Impact energy measurement in time-of-flight mass spectrometry with cryogenic microcalorimeters

Hilton, G. C.; Martinis, John M.; Wollman, D. A.; Irwin, K. D.; Dulcie, L. L.; Gerber, Daniel; Gillevet, Patrick M.; Twerenbold, Damian

Impact energy measurement in time-of-flight mass spectrometry with cryogenic microcalorimeters

G. C. Hilton (), John M. Martinis, D. A. Wollman, K. D. Irwin, L. L. Dulcie, Daniel Gerber, Patrick M. Gillevet and Damian Twerenbold
Additional contact information
G. C. Hilton: National Institute of Standards and Technology
John M. Martinis: National Institute of Standards and Technology
D. A. Wollman: National Institute of Standards and Technology
K. D. Irwin: National Institute of Standards and Technology
L. L. Dulcie: National Institute of Standards and Technology
Daniel Gerber: Institut de Physique de l'Université Rue A.-L. Breguet 1
Patrick M. Gillevet: Institute of Bioscience, Bioinformatics, and Biotechnology, George Mason University
Damian Twerenbold: Institut de Physique de l'Université Rue A.-L. Breguet 1

Nature, 1998, vol. 391, issue 6668, 672-675

Abstract: Abstract Time-of-flight mass spectrometry—most notably matrix-assisted laser-desorption-ionization time-of-flight (MALDI-TOF) spectrometry1—is an important class of techniques for the study of proteins and other biomolecules2. Although these techniques provide excellent performance for masses up to about 20,000 daltons, there has been limited success in achieving good mass resolution at higher masses. This is because the sensitivity of the microchannel plate (MCP) detectors used in most systems decreases rapidly with increasing particle mass, limiting the utility of MCP detectors for very large masses. It has recently been proposed that cryogenic particle detectors may provide a solution to these difficulties3. Cryogenic detectors measure the thermal energy deposited by the particle impact, and thus have a sensitivity that is largely independent of particle mass. Recent experiments4,5,6 have demonstrated the sensitivity of cryogenic particle detectors to single biomolecules, a quantum efficiency several orders of magnitude larger than the MCP detectors, and sensitivity to masses as large as 750,000 daltons. Here we present results demonstrating an order of magnitude better energy resolution than previous measurements, allowing direct determination of particle charge state during acceleration7. Although application of these detectors to practical mass spectrometry will require further development of the detectors and cryogenics, these detectors can be used to elucidate the performance-limiting processes that occur in such systems.

Date: 1998
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DOI: 10.1038/35582

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