Abstract
BackgroundTo develop and evaluate the feasibility of a data-driven deep learning approach (deepAC) for positron-emission tomography (PET) image attenuation correction without anatomical imaging. A PET attenuation correction pipeline was developed utilizing deep learning to generate continuously valued pseudo-computed tomography (CT) images from uncorrected 18F-fluorodeoxyglucose (18F-FDG) PET images. A deep convolutional encoder-decoder network was trained to identify tissue contrast in volumetric uncorrected PET images co-registered to CT data. A set of 100 retrospective 3D FDG PET head images was used to train the model. The model was evaluated in another 28 patients by comparing the generated pseudo-CT to the acquired CT using Dice coefficient and mean absolute error (MAE) and finally by comparing reconstructed PET images using the pseudo-CT and acquired CT for attenuation correction. Paired-sample t tests were used for statistical analysis to compare PET reconstruction error using deepAC with CT-based attenuation correction.ResultsdeepAC produced pseudo-CTs with Dice coefficients of 0.80 ± 0.02 for air, 0.94 ± 0.01 for soft tissue, and 0.75 ± 0.03 for bone and MAE of 111 ± 16 HU relative to the PET/CT dataset. deepAC provides quantitatively accurate 18F-FDG PET results with average errors of less than 1% in most brain regions.ConclusionsWe have developed an automated approach (deepAC) that allows generation of a continuously valued pseudo-CT from a single 18F-FDG non-attenuation-corrected (NAC) PET image and evaluated it in PET/CT brain imaging.
Highlights
To develop and evaluate the feasibility of a data-driven deep learning approach for positron-emission tomography (PET) image attenuation correction without anatomical imaging
Convolutional encoder-decoder architecture The key component of our proposed method is a deep convolutional encoder-decoder (CED) network, which is capable of mapping the NAC PET image into a pixel-wise continuously valued pseudo-computed tomography (CT) image
The CED framework was modified based on the network structure used in a previous study for generating discrete three-class pseudo-CT in PET/Magnetic resonance (MR) attenuation correction [15]
Summary
To develop and evaluate the feasibility of a data-driven deep learning approach (deepAC) for positron-emission tomography (PET) image attenuation correction without anatomical imaging. A PET attenuation correction pipeline was developed utilizing deep learning to generate continuously valued pseudo-computed tomography (CT) images from uncorrected 18F-fluorodeoxyglucose (18F-FDG) PET images. The model was evaluated in another 28 patients by comparing the generated pseudo-CT to the acquired CT using Dice coefficient and mean absolute error (MAE) and by comparing reconstructed PET images using the pseudo-CT and acquired CT for attenuation correction. In simultaneous PET/MR systems, estimation of the required attenuation map is based on MR images (which does not increase patient ionizing radiation dose) and is challenging because the bone, the tissue with the largest attenuation coefficient, is not visible with positive contrast under typical MR acquisitions. Even with advanced acquisitions, bony structure and air often remain difficult to distinguish, and errors remain in attenuation calculation [3, 7, 8]
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