Imaging simulation of a dual-panel PET geometry with ultrafast TOF detectors (2502.01006v2)

Abstract: In positron emission tomography (PET), time-of-flight (TOF) information localizes source positions along lines of response. Cherenkov-radiator-integrated microchannel-plate photomultiplier tubes have achieved 30 ps TOF resolution, demonstrating cross-sectional imaging without reconstruction. Such ultrafast TOF detectors would free PET from conventional ring geometries. Therefore, this study aimed at investigating imaging characteristics of a dual-panel PET with ultrafast TOF detectors using Geant4 simulation. Two detector panels ($142 \times 142~mm^2$), which consisted of 5.0 mm-thick bismuth germanate pixelized crystals with a 5.75 mm pitch, were placed face-to-face at a 300 mm distance. Spatial resolution and image noise with various TOF resolutions from 30 to 90 ps were evaluated. Because degraded efficiency may cancel TOF gain in image quality, detection efficiency was also parameterized by reducing coincidence counts. A numerical phantom, which consisted of multi-rod and uniform cylindrical activities (21 MBq in total), was simulated for 600 s. Regarding image reconstruction, results of a backprojection (i.e., no reconstruction) were compared with those of the maximum likelihood expectation maximization (MLEM). The dual-panel PET required a 40 ps TOF resolution to have a similar spatial resolution to that of a non-TOF ring PET (300 mm in diameter) for the same detection efficiency. The TOF resolution should be 30 ps with half the efficiency to maintain a similar image noise to that of the 40 ps TOF with complete efficiency. MLEM provided better imaging performance than backprojection, even at 30 ps TOF. The feasibility of the proposed dual-panel PET with ultrafast TOF detectors was shown.