Dominic M. Clarke

Concise Review: Guidance in Developing Commercializable Autologous/Patient-Specific Cell Therapy Manufacturing

Cell therapy is poised to play an enormous role in regenerative medicine. However, little guidance is being made available to academic and industrial entities in the start‐up phase. In this technical review, members of the International Society for Cell Therapy provide guidance in developing commercializable autologous and patient‐specific manufacturing strategies from the perspective of process development. Special emphasis is placed on providing guidance to small academic or biotech researchers as to what simple questions can be addressed or answered at the bench in order to make their cell therapy products more feasible for commercial‐scale production. We discuss the processes that are required for scale‐out at the manufacturing level, and how many questions can be addressed at the bench level. The goal of this review is to provide guidance in the form of topics that can be addressed early in the process of development to better the chances of the product being successful for future commercialization.

Cryopreservation of umbilical cord blood with a novel freezing solution that mimics intracellular ionic composition.

BACKGROUND: Cryopreservation protocols have remained relatively unchanged since the first umbilical cord blood banking program was established. This study evaluated the preservation efficacy of a novel intracellular‐like cryopreservation solution (CryoStor, BioLife Solutions, Inc.), the rate of addition of two cryopreservation solutions to cord blood units (CBUs), and reduced final dimethyl sulfoxide (DMSO) concentration of 5%.

Managing particulates in cellular therapy

he concept of particulates, while common to many in the pharmaceutical and blood transfusion disciplines, represents a distinct challenge in the field of cellular therapy. With newly discovered products advancing through clinical trials, the focus has shifted to ensuring products are manufactured in a reliable and safe manner. Given the unique manufacturing processes and resulting products (i.e. the cell being the active ingredient of the product), the way in which particulates are viewed and subsequently tested needs to be reviewed. No specific test or method for particulates will apply to all products, and guidance documents will be generated over time as more cell therapy products are approved. The details of the processes, testing methods used and acceptance criteria established for particulates will play a major role in generating the guidance documents. This will ultimately allow for the manufacture and administration of safe and effective products without thwarting advancement of the cellular therapy field. The intent of this review is to bring awareness to the topic of particulates with respect to cell therapy, and encourage a more open dialog and exchange of examples within the industry. We have reviewed the concept of particulates, where they originate and how they are introduced to cell therapy products, and the current methods available for their detection. We have also reviewed the relevance of current guidance documents and present potential strategies to move forward and address and control unwanted contaminating particulates in cell therapy products.

Managing particulates in cell therapy: Guidance for best practice.

The intent of this article is to provide guidance and recommendations to cell therapy product sponsors (including developers and manufacturers) and their suppliers in the cell therapy industry regarding particulate source, testing, monitoring and methods for control. This information is intended to help all parties characterize the processes that generate particulates, understand product impact and provide recommendations to control particulates generated during manufacturing of cell therapy products.