Incorporating human and learned domain knowledge into training deep neural networks: A differentiable dose volume histogram and adversarial inspired framework for generating Pareto optimal dose distributions in radiation therapy
Dan Nguyen, Rafe McBeth, Azar Sadeghnejad Barkousaraie, Gyanendra, Bohara, Chenyang Shen, Xun Jia, Steve Jiang

TL;DR
This paper introduces a novel differentiable dose volume histogram loss combined with adversarial training to generate Pareto optimal radiation dose distributions efficiently, improving accuracy and reducing planning time in radiation therapy.
Contribution
It presents a new domain-specific differentiable loss function integrated with adversarial learning for deep neural networks in radiation therapy dose prediction.
Findings
The combined MSE+DVH+ADV model achieved the lowest prediction error across multiple metrics.
Prediction time per model is approximately 0.052 seconds, enabling real-time application.
The approach significantly reduces treatment planning time and enhances dose distribution accuracy.
Abstract
We propose a novel domain specific loss, which is a differentiable loss function based on the dose volume histogram, and combine it with an adversarial loss for the training of deep neural networks to generate Pareto optimal dose distributions. The mean squared error (MSE) loss, dose volume histogram (DVH) loss, and adversarial (ADV) loss were used to train 4 instances of the neural network model: 1) MSE, 2) MSE+ADV, 3) MSE+DVH, and 4) MSE+DVH+ADV. 70 prostate patients were acquired, and the dose influence arrays were calculated for each patient. 1200 Pareto surface plans per patient were generated by pseudo-randomizing the tradeoff weights (84,000 plans total). We divided the data into 54 training, 6 validation, and 10 testing patients. Each model was trained for 100,000 iterations, with a batch size of 2. The prediction time of each model is 0.052 seconds. Quantitatively, the…
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