Performance evaluation of the next generation solid-state digital photon counting PET/CT system

BackgroundThe first solid-state silicon photomultiplier (SiPM) digital photon counting (DPC) clinical PET/CT system was introduced by Philips in recent years. The system differs from other SiPM-based PET/CT systems and uses lutetiumyttrium oxyorthosilicate (LYSO) scintillators directly coupled with their own individual SiPM DPC detectors eliminating the need for Anger-logic positioning decoding. We evaluated the system performance, characteristics, and stability of the next generation DPC clinical PET/CT based on NEMA NU2-2012 tests, NEMA NU2-2018 test (timing resolution) and human studies.ResultsAn energy resolution of 11.2% was measured. NEMA NU2-2012 tests revealed a spatial resolution (mm in FWHM) from (3.96, 4.01, 4.01) at 1cm to (5.81, 5.83, 4.95) at 20cm for (axial, radial, tangential). A 5.7cps/kBq system sensitivity was measured. Peak noise equivalent count rate (NECR) and peak true count rate could not be determined as each exhibited increasing values up to the maximum activity measured (similar to 1100MBq). The maximum NECR was 171kcps @ 50.5kBq/mL, with corresponding scatter fraction of 30.8% and maximum trues of 681kcps. NEMA hot sphere contrast ranged from 62% (10mm) to 88% (22mm), cold sphere contrast of 86% (28mm) and 89% (37mm). A timing resolution of 322ps (Na-22 point source based) and 332ps (NEMA NU2-2018) was obtained. It revealed <1% change in TOF timing and0.4% change in energy resolution during 31-month stability monitoring. CQIE assessment found <3% axial variance in SUV. 100-60% recovery coefficients of activity concentration at various sphere sizes and contrast levels were measured.Conclusions: This scanner represents the first solid-state DPC PET/CT, a technologic leap beyond photomultipliers tubes and anger logic. It presents considerable improvements in system performance and characteristics with excellent time-of-flight capability compared to conventional photomultiplier tube (PMT) PET/CT systems. The DPC system leads to promising clinical opportunities with excellent image quality, lesion detectability, and diagnostic confidence.