Secondary ion images of the developing rat brain

Todd, Peter J.; McMahon, John M.; McCandlish, Carl A.

doi:10.1016/j.jasms.2004.04.029

Cited by 16 publications

(14 citation statements)

References 19 publications

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“…While much development has occurred for the application of SIMS to imaging endogenous components, or mostly molecular fragment ions, of tissues, the use of SIMS for drug and metabolite imaging has been limited [36][37][38][39]. Most of the work done related to the pharmaceutical field has been accomplished by atomic imaging of drugs with SIMS ion microscopy [40][41][42][43][44].…”

Section: Secondary Ion Msmentioning

confidence: 99%

Imaging Mass Spectrometry for Drugs and Metabolites

Oppenheimer

2013

Mass Spectrometry for Drug Discovery and Drug Development

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Section: Secondary Ion Msmentioning

confidence: 99%

Imaging Mass Spectrometry for Drugs and Metabolites

Oppenheimer

2013

Mass Spectrometry for Drug Discovery and Drug Development

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“…Consequently, in static SIMS, significantly less fragmentation of the molecular content occurs, which allows the technique to be used in imaging of small organic components [44][45][46] . To enhance the ionization yield for large intact molecular ions by SIMS, different kinds of surface modifications (MALDI matrices [47][48][49][50][51] , silver 52 and gold [53][54][55][56][57] ) as well as the use of polyatomic primary ion beams [58][59][60][61][62][63] have been suggested. Although these methods have been shown to desorb and ionize peptide and proteins from model samples, in direct tissue analysis they are highly biased toward lipids and steroids.…”

Section: Simsmentioning

confidence: 99%

Imaging mass spectrometry at cellular length scales

et al. 2007

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Imaging mass spectrometry (IMS) allows the direct investigation of both the identity and the spatial distribution of the molecular content directly in tissue sections, single cells and many other biological surfaces. In this protocol, we present the steps required to retrieve the molecular information from tissue sections using matrix-enhanced (ME) and metal-assisted (MetA) secondary ion mass spectrometry (SIMS) as well as matrix-assisted laser desorption/ionization (MALDI) IMS. These techniques require specific sample preparation steps directed at optimal signal intensity with minimal redistribution or modification of the sample analytes. After careful sample preparation, different IMS methods offer a unique discovery tool in, for example, the investigation of (i) drug transport and uptake, (ii) biological processing steps and (iii) biomarker distributions. To extract the relevant information from the huge datasets produced by IMS, new bioinformatics approaches have been developed. The duration of the protocol is highly dependent on sample size and technique used, but on average takes approximately 5 h.

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“…For example, using high-resolution SIMS, the distribution of 28 CNin a single U-14 C-thymidine-labeled chromosome, as well as that of Ca 2+ , Mg 2+ , Na + , and K + associated with mitotic chromosomes, has been studied [23,24]. There have been many reports of SIMS having provided images of a variety of samples, including neuroblastoma cells [25], oligodendrocytes [17], astrocytes [17], molluscan neurons [2], human glioblastoma cells [26], human melanoma cells [27,28], rat glioma cells [29], molluscan ganglion sections [30,31], cockroach neurohemal organ [30], rat cerebellum [32], and sections of rat [3,[33][34][35], mouse [36,37], and human [38] brains. Localization of elements such as aluminum [38], boron, calcium [29,39], fluorine [26], and sodium and potassium [3,17,28,29] have also been reported using SIMS imaging with cellular or even subcellular resolutions.…”

Section: Sims and Ams Imagingmentioning

confidence: 99%

Mass Spectrometric Imaging of the Nervous System

Rubakhin¹,

Hatcher²,

Monroe³

et al. 2007

CPD

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Mass spectrometric imaging (MSI) integrates multiple fields of analytical and biomedical research with the goal of generating chemical maps that present the identity and location of the elements, molecules, and molecular complexes that comprise biological structures. Rapid advances in the development of MSI, which include a broad range of sampling and mass spectrometry strategies, allow the increasingly information-rich creation of chemical images of structurally complex tissues, individual cells, and even single chromosomes. Here we describe a variety of MSI techniques available to investigate the nervous system, with particular focus on the capability of MSI to examine both normal and diseased brain function. An important investigative tool, MSI offers tremendous potential in fundamental studies of brain chemistry, localization of pharmaceutical compounds, and the discovery of biomarkers for different neuropathologies.

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Secondary ion images of the developing rat brain

Cited by 16 publications

References 19 publications

Imaging Mass Spectrometry for Drugs and Metabolites

Imaging Mass Spectrometry for Drugs and Metabolites

Imaging mass spectrometry at cellular length scales

Mass Spectrometric Imaging of the Nervous System

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