An image-based deep learning framework for individualising radiotherapy dose: a retrospective analysis of outcome prediction

Lou, Bin; Doken, BA Semihcan; Zhuang, Tingliang; Wingerter, BE Danielle; Gidwani, Mishka; Mistry, N; Ladic, Lance; Kamen, Ali; Abazeed, Mohamed E.

doi:10.1016/s2589-7500(19)30058-5

Cited by 158 publications

(98 citation statements)

References 41 publications

(62 reference statements)

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“…The present pipeline can eventually be expanded to include automatic classification of a BMs histology [28], prediction of treatment response [29] or to directly influence the treatment e.g. through dose optimization [30].…”

Section: Discussionmentioning

confidence: 99%

Deep convolutional neural networks for automated segmentation of brain metastases trained on clinical data

et al. 2020

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Introduction: Deep learning-based algorithms have demonstrated enormous performance in segmentation of medical images. We collected a dataset of multiparametric MRI and contour data acquired for use in radiosurgery, to evaluate the performance of deep convolutional neural networks (DCNN) in automatic segmentation of brain metastases (BM). Methods: A conventional U-Net (cU-Net), a modified U-Net (moU-Net) and a U-Net trained only on BM smaller than 0.4 ml (sU-Net) were implemented. Performance was assessed on a separate test set employing sensitivity, specificity, average false positive rate (AFPR), the dice similarity coefficient (DSC), Bland-Altman analysis and the concordance correlation coefficient (CCC). Results: A dataset of 509 patients (1223 BM) was split into a training set (469 pts) and a test set (40 pts). A combination of all trained networks was the most sensitive (0.82) while maintaining a specificity 0.83. The same model achieved a sensitivity of 0.97 and a specificity of 0.94 when considering only lesions larger than 0.06 ml (75% of all lesions). Type of primary cancer had no significant influence on the mean DSC per lesion (p = 0.60). Agreement between manually and automatically assessed tumor volumes as quantified by a CCC of 0.87 (95% CI, 0.77-0.93), was excellent. Conclusion: Using a dataset which properly captured the variation in imaging appearance observed in clinical practice, we were able to conclude that DCNNs reach clinically relevant performance for most lesions. Clinical applicability is currently limited by the size of the target lesion. Further studies should address if small targets are accurately represented in the test data.

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Section: Discussionmentioning

confidence: 99%

Deep convolutional neural networks for automated segmentation of brain metastases trained on clinical data

et al. 2020

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“…Furthermore, that this heterogeneity is driven and influenced by changes in the tumor genome is now accepted-indeed, large-scale classification efforts have been performed to understand these differences. [8][9][10] In addition, there have been several efforts to understand surrogate genomic metrics for individual patient's resistance to radiation, 9 imaging-based studies, 11 and theoretical studies of the tumor microenvironment. 12 We previously proposed that the gene expression-based radiosensitivity index (RSI), a surrogate for intrinsic cellular radiosensitivity, and the genomic-adjusted radiation dose (GARD), an individualized quantitative metric of the biological effect of RT, could serve as the first approach to biology based RT.…”

Section: Introductionmentioning

confidence: 99%

Personalizing Radiotherapy Prescription Dose Using Genomic Markers of Radiosensitivity and Normal Tissue Toxicity in NSCLC

Scott

Sedor

Scarborough

et al. 2021

Journal of Thoracic Oncology

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“…Chest computed tomography (CT) can effectively capture the manifestations of COVID-19 infections and even asymptomatic infections 10 – 12 . Deep learning, an artificial intelligence (AI) technology, has achieved impressive performance in the analysis of CT images 13 – 16 . Chest CT with the aid of deep learning offers promises to reduce the burden of prompt mass case detection, especially under the shortage of RT-PCR 17 .…”

Section: Introductionmentioning

confidence: 99%

Assisting scalable diagnosis automatically via CT images in the combat against COVID-19

Liu

Dai

et al. 2021

Sci Rep

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The pandemic of Coronavirus Disease 2019 (COVID-19) is causing enormous loss of life globally. Prompt case identification is critical. The reference method is the real-time reverse transcription PCR (RT-PCR) assay, whose limitations may curb its prompt large-scale application. COVID-19 manifests with chest computed tomography (CT) abnormalities, some even before the onset of symptoms. We tested the hypothesis that the application of deep learning (DL) to 3D CT images could help identify COVID-19 infections. Using data from 920 COVID-19 and 1,073 non-COVID-19 pneumonia patients, we developed a modified DenseNet-264 model, COVIDNet, to classify CT images to either class. When tested on an independent set of 233 COVID-19 and 289 non-COVID-19 pneumonia patients, COVIDNet achieved an accuracy rate of 94.3% and an area under the curve of 0.98. As of March 23, 2020, the COVIDNet system had been used 11,966 times with a sensitivity of 91.12% and a specificity of 88.50% in six hospitals with PCR confirmation. Application of DL to CT images may improve both efficiency and capacity of case detection and long-term surveillance.

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An image-based deep learning framework for individualising radiotherapy dose: a retrospective analysis of outcome prediction

Cited by 158 publications

References 41 publications

Deep convolutional neural networks for automated segmentation of brain metastases trained on clinical data

Deep convolutional neural networks for automated segmentation of brain metastases trained on clinical data

Personalizing Radiotherapy Prescription Dose Using Genomic Markers of Radiosensitivity and Normal Tissue Toxicity in NSCLC

Assisting scalable diagnosis automatically via CT images in the combat against COVID-19

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