Your search keyword '"Paediatric abdominal tumours"' showing total 2 results

1. Deep learning prediction of proton and photon dose distributions for paediatric abdominal tumours.

Author

Guerreiro, F., Seravalli, E., Janssens, G.O., Maduro, J.H., Knopf, A.C., Langendijk, J.A., Raaymakers, B.W., and Kontaxis, C.

Subjects

*RADIOTHERAPY, *DEEP learning, *VOLUMETRIC-modulated arc therapy, *PHOTONS, *PROTONS, *FORECASTING

Abstract

• Deep-learning networks for prediction of PBS and VMAT doses were established. • Relative errors between planned and predicted doses were minimal in the target. • Strong correlation (r > 0.9) was found between planned and predicted DVH metrics. • The networks classified the PBS dosimetric benefit over VMAT with 98% precision. • Proposed networks can accurately predict the treatment modality selection outcome. Dose prediction using deep learning networks prior to radiotherapy might lead tomore efficient modality selections. The study goal was to predict proton and photon dose distributions based on the patient-specific anatomy and to assess their clinical usage for paediatric abdominal tumours. Data from 80 patients with neuroblastoma or Wilms' tumour was included. Pencil beam scanning (PBS) (5 mm/ 3%) and volumetric-modulated arc therapy (VMAT) plans (5 mm) were robustly optimized on the internal target volume (ITV). Separate 3-dimensional patch-based U-net networks were trained to predict PBS and VMAT dose distributions. Doses, planning-computed tomography images and relevant optimization masks (ITV, vertebra and organs-at-risk) of 60 patients were used for training with a 5-fold cross validation. The networks' performance was evaluated by computing the relative error between planned and predicted dose-volume histogram (DVH) parameters for 20 inference patients. In addition, the organs-at-risk mean dose difference between modalities was calculated using planned and predicted dose distributions (ΔD mean = D VMAT -D PBS). Two radiation oncologists performed a blind PBS/VMAT modality selection based on either planned or predicted ΔD mean. Average DVH differences between planned and predicted dose distributions were ≤ |6%| for both modalities. The networks classified the organs-at-risk D mean difference as a gain (ΔD mean > 0) with 98% precision. An identical modality selection based on planned compared to predicted ΔD mean was made for 18/20 patients. Deep learning networks for accurate prediction of proton and photon dose distributions for abdominal paediatric tumours were established. These networks allowing fast dose visualisation might aid in identifying the optimal radiotherapy technique when experience and/or resources are unavailable. [ABSTRACT FROM AUTHOR]

Published

2021

2. Deep learning prediction of proton and photon dose distributions for paediatric abdominal tumours

Author

Filipa Guerreiro, Johannes A. Langendijk, Bas W. Raaymakers, C Kontaxis, Enrica Seravalli, Antje Knopf, John H. Maduro, Geert O. Janssens, Guided Treatment in Optimal Selected Cancer Patients (GUTS), and Damage and Repair in Cancer Development and Cancer Treatment (DARE)

Subjects

Organs at Risk, Abdominal tumours, medicine.medical_treatment, Dose prediction, Cross-validation, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Paediatric abdominal tumours, Deep Learning, Photon therapy, Proton Therapy, Medicine, Humans, Radiology, Nuclear Medicine and imaging, Pencil-beam scanning, Child, Proton therapy, Modality (human–computer interaction), business.industry, Deep learning, Radiotherapy Planning, Computer-Assisted, Radiotherapy Dosage, Hematology, Patient referral, Radiation therapy, Oncology, 030220 oncology & carcinogenesis, Abdominal Neoplasms, Artificial intelligence, Tomography, Radiotherapy, Intensity-Modulated, Protons, business, Nuclear medicine

Abstract

Objective Dose prediction using deep learning networks prior to radiotherapy might lead tomore efficient modality selections. The study goal was to predict proton and photon dose distributions based on the patient-specific anatomy and to assess their clinical usage for paediatric abdominal tumours. Material and methods Data from 80 patients with neuroblastoma or Wilms’ tumour was included. Pencil beam scanning (PBS) (5 mm/ 3%) and volumetric-modulated arc therapy (VMAT) plans (5 mm) were robustly optimized on the internal target volume (ITV). Separate 3-dimensional patch-based U-net networks were trained to predict PBS and VMAT dose distributions. Doses, planning-computed tomography images and relevant optimization masks (ITV, vertebra and organs-at-risk) of 60 patients were used for training with a 5-fold cross validation. The networks’ performance was evaluated by computing the relative error between planned and predicted dose-volume histogram (DVH) parameters for 20 inference patients. In addition, the organs-at-risk mean dose difference between modalities was calculated using planned and predicted dose distributions (ΔDmean = DVMAT-DPBS). Two radiation oncologists performed a blind PBS/VMAT modality selection based on either planned or predicted ΔDmean. Results Average DVH differences between planned and predicted dose distributions were ≤ |6%| for both modalities. The networks classified the organs-at-risk Dmean difference as a gain (ΔDmean > 0) with 98% precision. An identical modality selection based on planned compared to predicted ΔDmean was made for 18/20 patients. Conclusion Deep learning networks for accurate prediction of proton and photon dose distributions for abdominal paediatric tumours were established. These networks allowing fast dose visualisation might aid in identifying the optimal radiotherapy technique when experience and/or resources are unavailable.

Published

2020