Abstract

Purpose: Treatment planning for pancreas stereotactic body radiation therapy (SBRT) is a difficult and time-consuming task. In this study, we aim to develop a novel deep learning framework to generate clinical-quality plans by direct prediction of fluence maps from patient anatomy using convolutional neural networks (CNNs).Materials and Methods: Our proposed framework utilizes two CNNs to predict intensity-modulated radiation therapy fluence maps and generate deliverable plans: (1) Field-dose CNN predicts field-dose distributions in the region of interest using planning images and structure contours; (2) a fluence map CNN predicts the final fluence map per beam using the predicted field dose projected onto the beam's eye view. The predicted fluence maps were subsequently imported into the treatment planning system for leaf sequencing and final dose calculation (model-predicted plans). One hundred patients previously treated with pancreas SBRT were included in this retrospective study, and they were split into 85 training cases and 15 test cases. For each network, 10% of training data were randomly selected for model validation. Nine-beam benchmark plans with standardized target prescription and organ-at-risk constraints were planned by experienced clinical physicists and used as the gold standard to train the model. Model-predicted plans were compared with benchmark plans in terms of dosimetric endpoints, fluence map deliverability, and total monitor units.Results: The average time for fluence-map prediction per patient was 7.1 s. Comparing model-predicted plans with benchmark plans, target mean dose, maximum dose (0.1 cc), and D95% absolute differences in percentages of prescription were 0.1, 3.9, and 2.1%, respectively; organ-at-risk mean dose and maximum dose (0.1 cc) absolute differences were 0.2 and 4.4%, respectively. The predicted plans had fluence map gamma indices (97.69 ± 0.96% vs. 98.14 ± 0.74%) and total monitor units (2,122 ± 281 vs. 2,265 ± 373) that were comparable to the benchmark plans.Conclusions: We develop a novel deep learning framework for pancreas SBRT planning, which predicts a fluence map for each beam and can, therefore, bypass the lengthy inverse optimization process. The proposed framework could potentially change the paradigm of treatment planning by harnessing the power of deep learning to generate clinically deliverable plans in seconds.

Highlights

  • Pancreatic cancer is an aggressive and lethal malignancy that accounted for an estimated 4.5% of all cancer-related deaths worldwide in 2018 (Bray et al, 2018)

  • The projection of field dose and planning target volume (PTV) along the beam’s eye view (BEV) is relatively time-consuming compared to convolutional neural network (CNN) predictions

  • A deep learning (DL) model-predicted plan was generated within 1 to 2 min, including calculating the model-predicted plan dose in Treatment Planning System (TPS), as compared to the traditional manual planning, which takes between 1 and 3 h

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Summary

Introduction

Pancreatic cancer is an aggressive and lethal malignancy that accounted for an estimated 4.5% of all cancer-related deaths worldwide in 2018 (Bray et al, 2018). Stereotactic body radiation therapy (SBRT) utilizes sophisticated image-guidance and motion-management techniques to allow the delivery of a highly conformal dose of radiation to the target while sparing the surrounding normal tissues. Due to the nature of the higher fractional dose, achieving steeper dose gradients is prioritized to better spare the gastrointestinal (GI) organs at risk (OARs), such as the stomach and duodenum/small bowel. The highly variable planning target volume (PTV) and OAR geometry make the planning task extremely challenging. The consistency of plan quality is hard to maintain due to time pressure and the planner’s experience, which may result in suboptimal plans. A system capable of maintaining consistently high plan quality is warranted in modern radiation oncology departments

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