Multi-Source Semi-Stationary CT for Brain Imaging: Development and Assessment of a Prototype System and Image Formation Algorithms

T. McSkimming; A. Lopez-Montes; A. Skeats; C. Delnooz; B. Gonzales; E. Perilli; K. Reynolds; J. H. Siewerdsen; W. Zbijewski; Alejandro Sisniega Crespo

doi:10.1117/12.3006970

Multi-Source Semi-Stationary CT for Brain Imaging: Development and Assessment of a Prototype System and Image Formation Algorithms

T. McSkimming, A. Lopez-Montes, A. Skeats, C. Delnooz, B. Gonzales, E. Perilli, K. Reynolds, J. H. Siewerdsen, W. Zbijewski, Alejandro Sisniega Crespo

School of Medicine

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Purpose: Multi-source array (MXA) Computed Tomography systems pose challenges related to sampling and x-ray scatter. We present a semi-stationary head CT system and image formation pipeline including adaptive scatter estimation and image reconstruction based on learned diffusion models. Methods: The CT was evaluated on a robotic bench system including a miniaturized carbon-nanotube x-ray source and a curved-panel detector. Scatter correction was achieved with an Adaptive Deep Scatter Estimation (ADSE) method combining geometry-invariant projection-based scatter estimation with geometry-adaptive registration and scaling. Image reconstruction followed a Diffusion Posterior Sampling method (DPS-Recon) combining an unconditional diffusion model with measured data consistency. Image quality was assessed using anthropomorphic phantoms for a semi-stationary protocol involving a 21-source MXA rotated to three positions. Results: ADSE resulted in 118% mean increase in feature contrast accuracy, 1.75 to 13-fold improvement in CNR for variable contrast features (-337HU to 885HU), and 3.56-fold improvement in CNR for variable size features (2mm-12mm, 110HU) compared to uncorrected reconstructions. Non-uniformity reduced 50% for the three slices. DPS-Recon reduced limited sampling artifacts and improved visualization of soft-tissue structures, particularly in less densely sampled and bony anatomy locations, and further reduced non-uniformity by 20% in the superior brain location. Conclusion: We present first experimental results from a semi-stationary, multi-source CT utilizing CNT x-ray sources and curved-panel detector coupled to an imaging chain that addressed the main challenges inherent to the architecture. Metrics of CT number accuracy, image uniformity, and soft-tissue visualization showed promising performance for visualization of stroke radiological markers with the proposed approach.

Original language	English (US)
Title of host publication	Medical Imaging 2024
Subtitle of host publication	Physics of Medical Imaging
Editors	Rebecca Fahrig, John M. Sabol, Ke Li
Publisher	SPIE
ISBN (Electronic)	9781510671546
DOIs	https://doi.org/10.1117/12.3006970
State	Published - 2024
Event	Medical Imaging 2024: Physics of Medical Imaging - San Diego, United States Duration: Feb 19 2024 → Feb 22 2024

Publication series

Name	Progress in Biomedical Optics and Imaging - Proceedings of SPIE
Volume	12925
ISSN (Print)	1605-7422

Conference

Conference	Medical Imaging 2024: Physics of Medical Imaging
Country/Territory	United States
City	San Diego
Period	2/19/24 → 2/22/24

Keywords

carbon nanotubes
cone-beam CT
deep learning
diffusion posterior sampling
multi-source
scatter
stroke

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics
Biomaterials
Radiology Nuclear Medicine and imaging

Access to Document

10.1117/12.3006970

Cite this

McSkimming, T., Lopez-Montes, A., Skeats, A., Delnooz, C., Gonzales, B., Perilli, E., Reynolds, K., Siewerdsen, J. H., Zbijewski, W., & Sisniega Crespo, A. (2024). Multi-Source Semi-Stationary CT for Brain Imaging: Development and Assessment of a Prototype System and Image Formation Algorithms. In R. Fahrig, J. M. Sabol, & K. Li (Eds.), Medical Imaging 2024: Physics of Medical Imaging Article 129251B (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 12925). SPIE. https://doi.org/10.1117/12.3006970

Multi-Source Semi-Stationary CT for Brain Imaging: Development and Assessment of a Prototype System and Image Formation Algorithms. / McSkimming, T.; Lopez-Montes, A.; Skeats, A. et al.
Medical Imaging 2024: Physics of Medical Imaging. ed. / Rebecca Fahrig; John M. Sabol; Ke Li. SPIE, 2024. 129251B (Progress in Biomedical Optics and Imaging - Proceedings of SPIE; Vol. 12925).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

McSkimming, T, Lopez-Montes, A, Skeats, A, Delnooz, C, Gonzales, B, Perilli, E, Reynolds, K, Siewerdsen, JH , Zbijewski, W & Sisniega Crespo, A 2024, Multi-Source Semi-Stationary CT for Brain Imaging: Development and Assessment of a Prototype System and Image Formation Algorithms. in R Fahrig, JM Sabol & K Li (eds), Medical Imaging 2024: Physics of Medical Imaging., 129251B, Progress in Biomedical Optics and Imaging - Proceedings of SPIE, vol. 12925, SPIE, Medical Imaging 2024: Physics of Medical Imaging, San Diego, United States, 2/19/24. https://doi.org/10.1117/12.3006970

McSkimming T, Lopez-Montes A, Skeats A, Delnooz C, Gonzales B, Perilli E et al. Multi-Source Semi-Stationary CT for Brain Imaging: Development and Assessment of a Prototype System and Image Formation Algorithms. In Fahrig R, Sabol JM, Li K, editors, Medical Imaging 2024: Physics of Medical Imaging. SPIE. 2024. 129251B. (Progress in Biomedical Optics and Imaging - Proceedings of SPIE). doi: 10.1117/12.3006970

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title = "Multi-Source Semi-Stationary CT for Brain Imaging: Development and Assessment of a Prototype System and Image Formation Algorithms",

abstract = "Purpose: Multi-source array (MXA) Computed Tomography systems pose challenges related to sampling and x-ray scatter. We present a semi-stationary head CT system and image formation pipeline including adaptive scatter estimation and image reconstruction based on learned diffusion models. Methods: The CT was evaluated on a robotic bench system including a miniaturized carbon-nanotube x-ray source and a curved-panel detector. Scatter correction was achieved with an Adaptive Deep Scatter Estimation (ADSE) method combining geometry-invariant projection-based scatter estimation with geometry-adaptive registration and scaling. Image reconstruction followed a Diffusion Posterior Sampling method (DPS-Recon) combining an unconditional diffusion model with measured data consistency. Image quality was assessed using anthropomorphic phantoms for a semi-stationary protocol involving a 21-source MXA rotated to three positions. Results: ADSE resulted in 118% mean increase in feature contrast accuracy, 1.75 to 13-fold improvement in CNR for variable contrast features (-337HU to 885HU), and 3.56-fold improvement in CNR for variable size features (2mm-12mm, 110HU) compared to uncorrected reconstructions. Non-uniformity reduced 50% for the three slices. DPS-Recon reduced limited sampling artifacts and improved visualization of soft-tissue structures, particularly in less densely sampled and bony anatomy locations, and further reduced non-uniformity by 20% in the superior brain location. Conclusion: We present first experimental results from a semi-stationary, multi-source CT utilizing CNT x-ray sources and curved-panel detector coupled to an imaging chain that addressed the main challenges inherent to the architecture. Metrics of CT number accuracy, image uniformity, and soft-tissue visualization showed promising performance for visualization of stroke radiological markers with the proposed approach.",

keywords = "carbon nanotubes, cone-beam CT, deep learning, diffusion posterior sampling, multi-source, scatter, stroke",

author = "T. McSkimming and A. Lopez-Montes and A. Skeats and C. Delnooz and B. Gonzales and E. Perilli and K. Reynolds and Siewerdsen, {J. H.} and W. Zbijewski and {Sisniega Crespo}, Alejandro",

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AU - Skeats, A.

AU - Delnooz, C.

AU - Gonzales, B.

AU - Perilli, E.

AU - Reynolds, K.

AU - Siewerdsen, J. H.

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N2 - Purpose: Multi-source array (MXA) Computed Tomography systems pose challenges related to sampling and x-ray scatter. We present a semi-stationary head CT system and image formation pipeline including adaptive scatter estimation and image reconstruction based on learned diffusion models. Methods: The CT was evaluated on a robotic bench system including a miniaturized carbon-nanotube x-ray source and a curved-panel detector. Scatter correction was achieved with an Adaptive Deep Scatter Estimation (ADSE) method combining geometry-invariant projection-based scatter estimation with geometry-adaptive registration and scaling. Image reconstruction followed a Diffusion Posterior Sampling method (DPS-Recon) combining an unconditional diffusion model with measured data consistency. Image quality was assessed using anthropomorphic phantoms for a semi-stationary protocol involving a 21-source MXA rotated to three positions. Results: ADSE resulted in 118% mean increase in feature contrast accuracy, 1.75 to 13-fold improvement in CNR for variable contrast features (-337HU to 885HU), and 3.56-fold improvement in CNR for variable size features (2mm-12mm, 110HU) compared to uncorrected reconstructions. Non-uniformity reduced 50% for the three slices. DPS-Recon reduced limited sampling artifacts and improved visualization of soft-tissue structures, particularly in less densely sampled and bony anatomy locations, and further reduced non-uniformity by 20% in the superior brain location. Conclusion: We present first experimental results from a semi-stationary, multi-source CT utilizing CNT x-ray sources and curved-panel detector coupled to an imaging chain that addressed the main challenges inherent to the architecture. Metrics of CT number accuracy, image uniformity, and soft-tissue visualization showed promising performance for visualization of stroke radiological markers with the proposed approach.

AB - Purpose: Multi-source array (MXA) Computed Tomography systems pose challenges related to sampling and x-ray scatter. We present a semi-stationary head CT system and image formation pipeline including adaptive scatter estimation and image reconstruction based on learned diffusion models. Methods: The CT was evaluated on a robotic bench system including a miniaturized carbon-nanotube x-ray source and a curved-panel detector. Scatter correction was achieved with an Adaptive Deep Scatter Estimation (ADSE) method combining geometry-invariant projection-based scatter estimation with geometry-adaptive registration and scaling. Image reconstruction followed a Diffusion Posterior Sampling method (DPS-Recon) combining an unconditional diffusion model with measured data consistency. Image quality was assessed using anthropomorphic phantoms for a semi-stationary protocol involving a 21-source MXA rotated to three positions. Results: ADSE resulted in 118% mean increase in feature contrast accuracy, 1.75 to 13-fold improvement in CNR for variable contrast features (-337HU to 885HU), and 3.56-fold improvement in CNR for variable size features (2mm-12mm, 110HU) compared to uncorrected reconstructions. Non-uniformity reduced 50% for the three slices. DPS-Recon reduced limited sampling artifacts and improved visualization of soft-tissue structures, particularly in less densely sampled and bony anatomy locations, and further reduced non-uniformity by 20% in the superior brain location. Conclusion: We present first experimental results from a semi-stationary, multi-source CT utilizing CNT x-ray sources and curved-panel detector coupled to an imaging chain that addressed the main challenges inherent to the architecture. Metrics of CT number accuracy, image uniformity, and soft-tissue visualization showed promising performance for visualization of stroke radiological markers with the proposed approach.

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ER -

Multi-Source Semi-Stationary CT for Brain Imaging: Development and Assessment of a Prototype System and Image Formation Algorithms

Abstract

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Keywords

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