Application of quality by design principles to the development and technology transfer of a major process improvement for the manufacture of a recombinant protein.

This study describes the application of quality by design (QbD) principles to the development and implementation of a major manufacturing process improvement for a commercially distributed therapeutic protein produced in Chinese hamster ovary cell culture. The intent of this article is to focus on QbD concepts, and provide guidance and understanding on how the various components combine together to deliver a robust process in keeping with the principles of QbD. A fed-batch production culture and a virus inactivation step are described as representative examples of upstream and downstream unit operations that were characterized.

Cell motility and SCAR localisation in axenically growing Dictyostelium cells.

Dictyostelium is a popular experimental organism, in particular for studies of actin dynamics, cell motility and chemotaxis. We find that the motility of axenic cells is unexpectedly different from other strains during growth. In particular, vegetative AX3 cells do not show detectable localisation of SCAR and its regulatory complex to actin-rich protrusions such as filopodia and pseudopodia.

Nap1 regulates Dictyostelium cell motility and adhesion through SCAR-dependent and -independent pathways.

SCAR--also known as WAVE--is a key regulator of actin dynamics. Activation of SCAR enhances the nucleation of new actin filaments through the Arp2/3 complex, causing a localized increase in the rate of actin polymerization . In vivo, SCAR is held in a large regulatory complex, which includes PIR121 and Nap1 proteins, whose precise role is unclear.

Modulation of cell cycle for enhancement of antibody productivity in perfusion culture of NS0 cells.

A prolonged period of high productivity at high cell density is desirable for industrial production of biopharmaceuticals. Previous efforts have shown that cessation of cell proliferation in low cell density culture results in increased productivity. We report here further results on multigenic manipulation of cell cycle and apoptosis to enhance productivity at high cell density.

Chromatographic removal combined with heat, acid and chaotropic inactivation of four model viruses.

The virus removal of protein A affinity chromatography, inactivation capacity, acid pH and a combination of high temperature with a chaotropic agent was determined in this work. The model viruses studied were sendaivirus, human immunodeficency virus (HIV-IIIb), human poliovirus type-II, human herpesvirus I and canine parvovirus. The protein A affinity chromatography showed a maximum reduction factor of 8 logs in the case of viruses larger than 120 nm size, while for small viruses (18-30 nm) the maximum reduction factor was about 5 logs.