SBIR-STTR Award

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) project is to provide analytical technology that will foster the commercial development of complicated biomanufactured products. The most pressing need is to reduce the time and cost to bring the latest generation of biotherapeutic drugs to market. Currently, upwards of eight years and $1B is spent to move a candidate drug from discovery through final approval. Along the way $300M is consumed by analytical testing procedures to certify the product. The American healthcare system will benefit from new and less expensive analytical technologies that reduce certification costs and lead to less expensive drugs. Manufacturing efficiency also can be improved using the proposed technology. Biomanufactured products are harvested from cultured cells, and there are times when the culturing process fails to produce a perfect product. Detecting impurities and spoilage during manufacturing will further reduce manufacturing costs and directly benefit the consumer through the delivery of better therapeutic products and treatment regimens.This SBIR Phase I project proposes to quantify the validity of an ion mobility spectrometer as a high-throughput tool for screening conformational variation, purity, and aggregation of biotherapeutic drugs. Conformation imparts functionality to a protein and any variation in conformation implies there is a variation in biochemical activity, which is undesirable. Ion mobility is a technique that determines molecular cross-section, which in turn is a measure of a molecule's conformation. The gold standard for determining protein conformation is x-ray crystallography, a methodology limited by throughput. There is an unmet need to develop faster ways to measure protein conformation. The proposed technology determines a protein conformation rapidly across all phases of biotherapeutic drug development from discovery, expression system testing, scale up and manufacturing. Additionally, the patented design for this ion mobility spectrometer provides a way to measure changes in conformation that might result as a consequence of exposure to thermal, chemical, and photo-induced stress as needed for drug stability and developability testing. The proposed work will quantify resolution, reproducibility, accuracy, and throughput for this benchtop instrument. The evaluation will be performed using antigen-antibody pairs and several biotherapeutic drugs in collaboration with an academic group and industry partners.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase II project will be the development of an analytical instrument to detect protein changes across all stages of protein production. The production of highly-engineered therapeutic proteins has outpaced the development of analytical assays to guarantee effectiveness, purity, and shelf life of the drug. A key control parameter during manufacturing is protein conformation; currently, this is difficult to monitor with commercially available technology. The goal of this project is to provide manufacturers with a new generation of analytical technology that allows them to identify variations between batches. This technology also provides information about product stability so manufacturers can guarantee a longer shelf life for their products, regardless of storage conditions. It is anticipated that this instrument will increase efficacy at all stages, from discovery through scaled-up production and formulation to pre-release certification. This SBIR Phase II project aims to improve biotherapeutic drug production through the commercialization of analytical technology that provides a new metric for the rapid QC/QA assessment of the conformation of proteins. The gold standard for determining protein conformation is x-ray crystallography - a time-consuming technique that requires high quality crystals and a high-energy physics facility to produce coherent x-rays. The proposed highly sensitive bench-top ion mobility spectrometer detects small variations in the cross-sectional area of a protein and detects small conformational changes. This provides a capability to determine protein stability during discovery when only microgram quantities of recombinantly expressed proteins are available. This process also indicates if a protein refolded after it was subjected to a pH change during purification, and thus it may be used to identify challenges to long-term shelf life. This instrument will be used to demonstrate that for the first time, ion mobility will produce highly-reproducible and biologically relevant measurements of the quality of biomanufactured proteins. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.