2. Microbeam TechniquesNo Access

RECENT BIOMEDICAL APPLICATIONS OF THE OXFORD SCANNING PROTON MICROPROBE

GEOFFREY W. GRIME

University of Oxford Department of Materials, Parks Road, Oxford, OX1 3PH, UK

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EVA PÅLSGÅRD

University of Oxford Department of Materials, Parks Road, Oxford, OX1 3PH, UK

Present address: Centre for Surface Biotechnology, BMC, University of Uppsala, SE-75123 Uppsala, Sweden.

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ELSPETH F. GARMAN

University of Oxford Department of Biochemistry, South Parks Road, Oxford, UK

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MARTA UGARTE

University of Oxford, Nuffield Laboratory of Ophthalmology, The Eye Hospital, Walton Street, Oxford, UK

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DAVID POTTAGE

Applied Bio-Composites Group, University of Southampton Department of Chemistry, Southampton, UK

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, and

PAUL WYETH

Applied Bio-Composites Group, University of Southampton Department of Chemistry, Southampton, UK

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https://doi.org/10.1142/S0129083599000309Cited by:6 (Source: Crossref)

Abstract

The Oxford Scanning Proton Microprobe continues to be used in the field of trace element measurement in biological systems, exploiting the unique advantages of sensitive, quantitative trace element analysis using PIXE, high spatial resolution and the long penetrating power of MeV protons. This paper outlines a number of recent applications which highlight these advantages. These include: (a) Analysing the distribution of metals in the pupae of leaf-cutting ants to determine the storage sites and transport mechanism of metals used to harden the edges of the mandibles. (b) A study of the distribution of zinc in the retina of rats to determine the role of zinc in light and dark adaptation of the eye. (c) The analysis of crystals of proteins and other large organic molecules prepared for structure determination using x-ray diffraction. These often contain metal atoms, and the identity and concentration of the metal is an important diagnostic for determining the nature of the protein and the quality of the crystallisation. The crystals are normally small (~100μm) and so microPIXE is being used to characterise them. This technique has wide ranging applications, including qualitative and quantitative identification of metals in reaction centres, in active sites and in metal binding proteins, and of DNA or RNA bound to proteins.

Keywords:

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