A Deep-Learning-Based Method for Correction of Bone-Induced CT Beam-Hardening Artifacts

The X-ray attenuation coefficients generally decrease as the X-ray energy increases, which leads to beam-hardening artifacts in computed tomography (CT). Due to the difference of dependence of the attenuation coefficients on energy for soft tissue and bone in human body, a simple water precorrection procedure was unable to correct the bone-induced artifacts. Conventional empirical beam-hardening correction (EBHC) method rely on empirical image segmentation and data combination processes and may not be able to fully correct the artifacts. We developed a physics-driven deep-learning-based method, which followed the workflow of the EBHC method but replaced the empirical components of the EBHC method with neural networks. Numerical experiments were performed to validate the proposed method and benchmark its performance with the EBHC method and the end-to-end training strategies based on two popular neural networks, i.e., U-net and RED-CNN. Results demonstrate that the proposed method achieved the best performance in both qualitative and quantitative aspects.

[1]  Dianlin Hu,et al.  TIME-Net: Transformer-Integrated Multi-Encoder Network for limited-angle artifact removal in dual-energy CBCT , 2022, Medical Image Anal..

[2]  Dianlin Hu,et al.  DIOR: Deep Iterative Optimization-Based Residual-Learning for Limited-Angle CT Reconstruction , 2022, IEEE Transactions on Medical Imaging.

[3]  Zhiwei Wang,et al.  Sparse-view cone beam CT reconstruction using dual CNNs in projection domain and image domain , 2021, Neurocomputing.

[4]  Guang-Hong Chen,et al.  Accurate and robust sparse-view angle CT image reconstruction using deep learning and prior image constrained compressed sensing (DL-PICCS). , 2021, Medical physics.

[5]  Hongming Shan,et al.  DU-GAN: Generative Adversarial Networks With Dual-Domain U-Net-Based Discriminators for Low-Dose CT Denoising , 2021, IEEE Transactions on Instrumentation and Measurement.

[6]  Hu Chen,et al.  Disentangled generative adversarial network for low-dose CT , 2021, EURASIP J. Adv. Signal Process..

[7]  Csaba Olasz,et al.  Beam hardening artifact removal by the fusion of FBP and deep neural networks , 2021, International Conference on Digital Image Processing.

[8]  Guang-Hong Chen,et al.  High Pitch Helical CT Reconstruction , 2021, IEEE Transactions on Medical Imaging.

[9]  Hao Gong,et al.  Deep-learning-based direct synthesis of low-energy virtual monoenergetic images with multi-energy CT , 2021, Journal of medical imaging.

[10]  Hongming Shan,et al.  Deep Efficient End-to-End Reconstruction (DEER) Network for Few-View Breast CT Image Reconstruction , 2020, IEEE Access.

[11]  Chang Min Hyun,et al.  A two-stage approach for beam hardening artifact reduction in low-dose dental CBCT , 2020, IEEE Access.

[12]  Zhanli Hu,et al.  Artifact removal using a hybrid-domain convolutional neural network for limited-angle computed tomography imaging , 2020, Physics in medicine and biology.

[13]  Cynthia H McCollough,et al.  Ultra-fast-pitch acquisition and reconstruction in helical CT , 2020 .

[14]  Rama Chellappa,et al.  DuDoNet: Dual Domain Network for CT Metal Artifact Reduction , 2019, 2019 IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR).

[15]  Javad Alirezaie,et al.  Deep Learning for Low-Dose CT Denoising Using Perceptual Loss and Edge Detection Layer , 2019, Journal of Digital Imaging.

[16]  Jianhua Ma,et al.  Radon inversion via deep learning , 2018, Medical Imaging.

[17]  Hyojin Kim,et al.  Lose the Views: Limited Angle CT Reconstruction via Implicit Sinogram Completion , 2017, 2018 IEEE/CVF Conference on Computer Vision and Pattern Recognition.

[18]  Hengyong Yu,et al.  Convolutional Neural Network Based Metal Artifact Reduction in X-Ray Computed Tomography , 2017, IEEE Transactions on Medical Imaging.

[19]  Jin Keun Seo,et al.  CT sinogram‐consistency learning for metal‐induced beam hardening correction , 2017, Medical physics.

[20]  Jong Chul Ye,et al.  Multi-Scale Wavelet Domain Residual Learning for Limited-Angle CT Reconstruction , 2017, ArXiv.

[21]  Feng Lin,et al.  Low-Dose CT With a Residual Encoder-Decoder Convolutional Neural Network , 2017, IEEE Transactions on Medical Imaging.

[22]  Ken D. Sauer,et al.  A Model-Based Image Reconstruction Algorithm With Simultaneous Beam Hardening Correction for X-Ray CT , 2015, IEEE Transactions on Computational Imaging.

[23]  Marc Kachelrieß,et al.  Empirical beam hardening correction (EBHC) for CT. , 2010, Medical physics.

[24]  Jeffrey A. Fessler,et al.  Segmentation-free statistical image reconstruction for polyenergetic x-ray computed tomography with experimental validation , 2003 .

[25]  Patrick Dupont,et al.  An iterative maximum-likelihood polychromatic algorithm for CT , 2001, IEEE Transactions on Medical Imaging.

[26]  H. Skinner,et al.  CT image correction for beam hardening using simulated projection data , 1990 .

[27]  D D Robertson,et al.  Quantitative bone measurements using x-ray computed tomography with second-order correction. , 1986, Medical physics.

[28]  R. Alfidi,et al.  The environmental density artifact: a beam-hardening effect in computed tomography. , 1981, Radiology.

[29]  J. P. Stonestrom,et al.  A Framework for Spectral Artifact Corrections in X-Ray CT , 1981, IEEE Transactions on Biomedical Engineering.

[30]  G T Herman,et al.  Demonstration of Beam Hardening Correction in Computed Tomography of the Head , 1979, Journal of computer assisted tomography.

[31]  P. Joseph,et al.  A Method for Correcting Bone Induced Artifacts in Computed Tomography Scanners , 1978, Journal of computer assisted tomography.

[32]  R. Alvarez,et al.  An inaccuracy in computed tomography: the energy dependence of CT values. , 1977, Radiology.

[33]  R. Brooks,et al.  Beam hardening in x-ray reconstructive tomography. , 1976, Physics in medicine and biology.

[34]  W D McDavid,et al.  Spectral effects on three-dimensional reconstruction from rays. , 1975, Medical physics.

[35]  Weiwen Wu,et al.  Deep Embedding-Attention-Refinement for Sparse-View CT Reconstruction , 2023, IEEE Transactions on Instrumentation and Measurement.

[36]  J. Hsieh,et al.  An iterative approach to the beam hardening correction in cone beam CT. , 2000, Medical physics.

[37]  G. Herman Correction for beam hardening in computed tomography. , 1979, Physics in medicine and biology.

[38]  W D McDavid,et al.  Correction for spectral artifacts in cross-sectional reconstruction from x rays. , 1977, Medical physics.

[39]  R. Brooks,et al.  Beam hardening in X-ray reconstructive tomography , 1976 .

[40]  R E Alvarez,et al.  Energy-selective reconstructions in X-ray computerised tomography , 1976 .