WE‐C‐WAB‐06: Effects of Radiation On Functional Bone Marrow in Patients with Pelvic Malignancies

Purpose: To test the hypothesis that pelvic bone marrow fat fraction (FF) (i.e., quantity of fat relative to water) varies with glucose metabolism and radiation dose in patients undergoing pelvic radiotherapy. Methods: 34 patients with pelvic malignancies were enrolled from 2009‐2012 on prospective trials; 31 received concurrent chemotherapy. All patients underwent baseline 18 F‐FDG‐PET and quantitative MRI with IDEAL‐IQ. 9 patients underwent PET/CT simulation, 15 PET/CT, and 10 PET‐only. 18 and 14 patients underwent IDEAL‐IQ at mid‐treatment and 1–3 weeks post‐treatment, respectively. PET‐only scans were rigidly registered to the planning CT (pCT). PET/CT and IDEAL‐IQ scans were deformably registered to the pCT (Velocity AI, Atlanta, GA). Each image was resampled to the pCT, creating a database of FF, dose, and body weight‐standardized uptake value (SUVbw) for each voxel. Analyses were performed on pelvic bone from L5 to ischia. Spearman rank correlation coefficients (SRCC) were estimated comparing SUVbw and dose vs. FF 1 , ΔFF 21 , and ΔFF 31 . FF 1 represents FF at baseline and ΔFF 21 and ΔFF 31 represent change in FF from baseline to mid‐and post‐treatment, respectively. Mean SRCCs were tested for significance using a 2‐sided t‐test. Results: Data analysis was completed for 15 patients (13 gynecologic, 7 anal cancer). We observed a significant negative correlation between SUVbw and FF1, and significant positive correlations between SUVbw and ΔFF 21 and ΔFF 31 (Table), indicating that high metabolic activity correlated with lower FF (a surrogate for red marrow) and increased conversion to fat (yellow marrow) during radiotherapy. We observed significant positive correlations between radiation dose and ΔFF 21 and ΔFF 31 , indicating that regions of higher dose were more likely to convert to fat (Table). No correlation was observed between dose and FF1. Conclusion: Preliminary results suggest that red marrow has higher metabolic activity, and is more likely to convert to yellow marrow during radiotherapy, in a dose‐dependent manner. Funding has been provided by NIH R21 Research Grant (#CA162718‐01) and by the American Society of Clinical Oncology.