BioPharm International: Steps to Process Development Optimization

Featured Contributor: Daniel Giroux, VP of Biologics Development

The development and production of biologics can be a complex process. And the manufacture of biopharmaceuticals requires that processes be developed and validated so that product specifications can be met to create a safe and effective biologic drug. Steps can be taken at each stage of the development and manufacturing of biologics to ensure processes are optimized for the best results.

Sponsor companies often look to contract development and manufacturing organizations (CDMOs) to help with process development of these products. The following article provides advice and insight from experts and bio/pharma CDMOs on how process development can be optimized.

Upstream processes

A scalable production system is necessary when considering how to optimize upstream processes, according to Daniel Giroux, vice-president of Biologics Development at Abzena. Typical large-scale systems range from using 500- to 2000-L bioreactors, and the scale can prevent experiments. “If you have a single, 2000-L reactor, you can’t run multiple experiments for optimization,” says Giroux. A small-scale system will be needed in which growth and production parameters of the larger-scale system can be reproduced.

After the small-scale model is created, a design-of-experiment (DoE) approach can be used to identify parameters that may impact the titer or the product quality. “You create a statistical experiment where you’re varying those parameters in combination and singly. And then you execute that experiment in parallel bioreactor systems, so a small-scale reactor where you have many of them,” Giroux explains. Statistical tools can then be used to pull data from DoEs and models to optimize input parameters to achieve maximal titers.

Process intensification is another approach Giroux points to, where higher cell densities are used at inoculation to increase the area under the cell density versus culture time curve. “You want your cell density to be high for a longer period of time,” Giroux says. “And by starting at a higher cell density, it lets you do that, and you basically get 50 to 100% more titer in an intensified fed batch process. That means, though, that you have to develop a perfusion process for your penultimate reactor, your last seed reactor, so that you can actually have enough cells to inoculate your production systems at these higher densities.”

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