Improving product quality and productivity of bispecific molecules through the application of continuous perfusion principles.

Bispecific protein scaffolds can be more complex than traditional monoclonal antibodies (MAbs) because two different sites/domains for epitope binding are needed. Because of this increased molecular complexity, bispecific molecules are difficult to express and can be more prone to physical and chemical degradation compared to MAbs, leading to higher levels of protein aggregates, clipped species, or modified residues in cell culture. In this study, we investigated cell culture performance for the production of three types of bispecific molecules developed at Amgen.

Perfusion CHO cell culture applied to lower aggregation and increase volumetric productivity for a bispecific recombinant protein.

Secreted recombinant proteins can aggregate during cell culture. We studied a poorly-behaved bispecific scaffold that increasingly aggregated (up to 62% high molecular weight species, HMW) as a function of culture time in a fed-batch and intensified cell culture processes. We identified that protein aggregates increased with accumulated protein concentration inside the bioreactor.

Failure to Thrive: An Expanded Differential Diagnosis.

The patient is a term 6-month-old male, who presented with failure to thrive since birth. History was remarkable for suspected milk and soy protein allergy, gastroesophageal reflux, constipation, and abdominal distension that was present since birth. He was losing weight despite oral intake of over 100 kcal/kg per day.

A novel mammalian cell line development platform utilizing nanofluidics and optoelectro positioning technology.

Generating a highly productive cell line is resource intensive and typically involves long timelines because of the need to screen large numbers of candidates in protein production studies. This has led to miniaturization and automation strategies to allow for reductions in resources and higher throughput. Current approaches rely on the use of standard cell culture vessels and bulky liquid handling equipment.

Analysis of Tubespins as a suitable scale-down model of bioreactors for high cell density CHO cell culture.

High cell density (HCD) culture increases recombinant protein productivity via higher biomass. Compared to traditional fed-batch cultures, HCD is achieved by increased nutrient availability and removal of undesired metabolic components via regular medium replenishment. HCD process development is usually performed in instrumented lab-scale bioreactors (BR) that require time and labor for setup and operation.