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2006

Gene therapy has already shown some great results in treatment and cure of some monogene diseases, such as diabetes. While the use of genetically modified viruses raises safety concerns, synthetic formulations of genes inserted in plasmids are regarded as safer. At present, most clinical trials involve plasmids smaller than 10 kb. However, the concern that regulation of the functioning of the gene is ensured together with the expectation of the progression of gene therapy to multigene disfunctions, like cancer or complex nevrodegenerative disfunctions (Alzheimer disease), will require the production of larger plasmids [1].

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2005

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).

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2004

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.

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2003

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.

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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).

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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).

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2002

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.

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Most commonly plasmids are manufactured by fermentation of E. coli. In the cells several isoforms of the plasmid are generated: supercoiled (sc), open circular (oc) and linear as well as dimeric forms. After alkaline lysis plasmids are accompanied in solution by genomic DNA (gDNA), RNA, proteins and other cell compounds [1]. In addition to these impurities, the plasmid isoforms have to be separated efficiently in order to get a final product containing > 95 % of ccc form [2]. Chromatographic resins used in biotechnology are usually designed for the separation of polypeptides, providing only low capacity for polynucleotides (< 1 mg/mL).

In this work we present an optimised purification step for large scale purification of therapeutic applicable pDNA, based on an alternative chromatography resin (CIM Convective Interaction Media®).

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2000

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 purification of plasmid DNA as well as for the concentration of viruses. Plasmid DNAs are circular duplex DNA molecules that are maintained stable as episomal genetic information within bacteria. They play an important role in gene technology - they are used for applications such as transformation, sequencing, transfection studies, etc. These applications require satisfactory purity of used plasmid DNA. For purification of plasmid DNA from Escherichia coli, monolithic units as anion-exchangers (CIM® DEAE and QA disks) were used. Separation of RNA from DNA as well as concentration of plasmid DNA were performed on the same disks.

All the methods for concentration of viruses, in general, are expensive, time-consuming and they are frequently not very successful. Therefore an attempt to bind viruses on an anion exchanger (CIM® DEAE disk) and elute bound virions in small volume (concentration) was done. As a model virus, measles was chosen. Using CIM® DEAE disk concentration of the measles viruses was successfully performed in less than 10 minutes.

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Production and down-stream 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 purification of plasmid DNA as well as for the concentration of viruses.

Plasmid DNAs are circular duplex DNA molecules that are maintained stable as episomal genetic information within bacteria. They play an important role in gene technology - they are used for applications such as transformation, sequencing, transfection studies, etc. These applications require satisfactory purity of used plasmid DNA. For purification of plasmid DNA from Escherichia coli, monolithic units as anion-exchangers (CIM® DEAE and QA disks) were used. Separation of RNA from DNA as well as concentration of plasmid DNA were performed on the same disks.

All the methods for concentration of viruses, in general, are expensive, time-consuming and they are frequently not very successful. Therefore an attempt to bind viruses on an anion exchanger (CIM® DEAE disk) and elute bound virions in small volume (concentration) was done. As a model virus, measles was chosen. Using CIM® DEAE disk concentration of the measles viruses was successfully performed in less than 10 minutes.

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1999

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.

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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.

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