On‐tissue chemical derivatization in mass spectrometry imaging

Harkin, Carla; Smith, Karl W.; Cruickshank, Faye L.; Mackay, C. Logan; Flinders, Bryn; Heeren, Ron M. A.; Moore, Tara; Brockbank, Simon; Cobice, Diego

doi:10.1002/mas.21680

Cited by 69 publications

(56 citation statements)

References 167 publications

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“…If the compound was not well ionized and detected, it was necessary to optimize the ionization using on-tissue chemical derivatization (OTCD). OTCD can be used as a tool to study the spatial distribution of poorly ionizable molecules within tissue (Claes et al 2019;Harkin et al 2021). Derivatization was carried out in this study using Girard's reagent T (GT) (Shimma et al 2016).…”

Section: Methodsmentioning

confidence: 99%

Profile of cryptobrachytone C accumulation in Cryptocarya pulchrinervia leaves using MALDI-MSI

et al. 2021

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Abstract. Ratnasari J, Esyanti RR, Tan MI, Juliawaty LD, Shimma S. 2021. Profile of cryptobrachytone C accumulation in Cryptocarya pulchrinervia leaves using MALDI-MSI. Biodiversitas 22: 1172-1178. Cryptobrachytone C is an active compound isolated from leaves of Cryptocarya pulchrinervia, an indigenous plant from Indonesia. Cryptobrachytone C is cytotoxic against P388 leukemia cancer cell lines. A profile of cryptobrachytone C accumulation in leaves based on physiological age is necessary to study cryptobrachytone C production in the plant since it has anticancer potential. In situ profiling of cryptobrachytone C accumulation in leaves was carried out by imaging techniques using matrix-assisted laser desorption/ionization mass spectrometry imaging (MALDI-MSI). The cryptobrachytone C ionization efficiency was carried out by derivatization using Girard-T reagent and coating with α-cyano-4-hydroxycinnamic acid (α-CHCA) matrix. Scanned leaves show higher accumulation intensity in the second leaf. Quantitative accumulation profiling was conducted using GC-MS, where the highest amount of cryptobrachytone C was on the second leaf at 87.07 ± 47.21 mg. This showed that the most effective isolation of cryptobrachytone C would be obtained from young leaves of Cryptocarya pulchrinervia. This profile would play a role in cryptobrachytone C production in-situ or ex-situ using tissue culture.

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Section: Methodsmentioning

confidence: 99%

Profile of cryptobrachytone C accumulation in Cryptocarya pulchrinervia leaves using MALDI-MSI

et al. 2021

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“…The on-tissue chemical derivatization (OTCD), which is spray chemical derivatization first followed by matrix application (Harkin et al, 2021), has been used to improve ionization efficiency to effectively detect analytes directly from both fresh frozen tissue and FFPE tissue. Now OTCD has developed rapidly and used to detect many biological molecules, such as N-glycan (Nishikaze et al, 2013;Holst et al, 2016;Zhang et al, 2020;Saito et al, 2021), drugs (Barre et al, 2016, amines (Chacon et al, 2011;Manier et al, 2014), fatty acids (Wu et al, 2016;Wang et al, 2019;Iwama et al, 2021), amino acids (Toue et al, 2014;Esteve et al, 2016;Guo et al, 2020), poisons (Beasley et al, 2016), plant hormones (Enomoto et al, 2018), peptides (Franck et al, 2010), steroids (Guo et al, 2020;Angelini et al, 2021;Song et al, 2021), neurotransmitters (Ito and Hiramoto, 2019;Palanisamy et al, 2020;Shariatgorji et al, 2020), and so on.…”

Section: Reactive Matrices For Chemical Derivatizationmentioning

confidence: 99%

Advances in MALDI Mass Spectrometry Imaging Single Cell and Tissues

Zhu

Chen

et al. 2022

Front. Chem.

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Compared with conventional optical microscopy techniques, mass spectrometry imaging (MSI) or imaging mass spectrometry (IMS) is a powerful, label-free analytical technique, which can sensitively and simultaneously detect, quantify, and map hundreds of biomolecules, such as peptides, proteins, lipid, and other organic compounds in cells and tissues. So far, although several soft ionization techniques, such as desorption electrospray ionization (DESI) and secondary ion mass spectrometry (SIMS) have been used for imaging biomolecules, matrix-assisted laser desorption/ionization (MALDI) is still the most widespread MSI scanning method. Here, we aim to provide a comprehensive review of MALDI-MSI with an emphasis on its advances of the instrumentation, methods, application, and future directions in single cell and biological tissues.

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“…Although chemical derivatization is routinely employed to increase analyte stability, install isotopic markers, or improve ionization yields in metabolomics and lipidomics for both LC-MS and MSI [13,[110][111][112][113], derivatization reactions that improve structural characterization of analytes without suffering consequences of complicated sample preparation steps were rare until recently. However, the discovery by Ma and Xia [114] that light-induced Paternò-Büchi (PB) reactions can aid DB position assignments with relative ease and with inexpensive equipment has sparked the interest in chemical derivatization strategies that enable structure elucidation.…”

Section: Chemical Derivatization Prior To Tandem Msmentioning

confidence: 99%

Advanced tandem mass spectrometry in metabolomics and lipidomics—methods and applications

Heiles

2021

Anal Bioanal Chem

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Metabolomics and lipidomics are new drivers of the omics era as molecular signatures and selected analytes allow phenotypic characterization and serve as biomarkers, respectively. The growing capabilities of untargeted and targeted workflows, which primarily rely on mass spectrometric platforms, enable extensive charting or identification of bioactive metabolites and lipids. Structural annotation of these compounds is key in order to link specific molecular entities to defined biochemical functions or phenotypes. Tandem mass spectrometry (MS), first and foremost collision-induced dissociation (CID), is the method of choice to unveil structural details of metabolites and lipids. But CID fragment ions are often not sufficient to fully characterize analytes. Therefore, recent years have seen a surge in alternative tandem MS methodologies that aim to offer full structural characterization of metabolites and lipids. In this article, principles, capabilities, drawbacks, and first applications of these “advanced tandem mass spectrometry” strategies will be critically reviewed. This includes tandem MS methods that are based on electrons, photons, and ion/molecule, as well as ion/ion reactions, combining tandem MS with concepts from optical spectroscopy and making use of derivatization strategies. In the final sections of this review, the first applications of these methodologies in combination with liquid chromatography or mass spectrometry imaging are highlighted and future perspectives for research in metabolomics and lipidomics are discussed. Graphical abstract

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On‐tissue chemical derivatization in mass spectrometry imaging

Cited by 69 publications

References 167 publications

Profile of cryptobrachytone C accumulation in Cryptocarya pulchrinervia leaves using MALDI-MSI

Profile of cryptobrachytone C accumulation in Cryptocarya pulchrinervia leaves using MALDI-MSI

Advances in MALDI Mass Spectrometry Imaging Single Cell and Tissues

Advanced tandem mass spectrometry in metabolomics and lipidomics—methods and applications

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