Keven Lothert, Yasmina M. J. Harsy, Patrick Endres, Egbert Müller, Michael W. Wolff
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引用次数: 1
摘要
近年来,利用受限存取介质(RAM)进行纳米颗粒(如病毒)纯化的多模态色谱技术越来越受到人们的关注。这些色谱树脂结合了颗粒壳上的尺寸排除和核心内的吸附相互作用。因此,可以保留较小的工艺相关杂质,例如DNA和蛋白质,而较大的产品病毒可以不受阻碍地通过。我们评估了一系列目前可用的RAM,不同于外壳的孔切断和核心化学成分,用于纯化细胞培养衍生的澄清模型病毒,即Orf病毒(ORFV)。我们检查了杂质消耗和产品回收作为评估色谱柱性能的相关标准,以及评估多种用途应用的放大稳健性和再生潜力。结果表明,一些色谱柱(如Capto Core)可以同时去除DNA和蛋白质,而另一些色谱柱(如Monomix Core 60 (MC60))更适合去除DNA。此外,使用具有较大壳孔(5000 kDa vs 700 kDa)和较弱结合相互作用(阴离子交换vs多模态)的柱有助于柱再生。根据这些发现,RAM树脂的选择应根据各自的饲料样品组成和计划的应用周期数量来选择。
Evaluation of restricted access media for the purification of cell culture-derived Orf viruses
Recently, multimodal chromatography using restricted access media (RAM) for the purification of nanoparticles, such as viruses has regained increasing attention. These chromatography resins combine size exclusion on the particle shell and adsorptive interaction within the core. Accordingly, smaller process-related impurities, for example, DNA and proteins, can be retained, while larger product viruses can pass unhindered. We evaluated a range of currently available RAM, differing in the shells’ pore cut-off and the core chemistry, for the purification of a cell culture-derived clarified model virus, namely the Orf virus (ORFV). We examined impurity depletion and product recovery as relevant criteria for the evaluation of column performance, as well as scale-up robustness and regeneration potential for evaluating a multiple use application. The results indicate that some columns, for example, the Capto Core, enable both a high DNA and protein removal, while others, for example, the Monomix Core 60 (MC60), are more suitable for DNA depletion. Furthermore, column regeneration is facilitated by using columns with larger shell pores (5000 vs. 700 kDa) and weaker binding interactions (anion exchange vs. multimodal). According to these findings, the choice of RAM resins should be selected according to the respective feed sample composition and the planned number of application cycles.
期刊介绍:
Engineering in Life Sciences (ELS) focuses on engineering principles and innovations in life sciences and biotechnology. Life sciences and biotechnology covered in ELS encompass the use of biomolecules (e.g. proteins/enzymes), cells (microbial, plant and mammalian origins) and biomaterials for biosynthesis, biotransformation, cell-based treatment and bio-based solutions in industrial and pharmaceutical biotechnologies as well as in biomedicine. ELS especially aims to promote interdisciplinary collaborations among biologists, biotechnologists and engineers for quantitative understanding and holistic engineering (design-built-test) of biological parts and processes in the different application areas.
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