Frontiers in Oncology (Jan 2022)

Multi-Organ Omics-Based Prediction for Adaptive Radiation Therapy Eligibility in Nasopharyngeal Carcinoma Patients Undergoing Concurrent Chemoradiotherapy

  • Sai-Kit Lam,
  • Yuanpeng Zhang,
  • Jiang Zhang,
  • Bing Li,
  • Jia-Chen Sun,
  • Carol Yee-Tung Liu,
  • Pak-Hei Chou,
  • Xinzhi Teng,
  • Zong-Rui Ma,
  • Rui-Yan Ni,
  • Ta Zhou,
  • Tao Peng,
  • Hao-Nan Xiao,
  • Tian Li,
  • Ge Ren,
  • Andy Lai-Yin Cheung,
  • Andy Lai-Yin Cheung,
  • Francis Kar-Ho Lee,
  • Celia Wai-Yi Yip,
  • Kwok-Hung Au,
  • Victor Ho-Fun Lee,
  • Amy Tien-Yee Chang,
  • Lawrence Wing-Chi Chan,
  • Jing Cai

DOI
https://doi.org/10.3389/fonc.2021.792024
Journal volume & issue
Vol. 11

Abstract

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PurposeTo investigate the role of different multi-organ omics-based prediction models for pre-treatment prediction of Adaptive Radiotherapy (ART) eligibility in patients with nasopharyngeal carcinoma (NPC).Methods and MaterialsPre-treatment contrast-enhanced computed tomographic and magnetic resonance images, radiotherapy dose and contour data of 135 NPC patients treated at Hong Kong Queen Elizabeth Hospital were retrospectively analyzed for extraction of multi-omics features, namely Radiomics (R), Morphology (M), Dosiomics (D), and Contouromics (C), from a total of eight organ structures. During model development, patient cohort was divided into a training set and a hold-out test set in a ratio of 7 to 3 via 20 iterations. Four single-omics models (R, M, D, C) and four multi-omics models (RD, RC, RM, RMDC) were developed on the training data using Ridge and Multi-Kernel Learning (MKL) algorithm, respectively, under 10-fold cross validation, and evaluated on hold-out test data using average area under the receiver-operator-characteristics curve (AUC). The best-performing single-omics model was first determined by comparing the AUC distribution across the 20 iterations among the four single-omics models using two-sided student t-test, which was then retrained using MKL algorithm for a fair comparison with the four multi-omics models.ResultsThe R model significantly outperformed all other three single-omics models (all p-value<0.0001), achieving an average AUC of 0.942 (95%CI: 0.938-0.946) and 0.918 (95%CI: 0.903-0.933) in training and hold-out test set, respectively. When trained with MKL, the R model (R_MKL) yielded an increased AUC of 0.984 (95%CI: 0.981-0.988) and 0.927 (95%CI: 0.905-0.948) in training and hold-out test set respectively, while demonstrating no significant difference as compared to all studied multi-omics models in the hold-out test sets. Intriguingly, Radiomic features accounted for the majority of the final selected features, ranging from 64% to 94%, in all the studied multi-omics models.ConclusionsAmong all the studied models, the Radiomic model was found to play a dominant role for ART eligibility in NPC patients, and Radiomic features accounted for the largest proportion of features in all the multi-omics models.

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