Using domain knowledge for robust and generalizable deep learning-based CT-free PET attenuation and scatter correction.
Rui GuoSong XueJiaxi HuHasan SariClemens MingelsKonstantinos G ZeimpekisGeorge PrenosilYue WangYu ZhangMarco ViscioneRaphael SznitmanAxel RomingerBiao LiKuangyu ShiPublished in: Nature communications (2022)
Despite the potential of deep learning (DL)-based methods in substituting CT-based PET attenuation and scatter correction for CT-free PET imaging, a critical bottleneck is their limited capability in handling large heterogeneity of tracers and scanners of PET imaging. This study employs a simple way to integrate domain knowledge in DL for CT-free PET imaging. In contrast to conventional direct DL methods, we simplify the complex problem by a domain decomposition so that the learning of anatomy-dependent attenuation correction can be achieved robustly in a low-frequency domain while the original anatomy-independent high-frequency texture can be preserved during the processing. Even with the training from one tracer on one scanner, the effectiveness and robustness of our proposed approach are confirmed in tests of various external imaging tracers on different scanners. The robust, generalizable, and transparent DL development may enhance the potential of clinical translation.
Keyphrases
- pet imaging
- positron emission tomography
- contrast enhanced
- image quality
- computed tomography
- deep learning
- high frequency
- dual energy
- healthcare
- magnetic resonance imaging
- transcranial magnetic stimulation
- magnetic resonance
- randomized controlled trial
- systematic review
- artificial intelligence
- risk assessment
- pet ct
- human health
- single cell
- climate change