SBIR-STTR Award

A Programmable Residual Solvent Analyzer based on Fourier Transform Molecular Rotational Resonance (FT-MRR) Spectroscopy
Award last edited on: 6/26/2017

Sponsored Program
SBIR
Awarding Agency
NSF
Total Award Amount
$1,145,928
Award Phase
2
Solicitation Topic Code
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Principal Investigator
Brent Harris

Company Information

BrightSpec

770 Harris Street Suite 104B
Charlottesville, VA 22911
   (434) 202-2391
   inquiries@brightspec.com
   www.brightspec.com
Location: Single
Congr. District: 05
County: Albemarle

Phase I

Contract Number: 1448551
Start Date: 1/1/2015    Completed: 6/30/2015
Phase I year
2015
Phase I Amount
$149,907
This Small Business Innovation Research Phase I project will develop a new analytical chemistry technique for rapid quantitation of chemicals in complex mixtures. The life science and chemical instrumentation market is $45 billion annually. The introduction of Quality by Design manufacturing processes has increased the need for accurate, high-speed, maintenance-free techniques for chemical analysis. The target application for this project is the detection of residual chemical solvents and genotoxic impurities in pharmaceutical manufacturing. The new technique to be developed uses molecular rotational resonance (MRR) spectroscopy to identify molecules based on their three dimensional geometry, resulting in a method with high chemical specificity. MRR is a high-resolution spectroscopy technique that makes it possible to directly analyze gas mixtures containing a large number of chemicals without the need for prior chemical separation using chromatography - a time-consuming step of current analysis methods that requires significant technical supervision. As a result, MRR-based chemical analysis instruments can provide rapid measurements of trace levels of chemicals in a manner that is compatible with real-time manufacturing processes requiring constant measurement for quality assurance. Chemical analysis instruments using MRR spectroscopy offer lower cost of ownership through higher measurement throughput, reduced consumables cost, and maintenance-free operation.

The intellectual merit of this project is the introduction of a new technique for chemical analysis that solves major problems in the current set of tools available to the field. MRR spectroscopy has the highest chemical selectivity of any spectroscopy technique and can easily distinguish molecular isomers - a challenge for techniques that rely on mass to establish the chemical identity. Compared to other spectroscopy techniques, the method has higher spectral resolution that makes it possible to accurately analyze samples that are mixtures of many compounds (with several components at trace levels). Unlike mass spectrometry methods, the gas mixtures can be directly analyzed without the need for prior chemical separation using gas chromatography (GC). As a spectroscopy method, quantitative chemical analysis can be performed without the labor intensive and time-consuming process of running measurement standards. The instrument combines recent advances in high-power, solid-state millimeter wave (mm-wave) light sources, low-cost microwave synthesizer integrated circuits, and high-speed digital electronics to implement a time-domain, Fourier transform (FT) measurement approach. FT-MRR spectrometers reduce the measurement time by a factor of 1000 or more over existing rotational spectroscopy techniques, making the technique competitive with other high-sensitivity chemical analysis tools.

Phase II

Contract Number: 1556035
Start Date: 2/15/2016    Completed: 1/31/2018
Phase II year
2016
(last award dollars: 2018)
Phase II Amount
$996,021

This Small Business Innovation Research Phase II project will develop a new analytical chemistry instrument for rapid quantitation of residual chemical impurities in complex mixtures. The target application for this project is the detection of genotoxic impurities during early drug development in pharmaceutical manufacturing. The instrument to be developed uses Fourier transform molecular rotational resonance (FT-MRR) spectroscopy to identify molecules based on their three dimensional geometry, which permits high chemical specificity. FT-MRR is a high-resolution spectroscopy technique that makes it possible to directly analyze gas mixtures containing a large number of chemicals without the need for prior chemical separation using chromatography - a time-consuming step of current analysis methods that requires significant technical supervision. As a result, FT-MRR based chemical analysis instruments have the potential to speed up innovation for pharmaceutical manufacturers by reducing analytical development cycles from weeks to hours during the high-throughput drug innovation process. Chemical analysis instruments using FT-MRR spectroscopy enable faster innovation in research and development labs with the added benefit of seamless method transferability to on-line process monitoring applications and routine quality control for final product release.The ability to transfer analysis methods into routine analysis is important to the industry goal of continuous manufacturing for pharmaceuticals. It is enabled for FT-MRR in part (yet critically) by the two main objectives of this Phase II effort: the development of sampling automation for FT-MRR and the design of a cost-reduced, targeted FT-MRR system. Concepts for both of these designs were successfully tested during Phase I. The intellectual merit of this project is the introduction of a new technique for chemical analysis that senses chemicals based on the absolute molecular structure, with no orthogonal analysis required. FT-MRR spectral fingerprints can distinguish molecular isomers, conformers, isotopologues, and even enantiomers. With this kind of absolute structure information, FT-MRR can enable new studies that trace chemical pathways with site-specific isotopic ratio information and chiral detection. Both concepts are otherwise very challenging with current technology. The FT-MRR instrument to be built for this project combines recent advances in high-power, solid-state millimeter wave (mm-wave) light sources, low-cost microwave synthesizer integrated circuits, and high-speed digital electronics to implement a time-domain, Fourier transform (FT) measurement approach. Standard methods for chemical sampling will be integrated to maximize the ease-of-use and robustness of FT-MRR instruments.