Determining the concentration of viruses is a crucial step in any production process. The most commonly used methods for virus quantification are either based on the infectivity of the virus (plaque assay, TCID50) determination of their genomic material (qPCR), or protein content (SRID, ELISA) and are very cumbersome and time consuming. HPLC analytical methods represent a fast alternative to these assays since they provide information on the virus content and purity in a matter of minutes. Due to the structural properties of the monolithic supports, monolithic analytical columns offer a great advantage over particle based HPLC columns in terms of time and their ability to separate large biomolecules, like viruses, VLPs, pDNA.
In this poster the performance of the CIMac™ Adeno Analytical Column – a monolith based anion exchange column, designed for fast and reproducible analyses of adenoviruses was evaluated. CIMac Adeno column can be used for designing a fast finger printing method that is applicable for monitoring the DSP production process of adenoviruses. Once the basic analytical parameters like linearity and sensitivity are determined using a purified adenoviral standard, the metod can be applied for quantitative determination of adenoviruses.
Enrichment of phosphopeptides prior to LC-MS analysis is a crucial sample preparation step because of their low stoichiometry in biological sample, longer retention on reversed phase columns, and lower ionization efficiency compared to non-phosphorylated peptides .The use of metal oxides, most prominently of TiO2 enabled efficient and relatively simple phosphopeptide-enrichment. In this study a new monolithic column from BIA Separations containing immobilized TiO2-nanoparticles was tested for its ability to enrich phosphopeptides. The TiO2-column was also tested for possible carryover originating from biological samples. In conclusion, tested monolithic TiO2 columns show significant binding ability for phosphopeptides and are considered as suitable for phosphopeptide enrichment.
The challenge of efficient purification of gene therapy vectors
• The most commonly used gene transfer vectors are adenoviruses, lentiviruses, adeno-associated viruses, retroviruses, vaccinia viruses, and pDNA
• Due to their large size and sensitivity to pH, temperature and shear stress, purification is challenging and time-consuming
• A fast and efficient downstream processing purification method is required to isolate sufficient amounts of vectors with the final purity and state that conforms to stringent regulatory demands.
Solution: Convective Interaction Media Monoliths
• Convective interaction media (CIM) monolith chromatography
• Functionalised polydimethacrylate (QA, DEAE, OH, SO3)
• Precisely defined pore sizes
• Radial flow of solute
• Convective mass transfer
Challenges in monitoring the quality of vaccine production
• Process Analytical Technology (PAT) ensures process reproducibility in bioprocessing
• A mechanism to design, analyze and control pharmaceutical manufacturing processes through the measurement of critical process parameters (CPP) which affect product quality attributes (CQA)
• Initiated by the FDA as part of the 21st Century GMP initiative in 2001 with the goal of increasing productivity
• Application of PAT in vaccine development and manufacturing is challenging due to the sample complexity and batch-to-batch variability.
• During the development of an up- and/or down-stream process of the target biomolecule, a fast, accurate and reliable analytical method is requried for determining the quantity and purity of the product intended for human use
Solution: Convective Interaction Media Monoliths
• Monoliths are chromatography media cast as a single block, inserted into a housing
• Highly inter-connected network of channels (1-2 μm) containing functionalised binding sites for large biomolecules (viruses, VLPs, pDNA, antibodies)
• Performance unaffected by increasing the flow rate or molecular size
A monolith is a stationary phase made of single piece of porous material. Unlike conventional particle-shaped chromatographic supports, the pores of the monolith are interconnected and form a network of channels with diameters ranging around 1500 nm. The binding sites in these channels are highly accessible for target molecules and since the predominant mass transfer depends on convection rather than diffusion, the dynamic binding capacity is flow independent. These characteristics make the monolithic supports suitable for fast separation and purification of large biomolecules such as proteins, DNA and viruses, which sometimes exceed 200 nm in size and thus have low diffusion constants.
In this work we tried to quantify influenza A virus using an analytical CIM monolith column. First a screening of available CIM stationary phases was performed in order to establish the optimal stationary phase for the binding of the virus. The effect of the mobile phase composition and pH on the recovery and peak shape of the virus was investigated. Linearity was examined. The amount of virus in the flow-through and elution fractions was determined with the haemagglutination assay and the purity of the fractions with SDS PAGE. All experiments were performed with an inactivated Influenza A/Wisconsin PZC whole virus sample that was produced in eggs.
There are two different designs of chromatographic columns concerning the flow profile. Most of today's HPLC columns belong to the group of so-called axial mode operating columns, while the radial ones with a radial flow pattern are more rare. Which type performs better depends on the particular case but it seems that the radial operating columns are attracting interest since they exhibit some beneficial features. One of the main problems of radial operating chromatographic columns is the changing of a mobile phase linear velocity over the chromatographic bed. Because of that, matrix efficiency for porous particulate supports varies by its position within the bed, and overall performance is more difficult to predict.
This problem is not present when the monolithic supports are used, since it was demonstrated that their chromatographic properties are flow unaffected even at the extreme linear velocities. This was confirmed also for the radial operating mode.
The monolith and radial flow housing were designed for extremely high flow rates, up to 70 CV/min, which is the range of the flow rates applied on membranes. This was achieved by proper monolith dimensions with the height of 55 mm, inner diameter of 6.0 mm and thickness of only 4.5 mm.
Recombinant Adenovirus (rAd) is commonly used for vaccination and gene transfer for cancer applications. This vector is widely used in phase I/II clinical trials. Therefore we believe that upstream and downstream processes should be improved.
We developed a production manufacturing process for rAd serotype 5 n HEK293 grown into disposable fixed-bed iCELLis™ bioreactors (ATMI LifeSciences). The purification process was reduced to one single chromatography step using the Convective Interaction Media, anion exchanger (CIM ® QA monolithic column, Bia Separations).
Briefly, rAd particles were extracted from cells using Triton X-100, depth filtered to discard cell debris, captured and purified out on CIM ® QA. The shallow gradient used for the elution of the vector allowed the separation of different rAd particles populations more or less enriched in full particles. A final step based on Tangential Flow Filtration (TFF) in hollow fibers allowed the removal of remaining impurities and the formulation of the vector batch.
In addition, we developed an analytical method on CIMac™ QA analytical column (Bia Separations) to characterize the different steps of the process, and to track the differences linked to the production runs to increase the robustness of the process. This method provided elution profiles for each step as well as titer of the purified rAd in the final step.
The rAd was produced in an iCELLis™ nano fixed-bed bioreactor (0.5-5.3 m2), purified in a 8mL CIM ® QA monolithic column, scaled up in a medium-scale size 80mL column. We are currently extending the rAd production in a 133m2 iCELLis I000™ bioreactor with a purification step using a 8L CIM® QA monolithic column to purify out up to 1x1015 vector particles.
Monolithic supports represent a new generation of chromatographic media. Due to their large inner channel diameters and enhanced mass transfer characteristics, methacrylate monoliths (CIM® monolithic columns) offer efficient and fast separation of large biomolecules like pDNA, viruses and monoclonal antibodies. High binding capacity for viral particles, good product recovery and resolution are also benefits of monoliths. During loading of MDCK cell-derived H1N1 inactivated influenza virus particles onto monolithic columns, increased back pressure is sometimes observed. This is especially an issue if a large amount of virus needs to be purified since the back pressure depends on the loading volume. The goal of this work was to determine the factors contributing to this effect. We tried to prevent the increased back pressure by treating virus harvests with different precolumn phases (LRATM - Lipid removal agent, Amberlite® XAD 7HP, epoxy monolithic column) and by filtering the virus material before loading it onto the column. To compare different pre-treatment strategies of the virus material the dynamic binding capacity of CIMac QA for virus was first determined, resulting in approximately 1x1013 virus particles per ml. Than loadings of the pre-treated virus material at 75% of the column capacity were performed and mass balances for the virus, DNA and proteins were investigated. Another goal of this work was to find a good regeneration strategy for the columns where increased back pressure occurred. For this reason different regeneration procedures using lipase, benzonase, 2-propanol and NaOH treatment were tested on the columns with increased back pressure.
Traditional waste water treatment usually does not remove or inactivate all of the potentially pathogen microorganisms present in the waste water. This is especially true for enteric viruses that are introduced into the environment through the discharge of effluent from waste water treatment plants - WWTP (Simmons et al, 2011). Although discharged concentrations of viruses are low they can still lead to infection. For some enteric viruses ingestion of only 10 - 100 virus particles is enough to initiate the disease, what calls for very sensitive detection methods. It has been previously shown that CIM-quaternary amine (QA) monolithic supports are a good tool for concentration of viruses in water (Gutierrez-Aguirre et al, 2011). Here we go one step further and evaluate CIM monoliths not just for concentration of enteric viruses but also for their removal from effluent waters.
Potato spindle tuber viroid (PSTVd) is the causal agent of a number of agriculturally important diseases. It is a single-stranded, circular and uncapsidated RNA molecule with 359 nucleotides and no coding capacity. Because of its complex secondary/tertiary structure it is very stable ex vivo and it is easily transmitted mechanically by contaminated hands, tools, machinery, etc. In this work, we describe the development and optimization of a method for concentrating PSTVd using CIM monolithic supports.
Objective – Influenza VLP
• Complex structure
• Different protein components
• Host cell derived lipid membrane
• ESAT6 epitope of M. tuberculosis engineered into influenza hemagglutinin [1,2]
• Optimal vaccine candidates
• Induce strong immune response 
• Contain no genetic information
In the last few years pharmacology has made a big step towards the new type of drugs, called biological drugs. Popularity and market for biological drugs grew exponentially, so did the need for fast and inexpensive purification. Classic liquid chromatography columns were unable to separate biological compounds in industrial quantities, therefore the scientists were looking for alternatives. One of them are monolithic materials. Monolithic materials, especially methacrylate monoliths, are becoming more and more popular in separation processes due to their fast separations, low pressure drop and mechanical stability.
In the context of preparing new columns and improving existing ones, we need to know every single chemical as well as mechanical property of our monolithic material. Here we present some key data and interesting correlations between mechanical and structural properties of GMA-co-EDMA porous monolith. In the first paragraph we compare nonmodified and DEAE modified monoliths with different average pore size and porosity, regarding to their compression and tension properties. The second paragraph deals with the impact of these parameters on the permeability of the column during separation.
Commonly, epoxide-based monoliths used as porous supports in affinity chromatography are synthesized from glycidyl methacrylate (GMA) and ethylene glycol dimethacrylate (EDMA) by free radical polymerization.
We prepared an epoxide-based monolith by self polymerization of polyglycidyl ethers where the epoxy groups serve as functional groups for the polymerization reaction as well as for the immobilization of the ligand.
Monolith technology has been employed in chromatography for a variety of applications using diverse substrates. The development of different column chemistries has led to the Thermo Scientific ProSwift line of monolith columns for analytical protein separation by ion exchange and reversed phase. Separation of biomolecules can be achieved at elevated linear velocities with minimal loss of resolution. Columns are designed to withstand extreme pH cleaning, desired for sterilization. The backbone and functionalization are optimized for high mass loading for small-scale preparative applications, the ideal first dimension separation of crude biological samples. Combined with increased sensitivity of a 1 mm format, detection of proteins of very low copy number in a crude samples is achievable.
We discuss here the ability to produce highly-reproducible columns with excellent stability as well as characteristics required for fast small-scale preparative analysis. HPLC column selection is a challenging task, specifically where the mixture contents is somewhat unknown. Many factors influence the choice of column used; chemistry, robustness, and reproducibility. For quality assurance, columns should be chosen that are reproducible both run to run and batch to batch. To prevent cross-contamination between samples, carryover and sterilization should be considered. For semi-prep, a combination of high mass loading and good resolution enable increased purity of peak fractions. Format and operational flow rate should be considered with respect to multidimensional analysis.
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.
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.
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.
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.
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.
Analysis of a large number of samples requires chromatographic support that not only enables fast separation and purification of a target biomolecule from a complex matrix but also support an automation of a process. The methacrylate 96-well monolithic plate format enables both. 96-well monolithic plate reduces experimental time because it allows fast and efficient evaluation of parameters for binding and elution conditions. This format is a quicker alternative to several consecutive tests on chromatographic column.