NSF Award
1556043
The broader impact/commercial potential of this Small Business Technology Transfer (STTR) Phase II project will be the discovery of new ionization technology for use with mass spectrometry. This technology will enable lower cost, lower energy use, and reduced user expertise, which may potentially drive mass spectrometry into large and underserved markets such as medical diagnostics and field portable instruments designed specifically for use in homeland security, bedside diagnostics, or bio-threat detection. The new technology changes the current understanding of ionization processes used in mass spectrometry and provides opportunities for new innovations to advance science through improved measurements, impacting fields such as health, safety, and security. The aims of this Phase II project are to develop interfaces to incorporate the platform developed in Phase I on most major mass spectrometer manufacturer's instruments and to develop technologies for rapid automate analyses even of surfaces. The research of Phase II is aimed to better understand the fundamentals of this new technology in order to drive commercial success in high sensitivity rapid analyses at a competitive price. Mass spectrometers are widely used representing a $4 billion industry of which ionization technology represents a significant commercial opportunity.<br/><br/>This STTR Phase II project proposes to revolutionize ionization in mass spectrometry by providing commercial products that utilize a simple and powerful ionization technology. The newly discovered process spontaneously converts large and small, volatile and nonvolatile compounds to the gas-phase ions necessary for analysis using mass spectrometry without employing currently used high cost lasers or high voltage. The method is broadly applicable for analysis of compounds such as drugs, lipids, carbohydrate conjugates, peptides, and proteins directly from bodily fluids or tissue, as well as synthetic polymers and inorganic catalytic surfaces. This technology is anticipated to augment or even replace older ionization methods in applications such as clinical analyses, pharmaceuticals, forensics, environmental, and food safety. The aims of the Phase II project are to implement the multifunctional platform developed during Phase I on a variety of manufacturer's instruments, automate the process to allow lower cost and faster analyses, and provide an automated surface analysis platform. Besides determining the best sample preparation methodologies and choice of solvents/matrices, the research objectives include innovative automated sample introduction technologies that eliminate the need for a conventional "ion source" while reducing the pumping requirements, which currently hinder development of small, low-cost portable mass spectrometers.
