Quantitative Spectral Computed Tomography
ID:25 View Protection:ATTENDEE Updated Time:2021-11-02 19:30:44 Hits:1610 Invited speech

Start Time:2021-11-15 00:10(Asia/Shanghai)

Duration:25min

Session:PS1 Plenary Session 1 » CT1Workshop on CT

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Abstract
While diagnostic spectral CT has been developed, there remains little effort in developing spectral imaging capability on cone-beam CT (CBCT). As CBCT has found increasingly important applications for surgical guidance and assessment in interventional radiology, radiation therapy, and orthopedic procedures, it is recognized that there is a need to develop spectral imaging capability on CBCT. In the presentation, using quantitative dual-energy CT (QDECT) as an example, I report some of our recent research on the development of algorithm-enabled spectral capability on conventional CBCT consisting of widely commodity components without involving hardware additions/modifications. optimization-based algorithms for accurate image reconstruction in QDECT. Evidence will be provided to show that the algorithms developed can potentially be exploited for enabling innovative design of QDECT and its scanning configurations of practical application significance.

If time allows, I will also discuss the claim in literature that machine learning (ML), neural network (NN), deep learning (DL) or artificial intelligence (AI) can solve an inverse problem in CT. Specifically, I will share with the audience recent results of the AAPM Grand Challenge on ML/NN/DL for sparse-view image reconstructions.
While diagnostic spectral CT has been developed, there remains little effort in developing spectral imaging capability on cone-beam CT (CBCT). As CBCT has found increasingly important applications for surgical guidance and assessment in interventional radiology, radiation therapy, and orthopedic procedures, it is recognized that there is a need to develop spectral imaging capability on CBCT. In the presentation, using quantitative dual-energy CT (QDECT) as an example, I report some of our recent research on the development of algorithm-enabled spectral capability on conventional CBCT consisting of widely commodity components without involving hardware additions/modifications. optimization-based algorithms for accurate image reconstruction in QDECT. Evidence will be provided to show that the algorithms developed can potentially be exploited for enabling innovative design of QDECT and its scanning configurations of practical application significance.

If time allows, I will also discuss the claim in literature that machine learning (ML), neural network (NN), deep learning (DL) or artificial intelligence (AI) can solve an inverse problem in CT. Specifically, I will share with the audience recent results of the AAPM Grand Challenge on ML/NN/DL for sparse-view image reconstructions.
Keywords
Speaker
Xiaochuan Pan
Professor The University of Chicago

Professor in the Department of Radiology
*Department of Radiation & Cellular Oncology
*The Committee on Medical Physics, the Comprehensive Cancer Center
*The College at The University of Chicago.

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Important Date
  • Conference Date

    Nov 13

    2021

    to

    Nov 14

    2021

  • Sep 30 2021

    Contribution Submission Deadline

  • Nov 14 2021

    Registration deadline

Sponsored By
Medical Physics Branch of Chinese Society of Biomedical Engineering
IEEE Beijing Section
Life Electronics Society of Chinese Institute of Electronics
Organized By
Anhui Biomedical Engineering Society.
University of Science and Technology of China
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