Impact of PET / CT system, reconstruction protocol, data analysis method, and repositioning on PET / CT precision: An experimental evaluation using an oncology and brain phantom

Purpose In longitudinal oncological and brain PET / CT studies, it is important to understand the repeatability of quantitative PET metrics in order to assess change in tracer uptake. The present studies were performed in order to assess precision as function of PET / CT system, reconstruction protocol, analysis method, scan duration (or image noise), and repositioning in the field of view. Methods Multiple (repeated) scans have been performed using a NEMA image quality ( IQ ) phantom and a 3D Hoffman brain phantom filled with 18 F solutions on two systems. Studies were performed with and without randomly (< 2 cm) repositioning the phantom and all scans (12 replicates for IQ phantom and 10 replicates for Hoffman brain phantom) were performed at equal count statistics. For the NEMA IQ phantom, we studied the recovery coefficients ( RC ) of the maximum ( SUV max ), peak ( SUV peak ), and mean ( SUV mean ) uptake in each sphere as a function of experimental conditions (noise level, reconstruction settings, and phantom repositioning). For the 3D Hoffman phantom, the mean activity concentration was determined within several volumes of interest and activity recovery and its precision was studied as function of experimental conditions. Results The impact of phantom repositioning on RC precision was mainly seen on the Philips Ingenuity PET / CT , especially in the case of smaller spheres (< 17 mm diameter, P  < 0.05). This effect was much smaller for the Siemens Biograph system. When exploring SUV max , SUV peak , or SUV mean of the spheres in the NEMA IQ phantom, it was observed that precision depended on phantom repositioning, reconstruction algorithm, and scan duration, with SUV max being most and SUV peak least sensitive to phantom repositioning. For the brain phantom, regional averaged SUV s were only minimally affected by phantom repositioning (< 2 cm). Conclusion The precision of quantitative PET metrics depends on the combination of reconstruction protocol, data analysis methods and scan duration (scan statistics). Moreover, precision was also affected by phantom repositioning but its impact depended on the data analysis method in combination with the reconstructed voxel size (tissue fraction effect). This study suggests that for oncological PET studies the use of SUV peak may be preferred over SUV max because SUV peak is less sensitive to patient repositioning/tumor sampling.