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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

TWO-DIMENSIONAL TANDEM MASS SPECTROMETRY: INSTRUMENTATION AND APPLICATION

Lucas J Szalwinski (12469362) 27 April 2022 (has links)
<p>Mass spectrometry has become the premium chemical identification method. The next advancement for mass spectrometry is the widespread use of mass spectrometers for on-site chemical/biological identification. Ion trap mass spectrometers have emerged as powerful on-site analytical platforms, in spite of limited mass resolution, due to their compatibility with ambient ionization methods and ready implementation of tandem mass spectrometry (MS/MS). However, conventionally operated ion traps are inefficient in accessing the entire tandem mass spectrometry dataspace. By operating the ion trap at a constant trapping voltage, more efficient tandem mass spectrometry scan modes are accessible. The most efficient is to acquire the entire tandem mass spectrometry data space and this work demonstrates three different methods of acquiring this data domain. These methods acquire the data in under a second and the best performing method was implemented in a miniature mass spectrometer without performance decrease. The impact of this device is most powerful when analysis requires the entire ionized sample be considered to determine the identity of the sample. This was shown to be useful for monitoring the lipid metabolism in a model microorganism. </p>
2

MULTI-DIMENSIONAL MASS SPECTROMETRY, MICROBES, AND THE DEMONS AMONGST THEM: RAPID UNTARGETED PROFILING OF MICROORGANISMS

L. Edwin Gonzalez (7289045) 30 November 2023 (has links)
<p dir="ltr">Mass spectrometry has been at the forefront of complex mixture analysis and, as a result, has greatly advanced the understanding of biological systems with its application in the biological sciences. One area in which mass spectrometry has succeeded is the area of microbiology and the identification of pathogens and has gained much attention from the biothreat detection community. Although this technology has matured in the past decade, very few systems have been developed for point-of-need analysis in cases such as the detection of biothreats. Current MS systems for the analysis of microbes utilizing MALDI-TOF-MS require large instruments to accommodate a drift tube long enough for high resolution mass analysis and high vacuum which is not amenable to the miniaturization requirements of point-of-need analysis. The previously mentioned methods also require extensive manipulation of the sample which takes time and can pose a risk to instrument operators in the biothreat detection space. Additionally, most mass spectrochemical instruments provide only one-dimension of data which can limits classification accuracy when using classification algorithms to provide an identity on a microbiological sample which could consist of any of the numerous common bacterial pathogens or biothreats.</p><p dir="ltr">A possible solution to this problem is the implementation of two-dimensional tandem mass spectrometry (2D MS/MS) which allows the analysis of the product ions of all precursor ions representing the result in the 2D MS/MS data domain. This methodology is possible with a linear quadrupolar ion trap mass analyzer and can be applied to miniature ion trap technology for portability. In this dissertation, a progression of mass spectrochemical analysis of biological systems from conventional methods to the implementation of 2D MS/MS is demonstrated: by (i) the development of a rapid biomolecule extraction method to analyze bacterial spores, using a (ii) modified linear quadrupolar ion trap mass spectrometer, (iii) then a miniature ion trap mass spectrometer, and (iv) finally adding numerical methods to discriminate between biological systems using data acquired on each 2D MS/MS instrument. This work is then taken a step further by developing a high throughput experimentation method in which DESI is coupled to 2D MS/MS to analyze a moderate number of samples rapidly, automatically, and with high reproducibility.</p>

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