CT radiomics compared to a clinical model for predicting checkpoint inhibitor treatment outcomes in patients with advanced melanoma

Laurens S. ter Maat (Corresponding author), Isabella A.J. van Duin, Sjoerd G. Elias, Tim Leiner, Joost J.C. Verhoeff, Eran R.A.N. Arntz, Max F. Troenokarso, Willeke A.M. Blokx, Ivana Isgum, Geraldine A. de Wit, Franchette W.P.J. van den Berkmortel, Marye J. Boers-Sonderen, Martijn F. Boomsma, Fons J.M. van den Eertwegh, Jan Willem B. de Groot, Djura Piersma, Art Vreugdenhil, Hans M. Westgeest, Ellen Kapiteijn, Paul J. van DiestJosien P.W. Pluim, Pim A. de Jong, Karijn P.M. Suijkerbuijk, Mitko Veta

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Abstract

Introduction: Predicting checkpoint inhibitors treatment outcomes in melanoma is a relevant task, due to the unpredictable and potentially fatal toxicity and high costs for society. However, accurate biomarkers for treatment outcomes are lacking. Radiomics are a technique to quantitatively capture tumour characteristics on readily available computed tomography (CT) imaging. The purpose of this study was to investigate the added value of radiomics for predicting clinical benefit from checkpoint inhibitors in melanoma in a large, multicenter cohort. Methods: Patients who received first-line anti-PD1±anti-CTLA4 treatment for advanced cutaneous melanoma were retrospectively identified from nine participating hospitals. For every patient, up to five representative lesions were segmented on baseline CT, and radiomics features were extracted. A machine learning pipeline was trained on the radiomics features to predict clinical benefit, defined as stable disease for more than 6 months or response per RECIST 1.1 criteria. This approach was evaluated using a leave-one-centre-out cross validation and compared to a model based on previously discovered clinical predictors. Lastly, a combination model was built on the radiomics and clinical model. Results: A total of 620 patients were included, of which 59.2% experienced clinical benefit. The radiomics model achieved an area under the receiver operator characteristic curve (AUROC) of 0.607 [95% CI, 0.562–0.652], lower than that of the clinical model (AUROC=0.646 [95% CI, 0.600–0.692]). The combination model yielded no improvement over the clinical model in terms of discrimination (AUROC=0.636 [95% CI, 0.592–0.680]) or calibration. The output of the radiomics model was significantly correlated with three out of five input variables of the clinical model (p < 0.001). Discussion: The radiomics model achieved a moderate predictive value of clinical benefit, which was statistically significant. However, a radiomics approach was unable to add value to a simpler clinical model, most likely due to the overlap in predictive information learned by both models. Future research should focus on the application of deep learning, spectral CT-derived radiomics, and a multimodal approach for accurately predicting benefit to checkpoint inhibitor treatment in advanced melanoma.

Original languageEnglish
Pages (from-to)167-177
Number of pages11
JournalEuropean Journal of Cancer
Volume185
DOIs
Publication statusPublished - May 2023

Funding

This research was funded by The Netherlands Organization for Health Research and Development (ZonMW, project number 848101007 ) and Philips.

FundersFunder number
Philips
ZonMw : Dutch Organisation for Health Research and Development848101007

    Keywords

    • Checkpoint inhibition
    • Computed tomography
    • Machine learning
    • Metastatic melanoma
    • Radiomics
    • Response prediction
    • Melanoma/diagnostic imaging
    • Skin Neoplasms/diagnostic imaging
    • Humans
    • Treatment Outcome
    • Tomography, X-Ray Computed
    • Retrospective Studies

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