Posters

Commercially available CIM® disk monolithic columns are intended for very fast analyzes and laboratory purification. Their shape is a compromise to achieve acceptable resolution and binding capacity what make them suitable for wide range of laboratory applications. Separations of complex protein mixtures can be carried out within just a few seconds because of flow unaffected resolution and, on the other hand, purification can be effectuated with high productivity due to flow-unaffected dynamic binding capacity [1]. However, in many cases in the field of molecular biology, only a limited amount of sample is available. In such a case it is beneficial to work with small columns having high resolution or they can be used as affinity columns or bioreactors saving significant amount of valuable ligand. Having this goal in mind we developed CIM® disks with the volume of 1/10th and 1/100th of original volume. In comparison to conventional CIM® disks, they exhibit higher resolution and lower limit of detection, therefore smaller concentrations of target macromolecules can be detected. The separation ability and the protein capacity were tested on anion and cation exchange 3.4 mL and 34m L mini disk monolithic columns.

Analysis of a large numbers of samples requires chromatographic supports that not only enable fast separation and purification of a target biomolecules from a complex matrix but are also involved in an automation process. The 96 – microtiter plate format enables both. Although they are routinely used for decade's only recently few reports about the microtiter plates bearing monoliths as a separation media, were reported [1]. Because of advantageous properties such as flow unaffected dynamic binding capacity and resolution 96 - microtiter plates with methacrylate based monolith were prepared. Characterisation of such plate demonstrated that uniform flow rate can be achieved through all wells and no leakage is present. Efficient separation of proteins was achieved within minute. Furthermore CLC (Conjoined Liquid Chromatography) concept [2] originally derived for analytical columns on CIM disk, can easily be extrapolated to microtiter plates. We demonstrated that multidimensional chromatography with 96 – well plate is feasible and can further accelerate screening processes.

The Inter-alpha inhibitor protein family is comprised of complex plasma proteins that consist of a combination of multiple polypeptide chains (light and heavy chains) covalently linked by a chondroitin sulfate chain. The major forms found in human plasma in high concentration are Inter-alpha inhibitor (Ial), which consists of two heavy chains (Hl & H2) and a single light chain, and Pre-alpha Inhibitor (Pal), which consists of one heavy (H3) and one light chain (Fig 1). The light chain (bikunin) is known to inhibit several serine proteases, such as trypsin, human leukocyte chistase, plasmin and cathepsin G which are involved in inflammation, sepsis, tumor invasion and formation of metastasis. Recently, a monoclonal antibody against human inter-alpha inhibitor proteins (MAli 6931) was developed in our laboratory.

The analysis of molecular interactions is a key part of the drug discovery process, and analytical techniques are available for studying in vitro the ligand/target complex since the early stage of the drug development process.

With regard to the assessment of the activity of chemical libraries, the affinity chromatography on HPLC immobilized-enzyme column (or immobilized enzyme reactors, IMER) is one of most promising methodologies for HTS applications.

Human recombinant acetylcholinesterase (hAChE) represents a well-known target for drug-discovery in Alzheimer’s Disease.

Plasmids are excellent genetic vectors and have been widely used in gene manipulation and recombinant DNA technology for a long time. In recent years, plasmids are intensively investigated for gene therapy purposes and genetic vaccination. In this case, plasmid DNA (pDNA) of high purity is required. To follow such demands, several chromatographic steps are commonly needed. In the case of buffer compatibility, columns can be connected in-line to overcome time consuming and yield lowering multiple chromatographic steps. Since each of the unit operations contributes to the dispersion, the resolution is further decreased by each chromatographic step. This drawback might be surmounted by combining several chromatography steps into a single chromatography column. This approach is known as multidimensional or conjoint liquid chromatography (CLC).

Immobilized Metal-Affinity Chromatography (IMAC) is a chromatographic separation technique primarily used for the purification of proteins with exposed histidine residues and for recombinant proteins with histidine tags. Technique uses covalently bound chelating compounds on chromatographic supports to entrap metal ions, such as Cu2+, Ni2+, Zn2+, Co2+, which serve as affinity ligands for various proteins. CIM Convective Interaction Media is a monolithic chromatographic support intended for separation of large biomolecules, such as proteins, DNA and also viruses.

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.

Affinity chromatography is a key method for protein purification. Its main advantage is in the high specificity which enables purification of a single protein from complex biological mixtures. For practical use the specific ligand should be immobilised on insoluble matrix. As a matrix, standard chromatographic supports are commonly used. They are normally in form of small (some m in diameter) particles containing pores to provide high specific surface resulting in high binding capacity. The pores are normally closed on one side, thus the liquid inside them is stagnant and the molecules are transported to the active site by diffusion. Since the diffusion coefficients for macromolecules, such as proteins, are very low, diffusion determines the overall process dynamics. As a consequence, separation or purification of the proteins takes normally 0.5 to 1h even on analytical scale.

A large number of diagnostics and several therapeutic monoclonal antibodies (mAbs) have been approved worldwide and many more are expected to be approved and licensed in the near future. The reality and the fact that purification or downstream processing can contribute up to 80% of the total production costs of a biopharmaceutical, enhance the need for efficient purification methods. Liquid chromatography provide high level of purity required for human use, increases productivity and has therfore become the method of choice for purification of biopharmaceuticals.

Purification of mAbs can be achieved by a number of chromatographic methods, Protein A and Protein G affinity chromatography being especially powerful enabling high product purity with single chromatographic step.

Human plasma is a rich and readily accessible source for the detection of diagnostic markers and therapeutic targets for various human diseases. These are usually proteins that are present in human plasma in extremely low concentrations and are often masked by the high abundance proteins like immunoglobulin G (IgG) and human serum albumin (HSA), which represent over 75 % of all proteins. In order to enable the detection of potential biomarkers, IgG and HSA should be efficiently removed from the starting sample. In this work an affinity and a pseudoaffinity chromatographic column, used for an efficient removal of IgG and HSA from human plasma, were thoroughly characterized. A CIM monolithic column bearing Protein G ligands was
used for the removal of IgG, and a column bearing an anti-HSA dye was used for the depletion of HSA.

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.

By using a combination of two CIM® tube monolithic columns, OH and DEAE chemistry, we were able to successfully purify plasmid DNA from bacterial culture without using RNase. Purified plasmid DNA is very pure, since common contaminants, such as proteins, genomic DNA, endotoxins and RNA were under the detection limit. The scale up units produced according to cGMP standard are already used for the purification of plasmid DNA for gene therapy purposes on industrial scale.

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.

Tissue plasminogen activator (t-PA) is serine protease which converts plasminogen into plas-min dissolving the major component of blood clots, fibrin. So, it can be extremely useful in clinical practice to help curing of heart attack victims. The most available way protein producing is genetic engineering where separation and purification of goal protein are one of the important steps in protein producing process.

Recently developed High performance monolithic disk chromatography, HPMDC, seems to be a very attractive way for study quantitative affinity parameters of recombinant proteins with different ligands as well as for protein separations and purifications. High process speed prevents the denatura-tion due to temperature and solvents influence. The better mass transfer mechanism (convection rather than diffusion) allows to consider only the biospecific reaction as time limiting.

It is known that plasminogen, which is the natural substratum for t-PA, can be successfully used as affinity ligand to separate t-PA from cellular media. However, the use of synthetic ligands for affinity chromatography is more preferable due to their higher stability and lower total cost.

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.

Plasmids are episomes that have been recognized in few eukaryotic and most prokaryotic species. Some plasmids are excellent genetic vectors and they have been widely used in gene manipulation and recombinant DNA technology for a long time. In recent years plasmids were intensively used for gene therapy purposes (1). Most often purification starts with the cells harvest followed by alkaline lysis step in which ribonuclease A (RNase) is typically used. After that, plasmid DNA can be precipitated and used directly or can be further purified by different methods (2). Currently, several chromatographic methods, such as ion-exchange, size exclusion, affinity, and hydrophobic chromatography, have been demonstrated in plasmid purification (3). Until now a limited number of small scale purification methods without use of RNase were published. Convective Interaction Media CIM® is a monolithic chromatographic support for which has been shown that is very efficient for the separation of large molecules, such as proteins, DNA and viruses (4).

Plasmids are episomes that have been recognized in few eukaryotic and most prokaryotic species. Some plasmids are excellent genetic vectors and they have been widely used in gene manipulation and recombinant DNA technology for a long time. In recent years plasmids were intensively used for gene therapy purposes (1).Most often purification starts with the cells harvest followed by alkaline lysis step in which ribonucleaseA (RNase) is typically used. After that plasmid DNA can be precipitated and used directly or can be further purified by different methods (2).Currently, several chromatographic methods, such as ion-exchange, size exclusion, affinity, and hydrophobic chromatography, have been demonstrated in plasmid purification (3). Until now a limited number of small scale purification methods without use of RNase were published. Convective Interaction Media CIM®is a monolithic chromatographic support for which has been shown that is very efficient for the separation of large molecules, such as proteins, DNA and viruses (4).

The only four drugs approved for the clinical treatment of Alzheimer’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 acetyicholinesterase (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 il] we reported the immobilisation of AChE on a silica based chromatographic column (50 x 4.6 mm I.D.) The yield of immobilization and the stability of the AChE—IMEN were considered satisfactory, hut 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 min I.D.).

CIMa (Convective Interaction Media) monolithic supports (Bia Separations, Ljubljana) 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 CIM® disk with immobilised human recombinant acetylcholinesterase (HuAChECIM€ Disk) was developed. The activity of immobilised enzyme, the long term stability and reproducibility were tested. HuAChECIM disk was applied as an immobilised enzyme micro-reactor (micro-IMER) in on-line HPLC system for inhibitory potency determination of known AChE inhibitors.

The progress in gene-therapy and DNA vaccination leads to a growing demand of therapeutic applicable plasmid DNA (pDNA). To guarantee the supply for the clinical trials and finally for the market new pDNA production processes, which meet all regulatory requirements, have to be developed. Conventional small scale techniques can not easily be transferred to the manufacturing scale (technical reasons and safety considerations). We developed a generic large scale process for highly purified plasmids “free” of bacterial contaminants which works without enzymes, detergents (except SDS during the cell lysis) and organic solvents.