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2012

There is an increasing demand for highly purified immunoglobulin G since they have found wide range of potential application in immunodiagnostics and immunotherapy.

Human IgG (hIgG) consists of four subclasses (IgG1, IgG2, IgG3 and IgG4) that show differences in some of their physicochemical characterictics and biological properties.

The present research project aims to separate subclasses of hIgG using monolithic stationary phase by SMB technology.

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2011

Over the last two decades,the potential of virus-based biopharmaceuticals for application in gene therapy and vaccination brought new challenges in bioprocess development. Particularly, the downstream processing (DSP) of enveloped viruses shifted from bench-scale towards robust, scalable and cost-effective strategies to produce clinical grade viralvectors. Lenti viralvectors(LVs) hold great potential in gene therapy due to their ability to transduce non dividing cells and their capacity to sustain long-term transgene expression in several target cells, invitro and invivo1. However, despite significant progress, the quality of LV preparations, the purification and the concentration of high titers of these vectors is still cumbersome and costly. In this work, disposable membrane technologies, involving microfiltration, anion-exchange chromatography (AEXc) and a final ultrafiltration step, were the basis for the development of an optimized purification process for LV.

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2010

Over the last years, lentiviral vectors have emerged as valuable tools for transgene delivery because of their ability to transduce non-dividing cells and their capacity to sustain long-term transgene expression in target cells in vitro and in vivo. However, despite significant progress, the purification and concentration of high titer and high quality vector stocks is still time-consuming and scale-limited. We aimed to develop a simple and cost-effective capture purification step capable of separating the produced lentiviral vectors from the preparation originally containing a load of recombinant baculoviruses used to transiently transfect 293T producer cells. Even though recombinant baculoviruses do not present major safety concerns1, the final product (purified lentiviral vectors) should be pure enough to be tested in (pre-)clinical studies2. A capture step has been preliminarily evaluated. Both lentiviruses and baculoviruses are enveloped, thus per se prone to degradation through processing. Furthermore, both show overall surface negative charges at physiological pH3,4. As such, our rationale was to use an anion-exchange bind-elute step with enough resolution to separate the two viruses upon elution. It was likely that the difference in the overall electrostatic charges of the two viruses can be used to our advantage if a sufficiently extended salt elution gradient is used.

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Biomanufacturing of antibodies, therapeutic proteins and vaccines or gene delivery vectors (either DNA or virus based) is a very complicated process where many things can go wrong. This is even more pronounced as the target biomolecules are extremely susceptible to the environmental conditions both during cultivation (upstream processing) as well as during isolation and purification (downstream processing). One can always doubt whether we have enough information about our complex biomolecule samples to consistently develop a safe product by running a robust and efficient purification bioprocess.

By using and understanding novel technologies one can design new process analytic technology (PAT) initiatives to overcome some of these problems. Here, we present novel monolithic analytical columns — CIMac columns — that can bridge this gap. In the first example, CIMac columns were applied for monitoring the purification process of virus like particles (VLP) which are used for production of vaccines and as delivery systems in gene therapy. In the second example, the monolithic analytical columns were also applied for monitoring the fermentation process of bacteriophages.

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Avir Green Hills Biotechnology is developing innovative seasonal and pandemic influenza vaccines based on the deletion of the NS1 gene (del NS1 vaccine).The vaccine is replication-defective and applied intranasally. Recently,clinical phase I studies for H1N1 monovalent vaccine and H5N1 avian influenza vaccine were completed. Both were confirmed to be safe and immunogenic for humans. A production and purification process, which was successfully employed for the pilot-scale production of H1N1 and H5N1 influenza A vaccine virus, will be presented and compared to standard ultracentrifugation method. Details on obtained life virus yields as well as impurity removal will be given. The vaccine virus is produced in static cell culture using Vero (African Green monkey kidney) cells. After clarification the vaccine virus bulk is purified using the same(chromatography-based) scheme for all different subtypes: Concentration by tangential ultrafiltration, AEX chromatography using a CIM QA monolith, and an SEC polishing step allowing for buffer exchange. This purification scheme guarantees the thorough depletion of host cell DNA and total protein. For the ultracentrifugation approach chromatographic steps were replaced by a gradient ultracentrifugation step, comparison data are shown. In addition, an HPLC method for quantifying influenza virus in the vaccine with the use of CIM monolithic columns will be presented and the results will be compared with haemagglutination method.

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Rabies virus cause acute encephalitis. It is widely distributed around the globe and more than 55,000 people perish yearly and an additional 10 million post-exposure treatment are reported. About 95% of human deaths occur in Asia and Africa. In countries that are endemic to rabies an immense need for cost-effective large-scale production of the Rabies vaccine occurs. Achieving required quality is challenging because majority of rabies vaccines are produced in Vero cells. This makes Rabies vaccine difficult to manufacture due to low titre of vaccine with lots of residual cellular DNA and serum proteins.

The objective of this work was to improve purity of rabies vaccine regarding residual DNA presence. Different mobile phases with different pH values were explored. Moreover, to develop cost-efficient downstream process for Rabies vaccine, monolith-based purification step was performed in different stages of downstream processing. Chromatographical fractions were analyzed for efficiency of DNA removal. In addition, recovery of Rabies vaccine was monitored. Finally, knowing the optimal conditions, a step-wise gradient was used for purification of larger amount of Rabies vaccine.

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Protein L binds certain types of kappa light chains containing Fv and Fab fragments prepared from antibodies. In the case of IgG's the strong binding affinity refers only to human, mouse and rat species. It offers an advantage over Protein A and G as it binds to kappa light chains regardless of heavy chain subclass and can therefore binds up to 60% of IgG antibodies from human serum sample.

The main goal of our work was the preparation and characterization of CIM Protein L disks. First, Protein L disks with different densities of Protein L on the support were prepared in order to define the dependance of the IgG capacity on the amount of the bound Protein L. Further on, the method of characterization of Protein L disk using IgG was developed. In the end, the stability of the developed CIM Protein L disks in different solutions was tested in order to define the operating and storage conditions.

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2009

Adeno-associated virus (AAV) vectors continue to hold immense promise as gene transfer vehicles for a variety of gene therapy applications. Numerous pre-clinical and human clinical studies have been undertaken with rAAV, employing several of the identified serotypes to leverage their differing tissue tropism to correct a broad spectrum of genetic diseases. Despite the advantageous characteristics of rAAV and the extensive research into pre-clinical applications, production and purification scale-up continues to limit recombinant AAV (rAAV) use in large clinical trials that require even moderate vector doses. Therefore, AGTC has developed a high-yielding, scalable rAAV production system in suspension BHK cells that employs co-infection with two hybrid rHSV-rAAV vectors to provide all cis and trans-acting rAAV elements and the requisite helper virus functions for rAAV manufacturing.

In contrast to traditional, resin-based chromatography methods for rAAV purification, we have developed a two-step chromatographic process that employs a novel anion exchange Convective Interaction Media® monolithic column (CIM® monolith, BIA Separations) capture step followed by affinity chromatography (AVB Sepharose™, GE Healthcare), which yields rAAV vector stocks in very high purity. This scalable process allows significant reduction in processing time due to the high capture step dynamic binding capacity, flow rates and resolution. The resulting overall chromatography recovery compares favorably to our first and second generation processes which used three-step, resin-based column chromatography and membrane-based two step chromatography, respectively.

The CIM QA-AVB process was scaled to accommodate 10 L suspension production runs and was successful at recovering as much as 1 × 1015 purified AAV1 DRP in a single day. The process is highly reproducible and it is applicable for the purification of multiple AAV serotypes with over 95% purity and overall yield of > 30%.

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Avir Green Hills Biotechnology is developing innovative seasonal and pandemic influenza vaccines based on the deletion of the NS1 gene (delNS1 vaccine). The vaccine is replication-defective and applied intranasally. Currently, an H1N1 monovalent vaccine is being tested in a clinical phase I study, with an H5N1 avian influenza vaccine soon to be initiated. A production and purification process, which was successfully employed for the pilot-scale production of H1N1 and H5N1 influenza A vaccine virus, will be presented. Data on the selection of chromatographic media, relevant to eliminate downstream purification bottlenecks will also be discussed.

Details on obtained virus yields as well as impurity removal will be given. The vaccine virus is produced in static cell culture using Vero (African Green monkey kidney) cells. After clarification the vaccine virus bulk is purified using the same scheme for all different subtypes: Concentration by tangential ultra filtration, AEX chromatography using a CIM QA monolith, and an SEC polishing step allowing for buffer exchange. This purification scheme guarantees the thorough depletion of host cell DNA and total protein. In addition, an HPLC method for quantifying influenza virus in the vaccine with the use of CIM monolithic columns will be presented and the results will be compared with haemagglutination method.

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In an average influenza season, we face hundreds of thousands of influenza cases. Up to 50,000 deaths per year can be ascribed to influenza epidemics. Nevertheless, this is relatively harmless compared to the current, permanent threat of a worldwide pandemic caused by avian influenza.

AVIR Green Hills Biotechnology is developing innovative seasonal and pandemic influenza vaccines based on the deletion of the NS1 gene (ΔNS1 vaccine) [1]. The vaccine is replication-defective and applied intranasally. Currently, an H1N1 monovalent vaccine is being tested in a clinical phase I study and clinical trials with H5N1 avian influenza vaccine will follow in fall 2007.

A production process, which was successfully employed for the pilot-scale production of H1N1 and H5N1 influenza A virus is presented here. The upstream process is performed according to the specific requirements of the respective influenza subtypes. Currently, 15 L batches are produced in cell factories using Vero (African green monkey kidney) cells. The vaccine bulk is purified by using the very same scheme for all different subtypes. For purification, the cell culture supernatant is clarified by centrifugation and the virus is concentrated by tangential ultra filtration. The concentrated virus is subsequently purified in two chromatographic steps which were co-developed with BIA Separations d.o.o.: First, an anion exchange monolithic column is used. This is followed by size exclusion chromatography for polishing and buffer exchange.

This purification scheme guarantees the thorough depletion of host cell DNA and total protein, and recovers at least 25% of the infectious virus.

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2008

During last decades different methods for purification of influenza viruses have been described. Most of these methods were developed for purification of egg derived influenza virus which is still the main production system for influenza vaccine viruses. Since cell culture based technology is gaining more and more importance, the need for alternative, efficient and scaleable purification methods has risen. Chromatography is becoming a method of choice for purification of viruses. Relevance of this technique was recently demonstrated also for influenza viruses. Methacrylate monoliths are characterized by large channel diameter, high surface accessibility and convective mass transport. As a consequence they have high binding capacity for large molecules, enable high flow rates at low pressure drop and therefore increase productivity. Recently it has been proven that methacrylate monolithic columns can also be used for purification and concentration of different viruses.

It was the purpose of this work to explore possibilities for purification of influenza viruses on ion exchange methacrylate monoliths. Different subtypes of influenza A and influenza B virus were tested employing various ion exhange monolithic columns.

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During the last decade important developments in molecular medicine and adenoviral vector design have been achieved, leading to an increased use of adenoviral vectors in clinical gene therapy protocols. One of the main advantages of the adenovirus is their ability to replicate at high titres in permisive cell lines. The availability of large quantities of adenoviral vector preparations is recognized as an important limitation to pre-clinical and clinical studies. Consequently there is a global focus on large scale production of adenoviral vectors, providing high titres combined with fast, effective and reliable purification methods.

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2007

A number of IgM monoclonal antibodies are currently in development for treatment of autoimmune disease, infectious disease, and cancer. Growing interest in these molecules has created a need for an accurate, rapid, simple analytical method to measure IgM levels in cell culture supernatants, and to document the distribution of IgM and protein contaminants in chromatography fractions. High performance protein A columns are used for this application with IgG monoclonals, but IgMs are easily denatured by the harsh conditions required for elution of most affinity ligands. However, IgM monoclonals often exhibit strong retention on either cation exchangers, or anion exchangers, or both, making ion exchange chromatography a potential candidate for this application.

The large size of IgMs makes them a major challenge to particle-based chromatography media. Pentameric IgM has a mass of about 0.96 Md, and hexameric IgM about 1.15 Md. Their diffusion constants are about 2.5 x10-7 cm2/sec, about twice as slow as IgG. Since particle-based chromatography media mostly rely on diffusion for mass transport, both resolution and capacity are im- Figure 4 illustrates a modified anion exchange gradient configuration for monitoring the amount of IgM expressed in cell culture supernatants. A wash step was introduced to better remove con- paired, and increasingly so at higher flow rates.

Monolithic ion exchangers are characterized by an interconnected system of channels with diameters ranging 0.5 to 2.0 microns. This pore architecture supports convective flow, which conserves high resolution at high flow rates.[1] The lack of a void volume removes the major source of dispersion in chromatographic systems. This contributes to sharper peaks, which improves both resolution and sensitivity. Capacity is also conserved at high flow rates. This permits use of a microcolumn format that minimizes assay time and buffer consumption. This combination of features should make monoliths effective analytical tools for IgM.

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IgM can be used for several purposes such as early detection of certain diseases or, when labelled, localized cancer tumours. For their purification commonly chromatography is used. Methods for purifying such big molecules (M.w. around 950 kDa) are usually long and time consuming since these molecules have extremely low mobility therefore mass transfer between mobile and stationary phases is significantly reduced. When purified using affinity mode, serious decrease in IgM activity can occur because of long exposure to low pH in which they are unstable. Furthermore, because of their size, the IgM capacity of convenctional resins is rather low. CIM monoliths were already successfully used for fast separation of large molecules. In this work we tested applicability of anion-exchange CIM monolithic columns for preparation of IgM.

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2005

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.

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The rapidly growing interest in the area of proteomics induces intensive efforts to find robust, automated and sensitive high-throughput analytical tools. In this context, the concept of solid-phase digestion (ex. trypsin immobilization on a solid support[1]) has received great attention in the last years. Trypsin (EC 3.4.21.4) has been covalently immobilized on different monolithic supports and resulting bioreactors used as immobilized enzyme reactors (IMERs) for on-line digestion, peptide separation and peptide mapping. Bioreactors efficiencies were evaluated with different recombinant proteins after on-line digestion. The technique used for the separation and identification of peptides was high-performance liquid chromatography coupled with electrospray ionisation tandem mass spectrometry (LC-ESI-MS/MS).

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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.

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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.

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Viruses have proven to be useful vectors for gene therapy purposes. As therapeutics for human use they must be pure and contaminant free. Traditionally, viruses are purified by complicated and time consuming methods such as CsCl density gradient centrifugation or similar. In recent years liquid chromatography has became interesting method for virus purification. It provides high level of purity required for human use and increases productivity. Traditional chromatographic supports were mostly designed for purification of proteins and as such are commonly inappropriate for viruses. Alternative to traditional chromatographic support are methacrylate monoliths (CIM monoliths), characterized by large channel diameter, high surface accessibility and convective mass transport.

The aim of this work was to characterize CIM supports for separation and possible purification of a model virus Tomato mosaic virus (ToMV) from crude plant material.

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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.

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