The mass-mobility correlation redux: The conformational landscape of anhydrous biomolecules

McLean, John A.

doi:10.1016/j.jasms.2009.06.016

Cited by 87 publications

(103 citation statements)

References 48 publications

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“…4,62,63 Current mass analyzers are highly selective ( R p > 100,000), and, in many cases, accurate mass measurement when combined with tandem MS/MS capabilities can elucidate an analyte identification. However, when investigating analytical mixtures that possess isomers or investigating proteins which often express many conformers, ion mobility analysis is chemically insightful.…”

Section: Resultsmentioning

confidence: 99%

Correlating Resolving Power, Resolution, and Collision Cross Section: Unifying Cross-Platform Assessment of Separation Efficiency in Ion Mobility Spectrometry

2017

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Here we examine the relationship between resolving power (Rp), resolution (Rpp), and collision cross section (CCS) for compounds analyzed in previous ion mobility (IM) experiments representing a wide variety of instrument platforms and IM techniques. Our previous work indicated these three variables effectively describe and predict separation efficiency for drift tube ion mobility spectrometry (DTIMS) experiments. In this work we seek to determine if our previous findings are a general reflection of IM behavior applicable to various instrument platforms and mobility techniques. Results suggest IM distributions are well characterized by a Gaussian model and separation efficiency can be predicted based on empirical difference in the gas-phase CCS and a CCS-based resolving power definition (CCS/ΔCCS). Notably traveling wave (TWIMS) was found to operate at substantially higher resolutions than a single-peak resolving power suggested. When a CCS-based Rp definition was utilized, TWIMS was found to operate at a resolving power of between 40 and 50, confirming the previous observations by Giles and coworkers. After converting the separation axis (and corresponding resolving power) to cross section space it is possible to effectively predict separation behavior for all mobility techniques evaluated (i.e. uniform field, trapped ion mobility, traveling wave, cyclic and overtone instruments) using the equations described in this work. Finally, we are able to establish for the first time that the current state-of-the-art ion mobility separations benchmark at a CCS-based resolving powers above 300 which is sufficient to differentiate analyte ions with CCS differences as small as 0.5%.

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Section: Resultsmentioning

confidence: 99%

Correlating Resolving Power, Resolution, and Collision Cross Section: Unifying Cross-Platform Assessment of Separation Efficiency in Ion Mobility Spectrometry

2017

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“…Resolution is the most significant limitation of IMS for interrogation of complex biological mixtures whether for post-ionization separation, analytical applications, and/or structural characterization of ions which have similar ion-neutral collision cross sections [7,13]. Diffusion limited resolution is defined by Eq.…”

Section: Introductionmentioning

confidence: 99%

Increased ion transmission in IMS: A high resolution, periodic-focusing DC ion guide ion mobility spectrometer

Silveira

Gillig

Gamage

et al. 2011

International Journal of Mass Spectrometry

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“…Technical triplicates of extracts were analyzed in a randomized sequence using UPLC-IM-MS (Waters Synapt G2, Milford, MA) with lock mass correction to provide accurate mass measurements. During each spectral acquisition, an intact and fragmentation spectrum was taken for all ions present (herein referred to as MS E analysis (Plumb et al, 2006)) (Goodwin et al, 2012; McLean, 2009). Fragmentation was performed subsequent to IM separation, which allowed for the correlation of product ions to precursor origins through matched mobility.…”

Section: Resultsmentioning

confidence: 99%

Structuring Microbial Metabolic Responses to Multiplexed Stimuli via Self-Organizing Metabolomics Maps

Goodwin

Covington

Derewacz

et al. 2015

Chemistry & Biology

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Secondary metabolite biosynthesis in microorganisms responds to discrete chemical and biological stimuli; however, untargeted identification of these responses presents a significant challenge. Herein we apply multiplexed stimuli to Streptomyces coelicolor and collect the resulting response metabolomes via ion mobility-mass spectrometric analysis. Self-organizing map (SOM) analytics adapted for metabolomic data demonstrate efficient characterization of the subsets of primary and secondary metabolites that respond similarly across stimuli. Over 60% of all metabolic features inventoried from responses are either not observed under control conditions or produced at greater than two-fold increase in abundance in response to at least one of the multiplexing conditions, reflecting how metabolites encode phenotypic changes in an organism responding to multiplexed challenges. Using abundance as an additional filter, each of sixteen known S. coelicolor secondary metabolites is prioritized via SOM and observed at increased levels (1.2 – 22-fold compared to unperturbed) in response to one or more challenge conditions.

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The mass-mobility correlation redux: The conformational landscape of anhydrous biomolecules

Cited by 87 publications

References 48 publications

Correlating Resolving Power, Resolution, and Collision Cross Section: Unifying Cross-Platform Assessment of Separation Efficiency in Ion Mobility Spectrometry

Correlating Resolving Power, Resolution, and Collision Cross Section: Unifying Cross-Platform Assessment of Separation Efficiency in Ion Mobility Spectrometry

Increased ion transmission in IMS: A high resolution, periodic-focusing DC ion guide ion mobility spectrometer

Structuring Microbial Metabolic Responses to Multiplexed Stimuli via Self-Organizing Metabolomics Maps

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