Strengthening the analytical workflow for rAAV viral vector development
Sponsored by: Malvern Panalytical
Date: 23 April
Time: 3PM London/10AM New York
Rapid, label-free, non-destructive, low volume determination of total rAAV particle concentration
Recombinant Adeno-Associated Viruses (rAAV) are a well-studied class of viral vector that is being investigated intensively in the development of gene therapies. In order to develop efficient rAAV therapies produced through controlled and economical manufacturing processes, multiple challenges remain to be addressed.
rAAVs are typically produced in engineered cell lines in large bioreactors. Once produced inside the cell, the rAAV particles are released by lysis, and then isolated from the bulk harvest through multiple rounds of isolation; for example, via density gradient centrifugation, ion-exchange chromatography, and tangential flow filtration.
Throughout the downstream purification process, multiple assays are performed to determine key analytical attributes for the determination of yield, efficacy, and safety, as well as to enable process understanding and control. These parameters are typically, but not limited to, the following: capsid or particle count, genome count, % genome-containing or % full rAAV particles, serotype characterization, particle size, aggregation level and the presence of unwanted host-cell proteins and nucleotides.
The first three parameters (capsid/particle count, genome count, % full) are commonly measured using two or more of the following assays: qPCR, ELISA, AUC, HPLC-AEX, and/or TEM. Each method has intrinsic strengths and weaknesses, related to the parameter measured, desired throughput, accuracy, and sample volume requirements.
Multi-angle Dynamic Light Scattering (MADLS) is a novel technique capable of simultaneously measuring multiple rAAV parameters, including aggregation, capsid charge, and particle concentration. It is well-suited as a complementary assay that can be utilized in existing analytical workflows to provide rapid, label-free, non-destructive, low volume determination of the total rAAV particle concentration.
In this webinar, Jonathan Mehtala of Malvern Panalytical will discuss the MADLS measurement principle and the application of this novel method to the characterization of rAAV model samples, as well as rAAV therapies in development. Resulting data on the viral concentration and size of rAAV particles will be discussed, along with the effects of sample properties, such as material refractive index and viscosity. Kirsty McManus of Allergan will follow this with real world-examples of multi-serotype rAAV analysis case studies of drug substance and process development samples.
Please join us on April 23rd to learn more about the fast-moving world of gene therapy and the analytical characterization techniques designed to deliver robust, reliable and rapid results.
Senior Scientist (Analytical Sciences), Allergan Biologics Ltd.
Kirsty McManus graduated in 2010 with a BSc Honours Degree in Chemistry from the University of Bath. She worked as a scientist for Cyprotex Discovery in Macclesfield for 6 years where she specialized in high throughput LC-MS/MS optimization of small molecule compounds, along with developing bioanalytical methods for their analysis. She has worked for Allergan Biologics in Liverpool since June 2016, where she has a focus on biophysical characterization techniques, including the development and implementation of the Zetasizer Ultra system for the characterization of multi-serotype AAV particles.
Biosciences Field Application Scientist, Malvern Panalytical
Jonathan Mehtala received his PhD in Chemistry from Purdue University. At Purdue, Jonathan worked in the fields of nanomedicine and bioformulation to develop cancer therapies. Notably, he developed novel gold nanorod surface chemistry, gold nanorod mediated hyperthermia cancer therapies for the treatment of ovarian cancer, and PEGylated protein drug formulations for the treatment of breast cancer. Additionally, Jonathan used Nanoparticle Tracking Analysis to characterize a wide range of nanomaterials and protein aggregates.
Key Learning Objectives
- Gain an introduction to MADLS – a novel approach to DLS analysis
- Find out what makes MADLS a welcome addition to the analytical toolbox for viral vector production and development support
- Discover best practices and important considerations for the use of MADLS in viral vector analysis
- Find out how MADLS is applied in analytical workflows based on rAAV model samples, as well as rAAV therapies in development
- Head of Process Development
- Head of Analytical Development
- Head of Research and Development
- Head of Formulation Development
- Project Leaders
- Project Managers in CROs/CDMOs