Laser desorption ionization of small molecules assisted by tungsten oxide and rhenium oxide particles

Abstract: Inorganic metal oxides have shown potential as matrices for assisting in laser desorption ionization (LDI) with advantages over the aromatic acids typically used. Rhenium and tungsten oxides are an attractive option due to their high work functions and relative chemical inertness. In this work, it is shown that ReO3 and WO3, in microparticle (μP) powder forms, can efficiently ionize various types of small molecules and provide minimized background contamination at analyte concentrations below 1 ng/μL. This stu… Show more

“…[4,5] Among the established vacuum-based ionization methods,s econdary ion mass spectrometry (SIMS) [6] and matrixassisted laser desorption ionization (MALDI) [7][8][9] have been extensively applied for MSI, single cell, and subcellular analysis.I nm ost implementations,S IMS does not require am atrix and can achieve < 100 nm spatial resolution, how-ever it is known to induce ac onsiderable amount of fragmentation for large molecules.I nc ontrast, MALDI requires the addition of an organic matrix that can contribute to ion suppression and spectral interferences in the low mass range.E merging atmospheric-pressure MSI techniques, including desorption electrospray ionization (DESI) [10] and laser ablation electrospray ionization (LAESI) allow for direct tissue imaging with minimal sample preparation but typically provide limited spatial resolution. [12] Despite the large variety of these platforms (surface-assisted LDI (SALDI)), [13] carbon nanotubes, [14] porous alumina, [15] platinum nanoflowers, [16] diamond nanowires, [17] nanostructured gold thin film, [18] and zinc, tungsten, and rhenium oxide nanoparticles [19,20] ), only afew of them, for example,d esorption ionization on porous silicon (DIOS), [21,22] and nanostructure initiator mass spectrometry (NIMS) [23] have been broadly explored for MSI. [12] Despite the large variety of these platforms (surface-assisted LDI (SALDI)), [13] carbon nanotubes, [14] porous alumina, [15] platinum nanoflowers, [16] diamond nanowires, [17] nanostructured gold thin film, [18] and zinc, tungsten, and rhenium oxide nanoparticles [19,20] ), only afew of them, for example,d esorption ionization on porous silicon (DIOS), [21,22] and nanostructure initiator mass spectrometry (NIMS) [23] have been broadly explored for MSI.…”

“…[1,2] Targeted techniques,s uch as autoradiography and histological staining,require radioactive or fluorophore labeling resulting in al imited number of analytes that can be visualized in as ingle experiment. [12] Despite the large variety of these platforms (surface-assisted LDI (SALDI)), [13] carbon nanotubes, [14] porous alumina, [15] platinum nanoflowers, [16] diamond nanowires, [17] nanostructured gold thin film, [18] and zinc, tungsten, and rhenium oxide nanoparticles [19,20] ), only afew of them, for example,d esorption ionization on porous silicon (DIOS), [21,22] and nanostructure initiator mass spectrometry (NIMS) [23] have been broadly explored for MSI. [4,5] Among the established vacuum-based ionization methods,s econdary ion mass spectrometry (SIMS) [6] and matrixassisted laser desorption ionization (MALDI) [7][8][9] have been extensively applied for MSI, single cell, and subcellular analysis.I nm ost implementations,S IMS does not require am atrix and can achieve < 100 nm spatial resolution, how-ever it is known to induce ac onsiderable amount of fragmentation for large molecules.I nc ontrast, MALDI requires the addition of an organic matrix that can contribute to ion suppression and spectral interferences in the low mass range.E merging atmospheric-pressure MSI techniques, including desorption electrospray ionization (DESI) [10] and laser ablation electrospray ionization (LAESI) allow for direct tissue imaging with minimal sample preparation but typically provide limited spatial resolution.…”

“…[11] To overcome the challenges associated with matrix heterogeneity and interferences in the low m/z region, as ignificant number of matrix-free LDI techniques have been introduced. [12] Despite the large variety of these platforms (surface-assisted LDI (SALDI)), [13] carbon nanotubes, [14] porous alumina, [15] platinum nanoflowers, [16] diamond nanowires, [17] nanostructured gold thin film, [18] and zinc, tungsten, and rhenium oxide nanoparticles [19,20] ), only afew of them, for example,d esorption ionization on porous silicon (DIOS), [21,22] and nanostructure initiator mass spectrometry (NIMS) [23] have been broadly explored for MSI. In al imited number of applications,other matrix-free techniques,including LDI from laser engineered graphene paper, [24] carbonsubstrate-assisted LDI, [25] silica plate imprinting followed by LDI, [26] nanowire-assisted LDI (NALDI), [27] and SALDI, [28,29] were also explored for MSI.…”

Molecular Imaging of Biological Samples on Nanophotonic Laser Desorption Ionization Platforms

“…[4,5] Among the established vacuum-based ionization methods,s econdary ion mass spectrometry (SIMS) [6] and matrixassisted laser desorption ionization (MALDI) [7][8][9] have been extensively applied for MSI, single cell, and subcellular analysis.I nm ost implementations,S IMS does not require am atrix and can achieve < 100 nm spatial resolution, how-ever it is known to induce ac onsiderable amount of fragmentation for large molecules.I nc ontrast, MALDI requires the addition of an organic matrix that can contribute to ion suppression and spectral interferences in the low mass range.E merging atmospheric-pressure MSI techniques, including desorption electrospray ionization (DESI) [10] and laser ablation electrospray ionization (LAESI) allow for direct tissue imaging with minimal sample preparation but typically provide limited spatial resolution. [12] Despite the large variety of these platforms (surface-assisted LDI (SALDI)), [13] carbon nanotubes, [14] porous alumina, [15] platinum nanoflowers, [16] diamond nanowires, [17] nanostructured gold thin film, [18] and zinc, tungsten, and rhenium oxide nanoparticles [19,20] ), only afew of them, for example,d esorption ionization on porous silicon (DIOS), [21,22] and nanostructure initiator mass spectrometry (NIMS) [23] have been broadly explored for MSI. [12] Despite the large variety of these platforms (surface-assisted LDI (SALDI)), [13] carbon nanotubes, [14] porous alumina, [15] platinum nanoflowers, [16] diamond nanowires, [17] nanostructured gold thin film, [18] and zinc, tungsten, and rhenium oxide nanoparticles [19,20] ), only afew of them, for example,d esorption ionization on porous silicon (DIOS), [21,22] and nanostructure initiator mass spectrometry (NIMS) [23] have been broadly explored for MSI.…”

“…[1,2] Targeted techniques,s uch as autoradiography and histological staining,require radioactive or fluorophore labeling resulting in al imited number of analytes that can be visualized in as ingle experiment. [12] Despite the large variety of these platforms (surface-assisted LDI (SALDI)), [13] carbon nanotubes, [14] porous alumina, [15] platinum nanoflowers, [16] diamond nanowires, [17] nanostructured gold thin film, [18] and zinc, tungsten, and rhenium oxide nanoparticles [19,20] ), only afew of them, for example,d esorption ionization on porous silicon (DIOS), [21,22] and nanostructure initiator mass spectrometry (NIMS) [23] have been broadly explored for MSI. [4,5] Among the established vacuum-based ionization methods,s econdary ion mass spectrometry (SIMS) [6] and matrixassisted laser desorption ionization (MALDI) [7][8][9] have been extensively applied for MSI, single cell, and subcellular analysis.I nm ost implementations,S IMS does not require am atrix and can achieve < 100 nm spatial resolution, how-ever it is known to induce ac onsiderable amount of fragmentation for large molecules.I nc ontrast, MALDI requires the addition of an organic matrix that can contribute to ion suppression and spectral interferences in the low mass range.E merging atmospheric-pressure MSI techniques, including desorption electrospray ionization (DESI) [10] and laser ablation electrospray ionization (LAESI) allow for direct tissue imaging with minimal sample preparation but typically provide limited spatial resolution.…”

“…[11] To overcome the challenges associated with matrix heterogeneity and interferences in the low m/z region, as ignificant number of matrix-free LDI techniques have been introduced. [12] Despite the large variety of these platforms (surface-assisted LDI (SALDI)), [13] carbon nanotubes, [14] porous alumina, [15] platinum nanoflowers, [16] diamond nanowires, [17] nanostructured gold thin film, [18] and zinc, tungsten, and rhenium oxide nanoparticles [19,20] ), only afew of them, for example,d esorption ionization on porous silicon (DIOS), [21,22] and nanostructure initiator mass spectrometry (NIMS) [23] have been broadly explored for MSI. In al imited number of applications,other matrix-free techniques,including LDI from laser engineered graphene paper, [24] carbonsubstrate-assisted LDI, [25] silica plate imprinting followed by LDI, [26] nanowire-assisted LDI (NALDI), [27] and SALDI, [28,29] were also explored for MSI.…”

Molecular Imaging of Biological Samples on Nanophotonic Laser Desorption Ionization Platforms

“…Since the compounds chosen are usually very small (<100 Da), they eliminate the interference that is usually seen in the low mass range when using traditional MALDI matrices such as CHCA. Currently a range of compounds have been used as inorganic matrices including silica/ CHCA (Fleith et al, 2014), graphite (Sunner, Dratz, & Chen, 1995), -naphthylethylenediamine dihydrochlorid (NEDC) (Hou et al, 2014), sulfur (Kruegel, Pavlov, & Attygalle, 2013), titanium dioxide anatase (Castro et al, 2008), tungsten oxide (Bernier, Wysocki, & Dagan, 2015), mesoporous tungsten titanate (Shan et al, 2007), gold nano-particles (Marsico et al, 2015), and two dimensional graphene (Friesen et al, 2015).…”

The quest for improved reproducibility in MALDI mass spectrometry

“…A number of approaches were explored to avoid intense matrix signal generation by SOMs, e. g. matrix suppression effects, cyclodextrin‐supported 2,5‐DHB matrix, improved reactive functional groups, and chemical derivatization . Also, new classes of matrix systems were developed and successfully established, e. g. nanoparticles, ionic liquids, graphene, doped graphene, graphene oxides, graphite (GALDI‐MS), metal oxides, mostly targeting polar and non‐polar, biochemical LMWCs (e. g. amino acids, nucleosides, steroids, etc. ).…”

Amorphous Conjugated Polymers as Efficient Dual‐Mode MALDI Matrices for Low‐Molecular‐Weight Analytes