Efficient image reconstruction for a small animal PET system with dual‐layer‐offset detector design

Abstract

AbstractBackgroundA compact PET/SPECT/CT system Inliview‐3000B has been developed to provide multi‐modality information on small animals for biomedical research. Its PET subsystem employed a dual‐layer‐offset detector design for depth‐of‐interaction capability and higher detection efficiency, but the irregular design caused some difficulties in calculating the normalization factors and the sensitivity map. Besides, the relatively larger (2 mm) crystal cross‐section size also posed a challenge to high‐resolution image reconstruction.PurposeWe present an efficient image reconstruction method to achieve high imaging performance for the PET subsystem of Inliview‐3000B.MethodsList mode reconstruction with efficient system modeling was used for the PET imaging. We adopt an on‐the‐fly multi‐ray tracing method with random crystal sampling to model the solid angle, crystal penetration and object attenuation effect, and modify the system response model during each iteration to improve the reconstruction performance and computational efficiency. We estimate crystal efficiency with a novel iterative approach that combines measured cylinder phantom data with simulated line‐of‐response (LOR)‐based factors for normalization correction before reconstruction. Since it is necessary to calculate normalization factors and the sensitivity map, we stack the two crystal layers together and extend the conventional data organization method here to index all useful LORs. Simulations and experiments were performed to demonstrate the feasibility and advantage of the proposed method.ResultsSimulation results showed that the iterative algorithm for crystal efficiency estimation could achieve good accuracy. NEMA image quality phantom studies have demonstrated the superiority of random sampling, which is able to achieve good imaging performance with much less computation than traditional uniform sampling. In the spatial resolution evaluation based on the mini‐Derenzo phantom, 1.1 mm hot rods could be identified with the proposed reconstruction method. Reconstruction of double mice and a rat showed good spatial resolution and a high signal‐to‐noise ratio, and organs with higher uptake could be recognized well.ConclusionThe results validated the superiority of introducing randomness into reconstruction, and demonstrated its reliability for high‐performance imaging. The Inliview‐3000B PET subsystem with the proposed image reconstruction can provide rich and detailed information on small animals for preclinical research.