SU‐EE‐A4‐05: Individual Target Volume Definition in NSCLC Using PET

Purpose: To determine whether quantitatively segmented PET images could be used to identify the volume containing a tumor and its total motion. If possible, PET could provide individualized internal target volumes (ITV) in lung cancer. Method and Materials: A physiological phantom containing background level of Na‐22 was used. Two spheres filled with 0.5 mCi/ml of Na‐22 were used to simulate tumors; each was oscillated within one lung of the phantom with 4 preset motion extents in S/I, A/P, and M/L directions. PET and CT imaging were performed on an integrated PET/CT scanner. A CT‐based GTV was generated using a threshold of −850 HU. A population‐based margin of 15 mm, reflecting both motion and set‐up uncertainties, was added to generate a CT‐based PTV. A PET‐based ITV was defined using a threshold of three standard deviations above normal lung background. A set‐up margin of 7.5 mm was added to PET‐based ITVs to create PTVs. Image‐based PTVs were compared to ideal PTVs. Clinical validation of this methodology was performed on 7 patients with parenchymal lung lesions with the addition of digital fluoroscopy. 18‐FDG was used for patient PET scanning. Results: For the phantom study, PET‐based PTVs were closer to the ideal PTV than those based on CT. While the PET‐based PTVs were approximately half the size of the CT‐based PTVs, in no case would the PET‐based PTVs have resulted in geographical miss. For majority of the patients, PET accurately predicted or slightly over‐predicted the tumor motion extents compared to fluoroscopy; differences were within 2 voxels. Conclusion: Based on the phantom study and initial clinical validation, we have found that quantitatively segmented PET images can provide an accurate individualized ITV that correlates with a tumor and its motion. Conflict of Interest: Research was supported by NCI Canada with funds from Ontario Cancer Society.