Industrial scale-up of countercurrent chromatography: predictive scale-up

This study describes how scale-up in countercurrent chromatography (CCC) can be simply predicted on a process scale CCC device by running a preliminary analytical-sized sample and having knowledge of the stationary-phase retention at scale-up conditions. Results have shown that simple experimentation can lead within a day to a process with the capability of several kilograms per day (tons per year) compound yield, and that this is feasible with benchtop CCC units.     

Mathematical model of computer-programmed intermittent dual countercurrent chromatography applied to hydrostatic and hydrodynamic equilibrium systems

Dual high-speed countercurrent chromatography (dual CCC) literally permits countercurrent flow of two immiscible solvent phases continuously through the coiled column for separation of solutes according to their partition coefficients. Application of this technique has been successfully demonstrated by separation of analytes by gas–liquid and liquid–liquid two-phase systems. However, the method cannot be directly applied to the system with a set of coiled columns connected in series, since the countercurrent process is interrupted at the junction between the columns. However, this problem can be solved by intermittent dual CCC by eluting each phase alternately through the opposite ends of the separation column. This mode of application has an advantage over the conventional dual CCC in that the method can be applied to all types of CCC systems including hydrostatic equilibrium systems such as toroidal coil CCC and centrifugal partition chromatography. Recently, the application of this method to high-speed CCC (hydrodynamic system) has been demonstrated for separation of natural products by Hewitson et al. using a set of conventional multilayer coil separation columns connected in series. Here, we have developed a mathematical model for this intermittent dual CCC system to predict retention time of the analytes, and using a simplified model system the validity of the model is justified by a series of basic studies on both hydrodynamic and hydrostatic CCC systems with a computer-programmed single sliding valve. The present method has been successfully applied to spiral tube assembly high-speed CCC (hydrodynamic system) and toroidal coil CCC (hydrostatic system) for separation of DNP-amino acid samples with two biphasic solvent systems composed of hexane–ethyl acetate–methanol–0.1 M hydrochloric acid (1:1:1:1 and 4:5:4:5, v/v).     

用DHDECMP在逆流色谱上分离镧系金属离子

用DHDECMP(二己基-N,N-二乙基甲酰胺基亚甲基膦酸酯)的环己烷溶液作为固定相,硝酸溶液作为流动相,在逆流色谱上进行了镧系金属离子Ce^3^+,Nd^3^+,Sm^3^+,Gd^3^+,Tb^3^+,Dy^3^+,Er^3^+,Yb^3^+和Lu^3^+的相互分离研究。逆流色谱分离金属离子与分离有机物不同,保留体积不仅取决于静态分配比,还取决于萃取反应的机理。由逆流色谱得到的动态分配比和静态分配比成良好的线性关系,但并不相等,这一实验结果验证了有关理论研究结果。     

Countercurrent chromatographic separation: a hydrodynamic approach developed for extraction columns

In countercurrent chromatography (CCC) both stationary and mobile liquids undergo intense mixing in the variable force field of a coil planet centrifuge and the separation process, like the separation in conventional solvent extraction column, is influenced by longitudinal mixing in the phases and mass transfer between them. This paper describes how the residence time distribution (or the elution profile) of a solute in CCC devices and the interpretation of experimental peaks, can be described by a recently developed cell model of longitudinal mixing. The model considers a CCC column as a cascade of perfectly mixed equal-size cells, the number of which is determined by the rates of longitudinal mixing in the stationary and mobile phases. Experiments were carried out to demonstrate the validation of the model and the possibility of predicting the partitioning behaviour of the solutes. The methods for estimating model parameters are discussed. Longitudinal mixing rates in stationary and mobile phases have been experimentally determined and experimental elution profiles are compared with simulated peaks. It is shown that using the cell model the peak shape for a solute with a given distribution constant can be predicted from experimental data on other solutes.     

Synergistic Use of Countercurrent Chromatography and High Performance Liquid Chromatography for the Purification of Synthetic Peptides

Abstract

Examples are given demonstrating how countercurrent chromatography (CCC) and high performance liquid chromatography (HPLC) can be used together to purify synthetic peptides. In one example, CCC provided a preliminary purification of Met-Arg-Asp-Val-Val-Leu-Phe-Glu-Lys by enabling separation of ultraviolet absorbing, ninhydrin-negative material from the desired peptide. Final purification was achieved with HPLC without risk of harming the HPLC column. In a second example Tyr-Ala-Ala-Nle-Ala-Ala was completely purified by CCC with the CCC separation rapidly and conveniently monitored by HPLC. CCC appears to be a very useful technique for the peptide chemist.     

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.     

一种用于大容量逆流色谱制备的立式多层螺旋管行星式离心机

Owing to no complications caused by solid supports, such as adsorptive sample loss and deactivation, tailing of solute peaks, and contamination, countercurrent chromatography (CCC) has been an area of intense research since the first introduction of CCC in 1970,[1] and various apparatus and broad applications have been advanced[2,3]. For these developments, the type-J synchronous planet centrifuge has received considerable attention, which relies not only on its relatively simple mechanic design, but also on its high partition efficiency and short elution time caused by mixing and settling for the efficient chromatographic separations. In the past, however, almost all of type-J centrifuges rotated slowly were disposed horizontally due to the original design and some experiments that gravis plays an important role at a low rotary speed as similar to type-V rotating multilayer helical tube in unit gravity[4-9]. In fact,we discovered that the upright apparatus holds more retention of stationary phase than the horiziontal aparatus when large standard tubings were used as mutilayer coil column and the aparatus was operated under same contions. We report here a new coil planet centrifuge with four upright cylindrical columns for large scale countercurrent chromatographic preparation. The design principle and apparatus of UCCC is as samilar to type-J multilayer coil planet centrifuge. Four uptight cylindrical column holders are symmetrically arranged around the centrifuge axis as similar to the type-J HSCCC with three horizontal multilayer coils connected in series[8] . A series of experiments indicat that upright CCC has many advantages over the horizontal CCC when using a large-bore tube as multilayer coil column for large scale countercurrent chromatographic separation.Upright CCC provide a versatile countercurrent chromatographic method for large-scale preparation from very crude sample. It has good preparative capacity and flexible suitability to various sample and two-phase system.The present apparatus not only can be operated at a high speed as similar as commonly used HSCCC for the system having short settling time and but also can be run at a low speed for the system having relative long settling time. Because of automatical control and seal-free flow through device, the uptight CCC apparatus may be readily scaled up to industrial preparation.     

Dual-mode high-speed counter-current chromatography: retention, resolution and examples

Counter-current chromatography (CCC) is a very versatile technique offering high resolution power in recovering very pure compounds from complex matrices. Dual-mode CCC where the phase role is reversed during the separation is investigated here; it ensures elution of all the injected species from the column while, unlike backflush, the separation is still progressing after phase reversal; equations giving retention and retention factor are derived from the basic equations of chromatography. Compared to normal-mode CCC, it is shown that enhanced resolution in dual-mode CCC can be obtained in conditions derived from a theoretical model. The experimental section provides the validation of the retention prediction while resolution is also proven to be enhanced in dual-mode CCC. However, equations given in the theoretical section cannot fully explain the results obtained for resolution because they do not deal with kinetics. Dual-mode CCC has also been applied to separation of polyoxypropylene glycol polymers; separation can be achieved with a small number of experiments because all the injected compounds are eluted by reversing the phases. Dual-mode CCC also gave improved yields in the purification of antibiotics compared with previous results using normal-mode CCC.     

The Efficiency of Substance Separation in Countercurrent Liquid Chromatography

The effect of hydrodynamic parameters and the specific features of instrument design on the efficiency of substance separation in countercurrent liquid chromatography (CCC) was studied using a constant retention factor of the stationary phase in the column. The study was conducted with the separation of benzyl alcohol and p-cresol in a two-phase liquid system heptane–ethyl acetate–methanol–water (1.4 : 0.6 : 1 : 1) in as an example. It was shown that the peak resolution is improved with an increase in the rotational speed of the column and a decrease in the flow rate of the mobile phase. The best peak separation was attained using columns for which the ratio of the column rotation radius to the radius of column revolution was 0.615. It was shown that countercurrent chromatography allows the separation of substances with low partition constants (K < 1) in dilute solutions. The volume of the test sample may be up to 15% of the total volume of the chromatography column.     

Cell Separations on the Countercurrent Chromatograph

Abstract

Separation of cells differing only subtly has been achieved by partitioning between the two phases formed by solution of dextran and polyethylene glycol in water. Cell populations which have related, but not identical, surface properties seldom exhibit sufficiently different partition behavior to be separated in a single extraction. In such cases, repeated partitions are carried out via countercurrent distribution or countercurrent chromatography to effect the separation. Potential advantages of countercurrent chromatography are its ease and rapidity of operation. In the present work we describe our approach to determining and possibly improving the efficiency of polymer phase partitioning by countercurrent chromatography.     

Elution–extrusion countercurrent chromatography separation of six pairs of isomeric iridoids from Cornus officinalis Sieb. et Zucc. guided by ion current extraction in mass spectrometry

A mass spectrometry–guided elution–extrusion countercurrent chromatography protocol was developed to separate chemical components from Cornus officinalis Sieb. et Zucc. In this study, ion current extraction, a mass spectrometry–based data postacquisition method, was utilized to boost the separation power and scope of countercurrent chromatography technique. As a peak repicking and denoising tool, ion current extraction was carried out to process the liquid chromatography with mass spectrometry and the countercurrent chromatography with mass spectrometry data. So the target components were reacquired in the created extracted ion current patterns with enhanced responses and diminished background noise, which facilitated the distribution constant determination (by liquid chromatography with extracted ion current) and the targets fractionation (by countercurrent chromatography with extracted ion current). Under the guidance of the extracted ion currents of the target components and with the support of elution–extrusion mode in the countercurrent chromatography separation, six pairs of minor iridoid isomers were obtained in shortened experimental duration. Besides, a reciprocal shifted symmetry plot was established to represent the elution–extrusion countercurrent chromatography chromatogram. The results demonstrated the capability of the ion current extraction–guided elution–extrusion countercurrent chromatography protocol in discovery, analysis, and fractionation of low‐concentration and structurally similar chemicals from a complicated sample.     

Application of pH-Zone-Refining Countercurrent Chromatography in the Preparative Separation of Alkaloids from Traditional Chinese Medicine

pH-Zone-refining countercurrent chromatography (CCC) is a recently developed new preparative separation method based on conventional CCC. The method uses a retainer base (or acid) in the stationary phase to retain the analyses in the column and an eluent acid (or base) to elute the analyses according to their pKa values and hydrophobicities. It produces a succession of highly concentrated rectangular peaks with minimum overlap similar to those observed in displacement chromatography. pH-zone-refining CCC has important advantages over the conventional CCC including an over 10-fold increase (up to 10 gram or more) in sample loading capacity, high concentration of fractions, and concentration of minor impurities. pH-zone-refining CCC has been successfully applied to the preparative separation of a variety of compounds including both acidic and basic derivatives of amino acid, hydroxyxanthene dyes, peptides, alkaloids, indole auxins, structural, geometrial and optical isomers.     

Using the liquid nature of the stationary phase in countercurrent chromatography. IV. The cocurrent CCC method

The retention volumes of solutes in countercurrent chromatography (CCC) are directly proportional to their distribution coefficients, K(D) in the biphasic liquid system used as mobile and stationary phase in the CCC column. The cocurrent CCC method consists in putting the liquid "stationary" phase in slow motion in the same direction as the mobile phase. A mixture of five steroid compounds of widely differing polarities was used as a test mixture to evaluate the capabilities of the method with the biphasic liquid system made of water/methanol/ethyl acetate/heptane 6/5/6/5 (v/v) and a 53 mL CCC column of the coil planet centrifuge type. It is shown that the chromatographic resolution obtained in cocurrent CCC is very good because the solute band broadening is minimized as long as the solute is located inside the "stationary" phase. Pushing the method at its limits, it is demonstrated that the five steroids can still be (partly) separated when the flow rate of the two liquid phases is the same (2 mL/min). This is due to the higher volume of upper phase (72% of the column volume) contained inside the CCC column producing a lower linear speed compared to the aqueous lower phase linear speed. The capabilities of the cocurrent CCC method compare well with those of the gradient elution method in HPLC. Continuous detection is a problem due to the fact that two immiscible liquid phases elute from the column. It was partly solved using an evaporative light scattering detector.     

Enantioseparation of pheniramine enantiomers by high‐speed countercurrent chromatography using β‐cyclodextrin derivatives as a chiral selector

The enantioselective separation of pheniramine was studied by a high‐speed countercurrent chromatography method using β‐cyclodextrin derivatives as a chiral selector. Several key variables, for instance, type of organic solvent and chiral selector, concentration of chiral selector, pH value of aqueous phase, and temperature on the enantioselectivity, were investigated systematically by liquid–liquid extraction experiments. Combining the results of extraction experiments and high‐speed countercurrent chromatography, the most suitable conditions for separation of pheniramine enantiomers were obtained with the two‐phase system that consisted of isobutyl acetate/aqueous phase, containing 0.02 mol/L carboxymethyl‐β‐cyclodextrin, pH 8.50 at 278.15 K. Under the optimal conditions, pheniramine enantiomer was successfully resolved after four cycles of high‐speed countercurrent chromatography. By using high‐performance liquid chromatography to analyze the fractions, the purities of both (+)‐pheniramine and (–)‐pheniramine were over 99% and the recovery of this method was up to 85–90%.     

Universal counter-current chromatography modelling based on counter-current distribution

There is clearly a need for a model which is versatile enough to take into account the numerous operating modes and pump out procedures that can be used with counter-current chromatography (CCC). This paper will describe a universal model for counter-current chromatography based on counter-current distribution. The model is validated with real separations from the literature and against established CCC partition theory. This universal model is proven to give good results for isocratic flow modes, as well as for co-current CCC and dual flow CCC, and will likely also give good results for other modes such as intermittent CCC.     

逆流色谱分离感应耦合等离子质谱在线测量超痕量钚

将逆流色谱（CCC）与感应耦合等离子质谱（ICP-MS）相联,研究了几种两相体系在CCC中的固定相保留率,从中选择1％TNOA-正庚烷作固定相,通过CCC富集分离钚并去除基体及干扰元素,通过研究在线分离条件及定量方法等,建成了CCC分离ICP—MS在线测量超痕量钚的方法。采用该方法分析得到实际土壤样品中^239Pu的含量与由传统的分离方法给出的结果相吻合。     

Effective on‐line high‐speed shear dispersing emulsifier technique coupled with high‐performance countercurrent chromatography method for simultaneous extraction and isolation of carotenoids from Lycium barbarum L. fruits

An efficient combination strategy based on high‐speed shear dispersing emulsifier technique and high‐performance countercurrent chromatography was developed for on‐line extraction and isolation of carotenoids from the fruits of Lycium barbarum. In this work, the high‐speed shear dispersing emulsifier technique has been employed to extract crude extracts using the upper phase of high‐performance countercurrent chromatography solvent system composed of n‐hexane?dichloromethane?acetonitrile (10:4:6.5, v/v) as the extraction solvent. At the separation stage, the high‐performance counter‐current chromatography process adopts elution–extrusion mode and the upper phase of the solvent system as stationary phase (reverse‐phase mode). As a result, three compounds including zeaxanthin, zeaxanthin monopalmitate, and zeaxanthin dipalmitate with purities of 89, 90, and 93% were successfully obtained in one extraction‐separation operation within 120 min. The targeted compounds were analyzed and identified by high‐performance liquid chromatography, mass spectrometry, and NMR spectroscopy. The results indicated that the present on‐line combination method could serve as a simple, rapid, and effective way to achieve weak polar and unstable compounds from natural products.     

Efficient separation of tocopherol homologues in vegetable oil by ionic‐liquid‐based countercurrent chromatography using a non‐aqueous biphasic system

Tocopherol homologues are important fat‐soluble bioactive compounds with high nutritional value. However, it is of great challenge to separate these homologues because of their high structural similarities. In this work, ionic‐liquid‐based countercurrent chromatography was used for the separation and purification of tocopherol homologues. Conventional countercurrent chromatography and ionic‐liquid‐based countercurrent chromatography solvent systems were evaluated in respect of partition coefficient, separation factor, and stationary phase retention factor to separate these targets. Kind of ionic liquids, amount of ionic liquid, and sample amount were systematically optimized. A novel countercurrent chromatography non‐aqueous biphasic system composed of n‐hexane‐methanol‐1‐butyl‐3‐methylimidazolium chloride was established. The baseline separation of tocopherol mixtures was obtained in one cycle process. The ionic liquid played a key role in the countercurrent chromatography separation, which resulted in difference of partition behavior of individual tocopherol in the whole system through different hydrogen‐bonding affinity. Finally, n‐hexane‐methanol‐1‐butyl‐3‐methylimidazolium chloride (5:5:3, v/v) water‐free biphasic system was successfully applied to separate tocopherol homologues from vegetable oil that was not achieved beforehand. This method can be widely employed to separate many similar molecules such as tocotrienols, tocomonoenols, and marine‐derived tocopherol in food samples.     

Determination of liquid-liquid partition coefficients by separation methods

By essence, all kinds of chromatographic methods use the partitioning of solutes between a stationary and a mobile phase to separate them. Not surprisingly, separation methods are useful to determine accurately the liquid-liquid distribution constants, commonly called partition coefficient. After briefly recalling the thermodynamics of the partitioning of solutes between two liquid phases, the review lists the different methods of measurement in which chromatography is involved. The shake-flask method is described. The ease of the HPLC method is pointed out with its drawback: the correlation is very sensitive to congeneric effect. Microemulsion electrokinetic capillary electrophoresis has become a fast and reliable method commonly used in industry. Counter-current chromatography (CCC) is a liquid chromatography method that uses a liquid stationary phase. Since the CCC solute retention volumes are only depending on their partition coefficients, it is the method of choice for partition coefficient determination with any liquid system. It is shown that Ko/w, the octanol-water partition coefficients, are obtained by CCC within the -1 < log Ko/w < 4 range, without any correlation or standardization using octanol as the stationary phase. Examples of applications of the knowledge of liquid-liquid partition coefficient in the vast world of solvent extraction and hydrophobicity estimation are presented.