immiscible solvent phases in a cylindrical cavity of the separation column to perform efficient countercurrent chromatography. The partition efficiency obtained from the original vortex column was substantially improved by threading the cylindrical cavity to increase the area of mass transfer between the two phases. Partition efficiency of the threaded column was evaluated by three different two-phase solvent systems with a broad range of hydrophobicity each with a set of suitable test samples. Overall results of the present studies indicated that the threaded cylindrical column substantially improves the partition efficiency in terms of theoretical plate number, peak resolution, and height equivalent of one theoretical plate. The results also indicated that higher peak resolution is produced by eluting either the upper phase in the head to tail direction or the lower phase in the reversed direction. When there is a choice in the mobile phase, a better separation is achieved by using the less viscous phase as the mobile phase. Since the present system gives extremely low column pressure, it may be a potential alternative to the conventional type-J HSCCC system for a large-scale preparative separation.     

Separation of Substances in Rotating Coiled Columns: From Trace Elements to Microparticles

The potentialities of rotating coiled columns in countercurrent chromatography (CCC) and centrifugal field-flow fractionation (CFFF) are demonstrated. A rotating coiled column is a fluoroplastic or steel coil wound around a rigid cylindrical drum, which revolves about its axis and, at the same time, revolves around the central axis of the device called planet centrifuge. The stationary (liquid, solid, or heterogeneous) phase is retained in the column because of the centrifugal force field, and the mobile liquid phase is continuously pumped through the column. The methods for recovery, separation, and preconcentration of various trace elements in geological samples and high-purity substances with the use of two-phase liquid systems (CCC) are developed. Procedures are proposed for the continuous sequential extraction of various element species from soil and for the recovery of polycyclic aromatic hydrocarbons from sewage sludge with the use of natural suspensions or solid particulates as stationary phases. It is also shown that rotating coiled columns can be used in a new field, microparticle fractionation by CFFF.     

Recent advances in counter-current chromatography

During the past several years, counter-current chromatography (CCC) technology has been advanced to cover a broad spectrum of applications, from large-scale preparative to analytical-scale separations. These advances include liquid-liquid dual CCC, foam CCC and partition of macromolecules with aqueous-aqueous polymer phase systems. For these developments the synchronous coil planet centrifuge scheme has been used, which relies on a relatively simple mechanical design. Future developments in CCC may be focused on the improvement of the more intricate non-synchronous coil planet centrifuge scheme which has a greater potential for the separation of biopolymers and cell particles.