Photonenenergie als dritte Dimension bei der Analyse der kristallographischen Textur

Grünewald, Tilman A.; Rennhofer, Harald; Tack, Pieter; Garrevoet, Jan; Wermeille, D.; Thompson, Paul; Bras, Wim; Vincze, László; Lichtenegger, Helga C.

doi:10.1002/ange.201603784

Cited by 2 publications

(1 citation statement)

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“…Scanning SAXS has also become a routine application, for example in the analysis of textured samples such as teeth [116][117][118][119], bone [32-37, 120, 121], wood [28][29][30][31], silk [122] and polymers [123]. Extensions to three-dimensional SAXS imaging include 3D-SAXS [38-40, 124, 125], SAXS-CT [47,126] or energy-resolving SAXS [127]. However, as the experiments impose a significant radiation dose onto the sample, scanning SAXS and scanning X-ray diffraction have been largely restricted to strongly scattering materials (where the beam can be attenuated) or to materials which are comparatively radiation insensitive, such as bone for example.…”

Section: Introductionmentioning

confidence: 99%

Multiscale X-Ray Analysis of Biological Cells and Tissues by Scanning Diffraction and Coherent Imaging

Nicolas¹

2019

Göttingen Series in X-Ray Physics

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The Göttingen series in x-ray physics is intended as a collection of research monographs in x-ray science, carried out at the Institute for X-ray Physics at the Georg-August-Universität in Göttingen, and in the framework of its related research networks and collaborations. It covers topics ranging from x-ray microscopy, nano-focusing, wave propagation, image reconstruction, tomography, short x-ray pulses to applications of nanoscale x-ray imaging and biomolecular structure analysis. In most but not all cases, the contributions are based on Ph.D. dissertations. The individual monographs should be enhanced by putting them in the context of related work, often based on a common long term research strategy, and funded by the same research networks. We hope that the series will also help to enhance the visibility of the research carried out here and help others in the field to advance similar projects.

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Section: Introductionmentioning

confidence: 99%

Multiscale X-Ray Analysis of Biological Cells and Tissues by Scanning Diffraction and Coherent Imaging

Nicolas¹

2019

Göttingen Series in X-Ray Physics

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Scanning X-ray diffraction on cardiac tissue: automatized data analysis and processing

et al. 2017

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A scanning X-ray diffraction study of cardiac tissue has been performed, covering the entire cross section of a mouse heart slice. To this end, moderate focusing by compound refractive lenses to micrometer spot size, continuous scanning, data acquisition by a fast single-photon-counting pixel detector, and fully automated analysis scripts have been combined. It was shown that a surprising amount of structural data can be harvested from such a scan, evaluating the local scattering intensity, interfilament spacing of the muscle tissue, the filament orientation, and the degree of anisotropy. The workflow of data analysis is described and a data analysis toolbox with example data for general use is provided. Since many cardiomyopathies rely on the structural integrity of the sarcomere, the contractile unit of cardiac muscle cells, the present study can be easily extended to characterize tissue from a diseased heart.

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Photonenenergie als dritte Dimension bei der Analyse der kristallographischen Textur

Cited by 2 publications

References 30 publications

Multiscale X-Ray Analysis of Biological Cells and Tissues by Scanning Diffraction and Coherent Imaging

Multiscale X-Ray Analysis of Biological Cells and Tissues by Scanning Diffraction and Coherent Imaging

Scanning X-ray diffraction on cardiac tissue: automatized data analysis and processing

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