Your search keyword '"Dwivedi, Prabha"' showing total 14 results

1. Resistive glass IM-TOFMS

Author

Kaplan, Kimberly, Graf, Stephan, Tanner, Christian, Gonin, Marc, Fuhrer, Katrin, Knochenmuss, Richard, Dwivedi, Prabha, and Hill, Herbert H., Jr.

Subjects

Engineering design -- Methods, Time-of-flight mass spectrometry -- Equipment and supplies, Glass -- Usage, Chemistry

Abstract

The design of a new ion mobility mass spectrometer (IMMS) is presented. This new design features an ambient-pressure resistive glass ion mobility drift tube (RGIMS) coupled to a high-resolution time-of-flight mass spectrometer (TOFMS) by an enhanced interface that includes two segmented quadrupoles. The interface design demonstrates an increase in sensitivity while maintaining high resolving power typically achieved for ambient-pressure IMS drift tubes. Performance of the prototype instrument was evaluated and the analytical figures of merit for standard solutions as well as complex samples such as human blood were determined. For a 3 [micro]M solution of caffeine, the peak was collected in 36 s and gave a response of 10 counts/s. The detection limit (defined as 1 count/s) was calculated to be 300 nM concentration of caffeine from the response rate from the 36 s run. Controlled fragmentation of caffeine was achieved through adjustment of voltages applied on the interface lenses. Over 300 tentative metabolites were detected in human blood along with 80 isomers/isobars with ion counts > 5. Isotope ratios from extracted mass spectra of selected mobility peaks were used to identify selected metabolite compounds. High separation power for both IMS (resolving power, [t.sub.d]/[DELTA][t.sub.w1/2], was 85) and MS (mass resolving power, m/[DELTA]m, maximum was 7000 with a mass accuracy between 2 and 10 ppm) was measured. Developed software for data acquisition, control and display allowed flexibility in instrument control, data evaluation and visualization. 10.1021/ac1017259

Published

2010

2. Monitoring dynamic changes in lymph metabolome of fasting and fed rats by electrospray ionization-ion mobility mass spectrometry (ESI-IMMS)

Author

Kaplan, Kimberly, Dwivedi, Prabha, Davidson, Sean, Yang, Qing, Tso, Patrick, Siems, William, and Hill, Herbert H. Jr.

Subjects

Time-of-flight mass spectrometry -- Usage, Metabonomic analysis -- Reports, Lymphatics -- Physiological aspects, Lymphatics -- Chemical properties, Ionic mobility -- Analysis, Chemistry

Abstract

Ambient pressure ion mobility time-of-flight mass spectrometry (IMMS) has recently emerged as a rapid and efficient analytical technique for applications to metabolomics. Ah important application of metabolomics is to monitor metabolome shifts caused by stress due to toxin exposure, nutritional changes, or disease. The research presented in this paper uses IMMS to monitor metabolic changes in rat lymph fluid caused by dietary stresses over time. Extracts of metabolites found in the lymph fluid collected from dietary stressed rats were subjected to analysis by electrospray (ESI) IMMS operated both in positive and negative ion detection mode. Metabolites detected were tentatively identified based on their mass to charge ratio (m/z). In one sample, 1180 reproducible tentative metabolite ions were detected in negative mode and 1900 reproducible tentative metobolite ions detected in positive mode. Only biologically reproducible ions, defined as metabolite ions that were measured in different rats under the same treatment, were analyzed to reduce the complexity of the data. A metabolite peak list including m/z, mobility, and intensity generated for each metabolome was used to perform principle component analysis (PCA). Dynamic changes in metabolomes were investigated using principle components PC1 and PC2 that described 62% of the variation of the system in positive mode and 81% of the variation of the system in negative mode. Analysis of variance (ANOVA) was performed for PC 1 and PC2 and means were statistically evaluated. Profiles of intensifies were compared for tentative metabolite ions detected at different times before and after the rats were fed to identify the metabolites that were changing the most. Mobility-mass correlation curves (MMCC) were investigated for the different classes of compounds.

Published

2009

3. High-pressure ion mobility spectrometry

Author

Davis, Eric J., Dwivedi, Prabha, Tam, Maggie, Siems, William F., and Hill, Herbert H.

Subjects

Pressure -- Influence, Ionic mobility -- Research, Spectrum analysis -- Methods, Chemical weapons -- Properties, Chemistry

Abstract

The effects of above-ambient pressure on ion mobility on resolving power, resolution, and ion current were investigated using a small, stand-alone ion mobility spectrometer (IMS). This work demonstrates the first example of ion mobility spectrometry at pressures above ambient. Ion mobility spectra of chemical warfare agent (CWA) stimulant dimethyl methylphosphonate (DMMP) and several other standard compounds are shown for super-ambient conditions. The IMS was operated at pressures from 700 to 4560 Torr. An optimal resolving power was obtained at a specific voltage as a function of pressure, with higher optimal resolving powers obtained at higher voltages, as predicted from standard IMS theory. At high pressures, however, resolving power did not increase as much as theory predicted, presumably due to ion clustering. Nevertheless, an increase in pressure was found to improve resolution in IMS. One example where high pressure improved resolution was the separation of cyclohexylamine ([K.sub.0] = 1.83) and 2-hexanone ([K.sub.0] = 1.86) (where [K.sub.0] is the reduced mobility value). The product ions of these two compounds could not be separated at ambient pressure but could be nearly baseline separated when the pressure of the buffer gas was raised to 2280 Torr. Total ion current was also examined at pressures from ambient up to 4560 Torr. Total ion current, when investigated with pressure, was found to reach a maximum, initially rising with increased pressure.

Published

2009

4. Gas-phase chiral separations by ion mobility spectrometry

Author

Dwivedi, Prabha, Wu, Ching, Matz, Laura M., Clowers, Brian H., Siems, William F., and Hill, Herbert H., Jr.

Subjects

Spectrum analysis -- Usage, Chirality -- Research, Amino acids -- Research, Chemistry

Abstract

This article introduces the concept of chiral ion mobility spectrometry (CIMS) and presents examples demonstrating the gas-phase separation of enantiomers of a wide range of racemates including pharmaceuticals, amino acids, and carbohydrates. CIMS is similar to traditional ion mobility spectrometry, where gas-phase ions, when subjected to a potential gradient, are separated at atmospheric pressure due to differences in their shapes and sizes. In addition to size and shape, CIMS separates ions based on their stereospecific interaction with a chiral gas. In order to achieve chiral discrimination by CIMS, an asymmetric environment was provided by doping the drift gas with a volatile chiral reagent. In this study (S)-(+)-2-butanol was used as a chiral modifier to demonstrate enantiomeric separations of atenolol, serine, methionine, threonine, methyl [alpha]-glucopyranoside, glucose, penicillamine, valinol, phenylalanine, and tryptophan from their respective racemic mixtures.

Published

2006

5. Urinary Concentrations of the Antibacterial Agent Triclocarban in United States Residents: 2013-2014 National Health and Nutrition Examination Survey.

Author

Ye, Xiaoyun, Wong, Lee-Yang, Dwivedi, Prabha, Zhou, Xiaoliu, Jia, Tao, and Calafat, Antonia M.

Published

2016

6. Electrothermal Vaporization Sample Introduction for Spaceflight Water Quality Monitoring via Gas Chromatography-Differential Mobility Spectrometry.

Author

Wallace, William T., Gazda, Daniel B., Limercy, Thomas F., Minton, John M., Macatangay, Ariel V., Dwivedi, Prabha, and Fernández, Facundo M.

Published

2015

7. Plasma-Spray Ionization (PLASI): A Multimodal Atmospheric Pressure Ion Source for Liquid Stream Analysis.

Author

Kaylor, Adam, Dwivedi, Prabha, Pittman, Jennifer, Monge, María, Cheng, Guilong, Li, Shelly, and Fernández, Facundo

Subjects

*PLASMA spraying, *ATMOSPHERIC pressure, *LIQUID chromatography, *ELECTROSPRAY ionization mass spectrometry, *PLASMA gases

Abstract

A new ion generation method, named plasma-spray ionization (PLASI) for direct analysis of liquid streams, such as in continuous infusion experiments or liquid chromatography (LC), is reported. PLASI addresses many of the analytical limitations of electrospray ionization (ESI) and has potential for real time process stream analysis and reaction monitoring under atmospheric conditions in non-ESI friendly scenarios. In PLASI-mass spectrometry (MS), the liquid stream is pneumatically nebulized and partially charged at low voltages; the resultant aerosol is thus entrained with a gaseous plasma plume from a distal glow discharge prior to MS detection. PLASI-MS not only overcomes ESI-MS limitations but also generates simpler mass spectra with minimal adduct and cluster formation. PLASI utilizes the atomization capabilities of an ESI sprayer operated below the ESI threshold to generate gas-phase aerosols that are then ionized by the plasma stream. When operated at or above the ESI threshold, ionization by traditional ESI mechanisms is achieved. The multimodal nature of the technique enables readily switching between plasma and ESI operation. It is expected that PLASI will enable analyzing a wide range of analytes in complex matrices and less-restricted solvent systems, providing more flexibility than that achievable by ESI alone. [Figure not available: see fulltext.] [ABSTRACT FROM AUTHOR]

Published

2014

8. An Effective Approach for Coupling Direct Analysis in Real Time with Atmospheric Pressure Drift Tube Ion Mobility Spectrometry.

Author

Keelor, Joel, Dwivedi, Prabha, and Fernández, Facundo

Subjects

*ION mobility spectroscopy, *KIRLIAN photography, *ELECTRIC fields, *PHOTOIONIZATION, *PHARMACEUTICAL chemistry

Abstract

Drift tube ion mobility spectrometry (DTIMS) has evolved as a robust analytical platform routinely used for screening small molecules across a broad suite of chemistries ranging from food and pharmaceuticals to explosives and environmental toxins. Most modern atmospheric pressure IM detectors employ corona discharge, photoionization, radioactive, or electrospray ion sources for efficient ion production. Coupling standalone DTIMS with ambient plasma-based techniques, however, has proven to be an exceptional challenge. Device sensitivity with near-ground ambient plasma sources is hindered by poor ion transmission at the source-instrument interface, where ion repulsion is caused by the strong electric field barrier of the high potential ion mobility spectrometry (IMS) inlet. To overcome this shortfall, we introduce a new ion source design incorporating a repeller point electrode used to shape the electric field profile and enable ion transmission from a direct analysis in real time (DART) plasma ion source. Parameter space characterization studies of the DART DTIMS setup were performed to ascertain the optimal configuration for the source assembly favoring ion transport. Preliminary system capabilities for the direct screening of solid pharmaceuticals are briefly demonstrated. [Figure not available: see fulltext.] [ABSTRACT FROM AUTHOR]

Published

2014

9. Electro-Thermal Vaporization Direct Analysis in Real Time-Mass Spectrometry for Water Contaminant Analysis during Space Missions.

Author

Dwivedi, Prabha, Gazda, Daniel B., Keelor, Joel D., Limero, Thomas F., Wallace, William T., Macatangay, Ariel V., and Fernÿndez, Facundo M.

Subjects

*VAPORIZATION, *MASS spectrometry, *WATER, *MOLECULAR weights, *POLLUTANTS, *NITROGEN, *TIME-of-flight mass spectrometry

Abstract

The development of a direct analysis in real time-mass spectrometry (DART-MS) method and first prototype vaporizer for the detection of low molecular weight (~30-100 Da) contaminants representative of those detected in water samples from the International Space Station is reported. A temperature-programmable, electro-thermal vaporizer (ETV) was designed, constructed, and evaluated as a sampling interface for DART-MS. The ETV facilitates analysis of water samples with minimum user intervention while maximizing analytical sensitivity and sample throughput. The integrated DART-ETV-MS methodology was evaluated in both positive and negative ion modes to (1) determine experimental conditions suitable for coupling DART with ETV as a sample inlet and ionization platform for time-of-flight MS, (2) to identify analyte response ions, (3) to determine the detection limit and dynamic range for target analyte measurement, and (4) to determine the reproducibility of measurements made with the method when using manual sample introduction into the vaporizer. Nitrogen was used as the DART working gas, and the target analytes chosen for the study were ethyl acetate, acetone, acetaldehyde, ethanol, ethylene glycol, dimethylsilanediol, formaldehyde, isopropanol, methanol, methylethyl ketone, methylsulfone, propylene glycol, and trimethylsilanol. [ABSTRACT FROM AUTHOR]

Published

2013

10. Mass Spectrometry: Recent Advances in Direct Open Air Surface Sampling/lonization.

Author

Monge, Maria Eugenia, Harris, Glenn A., Dwivedi, Prabha, and Fernández, Facundo M.

Published

2013

11. Resistive Glass IM-TOFMS.

Author

Kimberly Kaplan, Graf, Stephan, Tanner, Christian, Gonin, Marc, Fuhrer, Katrin, Knochenmuss, Richard, Dwivedi, Prabha, and Hill, Jr., Herbert H.

Published

2010

12. Rapid Resolution of Carbohydrate Isomers by Electrospray Ionization Ambient Pressure Ion Mobility Spectrometry-Time-of-Flight Mass Spectrometry (ESI-APIMS-TOFMS)

Author

Dwivedi, Prabha, Bendiak, Brad, Clowers, Brian H., and Hill, Herbert H.

Subjects

*MASS spectrometry, *GLYCOSIDES, *MASS (Physics), *SPECTRUM analysis

Abstract

Carbohydrates are an extremely complex group of isomeric molecules that have been difficult to analyze in the gas phase by mass spectrometry because (1) precursor ions and product ions to successive stages of MSn are frequently mixtures of isomers, and (2) detailed information about the anomeric configuration and location of specific stereochemical variants of monosaccharides within larger molecules has not been possible to obtain in a general way. Herein, it is demonstrated that gas-phase analyses by direct combination of electrospray ionization, ambient pressure ion mobility spectrometry, and time-of-flight mass spectrometry (ESI-APIMS-TOFMS) provides sufficient resolution to separate different anomeric methyl glycosides and to separate different stereoisomeric methyl glycosides having the same anomeric configuration. Reducing sugars were typically resolved into more than one peak, which might represent separation of cyclic species having different anomeric configurations and/or ring forms. The extent of separation, both with methyl glycosides and reducing sugars, was significantly affected by the nature of the drift gas and by the nature of an adducting metal ion or ion complex. The study demonstrated that ESI-APIMS-TOFMS is a rapid and effective analytical technique for the separation of isomeric methyl glycosides and simple sugars, and can be used to differentiate glycosides having different anomeric configurations. [Copyright &y& Elsevier]

Published

2007

13. Separation of Sodiated Isobaric Disaccharides and Trisaccharides Using Electrospray Ionization-Atmospheric Pressure Ion Mobility-Time of Flight Mass Spectrometry

Author

Clowers, Brian H., Dwivedi, Prabha, Steiner, Wes E., Hill, Herbert H., and Bendiak, Brad

Subjects

*DISACCHARIDES, *ATMOSPHERIC pressure, *ORGANIC compounds, *MASS spectrometry

Abstract

A series of isobaric disaccharide-alditols, four derived from O-linked glycoproteins, and select trisaccharides were rapidly resolved using tandem high resolution atmospheric pressure ion-mobility time-of-flight mass spectrometry. Electrospray ionization was used to create the gas-phase sodium adducts of each carbohydrate. Using this technique it was possible to separate up to three isobaric disaccharide alditols and three trisaccharides in the gas phase. Reduced mobility values and experimentally determined ion-neutral cross sections are reported for each sodium-carbohydrate complex. These studies demonstrated that ion mobility separations at atmospheric pressure can provide a high-resolution dimension for analysis of carbohydrate ions that is complementary to traditional mass spectral (m/z) ion analysis. Combining these independent principles for separation of ions provides a powerful new bioanalytical tool for the identification of isomeric carbohydrates. [Copyright &y& Elsevier]

Published

2005

14. Microplasma Ionization of Volatile Organics for Improving Air/Water Monitoring Systems On-Board the International Space Station.

Author

Bernier, Matthew, Alberici, Rosana, Keelor, Joel, Dwivedi, Prabha, Zambrzycki, Stephen, Wallace, William, Gazda, Daniel, Limero, Thomas, Symonds, Josh, Orlando, Thomas, Macatangay, Ariel, and Fernández, Facundo

Subjects

*ION sources, *MINIATURE electronic equipment, *AIR quality monitoring, *MICROPLASMAS, *IONIZATION (Atomic physics)

Abstract

Low molecular weight polar organics are commonly observed in spacecraft environments. Increasing concentrations of one or more of these contaminants can negatively impact Environmental Control and Life Support (ECLS) systems and/or the health of crew members, posing potential risks to the success of manned space missions. Ambient plasma ionization mass spectrometry (MS) is finding effective use as part of the analytical methodologies being tested for next-generation space module environmental analysis. However, ambient ionization methods employing atmospheric plasmas typically require relatively high operation voltages and power, thus limiting their applicability in combination with fieldable mass spectrometers. In this work, we investigate the use of a low power microplasma device in the microhollow cathode discharge (MHCD) configuration for the analysis of polar organics encountered in space missions. A metal-insulator-metal (MIM) structure with molybdenum foil disc electrodes and a mica insulator was used to form a 300 μm diameter plasma discharge cavity. We demonstrate the application of these MIM microplasmas as part of a versatile miniature ion source for the analysis of typical volatile contaminants found in the International Space Station (ISS) environment, highlighting their advantages as low cost and simple analytical devices. [ABSTRACT FROM AUTHOR]

Published

2016