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Literature DB >> 22182730

Combined use of hard X-ray phase contrast imaging and X-ray fluorescence microscopy for sub-cellular metal quantification.

Ewelina Kosior¹, Sylvain Bohic, Heikki Suhonen, Richard Ortega, Guillaume Devès, Asuncion Carmona, Florence Marchi, Jean Francois Guillet, Peter Cloetens.

Abstract

Hard X-ray fluorescence microscopy and magnified phase contrast imaging are combined to obtain quantitative maps of the projected metal concentration in whole cells. The experiments were performed on freeze dried cells at the nano-imaging station ID22NI of the European Synchrotron Radiation Facility (ESRF). X-ray fluorescence analysis gives the areal mass of most major, minor and trace elements; it is validated using a biological standard of known composition. Quantitative phase contrast imaging provides maps of the projected mass and is validated using calibration samples and through comparison with Atomic Force Microscopy and Scanning Transmission Ion Microscopy. Up to now, absolute quantification at the sub-cellular level was impossible using X-ray fluorescence microscopy but can be reached with the use of the proposed approach. Copyright Â

Entities: Chemical Species

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Year: 2011 PMID： 22182730 DOI： 10.1016/j.jsb.2011.12.005

Source DB: PubMed Journal: J Struct Biol ISSN： 1047-8477 Impact factor: 2.867

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Cited

21 in total

10. X-ray nanoprobes and diffraction-limited storage rings: opportunities and challenges of fluorescence tomography of biological specimens.

Authors: Martin D de Jonge; Christopher G Ryan; Chris J Jacobsen
Journal: J Synchrotron Radiat Date: 2014-08-27 Impact factor: 2.616

Combined use of hard X-ray phase contrast imaging and X-ray fluorescence microscopy for sub-cellular metal quantification.

1. X-ray fluorescence imaging of the hippocampal formation after manganese exposure.

2. Alignment of low-dose X-ray fluorescence tomography images using differential phase contrast.

3. Preparing adherent cells for X-ray fluorescence imaging by chemical fixation.

4. Simultaneous cryo X-ray ptychographic and fluorescence microscopy of green algae.

Review 5. Elemental and chemically specific X-ray fluorescence imaging of biological systems.

6. 3D imaging of transition metals in the zebrafish embryo by X-ray fluorescence microtomography.

7. Subcellular redistribution and mitotic inheritance of transition metals in proliferating mouse fibroblast cells.

8. X-ray fluorescence imaging reveals subcellular biometal disturbances in a childhood neurodegenerative disorder.

Review 9. The role of iron in neurodegenerative disorders: insights and opportunities with synchrotron light.

10. X-ray nanoprobes and diffraction-limited storage rings: opportunities and challenges of fluorescence tomography of biological specimens.