Plasmid DNA purification development has been driven by the increased need for large quantities of highly purified, sterile plasmid DNA for clinical studies. Detailed characterization and development of the terminal sterile filtration process step is often limited due to time constraints and the scarcity of sufficient quantities of purified plasmid. However, the large size of the plasmid molecule and variations in conformation can lead to significant yield losses if this process step is not optimized. In this work, the gradual pore-plugging model of flow decay was found to be valid for plasmid DNA by using an ultra scaledown apparatus (1-4 cm(2) filter area). Filtration capacity was found to be insensitive to pressure. Multiple filter types were screened and both source and composition of materials were found to affect filter capacity dramatically. The filter capacity for plasmid was improved by increasing plasmid concentrations as well as by modifying buffer conditions to reduce the apparent size of the plasmid. Filtration capacities varied over a greater than 2 log range when plasmids with sizes ranging from 5.5 to 11 kb and supercoiled plasmid content of 55-95% were explored. Larger plasmids and feeds with lower supercoiled contents led to reduced capacities. These results can be used to define conditions for scale-up of plasmid sterile filtration, as evidenced by processing a 30 g lot using a filtration area of 1,000 cm(2), with a 96% yield, based on filtration capacity data from 4 cm(2) test filters.
As the field of plasmid DNA-based vaccines and therapeutics matures, improved methods for impurity clearance monitoring are increasingly valuable for process development and scale-up. Residual host-cell RNA is a major impurity in current large-scale separation processes for the production of clinical-grade plasmid DNA. Current RNA detection technologies include quantitative rtPCR, HPLC, and fluorescent dye-based assays. However, these methodologies are difficult to employ as in-process tests primarily as a result of impurity and buffer interferences. To address the need for a method of measuring RNA levels in various process intermediates, a sample pretreatment strategy has been developed that utilizes spermidine affinity precipitation to eliminate a majority of solution impurities, followed by a quantitative precipitation with alcohol to concentrate RNA and allow detection at lower concentrations. RNA concentrations as low as 80 ng/mL have been measured using detection with gel electrophoresis and 20 ng/mL if microplate-based detection with Ribogreen fluorescent dye is used. The assay procedure has been utilized to troubleshoot RNA clearance issues encountered during scale-up of a novel, non-chromatographic purification process for plasmid DNA. Assay results identified residual liquor removal inadequacies as the source of elevated RNA levels, enabling process modifications in a timely fashion.
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