Clinical suitability of deep learning based synthetic CTs for adaptive proton therapy of lung cancer

Purpose Adaptive proton therapy (APT) of lung cancer patients requires frequent volumetric imaging of diagnostic quality. Cone‐beam CT (CBCT) can provide these daily images, but x‐ray scattering limits CBCT‐image quality and hampers dose calculation accuracy. The purpose of this study was to generat...

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Bibliographic Details
Published in:Medical physics (Lancaster) 2021-12, Vol.48 (12), p.7673-7684
Main Authors: Thummerer, Adrian, Seller Oria, Carmen, Zaffino, Paolo, Meijers, Arturs, Guterres Marmitt, Gabriel, Wijsman, Robin, Seco, Joao, Langendijk, Johannes Albertus, Knopf, Antje‐Christin, Spadea, Maria Francesca, Both, Stefan
Format: Article
Language:English
Subjects:
adaptive proton therapy
Cone-Beam Computed Tomography
Deep Learning
DIAGNOSTIC IMAGING (IONIZING AND NON‐IONIZING)
Humans
Image Processing, Computer-Assisted
lung cancer
Lung Neoplasms - diagnostic imaging
Lung Neoplasms - radiotherapy
Proton Therapy
Radiotherapy Dosage
Radiotherapy Planning, Computer-Assisted
synthetic CT
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Summary:Purpose Adaptive proton therapy (APT) of lung cancer patients requires frequent volumetric imaging of diagnostic quality. Cone‐beam CT (CBCT) can provide these daily images, but x‐ray scattering limits CBCT‐image quality and hampers dose calculation accuracy. The purpose of this study was to generate CBCT‐based synthetic CTs using a deep convolutional neural network (DCNN) and investigate image quality and clinical suitability for proton dose calculations in lung cancer patients. Methods A dataset of 33 thoracic cancer patients, containing CBCTs, same‐day repeat CTs (rCT), planning‐CTs (pCTs), and clinical proton treatment plans, was used to train and evaluate a DCNN with and without a pCT‐based correction method. Mean absolute error (MAE), mean error (ME), peak signal‐to‐noise ratio, and structural similarity were used to quantify image quality. The evaluation of clinical suitability was based on recalculation of clinical proton treatment plans. Gamma pass ratios, mean dose to target volumes and organs at risk, and normal tissue complication probabilities (NTCP) were calculated. Furthermore, proton radiography simulations were performed to assess the HU‐accuracy of sCTs in terms of range errors. Results On average, sCTs without correction resulted in a MAE of 34 ± 6 HU and ME of 4 ± 8 HU. The correction reduced the MAE to 31 ± 4HU (ME to 2 ± 4HU). Average 3%/3 mm gamma pass ratios increased from 93.7% to 96.8%, when the correction was applied. The patient specific correction reduced mean proton range errors from 1.5 to 1.1 mm. Relative mean target dose differences between sCTs and rCT were below ± 0.5% for all patients and both synthetic CTs (with/without correction). NTCP values showed high agreement between sCTs and rCT (
ISSN:0094-2405
2473-4209
DOI:10.1002/mp.15333