Využití ambientních ionizačních technik v hmotnostní spektrometrii / The use of ambient ionization techniques in mass spectrometry

Rejšek, Jan

January 2013

Keywords: ambient ionization techniques; mass spectrometry; desorption electrospray ionization; desorption atmospheric pressure photoionization; thin layer chromatography; lipids, mass spectrometry imaging Ambient ionization technique in mass spectrometry is an ionization, which carries out in open space outside the machine and which does not require any, or only a minimal sample pretreatment. DESI (desorption electrospray ionization) and DAPPI (desorption atmospheric pressure photoionization) equipped with software control of the spray emitter position for analysis of low molecular organic compounds were investigated in this thesis. These methods use a spray of solvents for desorption and ionization molecules from solid substrate. Conditions for the successful analysis of phospholipids, wax esters and some other compounds were developed. Ambient ionization techniques were quantitatively compared. The application was HPTLC/DESI-MS of lipid's mixture and HPTLC/DAPPI-MS of vernix caseosa. DAPPI-MS was applied for the analysis of termites of Prorhinotermes genus (Isoptera, Rhinotermitidae). Pilot experiments of two dimensional analysis and mass spectrometry imaging were realized.

Utilization of Mass Spectrometry to Characterize, Image, and Quantify Small Molecules

Hilary Brown (8081510)

04 December 2019

Ambient ionization techniques, such as nanoDESI and nanoESI, allow for the direct analysis of complex samples under atmospheric pressure with no sample pretreatment. These ionization techniques are utilized for a variety of applications, including lipidomics, online reactions and imaging of small molecules. Nanoelectrospray ionization (nanoESI) is an ionization technique that is similar to electrospray ionization (ESI) but uses smaller sample volumes. NanoESI can be used for complex biological sample analysis and when coupled with online photochemical reactions, such as the Paternò-Büchi (PB) reaction, structural information about lipids can be determined. Likewise, nanoDESI is another ambient ionization technique that employs the ESI mechanism but incorporates online liquid extraction of analytes. This technique is easily incorporated to mass spectrometry imaging (MSI) to provide spatial localization of biomolecules in tissues. Additionally, nanoDESI allows for tunable solvent extraction and online derivatization reactions. These techniques were used to determine structural information of neutral lipids, to image lipids from different developmental stages of lung tissue, and to image and quantify small molecule drugs and metabolites in tissue.

Nano-DESI

Mass Spectrometry Imaging

Paternò-Büchi Reaction

Ambient Ionization

nanoESI

Microdroplets: Chemistry, Applications and Manipulation Using Ionization Sources and Mass Spectrometry

Kiran S Iyer (6833102)

04 December 2019

There is widespread use of ionization sources (ambient and non-ambient) for a variety of applications. More recently, charged microdroplets generated by electrospray ionization and paper spray have been used to conduct chemistry at faster rates compared to bulk volumes. Uncharged droplets such as those generated by the Leidenfrost technique have also been used to explore chemistry and study the degradation of drugs in an accelerated manner. These microdroplets serve as reaction vessels in which in which some reactions are known to occur at accelerated rates. Such chemistry can be particularly useful in pharmaceutical settings to rapidly synthesize small amounts of materials in relatively short amount of time. Additionally, microdroplets may also be used to perform high throughput screening analysis. While several parameters influencing the rate of reaction in microdroplets have been explored (such as spray distance and reagent concentration), the mechanism of reaction acceleration has not been probed to a significant extent. A major portion of my dissertation describes the use of charged and uncharged microdroplets to perform quick chemistry, guide microfluidic synthesis of drugs such as diazepam, perform scale up of copper catalyzed C-O and C-N coupling reactio<a></a>ns and screen reaction conditions for pharmaceutically relevant reactions such as the Suzuki cross-coupling reaction. Additionally, work discussed here also describes development and use of existing techniques such as structured illumination microscopy to measure droplet sizes, explore the role of distances on droplet size, and study the effect of surfactants on the rate of reactions in microdroplets generated by nano-electrospray ionization. A mathematical model to understand the mechanism of increased reaction rates in microdroplets has also been presented. Additionally, this dissertation also describes ways to manipulate ions in air using various designs of 3D-printed electrodes that operate with DC potentials only and which can be easily coupled with nano-electrospray ionization sources to transmit ions over long distances

Analytical Spectrometry

Mass Spectrometry

Microdroplets

Ion Manipulation

Ambient Ionization

Detection and Quantitation of Hazardous Chemicals in Environmental Matrices using Paper Spray Mass Spectrometry

Dowling, Sarah Naciye

08 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Paper spray mass spectrometry (PS-MS) is an ambient ionization technique that has been proven useful in many types of investigative analyses. However, the use of this technique with regards to environmental samples has been largely unexplored since the technique’s development. In this work, paper spray mass spectrometry was utilized to detect and quantify compounds for environmental, forensic and chemical defense applications. Due to the sensitive nature of some projects, the work was split into two volumes. Volume 1 focuses on the detection of pharmaceuticals in soil using paper spray (Chapter 2) and the detection of chemical warfare agent (CWA) simulants and CWA hydrolysis products (Chapter 3). Volume 2 focuses on the detection and quantitation of fentanyl analogs in environmental matrices. Chapter 5 focuses on the rapid analysis of fentanyl analogs in soil matrices. The following chapter evaluates the ability of PS-MS to detect low concentrations of fentanyl analogs in water (Chapter 6). Throughout this work, paper spray has proven to be an effective, rapid alternative to chromatography for the analysis of environmental samples.

Paper Spray Ionization

Forensic Chemistry

Environmental Chemistry

Analytical Chemistry

Ambient Ionization

Mass Spectrometry

Development of Paper-Based Immunoassay and Reaction Screening Platforms for Direct Mass Spectrometry Detection under Ambient Condition

Lee, Suji

January 2021

No description available.

Analytical Chemistry

Mass Spectrometry

malaria diagnosis

point-of-care

ambient ionization

gas-phase reaction

Development of Substrate-based Ambient Ionization Techniques for Direct Sampling by Mass Spectrometry

Jackson, Sierra

January 2021

No description available.

Chemistry

Analytical methods

Ambient ionization

Mass spectrometry

Hemoglobin

Bloodstain analysis

Pesticide analysis

Paper-based microfluidics

Paper-based immunoassay

Paper spray

LASER ELECTROSPRAY MASS SPECTROMETRY: INSTRUMENTATION AND APPLICATION FOR DIRECT ANALYSIS AND MOLECULAR IMAGING OF BIOLOGICAL TISSUE

Shi, Fengjian

January 2017

This dissertation elucidates the instrumentation and application of a hybrid ambient ionization source, laser electrospray mass spectrometry (LEMS), for the direct analysis and molecular imaging of biological tissue without matrix deposition. In LEMS, laser pulses from a Ti:Sapphire laser amplifier (60 fs, 800 nm, and 1 mJ) interact with surface analytes and transfer them from the condensed phase into the gas phase without the requirement of either exogenous matrix or endogenous water in the sample. The laser vaporized analytes are captured and ionized by an electrospray source, and finally detected by a mass analyzer. It was found that a turn-key, robust femtosecond fiber laser with longer wavelength, longer duration, and lower pulse energy at 1042 nm, 425 fs, and 50 µJ, respectively, provided comparable results with the Ti:Sapphire laser. Vaporization of intact, dried or aqueous cytochrome c and lysozyme samples was demonstrated by the fiber laser. A charge states distribution at lower charge states indicating folded conformation of proteins and the hemoglobin α subunit-heme complex from whole blood was observed. Endogenous anthocyanins, sugars, and other metabolites were detected and revealed the anticipated metabolite profile for the flower petal and leaf samples by the fiber laser. Phospholipids, especially phosphatidylcholine, were identified from a fresh mouse brain section sample. These lipid features were suppressed in both the fiber laser and Ti:Sapphire LEMS measurement in the presence of optimal cutting temperature compounds which are commonly used in animal tissue cryosectioning. This dissertation also details the design of an automated mass spectrometry imaging source based on the Ti:Sapphire LEMS. The laser, translation stage, and mass analyzer are synchronized and controlled using a customized user interface to enable step-by-step scanning of the area of interest on a given tissue sample. The imaging source is coupled with a high resolution accurate mass quadrupole time-of-flight (QTOF) mass analyzer with tandem mass analysis capability. A lateral resolution of 60 µm was demonstrated on a patterned ink film by LEMS imaging. Plant metabolites including sugar and anthocyanins were directly imaged from a leaf sample. Small metabolites, lipids and proteins were simultaneously imaged from a single tissue section of a pig liver sample. Biomarkers of blood-brain barrier damage and traumatic brain injury (TBI) that occurred during the injury were detected and imaged from a TBI mouse brain. The loading values from principal component analysis (PCA) were shown to be useful for identification of features of interest from the large LEMS imaging dataset. / Chemistry

Chemistry, Analytical

Chemistry, Physical

Medical Imaging

Ambient Ionization

Biological Tissue

Electrospray Ionization

Femtosecond Laser Desorption

Mass Spectrometry

Mass Spectrometry Imaging

Detection and Quantitation of Hazardous Chemicals in Environmental Matrices using Paper Spray Mass Spectrometry: Volume 2

Sarah Dowling (6944351)

16 October 2019

<p>Paper spray mass spectrometry (PS-MS) is an ambient ionization technique that has been proven useful in many types of investigative analyses. However, the use of this technique with regards to environmental samples has been largely unexplored since the technique’s development. In this work, paper spray mass spectrometry was utilized to detect and quantify compounds for environmental, forensic and chemical defense applications. Due to the sensitive nature of some projects, the work was split into two volumes. Volume 1 focuses on the detection of pharmaceuticals in soil using paper spray (Chapter 2) and the detection of chemical warfare agent (CWA) simulants and CWA hydrolysis products (Chapter 3). Volume 2 focuses on the detection and quantitation of fentanyl analogs in environmental matrices. Chapter 5 focuses on the rapid analysis of fentanyl analogs in soil matrices. The following chapter evaluates the ability of PS-MS to detect low concentrations of fentanyl analogs in water (Chapter 6). Throughout this work, paper spray has proven to be an effective, rapid alternative to chromatography for the analysis of environmental samples. </p>

Environmental Chemistry

Forensic Chemistry

Analytical Chemistry

Forensic Chemistry

Ambient Ionization

Paper Spray Ionization

Mass Spectrometry

Environmental Chemistry

Development and Applications of Contained Ionization Sources for Direct Complex Mixture Analysis by Mass Spectrometry

Kulyk, Dmytro S.

02 October 2019

No description available.

Chemistry

Analytical Chemistry

Biochemistry

Pharmaceuticals

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