AMBIENT ELECTROSTATICS OF IONS AND CHARGED MICRODROPLETS PRODUCED VIA NANOELECTROSPRAY IONIZATION

Saquib Rahman (12030023)

25 July 2023

<p>Mass spectrometry, the science and technology of ions, owes much of its current popularity to the development of electrospray ionization. The development of electrospray ionization, along with its low flow-rate analog nanoelectrospray ionization, has increased the chemical space that can be investigated using mass spectrometers by orders of magnitude. While the interfacial chemistry of charged microdroplets that are generated by nanoelectrospray has been studied in detail, the physics of their motion, particularly in the presence of an applied field at ambient pressures, remains relatively unexplored. In this dissertation, an increase in ion currents detected by a commercial triple quadrupole mass spectrometer is used to demonstrate that: (i) the orthogonal injection of counterions into an electrode assembly can compensate for space charge effects and enhance the sampling of charged microdroplets from a nanoelectrospray focused electrostatically under ambient conditions into the mass spectrometer; and (ii) the ease of ion evaporation from charged microdroplets may be elucidated for small molecules based on their relative transmission through an electrode assembly for the simultaneous ambient electrostatic focusing of two nanoelectrosprays. In each case, the development is characterized by using ion trajectory calculations in conjunction with experiments, using homebuilt devices designed and fabricated in-house as rapid prototypes via 3D printing. In the open air, charged microdroplets have low kinetic energies with a narrow energy spread. Despite these limitations, this dissertation demonstrates, through the electrostatic manipulation of charged microdroplets produced via nanoelectrospray ionization, that a better understanding of the physics of moving charges in the open air can be used to increase the sensitivity of atmospheric pressure ionization.</p>

Analytical spectrometry

mass spectrometry

rapid prototyping

3D printing

nanoelectrospray ionization

electrostatics

ambient ionization source development

GAS-PHASE ION CHEMISTRY AND ION TRAP METHODOLOGIES FOR TRANSMETALATION REACTIONS AND IN-DEPTH LIPID ANALYSIS

Kimberly C Fabijanczuk (17364238)

14 November 2023

<p dir="ltr">Originating from J. J. Thomsons original work and the development of electrospray ionization (ESI) by John B. Fenn, mass spectrometry offers a versatile analytical tool to measure beyond an ion’s m/z, especially for biomolecules. Gas-phase ion/ion reactions within a mass spectrometer offers an attractive approach to study biomolecules as they take place on the millisecond and sub millisecond time scale, have high efficiency, allow oppositely charged ions to interact with each other in a controlled manner, and a allows for selection of each reactant prior to the reaction via ion isolation. This can be used to probe gas-phase chemistry that can reflect reactions in solution, however gas-phase reactions have no solvent effects and happen faster, making it a simpler experiment. Here, a variety of gas-phase ion/ion reactions and ion trap methodologies are described to study mostly lipids with a minor amount of transmetalation at the beginning.</p><p dir="ltr">First, a series of multivalent metals complexed to neutral ligands are demonstrated to form ion-pairs with tetraphenylborate anions via ion/ion reactions. The resulting products were subjected to collision induced activation (CID) to observe their involvement in transmetalation, complementary density functional theory (DFT) calculations are provided as well. Next, sequential ion/ion reactions were performed to convert isomeric phosphoinositol phosphates dianions to monocations to reveal structural characterization and isomeric differentiation utilizing tandem MS and dissociation kinetics. The following two chapters after, reports on complementary efforts to separate lipids in the gas-phase of different mass and charge but similar mass-to-charge (m/z) resulting in overlapping m/z signals. The first report demonstrates a physical approach where singly and double charged lipids are separated in space from each other, trapped simultaneously such that no information is lost. The second utilizes a lanthanide, Yb3+ trication complex that underwent ion/ion reactions with singly and doubly charged lipid anions of similar m/z that result in different m/z products for each singly and doubly charged lipids. Lastly, a sequential ion/ion approach utilizing hexa(ethylene glycol) dithiol as a novel reagent to charge invert structurally uninformative lipid cations to structurally informative anions with subsequent carbon-carbon double bond localization.</p>

Analytical spectrometry

Gas-Phase Ion Chemistry

Ion/ion reactions

shotgun lipidomics

transmetalation

charge state separation

lipid isomeric analysis

Minghe Li thesis final.pdf

Minghe Li (14184599)

29 November 2022

<p>The thesis consists of two main parts of nonlinear optical instrumentation development. </p> <p>Fluorescence-detected mid-infrared photothermal (F-PTIR) microscopy is demonstrated for sub-diffraction limited mid-infrared microspectroscopy of model systems and applied to probe phase transformations in amorphous solid dispersions. To overcome the diffraction limit in infrared imaging, a highly localized temperature-dependent photothermal effect is an attractive alternative indicator to infrared absorption. Photothermal atomic force microscopy infrared spectroscopy (AFM-IR) achieves nanometer resolution by monitoring heat caused expansion but only restricted on the surface. For 3D imaging, optically detected photothermal infrared (O-PTIR) combines an infrared laser with a visible probe source with to transduce photothermal refractive index changes (e.g., from changes in beam divergence or scattering). The sensitivity of O-PTIR is ultimately limited by the relatively weak dependence of refractive index with temperature, exhibiting changes of ~0.01% per oC. Fluorescence-detected photothermal mid-infrared (F-PTIR) spectroscopy (Fig. 1) is demonstrated herein to support 3D imaging with improved photothermal sensitivity. In F-FTIR, the sensitivity of fluorescence quantum efficiency to temperature change (~1-2% per oC) is used to transduce transient heat flux from localized IR absorption. The infrared spatial resolution of F-FTIR is defined by fluorescence microscopy and the thermal diffusivity of the sample instead of infrared wavelength. Initial F-PTIR proof of concept studies are described for microparticle assemblies of silica gel and polyethylene glycol, followed by applications of F-PTIR for analysis of localized composition within phase-separated domains induced by water vapor exposure of an amorphous solid dispersion (ritonavir in copovidone).</p> <p>Fluorescence recovery while photobleaching (FRWP) is demonstrated as a method for quantitative measurements of rapid diffusion mapping over the microsecond to millisecond time scale. Diffusion measurements are critical for molecular mobility assessment in cell biology, materials science and pharmacology. Fluorescence recovery after photobleaching (FRAP) is a well-known noninvasive optical microscopy method for measuring diffusion coefficients of macromolecules, such as proteins in cells and viscous solutions. However, conventional point-bleach FRAP is challenging to implement with multi-photon excitation and typically only supports diffusion analysis over millisecond time scales due to camera frame rate limitations. FRWP with patterned illumination addresses these limitations of FRAP by probing the fluorescence intensity changes while bleaching a comb pattern within a field of view (FoV). Fast-scanning of an ultrafast excitation beam distributes heat rapidly over multiple adjacent pixels, minimizing local heating effects that could complicate analogous diffusion measurements by point-bleach FRAP with multiphoton excitation. In FRWP, time-scales of the probed diffusion events are defined by a single line-pass time of a resonant scanning-mirror with a period of 125  s. In FRWP, the bleach pattern spans locations across the whole FoV, enabling diffusion mapping through image segmentation. More than a hundred bleaching and recovery events can be recorded during a single 10s measurement. Normal and anomalous diffusion of rhodamine-labeled bovine serum albumin (BSA) molecules was studied as a model system, with applications targeting rapid assessment of therapeutic macromolecule mobility within heterogeneous biological environments.</p>

Analytical spectrometry

photothermal IR spectroscopy

second harmonic generation

two photon flurescence

Bioavailability and Transformation of Silver Nanoparticles in the Freshwater Environment

Brittle, Seth William

January 2016

No description available.

Environmental Science

Chemistry

Nanoscience

Analytical Chemistry

silver nanoparticles

nanosilver

Nanotechnology

colloids

Instrumental Methods

ICP-OES

freshwater crayfish

benthic zone-indicator

Raman spectroscopy

nanoparticle adsorption

hyrdrated minerals

GAS-PHASE STUDIES OF METAL IONS IN BIOMOLECULE IONS

Nicole Michelle Brundridge (18290698)

03 April 2024

<p dir="ltr">Metal ions are typically considered a nuisance for mass spectrometry, as they can introduce chemical noise and distribute an analyte’s signal into multiple peaks. In some cases however, metal ions in biological solutions are either necessary for biomolecular structures, or so ubiquitous in a sample’s native solution conditions that they are difficult to fully remove. In this work, the role of metal ions in biological analytes is explored. For analytes that require metal ions to maintain higher order structures, a mass spectrometry method was developed to determine whether a stable structure is formed from metal ion adducts, or if the metal ion adducts are nonspecifically bound. Electron transfer of these structures reveals complementary fragmentation information, with the added discovery of new radical fragmentation pathways. With mass spectrometry, specific ligand and metal ion affinities can even be determined for analytes at low enough concentrations. In addition to analytes that require metals, an exploration on unwanted metal ion adduction during the electrospray ionization process is shown via gas-phase ion/ion reactions. Observing how specific anionic ligands exchange metals with protons from proteins on a small and controlled scale gives a greater understanding of what solutions can lead to the cleanest results. In addition, this work shows the possibility of finding anionic ligands that will instead exchange protons with metal ions found on proteins. In the gas-phase, these experiments have a high degree of control, leading to a much greater understanding of how metal ions influence mass spectrometry samples.</p>

Analytical spectrometry

Mass Spectrometry

G-Quadruplex

Electrospray ionization

Ion/Ion reaction

Collision-induced dissociation

<b>Development of a digital Dual-trap mass spectrometer for gas-phase ion/ion chemistry studies of High-Mass Biomolecules</b>

Liangxuan Fu (19154452)

17 July 2024

<p dir="ltr">Multiply-charged ions of intact biomolecules generated from electrospray ionization (ESI) have drawn researchers' interest in the field of native mass spectrometry (MS) for decades because these ions carry mass and charge information of the intact molecules and interactions among different units. However, the confinement of multiple charge states in a narrow range of <i>m/z</i> makes mass and charge assignments challenging, especially for analytes with a mass greater than 100 kDa. Gas-phase ion/ion reactions have proven to be powerful techniques that facilitate the interpretation of mass spectra of natively sprayed macromolecular analytes by manipulating the masses and charges of ions detected.</p><p dir="ltr">The proton-transfer reaction (PTR) is the most used gas-phase ion/ion reaction method. It utilizes perfluorinated PTR reagents to "grab" protons away from the analyte ions, thereby reducing their charges. A novel charge state manipulation technique called "ion parking," based on PTR, has been developed. In this method, ion signals are accumulated to one or a range of charge states by selectively inhibiting reactions between the target charge state and the PTR reagents via resonance excitation.</p><p dir="ltr">The multiply-charged ion attachment (MIA) reaction is another gas-phase ion/ion reaction approach. It utilizes the significant <i>m/z</i> displacement caused by the attachment of multiply-charged reagent ions, and it has been proven useful for mass analysis of heterogeneous macromolecular analytes with a mass greater than 1 MDa.</p><p dir="ltr">All gas-phase ion/ion reaction techniques require mutual storage of ions in opposite polarities within an electrodynamic quadrupole ion trap, such as a 3D quadrupole ion trap (QIT) or a linear quadrupole ion trap (LIT). Electrodynamic ion traps use high-voltage (HV) drive radio frequencies (RF) to trap ions in a quadrupolar field, typically employing a sinusoidal waveform (sine wave). A digital quadrupole ion trap (DIT) is an unconventional electrodynamic ion trap that uses a digital waveform (square wave) as the drive RF. The high agility of square waves makes DIT an ideal mass analyzer for studying high <i>m/z</i> ions resulting from gas-phase ion/ion reactions. This dissertation describes the development of a novel home-built digital dual-trap mass spectrometer and ion/ion chemistry studies of large biomolecules within the instrument.</p>

Analytical spectrometry

Digital ion trap

Gas-phase ion/ion chemistry

Mass spectrometry

Native MS

MS instrumentation

ADVANCES OF MID-INFRARED PHOTOTHERMAL MICROSCOPY FOR IMPROVED CHEMICAL IMAGING

Chen Li (8740413)

22 April 2020

<div>Vibrational spectroscopic imaging has become an emerging platform for chemical visualization of biomolecules and materials in complex systems. For over a century, both Raman and infrared spectroscopy have demonstrated the capability to recognize molecules of interest by harnessing the characteristic features from molecular fingerprints. With the recent development of hyperspectral vibrational spectroscopy imaging, which records the chemical information without sacrificing the spatial-temporal resolution, numerous discoveries has been achieved in the field of molecular and cellular biology. Despite the ability to provide complimentary chemical information to Raman-based approaches, infrared spectroscopy has not been extensively applied in routine studies due to several fundamental limitations: 1). the poor spatial resolution; 2). inevitable strong water absorption; 3). lack of depth resolution.</div><div>Mid-infrared photothermal (MIP) microscopy overcame all the above mentioned problems and for the first time, enabled depth-resolved in vivo infrared imaging of live cells, microorganisms with submicrometer spatial resolution. The development of epi-detected MIP microscopy further extends its application in pharmaceutical and materials sciences. With the deployment of difference frequency generation and other nonlinear optical techniques, the spectral coverage of the MIP microscopy was significantly enhanced to enable chemical differentiation in complex systems across the broad mid-infrared region. In addition to the efforts to directly improve the performance of MIP microscopy, a novel quantitative phase imaging approach based on polarization wavefront shaping via custom-designed micro-retarder arrays was developed to take advantage of the highly sensitive phase measurement in combination with the photothermal effect. Besides, the extended depth-of-field and multifocus imaging enabled by polarization wavefront shaping could both improve the performance of MIP microscopy for volumetric imaging.</div>

Nonlinear Optics and Spectroscopy

Structural Chemistry and Spectroscopy

Photothermal Microscopy

Chemical Imaging

IR spectroscopic study

Second Harmonic Generation Imaging

quantitative phase imaging

Wavefront shaping

two photon microscopy

IR imaging

Advances in gas chromatography, thermolysis, mass spectrometry, and vacuum ultraviolet spectrometry

Ashur Scott Rael (10701216)

11 May 2021

In the area of forensic chemistry, improved or new analysis methods are continually being investigated. One common and powerful technique used in forensic chemistry is wall-coated open-tubular column (WCOT) gas chromatography with electron ionization single quadrupole mass spectrometry (GC-MS). Improvements to and effectiveness of alternatives to this instrumental platform were explored in an array of parallel inquiries. The areas studied included the column for the chromatographic separation, the universal detection method employed, and the fragmentation method used to enhance molecular identification. <br><br>Superfine-micropacked capillary (SFµPC) columns may provide an alternative to commercial packed GC columns and WCOT GC columns that combines the benefits of the larger sample capacity of packed columns and the benefits of the excellent separation capabilities and mass spectrometry (MS) flow rate compatibility of WCOT columns. SFµPC columns suffer from high inlet pressure requirements and prior reported work has required specialized instrumentation for their use. Fabrication of and chromatography with SFµPC GC columns was successfully achieved with typical GC-MS instrumentation and within the flow rate limit of a MS. Additionally, the use of higher viscosity carrier gasses was demonstrated to reduce the required inlet pressure for SFµPC GC columns.<br><br>Recently, a new vacuum ultraviolet spectrometer (VUV) universal detector has been commercialized for GC. The ability of VUV detectors to acquire absorbance spectra from 125 nm to 430 nm poses a potential alternative to MS. As such, GC-VUV provides an exciting potential alternative approach to achieving excellent quantitative and qualitative analysis across a wide range of analytes. The performance of VUV and MS detectors for forensic analysis in terms of quantitative and qualitative analysis was compared. Analysis of alkylbenzenes in ignitable liquids was explored, which can be important evidence from suspected arson fires and are difficult to differentiate with MS. The VUV detector was found to have superior specificity and comparable sensitivity to the MS detector in scan mode.<br><br>Addition of thermolysis (Th) as an orthogonal fragmentation pathway provides the opportunity to increase the differences between MS fragmentation patterns. Fragmentation has been widely established to aid in identification of molecules with MS by providing characteristic fragments at characteristic relative abundances. However, molecules with very similar structures do not result in sizable spectral differences in all cases with typical MS fragmentation techniques. A series of Th units were fabricated and integrated into GC-Th-MS instruments. Th-MS was conducted with the thermally labile nitrate esters across a range of instrumentation and thermal conditions.<br>

Analytical Spectrometry

Separation Science

Structural Chemistry and Spectroscopy

Forensic Chemistry

gas chromatography

packed capillary

vacuum ultraviolet spectrsoscopy

far ultraviolet spectroscopy

mass spectrometry

thermolysis

pyrolysis

AMBIENT IONIZATION MASS SPECTROMETRY FOR HIGH THROUGHPUT BIOANALYSIS

Nicolas Mauricio Morato Gutierrez (16635960)

25 July 2023

<p>The rapid analysis of complex samples using mass spectrometry (MS) provides valuable information in both point-of-care (e.g. drug testing) and laboratory-based applications, including the generation of spectral libraries for classification of biosamples, the identification of biomarkers through large-scale studies, as well as the synthesis and bioactivity assessments of large compound sets necessary for drug discovery. In all these cases, the inherent speed of MS is attractive, but rarely fully utilized due to the widespread use of sample purification techniques prior to analysis. Ambient ionization methodologies can help circumvent this drawback by facilitating high-throughput qualitative and quantitative analysis directly from the complex samples without any need for work-up. For instance, the use of swabs or paper substrates allows for rapid identification, quantification, and confirmation, of drugs of abuse from biofluids or surfaces of forensic interest in a matter of minutes, as described in the first two chapters of this dissertation. Faster analysis can be achieved using an automated desorption electrospray ionization (DESI) platform which allows for the rapid and direct screening of complex-sample microarrays with throughputs better than 1 sample per second, giving access to rich spectral information from tens of thousands of samples per day. The development of the bioanalytical capabilities of this platform, particularly within the context of drug discovery (e.g. bioactivity assays, biosample analysis), is described across most other chapters of this dissertation. The use of DESI, a contactless ambient ionization method developed in our laboratory and whose 20 years of history are overviewed in the introduction of this document, provides an additional advantage as the secondary microdroplets generated through the DESI process act as reaction vessels that can accelerate organic reactions by up to six orders of magnitude, facilitating on-the-fly synthesis of new compounds from arrays of starting materials. Unique implications of this microdroplet chemistry in the prebiotic synthesis of peptides and spontaneous redox chemistry at air-solution interfaces, together with its practical applications to the synthesis of new drug molecules, are also overviewed. The success obtained with the first automated DESI-MS system, developed within the DARPA Make It program, led to increased interest in a new-generation platform which was designed over the past year, as overviewed in the last section of this dissertation, and which is currently being installed for validation prior to the transfer of the technology to NCATS, where we anticipate it will make a significant impact through the consolidation and acceleration of the early drug discovery workflow.</p>

Analytical biochemistry

Enzymes

Analytical spectrometry

Bioassays

Biologically active molecules

Forensic chemistry

Mass spectrometry

High-throughput screening

Ambient ionization

Desorption electrospray ionization

Drug discovery

Biological assays

Forensic analysis

Microdroplet chemistry

High-throughput analysis

CHEMOMETRIC ANALYSIS OF VOLATILE ORGANIC COMPOUND BIOMARKERS OF DISEASE AND DEVELOPMENT OF SOLID PHASE MICROEXTRACTION FIBERS TO EVALUATE GAS SENSING LAYERS

Mark David Woollam (13143879)

26 July 2022

<p>Canines can detect different diseases simply by smelling different biological sample types, including  urine,  breath  and  sweat.  This  has  led  researchers  to  try  and  discovery  unique  volatile  organic compound (VOC) biomarkers. The power of VOC biomarkers lies in the fact that one day they may be able to be utilized for noninvasive, rapid and accurate diagnostics at a point of care using  miniaturized  biosensors.  However,  the  identity  of  the  specific  VOC  biomarkers  must  be  demonstrated before designing and fabricating sensing systems. Through  an  extensive  series  of  experiments,  VOCs  in  urine  are  profiled  by  solid  phase  microextraction (SPME) coupled to gas chromatography-mass spectrometry (GC-MS) to identify biomarkers for breast cancer using murine models. The results from these experiments indicated that  unique  classes  of  urinary  VOCs,  primarily  terpene/terpenoids  and  carbonyls,  are  potential  biomarkers  of  breast  cancer.  Through  implementing  chemometric  approaches,  unique  panels  of  VOCs  were  identified  for  breast  cancer  detection,  identifying  tumor  location,  determining  the  efficacy of dopaminergic antitumor treatments, and tracking cancer progression. Other diseases, including COVID-19 and hypoglycemia (low blood sugar) were also probed to identify volatile biomarkers present in breath samples.  VOC biomarker identification is an important step toward developing portable gas sensors, but  another  hurdle  that  exists  is  that  current  sensors  lack  selectivity  toward  specific  VOCs  of  interest.  Furthermore,  testing  sensors  for  sensitivity  and  selectivity  is  an  extensive  process  as  VOCs  must  be  tested  individually  because  the  sensors  do  not  have  modes  of  chromatographic  separation or compound identification. Another set of experiments is presented to demonstrate that SPME  fibers  can  be  coated  with  materials,  used  to  extract  standard  solutions  of  VOCs,  and  analyzed  by  GC-MS  to  determine  the  performance  of  various  gas  sensing  layers.  In  the  first  of  these  experiments,  polyetherimide  (PEI)  was  coated  onto  a  SPME  fiber  and  compared  to  commercial polyacrylate (PAA) fibers. The second experiment tuned the extraction efficiency of polyvinylidene fluoride (PVDF) - carbon black (CB) composites and showed that they had higher sensitivity  for  urinary  VOC  extraction  relative  to  a  polydimethylsiloxane  (PDMS)  SPME  fiber.  These results demonstrate SPME GC-MS can rapidly characterize and tune the VOC adsorption capabilities of gas sensing layers. </p>

Analytical spectrometry

Bioassays

Metabolomic chemistry

Separation science

Volatile Carbonyl Compounds

gas chromatography

Mass Spectrometric Analysis

biomarker discovery research