Correction for Mechanical Inaccuracies in a Scanning Talbot-Lau Interferometer

Wolfgang Noichl; Fabio De Marco; Konstantin Willer; Theresa Urban; Manuela Frank; Rafael Schick; Bernhard Gleich; Lorenz Hehn; Alex Gustschin; Pascal Meyer; Thomas Koehler; Ingo Maack; Klaus Jurgen Engel; Bernd Lundt; Bernhard Renger; Alexander Fingerle; Daniela Pfeiffer; Ernst Rummeny; Julia Herzen; Franz Pfeiffer

doi:10.1109/TMI.2023.3288358

Correction for Mechanical Inaccuracies in a Scanning Talbot-Lau Interferometer

Wolfgang Noichl
, Fabio De Marco
, Konstantin Willer
, Theresa Urban
, Manuela Frank
, Rafael Schick
, Bernhard Gleich
, Lorenz Hehn
, Alex Gustschin
, Pascal Meyer
, Thomas Koehler
, Ingo Maack
, Klaus Jurgen Engel
, Bernd Lundt
, Bernhard Renger
, Alexander Fingerle
, Daniela Pfeiffer
, Ernst Rummeny
, Julia Herzen
, Franz Pfeiffer

Technische Universität München
Kernforschungszentrum Karlsruhe
Philips Germany GmbH
Philips Medical Systems DMC GmbH
Philips Eindhoven

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

7 Zitate (Scopus)

Abstract

Grating-based X-ray phase-contrast and in particular dark-field radiography are promising new imaging modalities for medical applications. Currently, the potential advantage of dark-field imaging in early-stage diagnosis of pulmonary diseases in humans is being investigated. These studies make use of a comparatively large scanning interferometer at short acquisition times, which comes at the expense of a significantly reduced mechanical stability as compared to tabletop laboratory setups. Vibrations create random fluctuations of the grating alignment, causing artifacts in the resulting images. Here, we describe a novel maximum likelihood method for estimating this motion, thereby preventing these artifacts. It is tailored to scanning setups and does not require any sample-free areas. Unlike any previously described method, it accounts for motion in between as well as during exposures.

Originalsprache	Englisch
Seiten (von - bis)	28-38
Seitenumfang	11
Fachzeitschrift	IEEE Transactions on Medical Imaging
Jahrgang	43
Ausgabenummer	1
DOIs	https://doi.org/10.1109/TMI.2023.3288358
Publikationsstatus	Veröffentlicht - 1 Jan. 2024

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10.1109/TMI.2023.3288358

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Noichl, W., De Marco, F., Willer, K., Urban, T., Frank, M., Schick, R., Gleich, B., Hehn, L., Gustschin, A., Meyer, P., Koehler, T., Maack, I., Engel, K. J., Lundt, B., Renger, B., Fingerle, A., Pfeiffer, D., Rummeny, E., Herzen, J., & Pfeiffer, F. (2024). Correction for Mechanical Inaccuracies in a Scanning Talbot-Lau Interferometer. IEEE Transactions on Medical Imaging, 43(1), 28-38. https://doi.org/10.1109/TMI.2023.3288358

@article{8e7847c536224a129b83e6dbe992ece2,

title = "Correction for Mechanical Inaccuracies in a Scanning Talbot-Lau Interferometer",

abstract = "Grating-based X-ray phase-contrast and in particular dark-field radiography are promising new imaging modalities for medical applications. Currently, the potential advantage of dark-field imaging in early-stage diagnosis of pulmonary diseases in humans is being investigated. These studies make use of a comparatively large scanning interferometer at short acquisition times, which comes at the expense of a significantly reduced mechanical stability as compared to tabletop laboratory setups. Vibrations create random fluctuations of the grating alignment, causing artifacts in the resulting images. Here, we describe a novel maximum likelihood method for estimating this motion, thereby preventing these artifacts. It is tailored to scanning setups and does not require any sample-free areas. Unlike any previously described method, it accounts for motion in between as well as during exposures.",

keywords = "Image enhancement/restoration (noise and artifact reduction), X-ray imaging and computed tomography, image reconstruction-iterative methods",

author = "Wolfgang Noichl and \{De Marco\}, Fabio and Konstantin Willer and Theresa Urban and Manuela Frank and Rafael Schick and Bernhard Gleich and Lorenz Hehn and Alex Gustschin and Pascal Meyer and Thomas Koehler and Ingo Maack and Engel, \{Klaus Jurgen\} and Bernd Lundt and Bernhard Renger and Alexander Fingerle and Daniela Pfeiffer and Ernst Rummeny and Julia Herzen and Franz Pfeiffer",

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year = "2024",

month = jan,

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doi = "10.1109/TMI.2023.3288358",

language = "English",

volume = "43",

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Noichl, W, De Marco, F, Willer, K, Urban, T, Frank, M, Schick, R, Gleich, B, Hehn, L, Gustschin, A, Meyer, P, Koehler, T, Maack, I, Engel, KJ, Lundt, B, Renger, B, Fingerle, A, Pfeiffer, D, Rummeny, E , Herzen, J & Pfeiffer, F 2024, 'Correction for Mechanical Inaccuracies in a Scanning Talbot-Lau Interferometer', IEEE Transactions on Medical Imaging, Jg. 43, Nr. 1, S. 28-38. https://doi.org/10.1109/TMI.2023.3288358

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T1 - Correction for Mechanical Inaccuracies in a Scanning Talbot-Lau Interferometer

AU - Noichl, Wolfgang

AU - De Marco, Fabio

AU - Willer, Konstantin

AU - Urban, Theresa

AU - Frank, Manuela

AU - Schick, Rafael

AU - Gleich, Bernhard

AU - Hehn, Lorenz

AU - Gustschin, Alex

AU - Meyer, Pascal

AU - Koehler, Thomas

AU - Maack, Ingo

AU - Engel, Klaus Jurgen

AU - Lundt, Bernd

AU - Renger, Bernhard

AU - Fingerle, Alexander

AU - Pfeiffer, Daniela

AU - Rummeny, Ernst

AU - Herzen, Julia

AU - Pfeiffer, Franz

PY - 2024/1/1

Y1 - 2024/1/1

N2 - Grating-based X-ray phase-contrast and in particular dark-field radiography are promising new imaging modalities for medical applications. Currently, the potential advantage of dark-field imaging in early-stage diagnosis of pulmonary diseases in humans is being investigated. These studies make use of a comparatively large scanning interferometer at short acquisition times, which comes at the expense of a significantly reduced mechanical stability as compared to tabletop laboratory setups. Vibrations create random fluctuations of the grating alignment, causing artifacts in the resulting images. Here, we describe a novel maximum likelihood method for estimating this motion, thereby preventing these artifacts. It is tailored to scanning setups and does not require any sample-free areas. Unlike any previously described method, it accounts for motion in between as well as during exposures.

AB - Grating-based X-ray phase-contrast and in particular dark-field radiography are promising new imaging modalities for medical applications. Currently, the potential advantage of dark-field imaging in early-stage diagnosis of pulmonary diseases in humans is being investigated. These studies make use of a comparatively large scanning interferometer at short acquisition times, which comes at the expense of a significantly reduced mechanical stability as compared to tabletop laboratory setups. Vibrations create random fluctuations of the grating alignment, causing artifacts in the resulting images. Here, we describe a novel maximum likelihood method for estimating this motion, thereby preventing these artifacts. It is tailored to scanning setups and does not require any sample-free areas. Unlike any previously described method, it accounts for motion in between as well as during exposures.

KW - Image enhancement/restoration (noise and artifact reduction)

KW - X-ray imaging and computed tomography

KW - image reconstruction-iterative methods

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JO - IEEE Transactions on Medical Imaging

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Correction for Mechanical Inaccuracies in a Scanning Talbot-Lau Interferometer

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