UV-ozone ashing of cells and tissues for spatially resolved trace element analysis.

B. Gilbert; L. Perfetti; R. Hansen; D. Mercanti; P. Casalbore; R. Andres; P. Perfetti; G. Margaritondo; G. De Stasio

doi:10.2741/a488

UV-ozone ashing of cells and tissues for spatially resolved trace element analysis.

B. Gilbert, L. Perfetti, R. Hansen, D. Mercanti, P. Casalbore, R. Andres, P. Perfetti, G. Margaritondo, G. De Stasio

ENAC-IIC-GEL

Research output: Contribution to journal › Article › peer-review

Abstract

UV/ozone ashing of thin tissue sections and cell cultures is a simple technique to enhance relative elemental concentrations, while maintaining their spatial location at the sub-micron level. This approach may enhance the capability of spatially resolved analysis techniques to detect the distribution of trace elements in biological matrices. We present results from light microscopy and x-ray spectromicroscopy studies of tissues and cells demonstrating that the micro-structure is very well conserved. We show the signal enhancement resulting from the removal of carbon, which allows otherwise undetectable gadolinium to be mapped in cancer tissue for a novel neutron capture therapy.

Original language	English
Pages (from-to)	A10-17
Journal	Frontiers in bioscience : a journal and virtual library
Volume	5
DOIs	https://doi.org/10.2741/a488
Publication status	Published - 1 Jan 2000
Externally published	Yes

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10.2741/a488

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abstract = "UV/ozone ashing of thin tissue sections and cell cultures is a simple technique to enhance relative elemental concentrations, while maintaining their spatial location at the sub-micron level. This approach may enhance the capability of spatially resolved analysis techniques to detect the distribution of trace elements in biological matrices. We present results from light microscopy and x-ray spectromicroscopy studies of tissues and cells demonstrating that the micro-structure is very well conserved. We show the signal enhancement resulting from the removal of carbon, which allows otherwise undetectable gadolinium to be mapped in cancer tissue for a novel neutron capture therapy.",

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AU - Gilbert, B.

AU - Perfetti, L.

AU - Hansen, R.

AU - Mercanti, D.

AU - Casalbore, P.

AU - Andres, R.

AU - Perfetti, P.

AU - Margaritondo, G.

AU - De Stasio, G.

PY - 2000/1/1

Y1 - 2000/1/1

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AB - UV/ozone ashing of thin tissue sections and cell cultures is a simple technique to enhance relative elemental concentrations, while maintaining their spatial location at the sub-micron level. This approach may enhance the capability of spatially resolved analysis techniques to detect the distribution of trace elements in biological matrices. We present results from light microscopy and x-ray spectromicroscopy studies of tissues and cells demonstrating that the micro-structure is very well conserved. We show the signal enhancement resulting from the removal of carbon, which allows otherwise undetectable gadolinium to be mapped in cancer tissue for a novel neutron capture therapy.

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DO - 10.2741/a488

M3 - Article

C2 - 10799354

AN - SCOPUS:0034186646

SN - 1093-4715

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JO - Frontiers in bioscience : a journal and virtual library

JF - Frontiers in bioscience : a journal and virtual library

ER -

UV-ozone ashing of cells and tissues for spatially resolved trace element analysis.

Abstract

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