Process design of a fully integrated continuous biopharmaceutical process using economic and ecological impact assessment.

Continuous biomanufacturing is a promising alternative to current batch operation as it offers benefits in terms of improved productivity, product quality, and reduced footprint. This study aims to build a fully integrated continuous platform for monoclonal antibody (mAb) production incorporating novel technologies (like intensified seed expansion and continuous high cell density perfusion operations, single-pass tangential flow filtration, and single-use technologies) as well as media and buffer preparation steps. Economic assessment is performed on the basis of the total cost of goods (COGs), which is $102.2/g in the base-case scenario with a bioreactor scale of 500 L. E-factor is used as an environmental indicator and the result shows that 4865.6kg of process water and 11.1 kg of consumables are required to produce 1 kg mAbs. After the development and analysis of the benchmark process, scenario analysis is performed to assess the impacts of the bioreactor scale (60-2000 L) and upstream titers (1.12-2.08 g/L) on the process economics as well as on the environmental footprint. With the increase of bioreactor scale and mAb titer, the operating COGs per unit product decrease. Moreover, increasing the mAb titer is more favorable in terms of the ecological impacts. To investigate the production capacity, the upstream production is increased and the downstream bottlenecks are determined. It is found that only the multicolumn chromatographic (MCC) operations become the process bottleneck and the order of the MCC unit operation that becomes the process bottleneck depends on capacity utilization for that step. Finally, a new platform is built with the integration of membrane chromatography and the two designed processes are compared in terms of economic and ecological impacts.

Evaluation of the Design, Development, and Performance of a Mass-Flow Based, Open-Source Buffer Manufacturing System.

Buffer solutions are a critical component of the manufacturing process for therapeutic proteins and other biomolecules. The traditional way to make and use buffers is space and resource intensive, creating operational bottlenecks that impact efficiencies and costs. Here we describe a full-scale, current Good Manufacturing Practices (cGMP) capable buffer stock blending system that has an open-source, configurable design and that overcomes the challenges of traditional buffer preparation. The system comprises simplified control and operation using mass flow to provide on-demand supply of buffer solutions. The system also has self-cleaning capability and is amenable to be operated as a closed system. The data will demonstrate the excellent performance and capabilities of the system as well as illustrate its potential transformative impact on biomanufacturing.