PT - JOURNAL ARTICLE AU - Louise Emmett AU - Ur Metser AU - Glenn Bauman AU - Rodney J. Hicks AU - Andrew Weickhardt AU - Ian D. Davis AU - Shonit Punwani AU - Greg Pond AU - Sue Chua AU - Bao Ho AU - Edward Johnston AU - Frederic Pouliot AU - Andrew M. Scott TI - Prospective, Multisite, International Comparison of <sup>18</sup>F-Fluoromethylcholine PET/CT, Multiparametric MRI, and <sup>68</sup>Ga-HBED-CC PSMA-11 PET/CT in Men with High-Risk Features and Biochemical Failure After Radical Prostatectomy: Clinical Performance and Patient Outcomes AID - 10.2967/jnumed.118.220103 DP - 2019 Jun 01 TA - Journal of Nuclear Medicine PG - 794--800 VI - 60 IP - 6 4099 - http://jnm.snmjournals.org/content/60/6/794.short 4100 - http://jnm.snmjournals.org/content/60/6/794.full SO - J Nucl Med2019 Jun 01; 60 AB - A significant proportion of men with rising prostate-specific antigen (PSA) levels after radical prostatectomy (RP) fail prostate fossa (PF) salvage radiation treatment (SRT). This study was done to assess the ability of 18F-fluoromethylcholine (18F-FCH) PET/CT (hereafter referred to as 18F-FCH), 68Ga-HBED-CC PSMA-11 PET/CT (hereafter referred to as PSMA), and pelvic multiparametric MRI (hereafter referred to as pelvic MRI) to identify men who will best benefit from SRT. Methods: Prospective, multisite imaging studies were carried out in men who had rising PSA levels after RP, high-risk features, and negative/equivocal conventional imaging results and who were being considered for SRT. 18F-FCH (91/91), pelvic MRI (88/91), and PSMA (31/91) (Australia) were all performed within 2 wk. Imaging was interpreted by experienced local/central interpreters who were masked with regard to other imaging results, with consensus being reached for discordant interpretations. Expected management was documented before and after imaging, and data about all treatments and PSA levels were collected for 3 y. The treatment response to SRT was defined as a reduction in PSA levels of &gt;50% without androgen deprivation therapy. Results: The median Gleason score, PSA level at imaging, and PSA doubling time were 8, 0.42 (interquartile range, 0.29–0.93) ng/mL, and 5.0 (interquartile range, 3.3–7.6) months. Recurrent prostate cancer was detected in 28% (25/88) by pelvic MRI, 32% (29/91) by 18F-FCH, and 42% (13/31) by PSMA. This recurrence was found within the PF in 21.5% (19/88), 13% (12/91), and 19% (6/31) and at sites outside the PF (extra-PF) in 8% (7/88), 19% (17/91), and 32% (10/31) by MRI, 18F-FCH, and PSMA, respectively (P &lt; 0.004). A total of 94% (16/17) of extra-PF sites on 18F-FCH were within the pelvic MRI field. Intrapelvic extra-PF disease was detected in 90% (9/10) by PSMA and in 31% (5/16) by MRI. 18F-FCH changed management in 46% (42/91), and MRI changed management in 24% (21/88). PSMA provided additional management changes over 18F-FCH in 23% (7/31). The treatment response to SRT was higher in men with negative results or disease confined to the PF than in men with extra-PF disease (18F-FCH 73% [32/44] versus 33% [3/9] [P &lt; 0.02], pelvic MRI 70% [32/46] versus 50% [2/4] [P was not significant], and PSMA 88% [7/8] versus 14% [1/7] [P &lt; 0.005]). Men with negative imaging results (MRI, 18F-FCH, or PSMA) had high (78%) SRT response rates. Conclusion: 18F-FCH and PSMA had high detection rates for extra-PF disease in men with negative/equivocal conventional imaging results and rising PSA levels after RP. These findings affected management and treatment responses, suggesting an important role for PET in triaging men being considered for curative SRT.