Your search keyword '"K. Eric Milgram"' showing total 2 results

1. Quantitation of ion abundances in fourier transform ion cyclotron resonance mass spectrometry

Author

Clifford H. Watson, John R. Eyler, K. Eric Milgram, Kathryn R. Williams, and Kevin L. Goodner

Subjects

Chemistry, Analytical chemistry, Mass spectrometry, Window function, Fourier transform ion cyclotron resonance, symbols.namesake, Fourier transform, Apodization, Structural Biology, Isotopes of xenon, symbols, Transient response, Spectroscopy, Ion cyclotron resonance

Abstract

To improve the analytical usefulness of Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS), an extensive survey of various methods for quantitation of peak magnitudes has been undertaken using a series of simulated transient response signals with varying signal-to-noise ratio. Both peak height (five methods) and peak area (four methods) were explored for a range of conditions to determine the optimum methodology for quantitation. Variables included dataset size, apodization function, damping constant, and zero filling. Based on the results obtained, recommended procedures for optimal quantitation include: apodization using a function appropriate for the peak height ratios observed in the spectrum (i.e., Hanning for ratios of about 1:10, three-term Blackman-Harris for ratios of ∼1:100, or Kaiser-Bessel for ratios of ∼1:1000); zero filling until the peaks of interest are represented by 10–15 points (generally obtained with one order of zero filling); and use of the polynomial y = (ax2 + bx + c)n and the three data points of highest intensity of the peak to locate the peak maximum, Ymax = (−b2/4a + c)n. In this peak fitting procedure, which we have termed the “Comisarow method,” n is 5.5, 9.5, and 12.5 for the Hanning, three-term Blackman-Harris, and Kaiser-Bessel apodization functions, respectively. Accuracy of quantitation using an optimal peak height determination is about equal to that for peak area measurements. These recommendations were found to be valid when tested with real FTICR-MS spectra of xenon isotopes.

Published

1998

2. High-Resolution Inductively Coupled Plasma Fourier Transform Ion Cyclotron Resonance Mass Spectrometry

Author

Kevin L. Goodner, John R. Eyler, K. Eric Milgram, Alan G. Marshall, David W. Koppenaal, James D. Winefordner, Benjamin H. Smith, and R. S. Houk, Clifford H. Watson, Charles J. Barinaga, and Forest M. White

Subjects

Resolution (mass spectrometry), Chemistry, Mass spectrum, Analytical chemistry, Selected ion monitoring, Mass spectrometry, Inductively coupled plasma mass spectrometry, Ion cyclotron resonance, Fourier transform ion cyclotron resonance, Analytical Chemistry, Hybrid mass spectrometer

Abstract

Initial results obtained by incorporation of an inductively coupled plasma (ICP) ion source with a Fourier transform ion cyclotron resonance (FTICR) mass spectrometer are reported, along with spectra which demonstrate sub-milligram-per-liter detection limits and high mass resolution (mass resolving power, m/Δm10%V = 7000−10 000). Also shown is an ICP-FTICR spectrum with ultrahigh resolving power (m/Δm10%V = 88 000). Both instrumental configurations used to conduct this work, one at the University of Florida, and the other at the National High Magnetic Field Laboratory, are described. Also included are concise results from a computer aided interference study designed to enumerate mass spectral interferences requiring mass resolving power in excess of 10 000.

Published

1997