BackgroundSingle Photon Emission Computed Tomography (SPECT) sinogram restoration for low‐dose imaging is a critical challenge in medical imaging. Existing methods often overlook the characteristics of the sinograms, necessitating innovative approaches.PurposeIn this study, we introduce the Sinogram‐characteristic‐informed network (SCI‐Net) to address the restoration of low‐dose SPECT sinograms. Our aim is to build and train a model based on the characteristics of sinograms, including continuity, periodicity, multi‐scale properties of lines in sinograms, and others, to enhance the model's understanding of the restoration process.MethodsSCI‐Net incorporates several novel mechanisms tailored to exploit the inherent characteristics of sinograms. We implement a channel attention module with a decay mechanism to leverage continuity across adjacent sinograms, while a position attention module captures global correlations within individual sinograms. Additionally, we propose a multi‐stage progressive integration mechanism to balance local detail and overall structure. Multiple regularization terms, customized to sinogram image characteristics, are embedded into the loss function for model training.ResultsThe experimental evaluations are divided into two parts: simulation data evaluation and clinical evaluation. The simulation data evaluation is conducted on a dataset comprising ten organ types, generated by the SIMIND Monte Carlo program from extended cardiac‐torso (XCAT) anatomical phantoms. The dataset includes a total of SPECT sinograms with low‐dose as input data and normal‐dose as ground truth, consisting of 3881 sinograms in the training dataset and 849 sinograms in the testing set. When comparing the restoration of low‐dose sinograms to normal‐dose references, SCI‐Net effectively improves performance. Specifically, the peak signal‐to‐noise ratio (PSNR) and the structural similarity (SSIM) on sinograms increase from 15.72 to 34.66 ( 0.001) and 0.6297 to 0.9834 ( 0.001), respectively, and on reconstructed images, reconstructed by maximum likelihood‐expectation maximization (ML‐EM), the PSNR and the SSIM improve from 21.95 to 33.14 ( 0.001) and 0.9084 to 0.9866 ( 0.001), respectively. We compared SCI‐Net with existing methods, including baseline models, traditional reconstruction algorithms, end‐to‐end methods, sinogram restoration methods, and image post‐processing methods. The experimental results and visual examples demonstrate that SCI‐Net surpasses these existing methods in SPECT sinogram restoration. The clinical evaluation is conducted on clinical data of low‐dose SPECT sinograms for spleen, thyroid, skull, and bone. These SPECT projection data are obtained from Discovery NM/CT670 scans. We compare the reconstructed images from the SCI‐Net restored sinograms, the reconstructed images from the original low‐dose sinograms, and the reconstructed images using the built‐in algorithm of the Discovery NM/CT670. The results show that our method effectively reduces the coefficient of variation (COV) in the regions of interest (ROI) of the reconstructed images, thereby enhancing the quality of the reconstructed images through SPECT sinogram restoration.ConclusionsOur proposed SCI‐Net exhibits promising performance in the restoration of low‐dose SPECT projection data. In the SCI‐Net, we have implemented three mechanisms based on distinct forms, which are advantageous for the model to more effectively leverage the characteristics of sinograms and achieve commendable restoration outcomes.
