Global ETD Search

1	Elimination of Electrochemical Oxidation during Sample Ionization Using Liquid Sample Desorption Electrospray Ionization (DESI) Almowalad, Najah K., January 2016 (has links) No description available. Analytical Chemistry Electrospray Ionization Desorption Electrospray Ionization
2	Development of Ambient Mass Spectrometry for Protein/Peptide Characterization, Solvent-Free Analysis, and Electrochemical Reaction Monitoring Liu, Pengyuan 25 August 2015 (has links) No description available. Analytical Chemistry Chemistry Biochemistry Ambient mass spectrometry probe electrospray ionization proteomics solvent-free electrochemistry
3	Development of Thermal Desorption Electrospray Ionization Mass Spectrometry and its Applications in Food Safety Liu, Te-Lin 28 July 2012 (has links) Ambient ionization mass spectrometry, which has witnessed a flurry of recent developments, is a set of useful techniques for the analysis of samples under open-air conditions. It allows direct, rapid, real-time, high-throughput analysis with little or no sample pretreatment for the chemicals in solids or liquids. In this study, thermal desorption electrospray ionization mass spectrometry ( TD-ESI/MS ) involving direct insertion probe ( DIP ), thermal desorption ( TD ) and electrospray ionization ( ESI ) was used for the rapid screening of various types of samples. The source mainly consists of the sampling probe device, thermal desorption heating device, electrospray ionization device, ion source and temperature controller. A novel strategy involved in TD-ESI/MS processes where sampling, desorption, and ionization are separated as three independent events. The sampling probe is first used for the sampling of analytes and then inserted into a heat unit for thermal desorption. The desorbed analytes are finally carried into a reaction region with a stream of nitrogen gas, where charged methanol droplets were generated continuously by electrospray for post-ionization. Total analysis time is less than 10 seconds. Traditionally, three standard methods are used for the analysis for pesticide residues, biochemical, immunoassay and instrument. And, the instrument analysis is the most widely used because it provides lots of advantages in particularly accurate quantitative approach. However, its complicated steps take a long period of time for preparation. Here, we used TD-ESI/MS to rapidly screen the pesticide residues on the surface of fruits and vegetables. The MS/MS analysis was also performed to confirm those detected compounds. The experimental results of the standard deviation for reproducibility is 13.2% (n = 10), and the detection limit is approximately 10 ppb. Furthermore, several fruits and vegetables purchased from local market were used as test samples and pesticide residues on the surface of samples can be successfully detected via TD-ESI/MS. In addition, the TD-ESI/MS technique was also applied to the analysis of illegal additives or phthalates in food. In this study, the TD-ESI/MS technique emerges lots of advantages such as direct, rapid, real-time analysis of sample surface and sample pretreatment is not necessary, and shows highly potential for rapid screening of chemicals in food safety. ambient ionization mass spectrometry pesticide residues phthalates sampling probe
4	Mass Spectrometric Analysis of Thiol Proteins/Peptides Following Selenamide Derivatization And Electrolytic Reduction of Disulfide Bonds Zhang, Yun January 2012 (has links) No description available. Chemistry Mass spectrometry Desorption electrospray ionization Electrochemistry Thiol derivatization Disulfide bonds reduction Top-down protein analysis
5	Development and Applications of Liquid Sample Desorption Electrospray Ionization Mass Spectrometry (DESI-MS) Miao, Zhixin January 2012 (has links) No description available. Chemistry protein conformation fast reaction kinetics liquid chromotography-mass spectrometry protein supercharging
6	Characterization of the Desorption Electrospray Ionization Mechanism Using Microscopic Imaging of the Sample Surface Wood, Michael Craig 04 August 2011 (has links) (PDF) Desorption electrospray ionization (DESI) is an ambient ionization technique for mass spectrometry. This solvent based desorption ion source has wide applicability in surface analysis with minimal sample preparation. Interest in improving detection limits, broadening applications, and increasing the spatial resolution for chemical imaging has led to studies of the DESI mechanism. An inverted microscope has been used to image interactions between the DESI spray and test analytes on a glass surface. Microscopic images recorded with millisecond time resolution have provided important insights into the processes governing analyte transport and desorption. These insights are the basis of a rivulet-based model for desorption that differs significantly from the widely-accepted momentum transfer model. DESI Desorption Electrospray Ionization Microscopic Imaging Real-time Mechanism Fluorescence Absorption Coating Rivulets Mass Spectrometry Biochemistry Chemistry
7	Coupling Ambient Ionization Mass Spectrometry with Liquid Chromatography and Electrochemistry and Their Applications Cai, Yi January 2016 (has links) No description available. Chemistry Analytical Chemistry desorption electrospray ionization probe electrospray ionization liquid chromatography electrochemistry ultrafast separation
8	Ambient ionization mass spectrometry for the forensic screening of pharmaceuticals and the determination of potential drug candidates Nyadong, Leonard 12 November 2009 (has links) Ambient mass spectrometry (MS) is a new and growing sub-field in MS which has opened new research avenues, particularly for applications relating to the analysis of solid samples. Results on the implementation and application of ambient MS techniques including: desorption electrospray ionization (DESI) and direct analysis in real time (DART) indicated that these techniques could serve as complementary tools for the rapid qualitative screening of pharmaceuticals, allowing up to two orders of magnitude improvement in throughput compared to traditional methods such as liquid chromatography MS. The selectivity of DESI could be enhanced by performing the experiment in the reactive mode. In this mode, complexation reactions between reagents added to the spray solvent and analytes on the sample surface resulted in analyte stabilization, inhibiting fragmentation. They also resulted in a concomitant enhancement in the analyte surface activity, facilitating their evaporation from secondary droplets culminating in an improvement in sensitivity. Also for drug tablets analysis, the analyte signal dependency on DESI geometrical set-up variables could be mitigated following the careful and controlled addition of an isotopically labeled internal standard (IS) to the sample or by spraying samples with a pair of reagents with different affinities for the analyte. Either of these approaches resulted in an analyte-to-IS signal ratio (in the former) or an analyte complex ratio (in the later), which was largely independent of DESI experimental variables allowing quantitative analysis using this technique. DESI MS was also observed to be a very powerful tool for determining the 2-D distribution of various pharmaceutically important compounds on tablet and tissue surfaces. The ability to map the distribution of molecules of interest by DESI MS has very great implications in drug tablet quality control and in determining the role of chemical signals presented on tissue surfaces. DESI was observed to be limited to ionizing molecules of medium to high polarities without much limitation in terms of mass range, whereas DART was better suited for the analysis of molecules within a broader range of polarities, but within a more limited mass range (up to 800 Da approximately). These limitations were circumvented by implementing a novel multimode ambient ion source, desorption electrospray/metastable-induced ionization (DEMI), which combines various aspects of DESI and DART. Initial experiments with the DEMI ion source demonstrated its ability to enable the simultaneous analysis of molecules within a broader range of polarities and masses than DESI and DART alone. Direct analysis in real time Counterfeit drugs Antimalarials Artemisinins Desorption electrospray ionization Ambient mass spectrometry Mass spectrometry Mass spectrometry Forensic applications Chemistry, Forensic
9	The Development, Implementation and Application of Ambient Ionization Mass Spectrometry to Complex Polymeric Systems Whitson, Sara E. 17 December 2008 (has links) No description available. Chemistry Polymers mass spectrometry polymers polystyrene polyurethane ambient ionization
10	Desorption Electrospray Ionization Mass Spectrometry Imaging: Instrumentation, Optimization and Capabilities Dhunna, Manan 13 March 2014 (has links) (PDF) Desorption Electrospray Ionization Mass spectrometry Imaging (DESI-MSI) is an area of great interest and a promising tool in the field of chemical imaging. It is a powerful, label-free technique, which can determine, map and visualize different molecular compounds on a sample surface. The amount of information acquired in a single DESI-MSI experiment is enormous compared to other techniques, as it can simultaneously detect different compounds with their spatial distribution on the surface. The experiment can be used to produce two-dimensional and three-dimensional images. Chapter 2 focuses on the design and optimization of the setup for performing DESI-MS imaging on various substrates. The proposed setup was tested for its lateral spatial resolution. To provide proof-of-concept of the design, preliminary tests were performed to generate images from commercial thin layer chromatographic plates and photographic paper. Chapter 3 focuses on demonstrating the compatibility of novel microfabricated Thin Layer Chromatography plates (M-TLC plates) for detection with DESI-MSI. Desorption Electrospray Ionization DESI DESI-MSI M-TLC Ambient Ionization Mass Spectrometry Biochemistry Chemistry

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