A Deep Neural Network To Recover Missing Data In Small Animal Pet Imaging: Comparison Between Sinogram- And Image-Domain Implementations

Missing areas in PET sinograms and severe image artifacts as a consequence thereof, still gain prominence not only in sparse-ring detector configurations but also in full-ring PET scanners in case of faulty detectors. Empty bins in the projection domain, caused by inter-block gap regions or any failure in the detector blocks may lead to unacceptable image distortions and inaccuracies in quantitative analysis. Deep neural networks have recently attracted enormous attention within the imaging community and are being deployed for various applications, including handling impaired sinograms and removing the streaking artifacts generated by incomplete projection views. Despite the promising results in sparse-view CT reconstruction, the utility of deep-learning-based methods in synthesizing artifact-free PET images in the sparse-crystal setting is poorly explored. Herein, we investigated the feasibility of a modified U-Net to generate artifact-free PET scans in the presence of severe dead regions between adjacent detector blocks on a dedicated high-resolution preclinical PET scanner. The performance of the model was assessed in both projection and image-space. The visual inspection and quantitative analysis seem to indicate that the proposed method is well suited for application on partial-ring PET scanners.

[1]  John O. Prior,et al.  Low-Dose Imaging in a New Preclinical Total-Body PET/CT Scanner , 2019, Front. Med..

[2]  H. Zaidi,et al.  Advances in Preclinical PET Instrumentation. , 2020, PET clinics.

[3]  Jong Chul Ye,et al.  Deep Residual Learning for Compressed Sensing CT Reconstruction via Persistent Homology Analysis , 2016, ArXiv.

[4]  Seyedehsamaneh Shojaeilangari,et al.  Recovery of missing data in partial geometry PET scanners: Compensation in projection space vs image space , 2018, Medical physics.

[5]  Joel S. Karp,et al.  State of the art in total body PET , 2020, EJNMMI Physics.

[6]  Jens Gregor,et al.  CNN-based PET sinogram repair to mitigate defective block detectors , 2019, Physics in medicine and biology.

[7]  Habib Zaidi,et al.  Projection Space Implementation of Deep Learning–Guided Low-Dose Brain PET Imaging Improves Performance over Implementation in Image Space , 2020, The Journal of Nuclear Medicine.

[8]  G. Delso,et al.  The Effect of Defective PET Detectors in Clinical Simultaneous [18F]FDG Time-of-Flight PET/MR Imaging , 2017, Molecular Imaging and Biology.

[9]  Paul Kinahan,et al.  Statistical Image Reconstruction in PET with Compensation for Missing Data , 2001 .

[10]  John W. Clark,et al.  Dictionary learning for data recovery in positron emission tomography , 2015, Physics in medicine and biology.

[11]  H. Zaidi,et al.  NEMA NU-4 2008 Performance Evaluation of Xtrim-PET: A prototype SiPM-based preclinical scanner. , 2019, Medical physics.

[12]  Mark W. Lenox,et al.  Correction methods for missing data in sinograms of the HRRT PET scanner , 2002 .

[13]  Uygar Tuna,et al.  Gap-Filling for the High-Resolution PET Sinograms With a Dedicated DCT-Domain Filter , 2010, IEEE Transactions on Medical Imaging.

[14]  Hsuan-Ming Huang,et al.  Partial-ring PET image restoration using a deep learning based method. , 2019, Physics in medicine and biology.