Frontiers in Physiology (Jul 2022)

Deep learning predicts immune checkpoint inhibitor-related pneumonitis from pretreatment computed tomography images

  • Peixin Tan,
  • Wei Huang,
  • Lingling Wang,
  • Lingling Wang,
  • Lingling Wang,
  • Guanhua Deng,
  • Ye Yuan,
  • Ye Yuan,
  • Ye Yuan,
  • Shili Qiu,
  • Shili Qiu,
  • Shili Qiu,
  • Dong Ni,
  • Dong Ni,
  • Dong Ni,
  • Shasha Du,
  • Jun Cheng,
  • Jun Cheng,
  • Jun Cheng

DOI
https://doi.org/10.3389/fphys.2022.978222
Journal volume & issue
Vol. 13

Abstract

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Immune checkpoint inhibitors (ICIs) have revolutionized the treatment of lung cancer, including both non-small cell lung cancer and small cell lung cancer. Despite the promising results of immunotherapies, ICI-related pneumonitis (ICIP) is a potentially fatal adverse event. Therefore, early detection of patients at risk for developing ICIP before the initiation of immunotherapy is critical for alleviating future complications with early interventions and improving treatment outcomes. In this study, we present the first reported work that explores the potential of deep learning to predict patients who are at risk for developing ICIP. To this end, we collected the pretreatment baseline CT images and clinical information of 24 patients who developed ICIP after immunotherapy and 24 control patients who did not. A multimodal deep learning model was constructed based on 3D CT images and clinical data. To enhance performance, we employed two-stage transfer learning by pre-training the model sequentially on a large natural image dataset and a large CT image dataset, as well as transfer learning. Extensive experiments were conducted to verify the effectiveness of the key components used in our method. Using five-fold cross-validation, our method accurately distinguished ICIP patients from non-ICIP patients, with area under the receiver operating characteristic curve of 0.918 and accuracy of 0.920. This study demonstrates the promising potential of deep learning to identify patients at risk for developing ICIP. The proposed deep learning model enables efficient risk stratification, close monitoring, and prompt management of ICIP, ultimately leading to better treatment outcomes.

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