RT Journal Article SR Electronic T1 Deep Learning Based 3D Dose Estimation from Prompt Gamma Distribution for Proton Therapy Monitoring JF Journal of Nuclear Medicine JO J Nucl Med FD Society of Nuclear Medicine SP 574 OP 574 VO 61 IS supplement 1 A1 Wenzhuo Lu A1 Tianyu Ma A1 Tao Yang A1 Shouping Xu A1 Yaqiang Liu YR 2020 UL http://jnm.snmjournals.org/content/61/supplement_1/574.abstract AB 574Objectives: Prompt gamma (PG) imaging technique has been demonstrated to be very promising in real-time proton range monitoring in proton therapy. Despite the high correlation between PG and proton dose (PD) distribution, the detected PG cannot represent the delivered PD and be directly comparable with the planned PD. Here, we propose a deep learning based method to estimate the absolute PD from PG distribution. Methods: Monte Carlo simulation was performed using GATE v8.0 with the physics list QGSP_BERT_HP_EMY. Head and neck CT scans were performed on 14 volunteers, and the data were used to generate the heterogeneous medium distribution in the simulation. For each volunteer, incident monenergistic pencil beams with the energy of 150±0.8 MeV was simulated from two different positions. The spot size of proton beam was 6 mm ×10 mm. The total number of protons for each incidence was 1.2×108. The 3D PD deposited in each volunteer’s brain and the emitted PG with energy ranging from 2 MeV to 8 MeV were stored in a 300×234×300 image with 1 mm ×1 mm ×1 mm voxel size. 31 2D slices were extracted from the each 3D image. A U-net model was implemented to learn the PG-to-PD transform. Integrated CT and simulated PG distribution were used as two input channels for training, while the simulated PD was used as the label. Patches with size of 200×200 were randomly extracted from the images and then flipped both horizontally and vertically to augment the data and avoid over-fitting. L2 was chosen as the loss function to obtain stable solution. 480 epochs with size of 1600 were trained. Each epoch contained 100 batches with mini-batch size of 16. The model was trained with 744 pairs from 12 volunteers and tested with the remaining 2 volunteers. To investigate the performance of this proposed method, the estimated PD was first visually compared with simulated PD. The mean projected range equal the depth of the distal 80% point of the Bragg peak in different slices, D80, was calculated to measure the range accuracy of estimated PD. Also, the relative error of the cumulative dose in 3D ROI was calculated to compare the estimated PD and simulated PD quantitatively by rendering 2D slices together. Results: We observe very similar distribution between estimated PD and simulated PD. The range D80 bias is less than 0.5 mm for volunteer #1, where the Bragg peak locates in homogeneous brain regions. In volunteer #2, when the Bragg peak is near the nasal cavity, the range bias is less than 2.0 mm. The relative error of cumulative dose in a 3D ROI is less than 5% for all cases. Conclusion: The proposed deep learning based method satisfactorily recovers PD distribution from PG and corresponding CT data. This method shows great potential not only for range verification but also for quantitative 3D dose monitoring using PG in proton therapy. Further investigations are under way to implement the polyenergetic pencil beam scanning plans in simulation and estimation. Research Support: The research was supported by the National Natural Science Foundation of China (No. 81727807, No.11575096, No. 11605008) and National Key Research and Development (R&D) Plan of China (Grant ID. 2019YFF0302503 and 2016YFC0105405).