📝 SummarXiv

Abstract

Scattered coincidences introduce quantitative bias in positron emission tomography and must be compensated during reconstruction using an estimated scatter sinogram. These estimates are typically derived from simulators with simplified cylindrical scanner models that omit detector physics. Incorporating detector sensitivities for scatter is challenging, as scattered coincidences exhibit less constrained properties (e.g., incidence angles) than true events. We integrated a 5D single-photon detection probability lookup table (LUT; based on photon properties) into the simulator logic. The resulting scatter sinogram is scaled by a precomputed, LUT-specific scatter sensitivity sinogram to yield the final estimate. Scatter was simulated using MCGPU-PET, a fast Monte Carlo (MC) simulator with a simplified scanner model, and applied to phantom data from a simulated GE Signa PET/MR in GATE. We evaluated three scenarios: (1) long, high-count simulations from a known activity distribution (reference); (2) same distribution with limited simulation time and counts; (3) same low-count data with joint estimation of activity and scatter during reconstruction. In scenario 1, scatter-compensated reconstructions achieved <1% global bias in all active regions relative to true-only reconstructions. In scenario 2, noisy scatter estimates caused strong positive bias, but Gaussian smoothing restored accuracy to scenario 1 levels. In scenario 3, joint estimation under low-count conditions maintained <1% global bias in nearly all regions. Though demonstrated with a fast MC simulator, the proposed scatter sensitivity modeling could enhance existing single scatter simulators used clinically, which typically neglect detector physics. This proof-of-concept supports the feasibility of scatter estimation for real scans using fast MC simulation, offering improved accuracy and robustness to acquisition noise.