Sample preparation and mass spectrometry in proteome studies /

Hirschberg, Daniel,

January 2004

Diss. (sammanfattning) Stockholm : Karol. inst., 2004. / Härtill 7 uppsatser.

Protein mass spectrometry in the drug discovery process /

Tjernberg, Agneta,

January 2005

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2005. / Härtill 5 uppsatser.

Forensic and proteomic applications of thermal desorption ion mobility spectrometry and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry /

Ochoa, Mariela L.

January 2005

Thesis (Ph.D.)--Ohio University, March, 2005. / Includes bibliographical references (p. 163-176)

Forensic and proteomic applications of thermal desorption ion mobility spectrometry and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry

Ochoa, Mariela L.

January 2005

Thesis (Ph.D.)--Ohio University, March, 2005. / Title from PDF t.p. Includes bibliographical references (p. 163-176)

MATRIX-ASSISTED LASER DESORPTION/IONIZATION TIME-OF-FLIGHT MASS SPECTROMETRY OF BACTERIAL RIBOSOMAL PROTEINS AND RIBOSOMES

SUH, MOO-JIN

27 May 2005

No description available.

Nonpolar Matrices for Matrix Assisted Laser Desportion Ionization – Time of Flight – Mass Spectrometry

Robins, Chad LaJuan

13 July 2005

No description available.

Chemistry, Analytical

MALDI

Nonpolar Matrices

Charge-Transfer Ionization

Crude Oil

Mass Spectrometry

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

Optimisation of intact cell MALDI method for fingerprinting of methicillin-resistant Staphylococcus aureus

Jackson, K.A., Edwards-Jones, V., Sutton, Chris W., Fox, A.J.

January 2005

No / The use of matrix-assisted laser desorption/ionisation time-of-flight (MALDI-TOF) mass spectrometry on intact cell microorganisms, Intact Cell MALDI (ICM), has been shown by numerous workers to yield effective species level identification. Early work highlighted the significant effect that variation in culture media, incubation conditions and length of incubation had on the spectra produced. Therefore, in order to achieve reliable and reproducible species level identification and sub-typing of microorganisms from ICM fingerprints, it has been essential to develop standardised methods. For methicillin-resistant Staphylococcus aureus (MRSA), a major nosocomial pathogen, we have developed such a standardised method. In this paper we present the experimental parameters, namely, the incubation period, the number of passages required from lyophilised or stored isolates, the method of deposition of the bacterial cells, the concentration of matrix solution, the drying time of bacterial cells prior to the addition of the matrix solution, the time between preparation of the bacterial/matrix sample and analysis and the MALDI pulsed extraction setting, which were considered during the development of defined methods.

Staphylococcus aureus

Bacteria

Micrococcales

Micrococcaceae

Antibiotic

Antibacterial agent

Fingerprint method

Resistance

Meticillin

Padronização da espectrometria de massa MALDI-TOF para identificação de cepas de Trichosporon spp. de importância médica / Standardization of MALDI-TOF mass spectrometry for identification of Trichosporon spp of medical relevance

Almeida Júnior, João Nobrega de

01 April 2014

O gênero Trichosporon é composto por leveduras artrosporadas do Filo Basidiomycota e é conhecido agente de infecção fúngica invasiva (IFI) em pacientes imunodeprimidos ou com outros fatores de risco. Em pacientes onco-hematológicos é a principal levedura responsável por IFI depois do gênero Candida. Entre as espécies responsáveis por infecções no homem encontram-se: T. asahii, T. inkin, T. mucoides, T. dermatis, T. jirovecii, T. ovoides, T. cutaneum, T. montevideense, T. domesticum, T. asteroides, T. coremiiforme, T. faecale, T. dohaense, T. lactis, T. japonicum. A tecnologia de identificação de fungos por espectrometria de massa (SM) MALDI-TOF ainda carece de padronização para identificação de fungos do gênero Trichosporon, mas a literatura mostra resultados encorajadores. O objetivo deste estudo é padronizar a técnica de espectrometria de massa MALDI-TOF para a identificação das espécies do gênero Trichosporon de importância médica. O estudo foi realizado em cooperação entre a Divisão de Laboratório Central do Hospital das Clínicas da Faculdade de Medicina da Universidade de São Paulo (DLC, HC-FMUSP), Instituto de Medicina Tropical da USP (IMT-USP), Instituto Adolfo Lutz (IAL) e Laboratoire de Parasitologie-Mycologie do Hospital Saint Antoine de Paris, vinculado ao grupo de pesquisa INSERM/UPMC UMR S945 \"Immunité et Infection\" Faculté de Medecine et Université Pierre et Marie Curie de Paris. Noventa e três cepas/isolados foram analisado(a)s, sendo dezenove cepas de referência adquiridas junto à coleção holandesa Centraalbureau Schimmelcultures (CBS), 19 isolados do HC-FMUSP e IAL, e 55 isolados de diferentes hospitais franceses. A identificação molecular foi realizada através do sequenciamento da região IGS1 do rDNA e foi considerada como método de referência. O protocolo de extração de proteínas foi estabelecido através da comparação do desempenho de três metodologias (Bruker®, Cassagne et al., Sendid et al.). Os espectros de massa foram obtidos no laboratório de bacteriologia do Hospital Saint Antoine de Paris através do aparelho Microflex LT®. A interpretação dos resultados qualitativos e quantitativos (logscore) foi realizada através do Software Biotyper 3.0®. O desempenho de identificação do banco de espectros de referência Biotyper 3.0® foi comparado a outros cinco bancos criados a partir de espectros de referência (ERs) derivados de 18 cepas de referência CBS, sete isolados clínicos e 11 ERs do banco Biotyper 3.0. O protocolo de extração de proteínas descrito por Sendid et al. foi escolhido como protocolo de referência pois os espectros produzidos tiveram logscore superiores àqueles obtidos através do método do fabricante. O banco de ERs Biotyper 3.0® apresentou 32,3% de identificações corretas das espécies, sendo que o banco de ERs in house (número 5, constituído cepas CBS e isolados clínicos) apresentou 98,5% de identificações de espécies. Espectros de referência do banco de dados Biotyper 3.0® foram submetidos à identificação com a utilização dos ERs criados a partir de cepas CBS e isolados clínicos e foram evidenciados com erros de identificação: T. mucoides (2), T. ovoides (1) e T. cutaneum (2). Após padronização do protocolo de extração e criação de banco de ERs com cepas CBS e isolados clínicos caracterizados pelo sequenciamento da região IGS, a SM por MALDI-TOF apresentou-se como potente uma ferramenta para a identificação de fungos do gênero Trichosporon. O banco de ERs Biotyper 3.0® apresentou um fraco desempenho, relacionado a ERs que foram criados a partir de cepas mal identificadas / Trichosporon spp. are arthrospored yeasts from the Filum Basidiomycota that are known to produce invasive fungal infection (IFI) in patients with immunosupression or other risk factors. After Candida, Trichosporon is the second genus of yeasts responsible for IFI in patients with onco-hematological diseases. The most important species related to human infection are: T. asahii, T. inkin, T. mucoides, T. dermatis, T. jirovecii, T. ovoides, T. cutaneum, T. montevideense, T. domesticum, T. asteroides, T. coremiiforme, T. faecale, T. dohaense, T. lactis, T. japonicum. The technology of mass spectrometry (MS) for identification of Trichosporon species has not yet been standardized. However, preliminary promising results can be found in the literature. The objective of this study is to analyse and validate MS MALDI-TOF for the identification of Trichosporon species of medical relevance. This was a multicentric study with collaboration from the Central Laboratory Section from Clinics Hospital of the Medical School from the University of São Paulo (DLC-HCFMUSP), Tropical Medicine Institute from the University of São Paulo (IMT-USP), Instituto Adolfo Lutz (IAL) and Laboratoire de Parasitologie-Mycologie from the Hospital Saint Antoine of Paris and INSERM/UPMC UMR S945 \"Immunité et Infection\", Faculté de Medecine et Université Pierre et Marie Curie of Paris. Ninety three strains/isolates belonging to sixteen Trichosporon species were analysed. Nineteen were purchased from Centraalbureau Schimmelcultures (CBS) yeast collection, 19 belonged to HC-FMUSP and IAL collections, 55 belonged to different French collections. The reference identification method was the IGS1 rDNA sequencing. A protein extraction protocol was first established after comparing the performance of three different methodologies (Bruker(TM), Cassagne et al., Sendid et al.). The mass spectra were obtained through a Microflex LT(TM) mass spectrometer located at the bacteriology laboratory from Saint Antoine Hospital, Paris. Mass spectra, qualitative and quantitative results were produced through the software Biotyper 3.0(TM). The performance of the original main spectrum (MSP) library was compared to other 5 in house libraries built with the combination of MSPs derived from CBS strains (18), clinical strains (7) or (Bruker Daltonics/BD, Germany/USA) (11). The extraction protocol described by Sendid et al. showed better performance when compared to the manufacturer\'s one and was chosen for the subsequent extractions. Among the 6 different reference spectra databases tested, a specific one composed of 18 reference strains plus 7 clinical isolates (database 5) allowed the correct identification of 66 amongst 67 clinical isolates (98,5%). Biotyper 3.0 library produced only 32,3% of correct identifications. Biotyper\'s MSPs were submitted to cross-identification with MSPs derived from CBS strains and clinical isolates and misidentified original MSPs were identified: T. mucoides (2), T. ovoides (1) e T. cutaneum (2). While until now less widely applied to basidiomycetous fungi, MALDI-TOF appears to be a valuable tool for identifying clinical Trichosporon isolates at the species level. The MSP library Biotyper 3.0 showed a poorer performance which was due to misidentified strains utilized as reference for the MSPs

Micoses/diagnóstico

Molecular typing

Mycosis/diagnosis

Proteômica

Proteomics

Tipagem molecular

Trichosporon spp

Trichosporon spp

Liquid chromatography coupled with electrospray-ionization mass spectrometry and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry method development and applications for the analysis of food and medicinal herbs

Lee, Kim Chung

01 January 2009

No description available.

Analysis

Food

Herbs

High performance liquid chromatography

Medicinal plants

Time-of-flight mass spectrometry