Seungryong Cho scite author profile

Recently, a number of approaches to low-dose computed tomography (CT) have been developed and deployed in commercialized CT scanners. Tube current reduction is perhaps the most actively explored technology with advanced image reconstruction algorithms. Sparse data sampling is another viable option to the low-dose CT, and sparse-view CT has been particularly of interest among the researchers in CT community. Since analytic image reconstruction algorithms would lead to severe image artifacts, various iterative algorithms have been developed for reconstructing images from sparsely view-sampled projection data. However, iterative algorithms take much longer computation time than the analytic algorithms, and images are usually prone to different types of image artifacts that heavily depend on the reconstruction parameters. Interpolation methods have also been utilized to fill the missing data in the sinogram of sparse-view CT thus providing synthetically full data for analytic image reconstruction. In this paper, we introduce a deep-neuralnetwork-enabled sinogram synthesis method for sparse-view CT, and show its outperformance to the existing interpolation methods and also to the iterative image reconstruction approach.Index Terms-Deep learning, low-dose computed tomography (CT), sparse-view CT, view interpolation. I. INTRODUCTIONW ITH increased use of X-ray computed tomography (CT) in clinics, potential radiation hazard has been alarmed [1], [2]. There have been developed a host

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Deep Learning Diffuse Optical Tomography

Yoo

Sabir

Heo

et al. 2020

IEEE Trans. Med. Imaging

110

105

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Fluence-map generation for prostate intensity-modulated radiotherapy planning using a deep-neural-network

Lee

Kim

Kwak

et al. 2019

Sci Rep

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A deep-neural-network (DNN) was successfully used to predict clinically-acceptable dose distributions from organ contours for intensity-modulated radiotherapy (IMRT). To provide the next step in the DNN-based plan automation, we propose a DNN that directly generates beam fluence maps from the organ contours and volumetric dose distributions, without inverse planning. We collected 240 prostate IMRT plans and used to train a DNN using organ contours and dose distributions. After training was done, we made 45 synthetic plans (SPs) using the generated fluence-maps and compared them with clinical plans (CP) using various plan quality metrics including homogeneity and conformity indices for the target and dose constraints for organs at risk, including rectum, bladder, and bowel. The network was able to generate fluence maps with small errors. The qualities of the SPs were comparable to the corresponding CPs. The homogeneity index of the target was slightly worse in the SPs, but there was no difference in conformity index of the target, V60Gy of rectum, the V60Gy of bladder and the V45Gy of bowel. The time taken for generating fluence maps and qualities of SPs demonstrated the proposed method will improve efficiency of the treatment planning and help maintain the quality of plans.

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Endodontic Treatment of an Anomalous Anterior Tooth with the Aid of a 3-dimensional Printed Physical Tooth Model

Byun

Kim

Cho

et al. 2015

Journal of Endodontics

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Effects of sparse sampling schemes on image quality in low‐dose CT

et al. 2013

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Seungryong Cho

Deep-Neural-Network-Based Sinogram Synthesis for Sparse-View CT Image Reconstruction

Deep Learning Diffuse Optical Tomography

Fluence-map generation for prostate intensity-modulated radiotherapy planning using a deep-neural-network

Endodontic Treatment of an Anomalous Anterior Tooth with the Aid of a 3-dimensional Printed Physical Tooth Model

Effects of sparse sampling schemes on image quality in low‐dose CT

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