SU‐E‐J‐134: Motion Modeling of Non‐Small Cell Lung Nodules Based on Respiratory Mechanics

Purpose: To quantify the movements of non‐small cell lung nodules using 4D cone‐beam computed tomography (4D‐CBCT) that is automatically registered with planning CT, and to develop a mathematical model to predict the motion trajectory. Modeling the tumor motion may reduce the PTV and ultimately increase the therapeutic ratio. Methods: Absolute coordinates of the lung nodules in 15 patients were quantified for each phase of 4D‐CBCT scans using auto‐registration methods. Assuming respiration follows an elliptical pattern spatially in the lung, these coordinates were fitted to trigonometric functions in each x‐y‐z direction. Adjusting for phase dependence, the motion could be compared quantitatively for inter‐fractional and intra‐patient variations to determine if this model is universally applicable and has predictive value. Results: Examination of over 36 sets of 4D‐CBCT data shows acceptable agreement (< 2mm) with the elliptical model for both individual scans and over the course of treatment. Some inter‐fractional variations in amplitude and cycling periods indicate the need to remodel as patients' conditions change. The intra‐patient variations are significant and strongly dependent on the patient lung volume and tumor location, thus individual modeling of tumor motion is expected. Conclusions: The model indicates good agreement and clinical relevance with non‐small cell lung nodule motion, and it appears to be potentially relevant over the course of treatment. Most re‐acquired 4D‐CBCT images inter‐fractionally were within the baseline spatial resolution of the auto‐ registration technique. However, if remodeling is necessary inter‐fractionally, this model still has the potential for significant motion margin reduction over the course of treatment.