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2022

First chromatographic step in industrial platform using monoliths is a capture step, where rAAV is selectively bound to strong cation exchanger (SO3) in acidic pH conditions (1,2). In this step majority of host cell contaminants are removed and rAAV is strongly bound to the matrix. Productivity of the step is therefore strongly influenced by the dynamic binding capacity (DBC). DBC is dependent on the sample preparation prior to chromatography and the availability of the binding sites at the chromatographic matrix.

Due to increasing demand for rAAV quantity and quality for clinical manufacturing, large volumes of upstream produced material are being purified on industrial scale. At this point, rAAV capture is a first chromatographic step to be optimized for optimal selection of the chromatographic parameters. Doing this, SO3 monolithic columns can be used with their full potential. To reduce the development time using multi-factor screening and increase comparability during downstream process development, CIM® SO3 monolithic 96-well plates were introduced to Sartorius BIA Separations portfolio. Obtained results on small scale can be applied to the CIMmultus™ line, which is scalable to large industrial volume.

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CIMac™ pDNA Analytical Column is powerful tool for pDNA quantification for in-process control or in a QC laboratory. The column can separate pDNA isoforms from each-other and from RNA impurities. Monitoring of pDNA production leads to a controlled and robust process, and can result in consistent high quality of the final product.

Optimised methods are a key component of a well-functioning analytical system, sometimes requiring time-consuming method development and steep learning curves. The following two methods described in this quick start guide can provide a starting point for pDNA purity and isoform analysis.

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2021

Optimized analytical methods are key components of a well-functioning analytical system, while method development usually comes with a time-consuming learning curve and optimization.

PATfix pDNA analytics platform, designed for in-process control of linear pDNA production, enables monitoring of pDNA linearization progression, as shown in Figure 1. Fully optimized and validated analytical methods, as well as guidelines for buffer and sample preparation come as part of the PATfix system, allowing users to focus on their specific application. In addition, the PATfix pDNA analytical package includes a pDNA calibration standard, which enables accurate quantification of the pDNA species of interest.

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2020

Miniaturised immobilised enzymatic reactors can be used for small scale digestion of proteins. There is need for such devices; small scale devices are used either for processing of analytical sample quantities, or as proof of concept before protein digestion at larger scale. This application note compares the performance of a flow through miniaturised immobilised enzymatic reactor (μIMER) with in-solution batch digestion of simple proteins and complex matrices. Automation of peptide analysis by coupled LC-MS is explored as an option to increase throughput. In the cases evaluated, the miniaturised immobilised enzymatic reactor offered comparative results to overnight in-solution digestion, within less than 10 minutes.


Pre-activated CIMmic™ monolithic columns with 100 μL bed volume were immobilised with trypsin from bovine pancreas. This small format allows coupling to HPLC for on-line protein digestion, as well as syringe (manual) operation of the IMER. Pre-treated samples (denatured, alkylated and ultra-filtered) are injected into the column, and the eluate (tryptic digests) are subjected to LC-ESI-MS-MS analysis for protein identification and post-translational modification (PTM) determination.

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2019

Polyclonal anti-HSA antibodies were immobilised on CIMmic™ HDZ (hydrazide chemistry, 100 μL bed volume), following an optimised protocol. This CIMmic™ α-HSA column was prepared to quantitatively remove human serum albumin (HSA), the most abundant plasma protein in humans, and obtain albumin-free samples which can be further processed.
The CIMmic™ α-HSA column is optimized to selectively bind and remove HSA from plasma; albumins from other sources are bound with low efficiency. HSA depletion is carried out in two steps: (i) a loading step in which the diluted and filtered plasma sample is loaded into the column, HSA is bound and HSA-depleted plasma is collected downstream of the column and (ii) a regeneration step in which the bound HSA is removed and the column is regenerated.

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Pre-activated CIMmic™ Monolithic Columns are used as a basis for preparation of small volume affinity chromatographic columns as well as enzyme reactors. Small bed volume and flexible design makes them a powerful tool for screening purposes and immobilization protocol optimizations. Range of covalently bound ligands is wide and includes diverse set of proteins, peptides, nucleotides and other affinity ligands. The covalent nature of the bond between the ligand and matrix reduces leaching and improves stability and reusability. Reaction conditions must cater to their specific physiochemical nature.


Successful preparation of an affinity column includes a decision on the appropriate matrix chemistry and determination of an optimal immobilization protocol. Presented case study explores the basics of a coupling protocol optimization using covalent immobilization of Recombinant Prokaryotic Lectins (RPL-Gal1) on CIMmic CDI-0.1 and CIMmic ALD-0.1 columns, as an example. Carboxy imidazole (CDI) and aldehyde (ALD) activated CIMmic™ columns are used for covalent immobilization of amine or thiol containing molecules.

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CIMmic™ Monolithic Columns combine the advantages of the CIM® stationary phase with a flexible design and the possibility to operate with syringe. Discs containing the stationary phase can be easily interchanged inside the custom designed housing. Pre-activated chemistries enable immobilisation of numerous ligands and can be used for preparation of affinity chromatographic columns or enzyme reactors. Their small bed volume is particularly suitable for screening purposes and to optimise immobilisation protocols due to economic usage of often expensive ligands.

Carboxy imidazole (CDI) monolithic chromatographic columns are used for covalent immobilisation of proteins, peptides and other amine or thiol containing molecules. The covalent nature of the carbamate bond between the ligand and matrix reduces leaching and improves stability and reusability.

An example described below shows the feasibility of CIMmic™ CDI-0.1 utilisation for covalent immobilisation of recombinant protein A (r-pA). Additionally the example was used for the evaluation of the reproducibility of CIMmic™ CDI columns. The dynamic binding capacity for human polyclonal immunoglobulin (IgG) was used as metric for comparison of the affinity columns.

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2018

Coupling trypsin enzyme onto chromatographic supports provides a platform to reuse the enzyme and automate the hydrolysis process. A monolithic chromatographic support, such as Convective Interaction Media (CIM®), enables mass transfer of molecules within its channels exclusively by convective flow. This results in enzymatic conversion which is not limited by diffusion, making CIM® monoliths ideal for the preparation of immobilised monolith enzymatic reactors (IMERs). Sartorius BIA Separations offers CIMac™ trypsin IMER with a bed volume of 0.1 mL as analytical platform for mass spectrometry (MS)-based proteomics. Larger volume IMERs (up to 80 mL) are available for industrial scale production of protein hydrolysates. The following example describes the enzymatic production of β-Lactoglobulin (β-Lg) hydrolysates using monoliths with 2 μm (N1) or 6 μm (N2) average channel diameter.

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Bottom-up proteomic approach based on tandem mass spectrometry (MS/MS) is a method of choice for identification and quantitation of proteins in the complex biological samples. Followed by quantitative analysis of a protein sample, this approach enables the identification of putative biomarkers for early pathology diagnostics and differentiation. The main challenges confronting this analysis are suppression of low-abundance ions and the limited dynamic range of MS/MS.
Affinity depletion of abundant proteins is an important stage in routine sample preparation prior to tandem mass spectrometry (MS/MS) analysis of biological samples. One such protein is Human Serum Albumin (HSA). In this study, polyclonal αHSA antibodies were immobilised onto a chromatography support to use as immunoaffinity-based column (CIMac™ HDZ -αHSA) for HSA depletion from embryo culture media for in vitro fertilization (IVF).

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As an alternative to conventional particle-packed columns for liquid chromatography, CIM® monolithic supports can be used.1-3 They are extremely permeable and allow very efficient mass transport at low back pressures and good separation efficiency at high flow rates. Consequently, the time of chromatographic separation can be shortened. Such characteristics are very valuable in speciation analysis where preservation of the integrity of individual chemical species of a given element is of crucial importance.4,5 CIM® monolithic disks can be placed together in one housing forming so-called conjoint liquid chromatography (CLC), which combines two different chromatographic modes in one step.
For better understanding of anticancer therapy with Pt-based chemotherapeutics, the quality of pharmaceutical formulations must be assured and the behaviour of the drugs studied by separation and detection of the intact drug and its individual biotransformation species in clinical samples at therapeutically relevant levels. To study the interactions of Pt-based chemotherapeutics with serum proteins, two-dimensional chromatographic separation of serum proteins was suggested, combining size-exclusion and CIM DEAE monolithic.6 Since this procedure is time consuming the potential of the use of CLC was investigated.

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2017

Human coronavirus OC43 (HCoV-OC43) is a frequent cause of respiratory tract illness, ranging from common cold to severe disease. The research on coronaviruses and medical application of coronaviral vectors/vaccines requires a quality material of high purity. Unfortunately, virus preparations are highly contaminated with cell debris and purification requires laborious, cost-ineffective procedures.
Here, we report a simple and efficient method for coronavirus concentration and purification by the example of HCoV-OC43. To achieve this, virus chromatography was performed on CIM QA monolithic columns (Sartorius BIA Separations), with immobilized positively charged quaternary amines. The quality of the obtained virus stock was assessed with SDS Page electrophoresis, followed by Western blot analysis. Finally, infectivity of recovered virus was evaluated by titration.

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Sample displacement chromatography exploits the different relative binding affinities of components in a sample mixture to achieve accummulation of a desired substance on the column before elution. In pharmaceutical applications, requirements for purity and efficacy of plasmid DNA (pDNA) as a therapeutic product are stringent. The separation of linear, supercoiled (sc) and open-circular (oc) pDNA isoforms has already been established on CIM® butyl (C4 HLD) monolithic columns at preprative scale. This process requires high concentration of ammonium sulphate for loading which increases the overall production requirements. Competing adsorption in sample displacement chromatography utilises the binding capacity of the chromatographic resin more efficiently and increases productivity of the chromatographic step.
This application note investigates three monolithic chromatographic supports with different hydrophobicities regarding their applicability for sample displacement of pDNA. CIMac™ C4 HLD (butyl, high ligand density) as a commercial product and pyridine and histamine as custom immobilised columns are compared.

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2016

Influenza vaccines are still predominantly produced in embryonated chicken eggs and the purification processes barely have changed during the years. There is a growing need for fast, efficient and economical vaccine production.
So far, monolithic supports have been used successfully in virus purification and concentration, as well as in the purification of virus-like particles (VLP) propagated in cell cultures.
Therefore, our aim was to prove the applicability of monoliths in purification of influenza virus A propagated in embryonated chicken eggs.

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Monoclonal antibody (mAb) charge variants have gained considerable attention in the biotechnology industry, due to their potential influence on stability and biological activity of the active pharmaceutical. Cation-exchange chromatography (CEX) is historically one of the typical approaches for mAb purification and characterization, especially charge variant analysis. We have proven the flow independent separation of mAb charge variants using CIMac COOH monolithic column in a pH gradient. In this way, a resolution comparable to classical CEX particulate-based analytical columns was achieved in only 6 min analysis time. Therefore a CIMac COOH column is a perfect choice for fast Process Analytical Control (PAT) of purified mAb samples.

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Plasmid DNA (pDNA) as a pharmaceutical product has stringent requirements of purity and efficacy and often one or more chromatographic steps are used in the downstream process. High ligand density butyl-modified chromatographic monolith (CIMmultus™ C4 HLD, part of CIMmultus™ HiP² Plasmid Process Pack™ 1-1, product number 100.0011-2) is currently used in a polishing step of a pDNA purification process (1), is mainly used for separation of supercoiled (sc) pDNA separation from open circular (oc) and linear pDNA isoforms as well as for removal of remaining gDNA and RNA.
This application note presents a comparison of two different polishing processes employing monoliths, namely bind-elute (BE) and the more recently described (2) sample displacement purification (SDP).

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Transferrin (Tf) is a glycoprotein that transports iron to cells and has two N-glycosylation sites in humans – at asparagine 432 and asparagine 630. Carbohydrate-deficient Tf, which lacks one or both N-glycans, is the most common marker for congenital disorders of glycosylation.1 Altered Tf glycosylation has also been reported in hepatocellular carcinoma2 and chronic alcohol consumption.3,4 High-throughput Tf purification and glycan characterisation methods are under extensive development in order to facilitate screening of glycosylation patterns for population, genetic and clinical studies.

This application note describes the development of an immunoaffinity purification method on a CIMac™ analytical column with immobilised anti-transferrin antibodies (@Tf) and the successful transfer of the method to the monolithic 96-well plate (CIM® @Tf-0.2 monolithic 96-well plate). The affinity purification method has been used for Tf isolation from human blood plasma followed by ultra-performance liquid chromatography (UPLC) analysis of Tf N-glycosylation.

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Downstream processing of viruses in virus vaccine or virus vector production accounts for up to 70% of the overall production costs. Immunoaffinity chromatography is a powerful purification technique due to its high specificity but is disadvantageous by the fact that the elution conditions are often detrimental for both the immobilized proteins and target antigens, especially viruses.
This application note describes the mumps virus purification using monolith-based immunoaffinity stationary phase and recently invented native elution of the bound viruses using amino acid solutions under physiological pH.
 

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CIMac™ r-Protein A Analytical Column is a short bed, high performance monolithic column. It is intended for fast, efficient, and reproducible qualitative and quantitative analyses of Immunoglobulin G (IgG) and suitable for use with HPLC and UPLC systems. Quantification of IgG is possible between 0.2 μg and 20 μg. Its small volume and short column length allow operation at high volumetric flow rates (up to 3 mL/min). The information about product quantity and purity is thus generated in just 1 minute! The column has an innovative symmetric design for bi-directional flow contributing to longer lifetime.

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The CIMacTM antibody immobilization platform enables an elegant immobilization of antibodies, which can be used as immunosorbents in specific diagnostic applications as well as in downstream processes. In this work we show the dependence of the coupling strategy on CIM monolith with the chromatographic efficiency of final immunoaffinity adsorbent. Different activation chemistries  were tested for the immobilization of two model monoclonal antibodies (mAbs) with subsequent chromatographic characterization of the affinity support.

Column used for this application note were CIMac CDI, AE, EDA, HDZ, rpA.

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2015

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. In addition to that, the data obtained is very reproducible and accurate.


For any kind of quantification, a calibration curve obtained with a virus standard is needed. The work presented in this application note shows the excellent performance of the CIMac™ Adeno Analytical Column – a monolith based anion exchange column, designed for fast and reproducible analyses of adenoviruses.

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