Fast diagnosis of different infections is a crucial for a successful medical treatment. For diagnosis of certain diseases, separation of IgG and IgM in human serum is required to prevent interference or competing. This is usually achieved by adding adsorbent containing antihuman antibodies to the sample. Incubation from half to one hour is needed to achieve the complete removal of the antibody.
A quicker way to achieve the removal of antibody would be the use of a chromatographic support with specific ligand, which selectively binds the antibody. For example, a Protein G column can be used for removal of IgG. This is faster, but also much more expensivfe way of removing IgG's.
CIM Convective Interaction Media stationary phases represent a novel generation of stationary phases for liquid chromatography. Because of their monolithic structure, being designed for the separation and purification of macromolecules, they exhibit a higher dynamic capacity for very alrge molecules in comparison to traditional stationary phases, combined with much shorter process time that further result in a decreased loss of the biologic activity.
In this work, we present low price ligands (coupled to CIM chromatographic support), which can be used for efficient separation of IgG and IgM antibodies.
Immobilized Metal-Affinity Chromatography (IMAC) is a separation technique primarily intended for the purification of proteins with exposed histidine tags. Technique uses covalently bound chelating compounds on chromatographic supports to entrap metal ions, which serve as affinity ligands for various proteins. Iminodiacetic acid (IDA), nitrilotriacetic acid (NTA), carboxymethylated aspartic acid (CM-Asp), and N,N,N’-tris(carboximethyl) ethylenediamine (TED) are chelating compounds, most often used to entrap metal ions, such as Cu2+, Ni2+, Zn2+, Co2+ etc.
Convective Interaction Media CIM® is a monolithic support, which provides high rates of mass transfer at low pressure drops. It has been shown that CIM® supports are very efficient for the separation of large molecules, such as proteins and DNA (1). Recent publication has proved that CIM IMAC column can be used for separation of histidine containing peptides (2). Since efficient separation of large molecules is one of the main advantages of CIM® support, purification of His-tagged recombinant proteins on CIM IMAC column should be not only feasible but also simple, fast and efficient.
Membrane bound heterotrimeric guanine-nucleotide proteins (G-proteins) are the important components of the cellular signal transduction cascade. They are GTPases which cycle between an inactive and an active configuration by catalysing the exchange of GTP for GDP bound to G subunit. In our study we investigated separation of high affinity GTP'S binding proteins (G-proteins) from plasma membrane of porcine brain by HPLC using CIM® (Convective Interaction Media) supports. CIM® supports proved to be an efficient tool for cytosolic protein separation on second or minute time scale. No study of separation of membrane bound proteins by CIM® supports have been done so far.
Traditionally, viruses are purified by time consuming methods such as CsCl density gradient centrifugation or similar. These methods are often inefficient and limited to small scale. In recent years different methods for virus purification, based on ion exchange, gel filtration and affinity chromatography have became popular. Recently, CIM® disk monolithic columns were used for successful concentration of two plant viruses (1) and for improved detection of two human viruses (2). Cucumber mosaic virus (CMV) and Tomato mosaic virus (ToMV) were concentrated and subsequently detected from extremely diluted samples in which they were initially undetectable. Successful concentrations of both viruses encourage us to explore the possibilities of CIM® supports for virus purification. As a model virus ToMV was selected. ToMV is a rod shaped plant virus with a typical size of 300 x 18 nm and isoelectric point at pH 4.6.
The only four drugs approved for the clinical treatment of Alzheirner’s Disease (tacrine. rivastigmine, donepezil and galantamine) are acetylcholinesterase inhibitors which act by maintaining high levels of acetylcholine at the muscarinic and nicotinic receptors in the central nervous system. Human acetylcholinesterase (HuAChE) represents a widely studied target enzyme and it is still object of research for the development of new drugs as enzyme inhibitors.
In a previous paper we reported the immobilisation of AChE on a silica based chromatographic column (50 x 4.6 mm 1.0.) The yeld of immobilization and the stability of the AChE-IMER were considered satisfactory, but some problems arose. The length of the IMER and the large amount of enzyme covalently bound to the chromatographic support resulted in catalysis product long elution times and some inhibitors aspecific matrix absorption with delayed enzyme activity recovery. In order to avoid these complications and considering the high rate of AChE enzymatic reaction. we decided to reduce the dimension of the solid support for immobilization, hence the amount of immobilized enzyme, by selecting a monolithic matrix disk (12 x 3 mm I.D.).
CIM® (Convective Interaction Media) monolithic supports (Biaseparations. Lubiana) represent a novel generation of stationary phases used for liquid chromatography, bioconversions, and solid phase synthesis. As opposed to individual particles packed into chromatographic columns, CIM® supports are cast as continuous homogeneous phases and provide high rates of mass transfer at lower back pressure.
In the present work a CIMK disk with immobilised human recombinant acetylcholinesterase (HuAChE-ClM® Disk) was developed. The activity of immohilised enzyme, the long term stability and reproducibility were tested. HuAChE-CIM® disk was applied as an immobilised enzyme micro-reactor (micro-IMER) in on-line HPLC system for inhibitory potency determination of known AChE inhibitors.
Gene therapy which is becoming more and more important in human health care requires the purification of high molecular mass compounds, so called nanoparticles (e. g. viruses and plasmids). The method of choice to ensure proper purity would be chromatography.
Most of the chromatographic supports available on the market at the moment can not follow the requests for such work due to low binding capacity for large molecules, limitation with regards to the time of the separation process and requests for CIP (cleaning in place) and SIP (sanitation in place).
Monolithic supports represent a new generation of chromatographic supports. In contrast to conventional particle supports, where the void volume between individual porous particles is unavoidable, these supports consist of a single monolith highly interconnected with larger and smaller open flow-through channels. Due to the structure, molecules to be separated are transported to the active sites on the stationary phase by convection, resulting in very short separation times. This is especially true for large molecules.
In this work we will present the use of monolithic supports for the separation of different nanoparticles on analytical and preparative scales. It will be shown that monolithic supports can overcome the limitations of particle-based supports for the analytics and isolation of big molecules and represent a major step towards the safe and efficient purification or production of nanoparticles.
Traces of DNA in RNA samples represent impurities that could affect results of mRNA quantification and cDNA synthesis. In most cases, the DNA impurities in RNA samples are removed using enzyme deoxyribonuclease (DNase), which specifically breaks down DNA. In order to avoid the addition of DNase into the analyzing sample, the use of immobilized DNase on solid support is recommended. Because of the DNA size, very few supports available on the market enable efficient interaction between immobilized enzyme and DNA.
In recent years a new group of supports named monoliths was introduced. Because of enhanced exchange between mobile and stationary phase separation and bioconversion processes are significantly accelerated. Therefore also the efficiency of DNA removal using immobilised enzyme might be competitive to the degradation with free enzyme.
CIM Convective Interaction Media® are polymer-based monolithic supports which were introduced for chromatographic analyses, in-process control, solid phase extraction, and purification of target biomolecules, both on an analytical and on a preparative scale 1, 2. CIM supports perform high-resolution separations within seconds. This is predominantly due to the convective mass transport of the biomolecules between the mobile and stationary phases and the very low dead volume of the separation unit. One of the main concerns in the last few years was the batch-to-batch reproducibility of the monoliths during manufacturing and the possibility of using the monolithic supports for validated analytical methods. The batch-to-batch reproducibility in product preparation as well as its stability during analytical work should fulfill all the requirements for a validated analytical method. To demonstrate that this is possible, we have selected one complex example – the determination of impurities in immunoglobulins (IgGs) where a multidimensional, so called CLC (Conjoint Liquid Chromatography), approach combining the ion exchange and affinity chromatography was needed to properly analyze the sample.
Therefore, two CIM Protein G disks and one CIM QA disk were placed in series in one housing. Binding conditions were optimized in a way that the IgGs were bound to the CIM Protein G disks while Transferrin and Albumin were separated on a CIM QA disk. A complete separation of all three proteins was achieved in five minutes.
Convective Interaction Media (CIM) are newly developed polymer-based monolithic supports which were introduced for chromatographic analyses, in-process control, solid phase extraction and laboratory purification of target biomolecules, both on analytical and on preparative scale. CIM supports allow high resolution separations which can, in case of analytical units - disks - be carried out within seconds (Figures 1 and 2). This is due to predominantly convective mass transport of biomolecules between the mobile and stationary phase and low dead volumes. Additionally, the dynamic binding capacity is not affected by high flow rates.
CIM can be scaled up to preparative level. For this purpose, the tubular-shaped monolithic units are prepared and placed in special housings (Figure 3). These preparative tubes are intended for very fast preparative purification of biomolecules from complex mixtures. Due to their special design, which allows radial flow of the liquid through the porous wall of the tube, and due to their low resistance to flow, the separations can be carried out at high flow rates and low back pressures (Figure 4). Small-scale preparative tubes are made of the same material as analytical CIM disks. In this way, the purification and monitoring processes can be performed on the same type of support by applying identical separation modes. The scaling-up from analytical to preparative level can therefore be carried out in a much shorter time, thus considerably reducing the cost of process development. In addition, this speed has an economic potential not only for faster and therefore cheaper production, but it will also lead to better quality and yield of unstable products.
Strains of the anaerobic bacterial genus are thought to play an important role in fiber degradation. sp. Mz5 was previously isolated from the rumen of a black and white Friesian cow and its xylanolytic activity was proved to be at least 1,65 times higher than the activities of all of the compared well known xylan-degrading rumen bacterial species and strains (1). High xylanolytic activity was the reason for partial isolation of its xylanases in order to study their special characteristics and possible biotechnological applications later.
Production and downstream processing in biotechnology requires fast and accurate control of each step in the process. Liquid chromatography of biopolymers on so-called soft supports is typically slow, often causing significant product degradation. One way of improving these boundary conditions in liquid chromatography is the use of monolithic adsorbents. The basis for fast separations with such media is a reduced mass transfer resistance owing to the fact that pore diffusion is practically non-existent . Chromatography with compact, porous units such as monolithic columns is being used increasingly for analytical and preparative separations of biopolymers with apparent molecular mass ranging from several thousand to up to several million . This paper describes the use of a CIM® Convective Interaction Media  for fast in-process analyses and preparative separations (up-scaling) of pharmaceutically relevant biopolymers such as clotting factor IX. Human factor IX is a vitamin K-dependent multidomain glycoprotein synthesized in liver . The absence or a defect of factor IX causes haemophilia B, a genetic disease in which the clotting cascade is disturbed. The concentration of factor IX in human plasma is about 5 μg/ml (0.1 μM). Because of the low concentration in human plasma, isolation of clotting factor IX has been performed by a combination of different chromatographic methods. However, it has not been possible to remove vitronectin, one of the final contaminants from factor IX purified with conventional gel supports used in the manufacturing process of commercial factor IX preparations. This paper investigates the application of CIM® monolithic columns for the separation of vitronectin from factor IX and fast in-process control of factor IX .
High performance membrane chromatography (HPMC) proved to be a very efficient method for fast protein separations. Recently, it was shown to be applicable also for the isocratic separation of plasmid DNAconformations. However, no study about the separation of small molecules was performed until now. In this work, we investigated the possibility of gradient and isocratic separations of small molecules with Convective Interaction Media (CIM) disks of different chemistries. We proved that it was possible to achieve efficient separations of oligonucleotides and peptides in the ion-exchange mode as well as the separation of small hydrophobic molecules in the reversed phase mode. Fairly good separation of four oligonucleotides could be achieved on the disk of 0.3 mm thickness. The effect of the gradient parameters on the resolution in the case of gradient mode was studied and compared with the separation under isocratic conditions.
It was shown that similar peak resolution can be achieved in both gradient and isocratic modes. In addition, it was found that the flow rate does not have a pronounced influence on the resolution in the flow rate range between 1 and 10 mL/min. However, it seems that the resolution with the flow rate even slightly increases as a consequence of the increased pore accessibility. In accordance with conventional particle HPLC columns, the resolution increases with the monolith thickness. On the other hand, the mobile phase composition has to be carefully adjusted to obtain optimal resolution, especially in the case of isocratic separations. Because of this feature, CIM monoliths seem to be competitive to other, commercially available stationary phases.
Organic acids are important metabolites of several biochemical pathways in microorganisms and as such they are frequent main or by-products in different bioprocesses. Consequently, a demand for their monitoring is often present. One of the most applied methods for organic acids determination is certainly HPLC using different separation mechanisms such as reversed-phase, ion-exchange or ion-exclusion chromatography, all based on separation under isocratic flow conditions. To achieve the isocratic separation, multiple steps of adsorption-desorption process are needed and therefore conventional chromatographic columns with long layer of separation material were considered as a necessary tool for achieving this effect.
Recently, it was shown that isocratic separation could also be performed on thin monolithic layers. The isocratic separations of plasmid DNA conformers (1), oligonucleotides (2, 3) and peptides (3) in the ion-exchange mode were demonstrated as well as isocratic reversed-phase separation of a mixture of steroids was obtained (3) all on thin GMA-EDMA monoliths commercially available under trademark CIM™ (Convective Interaction Media). The results indicated the possibility of applying CIM™ monolithic columns also for isocratic separation of some other small charged molecules. Since the average analysis time using CIM™ disk monolithic columns is up to a few minutes, these supports can be a material of choice for separation of organic acids.
Found recently serine protease called, as tissue plasminogen activator (t-PA) is able to dissolve efficiently the blood clots. Thus this protein seems to be extremely useful in clinical practice in the cases of heart attack victims.
Real process of fibrinolysis in human blood system represents very complicated network of simultaneous biological events. It is clear that t-PA has a branched set of functional complements with their own, and probably different, affinity to this enzyme. It seems to be possible and quite interesting to investigate all these pairs separately creating them in vitro. At the same time, it is clear that the affinity chromatography approach could become as the most convenient way to create such biological pairs.
The recently developed High Performance Membrane (Monolith) Chromatography (HPMC) is quite promising in this regard, because of its high capacity and selectivity, combined with low backpressure and short operation times. Due to the inherent speed of the isolation it facilitates the recovery of a biologically active product, since the exposure to putative denaturing influences.
CIM® supports are novel monolithic chromatographic supports. In contrast to conventional particle based chromatographic supports they consist of a single porous polymer. The pores form a highly interconnected network, which enables the flow of the mobile phase through the monolith. Molecules to be separated are transported to the surface by the convection. Since the diffusion is not a bottleneck any more, also the resolution and the dynamic capacity of the monolith are flow independent and an average analysis time is typically below one minute. Furthermore, CIM® columns were successfully applied for the purification of proteins directly from the fermentation broth.
Manganese peroxidases (MnP) and lignin peroxidases (LiP) are a family of glicosilated hemo-proteins, which are excreted into the growth medium during the idiophasic growth of the white rot fungus Phanerochaete chrysosporium. They are both involved in the lignin degradation. For their analysis and separation from the growth medium, HPLC is commonly applied. Besides the separation by Na-acetate concentration gradient (2), also the chromatofocusing can be used (3). A fast method for LiP isoenzyme separation from the growth medium of P. chrysosporium using CIM™ QA disk monolithic columns has been recently developed (1). A modified method was tested on the growth medium containing MnP isoenzymes.
The aim of our work was to study the direct monitoring and purification of proteins from the fermentation broth using ion-exchange CIM® supports. Therefore, we studied the possibility of monitoring and purifying lignin peroxidase extracelular protein isoforms produced by the fungus Phanerochaete chrysosporium. These isoenzymes which also differ in their catalytic properties are able to partially depolymerize lignin and to oxidise several xenobiotics.
The white rot fungus Phanerochaete chrysosporium under nitrogen or carbon limitation produces extracellular lignin peroxidases (LiP). They are able to partially depolymerize lignin and to oxidize several xenobiotics (DDT, PCB, PAH, etc.). By HPLC separation and isoelectric focusing multiple molecular forms of LiP have been isolated from the culture filtrate. For the isolation of LiP from the growth medium, mostly the HPLC technique with ion exchange Mono-Q or DEAE columns is used. The medium should be dialyzed before separation and usually also concentrated. Medium freezing is used to remove mucilaginous polysaccharides which disturb separation. The whole procedure is time consuming and information about isoenzyme content and their relative amounts in the growth medium is delayed for at least 1 day. HPLC separation itself lasts nearly an hour. For the separation of LiP isoenzymes from the culture filtrate, we used the monolithic stationary phase with weak (DEAE-diethylamine) and strong (QA-quaternary amine) ion exchange groups commercially available under trademark CIM (Convective Interaction Media). CIM supports are glycidyl methacrylate based monolithic porous polymer supports. As such they differ from conventional particle shaped chromatographic supports. The liquid is forced to flow through the support channels. Molecules to be separated are transported mainly by convection resulting in travelling times shorter for at least an order of magnitude. As a consequence the resolution as well as the binding capacity remain unaffected with the flow rate and a shorter analysis time can be achieved. This effect is even more pronounced in the case of large molecules such as proteins, which have a low diffusion coefficient. As such, CIM units can be advantageous also for lignin peroxidase isoenzymes separation and purification.
Convective Interaction Technology (CIM®) offers a number of benefits for the purification of large molecules in comparison with conventional chromatography. The innovative matrix, cast as a single homogeneous piece, means that monolithic columns have a high pressure tolerance and allow fast operating flow rates.
Because the matrix structure is composed of large pores, mass transfer is essentially convective in contrast to conventional chromatography beads, where mass transfer is essentially diffusive. Therefore, CIM can be used at high flow rates without compromising binding capacity.
For these reasons, a monolithic column with anion exchange properties (CIM® QA) was selected to purify a very large protein (8 Mega Dalton) extracted from a marine mollusc.
Because 150 g of protein was required to perform preclinical trials, a scale-up of the process had to be designed and implemented. Early stage process development was carried out on an 8 mL column to determine the column loading capacity as well as the yield and the process reproducibility.
To improve binding on the column, stabilising agents had to be removed prior to this purification step. The protein had been observed to precipitate within hours of the removal of these reagents. Therefore, a suitable time frame for protein processing had to accommodate this instability.
Isolation and purification of proteins, peptides and polynucleotides as well as fractionation of biological mixtures are of great importance both for the solution of theoretical problems in chemistry and biology and the
realization of practical plans connected, in particular, with the production of medicines on the basis of large biomolecules. An important problem in the production of biological substances for medicine is to work out the step of their isolation and fine purification, e.g. creation of high performance separation methods, particularly, the chromatographic techniques. Here, fast and efficient affinity separations based on dynamical interaction of biocomplements play very important role.
High Performance Membrane (Monolith) Chromatography (HPMC) allows to solve all problems of High Liquid Chromatography (HPLC) demonstrating a number of number of distinct advantages. A small thickness of separation layer and opened structure of throughput channels where the separation takes place cause minimum difussion resistance for normal mass transport of the substances as well as low working back pressure and thus, the possibility of use of high elution flow rates.
In order to enable the detection of low abundance proteins from human plasma, it is necessary to remove high abundance proteins. Among them, human serum albumin and immonoglobulin G represent more than 75 % of all abundance proteins. There are many strategies developed for an efficient removal of these two main proteins, the majority of them rely on highly selective, yet expensive affinity techniques. In this work an affinity monolithic column was used for the depletion of IgG. For the removal of HSA we tested an alternative - complementary approach, where an ion-exchange mode was used as one of the depletion steps. the results were compared to the ones obtained by by using the prseudoaffinity columns.