Chris Hwang scite author profile

In the current environment of diverse product pipelines, rapidly fluctuating market demands and growing competition from biosimilars, biotechnology companies are increasingly driven to develop innovative solutions for highly flexible and cost-effective manufacturing. To address these challenging demands, integrated continuous processing, comprised of high-density perfusion cell culture and a directly coupled continuous capture step, can be used as a universal biomanufacturing platform. This study reports the first successful demonstration of the integration of a perfusion bioreactor and a four-column periodic counter-current chromatography (PCC) system for the continuous capture of candidate protein therapeutics. Two examples are presented: (1) a monoclonal antibody (model of a stable protein) and (2) a recombinant human enzyme (model of a highly complex, less stable protein). In both cases, high-density perfusion CHO cell cultures were operated at a quasi-steady state of 50-60 × 10(6) cells/mL for more than 60 days, achieving volumetric productivities much higher than current perfusion or fed-batch processes. The directly integrated and automated PCC system ran uninterrupted for 30 days without indications of time-based performance decline. The product quality observed for the continuous capture process was comparable to that for a batch-column operation. Furthermore, the integration of perfusion cell culture and PCC led to a dramatic decrease in the equipment footprint and elimination of several non-value-added unit operations, such as clarification and intermediate hold steps. These findings demonstrate the potential of integrated continuous bioprocessing as a universal platform for the manufacture of various kinds of therapeutic proteins.

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The business impact of an integrated continuous biomanufacturing platform for recombinant protein production

Walther¹,

Godawat²,

Hwang³

et al. 2015

Journal of Biotechnology

214

170

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Perfusion Cell Culture Decreases Process and Product Heterogeneity in a Head‐to‐Head Comparison With Fed‐Batch

Walther

Lü

Hollenbach

et al. 2018

Biotechnology Journal

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In this study, the authors compared the impacts of fed-batch and perfusion platforms on process and product attributes for IgG1- and IgG4-producing cell lines. A "plug-and-play" approach is applied to both platforms at bench scale, using commercially available basal and feed media, a standard feed strategy for fed-batch and ATF filtration for perfusion. Product concentration in fed-batch is 2.5 times greater than perfusion, while average productivity in perfusion is 7.5 times greater than fed-batch. PCA reveals more variability in the cell environment and metabolism during the fed-batch run. LDH measurements show that exposure of product to cell lysate is 7-10 times greater in fed-batch. Product analysis shows larger abundances of neutral species in perfusion, likely due to decreased bioreactor residence times and extracellular exposure. The IgG1 perfusion product also has higher purity and lower half-antibody. Glycosylation is similar across both culture modes. The first perfusion harvest slice for both product types shows different glycosylation than subsequent harvests, suggesting that product quality lags behind metabolism. In conclusion, process and product data indicate that intra-lot heterogeneity is decreased in perfusion cultures. Additional data and discussion is required to understand the developmental, clinical and commercial implications, and in what situations increased uniformity would be beneficial.

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Measurement and Control of Dissolved Carbon Dioxide in Mammalian Cell Culture Processes Using an in Situ Fiber Optic Chemical Sensor

Pattison¹,

Swamy²,

Mendenhall³

et al. 2000

Biotechnol. Prog.

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At high viable cell concentrations in large-scale mammalian cell culture processes, the accumulation of dissolved carbon dioxide (dCO 2 , typically quantified as an equilibrium gas-phase concentration) becomes problematic as a result of low CO 2 removal rates at reduced surface-to-volume ratios. High dCO 2 concentrations have previously been shown to inhibit cell growth and product formation in mammalian cells and to alter the glycosylation pattern of recombinant proteins. Therefore, reliable monitoring and control of dCO 2 are important for successful large-scale operation. Off-line measurements by instruments such as blood gas analyzers (BGA) are constrained by the low frequency of data collection and cannot be used for on-line control. In a preliminary evaluation of the YSI 8500 in situ sensor, a response time (t 90% ) of 6 min, sensitivity of 0.5% CO 2 (3.6 mmHg), and linearity of measurement (R 2 ) 0.9997) between the equivalent gas-phase partial pressure of 0-180 mmHg (0% and 25% CO 2 ) were established. Measurements were found to be unaffected by culture pH and typical mammalian cell culture concentrations of glucose, glutamine, glutamate, lactate, and ammonium. The sensor withstood repeated sterilization and cleaning cycles. The reliability of this sensor was demonstrated in microcarrier-based Chinese hamster ovary (CHO) cell perfusion cultures at reactor scales of 30, 40, 340, and 2000 L and was successfully implemented in a dCO 2 control strategy using N 2 sparging.

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High brightness photonic lantern kW-class amplifier

Montoya

Hwang

Aleshire

et al. 2018

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Chris Hwang

Integrated continuous production of recombinant therapeutic proteins

The business impact of an integrated continuous biomanufacturing platform for recombinant protein production

Perfusion Cell Culture Decreases Process and Product Heterogeneity in a Head‐to‐Head Comparison With Fed‐Batch

Measurement and Control of Dissolved Carbon Dioxide in Mammalian Cell Culture Processes Using an in Situ Fiber Optic Chemical Sensor

High brightness photonic lantern kW-class amplifier

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