Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging

Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging

Bibliographic Details
Main Author: Endres, Kevin J.
Language:English
Published: University of Akron / OhioLINK 2019
Subjects:
Chemistry
Analytical Chemistry
Materials Science
Polymer Chemistry
Polymers
mass spectrometry
tandem MS
polymer
terpyridine self-assemblies
coordination
equilibrium
ion mobility
collision cross-section
surface layer MALDI
ASAP
pyrolysis
cross-linking
hydrogel
MALDI MS Imaging
sublimation
polystyrene
PEG
thin film
Online Access:http://rave.ohiolink.edu/etdc/view?acc_num=akron1553096604194835
id ndltd-OhioLink-oai-etd.ohiolink.edu-akron1553096604194835
record_format oai_dc
collection NDLTD
language English
sources NDLTD
topic Chemistry
Analytical Chemistry
Materials Science
Polymer Chemistry
Polymers
mass spectrometry
tandem MS
polymer
terpyridine self-assemblies
coordination
equilibrium
ion mobility
collision cross-section
surface layer MALDI
ASAP
pyrolysis
cross-linking
hydrogel
MALDI MS Imaging
sublimation
polystyrene
PEG
thin film
spellingShingle Chemistry
Analytical Chemistry
Materials Science
Polymer Chemistry
Polymers
mass spectrometry
tandem MS
polymer
terpyridine self-assemblies
coordination
equilibrium
ion mobility
collision cross-section
surface layer MALDI
ASAP
pyrolysis
cross-linking
hydrogel
MALDI MS Imaging
sublimation
polystyrene
PEG
thin film
Endres, Kevin J.
Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging
author Endres, Kevin J.
author_facet Endres, Kevin J.
author_sort Endres, Kevin J.
title Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging
title_short Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging
title_full Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging
title_fullStr Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging
title_full_unstemmed Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging
title_sort mass spectrometry methods for macromolecules: polymer architectures, cross-linking, and surface imaging
publisher University of Akron / OhioLINK
publishDate 2019
url http://rave.ohiolink.edu/etdc/view?acc_num=akron1553096604194835
work_keys_str_mv AT endreskevinj massspectrometrymethodsformacromoleculespolymerarchitecturescrosslinkingandsurfaceimaging
_version_ 1719454721787297792
spelling ndltd-OhioLink-oai-etd.ohiolink.edu-akron15530966041948352021-08-03T07:09:37Z Mass Spectrometry Methods For Macromolecules: Polymer Architectures, Cross-Linking, and Surface Imaging Endres, Kevin J. Chemistry Analytical Chemistry Materials Science Polymer Chemistry Polymers mass spectrometry tandem MS polymer terpyridine self-assemblies coordination equilibrium ion mobility collision cross-section surface layer MALDI ASAP pyrolysis cross-linking hydrogel MALDI MS Imaging sublimation polystyrene PEG thin film This dissertation describes the development of novel mass spectrometry (MS) methodologies and techniques to improve, simplify and allow for specific characterizations of synthetic materials. Successful MS analyses are governed by the mass spectrometry principles surrounding specific ionization sources, mass analyzers and ion detecters. The methods described within this dissertation provide information about polymer materials that is historically difficult to determine using other available analytical techniques.Self-assembled terpyridine (tpy)-based metallomacrocycles that are coordinatively-bound using various transition metals were investigated through the analysis of their collision cross-section (CCS) values obtained by travelling wave ion mobility (TWIM)-MS separation, and through comparison to modeled/simulated structures and theoretical CCS values. This work demonstrated the uniquely powerful ability of TWIM-MS separation for architectural verification in samples containing stoichiometrically-defined isobaric ion species ranging from dimeric macrocycles to hexameric macrocycles. Furthermore, TWIM-MS was utilized in a separate project which allowed for the development of a method to monitor concentration dependent supramolecular structural equilibria and conformational trends. Using the methodology in this work, equilibrium constants were derived from these data; this was illustrated for two equilibria concerning the self-assembly of a tpy-based ligand containing a flexible crown ether moiety with Zn2+ ions, and a tetrakisterpyridinyl ligand with Cd2+ ions, which have previously been shown to reversibly interconvert. Additionally, experimental CCS values were also derived from drift time measurements and compared with theoretical predictions for these complex self-assembled terpyridine-based supramolecules to provide insight into their size, stoichiometry and architecture.Parallel studies have focused on the development of methods that can obtain connectivity and compositional information about covalently cross-linked polymers. The atmospheric solids analysis probe (ASAP) ionization source has been combined with MS, tandem MS (MS/MS) and TWIM to create an effective top-down technique for the molecular characterization of the mentioned materials, which were utilized in this project to address persisting structural questions about synthetic polymer cross-linking microstructures. The structural insight gained from these studies was illustrated by the analysis of two hydrogels: 1) oxime cross-linked poly(ethylene glycol) (PEG) hydrogels formed from the click-reaction between 4-arm PEG star polymers with levulinamide or levulinic acid end group functionalities and 4-arm PEG star polymers with aminoxyacetaamide or aminooxyacetic acid end group functionalities, and 2) cross-linked poly(methacrylate) (PMA)-PEG hydrogels formed from PEGdimethacrylate (PEGDMA) polymerized via radical propagation in the presence of a lithium acylphosphazine (LAP) photoinitiator and ultraviolet (UV) light. Lastly, the design of a surface-specific imaging technique with a probing depth of <2 nm, surface-layer matrix-assisted laser desorption ionization mass spectrometry imaging (SL-MALDI-MSI) is described. This technique has been developed and utilized to detect and elucidate defects in poly(styrene) (PS) and poly(methyl methacrylate) (PMMA) films. There are four major advantages of SL-MALDI-MSI over other surface analysis techniques, which are: (1) high specificity, as only the selected mass is measured; (2) direct information of the intact macromolecule rather than ambiguous data from molecular fragments or elements that may lead to misidentification of molecules at the surface; (3) no need for any fluorescent tagging or isotopic labelling; and (4) the possibility to perform MS/MS experiments. 2019-06-20 English text University of Akron / OhioLINK http://rave.ohiolink.edu/etdc/view?acc_num=akron1553096604194835 http://rave.ohiolink.edu/etdc/view?acc_num=akron1553096604194835 unrestricted This thesis or dissertation is protected by copyright: all rights reserved. It may not be copied or redistributed beyond the terms of applicable copyright laws.

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