X-ray deconvolution microscopy

Sebastian Ehn; Franz Michael Epple; Andreas Fehringer; David Pennicard; Heinz Graafsma; Peter Noël; Franz Pfeiffer

doi:10.1364/BOE.7.001227

X-ray deconvolution microscopy

Sebastian Ehn, Franz Michael Epple, Andreas Fehringer, David Pennicard, Heinz Graafsma, Peter Noël, Franz Pfeiffer

Chair of Biomedical Physics

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

10 Scopus citations

Abstract

Recent advances in single-photon-counting detectors are enabling the development of novel approaches to reach micrometer-scale resolution in x-ray imaging. One example of such a technology are the MEDIPIX3RX-based detectors, such as the LAMBDA which can be operated with a small pixel size in combination with real-time on-chip charge-sharing correction. This characteristic results in a close to ideal, box-like point spread function which we made use of in this study. The proposed method is based on raster-scanning the sample with sub-pixel sized steps in front of the detector. Subsequently, a deconvolution algorithm is employed to compensate for blurring introduced by the overlap of pixels with a well defined point spread function during the raster-scanning. The presented approach utilizes standard laboratory x-ray equipment while we report resolutions close to 10 μm. The achieved resolution is shown to follow the relationship (formula presented)f with the pixel-size p of the detector and the number of raster-scanning steps n.

Original language	English
Pages (from-to)	1227-1239
Number of pages	13
Journal	Biomedical Optics Express
Volume	7
Issue number	4
DOIs	https://doi.org/10.1364/BOE.7.001227
State	Published - 9 Mar 2016

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title = "X-ray deconvolution microscopy",

abstract = "Recent advances in single-photon-counting detectors are enabling the development of novel approaches to reach micrometer-scale resolution in x-ray imaging. One example of such a technology are the MEDIPIX3RX-based detectors, such as the LAMBDA which can be operated with a small pixel size in combination with real-time on-chip charge-sharing correction. This characteristic results in a close to ideal, box-like point spread function which we made use of in this study. The proposed method is based on raster-scanning the sample with sub-pixel sized steps in front of the detector. Subsequently, a deconvolution algorithm is employed to compensate for blurring introduced by the overlap of pixels with a well defined point spread function during the raster-scanning. The presented approach utilizes standard laboratory x-ray equipment while we report resolutions close to 10 μm. The achieved resolution is shown to follow the relationship (formula presented)f with the pixel-size p of the detector and the number of raster-scanning steps n.",

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AU - Ehn, Sebastian

AU - Epple, Franz Michael

AU - Fehringer, Andreas

AU - Pennicard, David

AU - Graafsma, Heinz

AU - Noël, Peter

AU - Pfeiffer, Franz

PY - 2016/3/9

Y1 - 2016/3/9

N2 - Recent advances in single-photon-counting detectors are enabling the development of novel approaches to reach micrometer-scale resolution in x-ray imaging. One example of such a technology are the MEDIPIX3RX-based detectors, such as the LAMBDA which can be operated with a small pixel size in combination with real-time on-chip charge-sharing correction. This characteristic results in a close to ideal, box-like point spread function which we made use of in this study. The proposed method is based on raster-scanning the sample with sub-pixel sized steps in front of the detector. Subsequently, a deconvolution algorithm is employed to compensate for blurring introduced by the overlap of pixels with a well defined point spread function during the raster-scanning. The presented approach utilizes standard laboratory x-ray equipment while we report resolutions close to 10 μm. The achieved resolution is shown to follow the relationship (formula presented)f with the pixel-size p of the detector and the number of raster-scanning steps n.

AB - Recent advances in single-photon-counting detectors are enabling the development of novel approaches to reach micrometer-scale resolution in x-ray imaging. One example of such a technology are the MEDIPIX3RX-based detectors, such as the LAMBDA which can be operated with a small pixel size in combination with real-time on-chip charge-sharing correction. This characteristic results in a close to ideal, box-like point spread function which we made use of in this study. The proposed method is based on raster-scanning the sample with sub-pixel sized steps in front of the detector. Subsequently, a deconvolution algorithm is employed to compensate for blurring introduced by the overlap of pixels with a well defined point spread function during the raster-scanning. The presented approach utilizes standard laboratory x-ray equipment while we report resolutions close to 10 μm. The achieved resolution is shown to follow the relationship (formula presented)f with the pixel-size p of the detector and the number of raster-scanning steps n.

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X-ray deconvolution microscopy

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