TY - JOUR
T1 - An artificial intelligence model predicts the survival of solid tumour patients from imaging and clinical data
AU - Schutte, Kathryn
AU - Brulport, Fabien
AU - Harguem-Zayani, Sana
AU - Schiratti, Jean Baptiste
AU - Ghermi, Ridouane
AU - Jehanno, Paul
AU - Jaeger, Alexandre
AU - Alamri, Talal
AU - Naccache, Raphaël
AU - Haddag-Miliani, Leila
AU - Orsi, Teresa
AU - Lamarque, Jean Philippe
AU - Hoferer, Isaline
AU - Lawrance, Littisha
AU - Benatsou, Baya
AU - Bousaid, Imad
AU - Azoulay, Mikael
AU - Verdon, Antoine
AU - Bidault, François
AU - Balleyguier, Corinne
AU - Aubert, Victor
AU - Bendjebbar, Etienne
AU - Maussion, Charles
AU - Loiseau, Nicolas
AU - Schmauch, Benoît
AU - Sefta, Meriem
AU - Wainrib, Gilles
AU - Clozel, Thomas
AU - Ammari, Samy
AU - Lassau, Nathalie
N1 - Publisher Copyright:
© 2022 The Author(s)
PY - 2022/10/1
Y1 - 2022/10/1
N2 - Background: The need for developing new biomarkers is increasing with the emergence of many targeted therapies. Artificial Intelligence (AI) algorithms have shown great promise in the medical imaging field to build predictive models. We developed a prognostic model for solid tumour patients using AI on multimodal data. Patients and methods: Our retrospective study included examinations of patients with seven different cancer types performed between 2003 and 2017 in 17 different hospitals. Radiologists annotated all metastases on baseline computed tomography (CT) and ultrasound (US) images. Imaging features were extracted using AI models and used along with the patients’ and treatments’ metadata. A Cox regression was fitted to predict prognosis. Performance was assessed on a left-out test set with 1000 bootstraps. Results: The model was built on 436 patients and tested on 196 patients (mean age 59, IQR: 51–6, 411 men out of 616 patients). On the whole, 1147 US images were annotated with lesions delineation, and 632 thorax-abdomen-pelvis CTs (total of 301,975 slices) were fully annotated with a total of 9516 lesions. The developed model reaches an average concordance index of 0.71 (0.67–0.76, 95% CI). Using the median predicted risk as a threshold value, the model is able to significantly (log-rank test P value < 0.001) isolate high-risk patients from low-risk patients (respective median OS of 11 and 31 months) with a hazard ratio of 3.5 (2.4–5.2, 95% CI). Conclusion: AI was able to extract prognostic features from imaging data, and along with clinical data, allows an accurate stratification of patients’ prognoses.
AB - Background: The need for developing new biomarkers is increasing with the emergence of many targeted therapies. Artificial Intelligence (AI) algorithms have shown great promise in the medical imaging field to build predictive models. We developed a prognostic model for solid tumour patients using AI on multimodal data. Patients and methods: Our retrospective study included examinations of patients with seven different cancer types performed between 2003 and 2017 in 17 different hospitals. Radiologists annotated all metastases on baseline computed tomography (CT) and ultrasound (US) images. Imaging features were extracted using AI models and used along with the patients’ and treatments’ metadata. A Cox regression was fitted to predict prognosis. Performance was assessed on a left-out test set with 1000 bootstraps. Results: The model was built on 436 patients and tested on 196 patients (mean age 59, IQR: 51–6, 411 men out of 616 patients). On the whole, 1147 US images were annotated with lesions delineation, and 632 thorax-abdomen-pelvis CTs (total of 301,975 slices) were fully annotated with a total of 9516 lesions. The developed model reaches an average concordance index of 0.71 (0.67–0.76, 95% CI). Using the median predicted risk as a threshold value, the model is able to significantly (log-rank test P value < 0.001) isolate high-risk patients from low-risk patients (respective median OS of 11 and 31 months) with a hazard ratio of 3.5 (2.4–5.2, 95% CI). Conclusion: AI was able to extract prognostic features from imaging data, and along with clinical data, allows an accurate stratification of patients’ prognoses.
KW - Antiangiogenic treatment
KW - Artificial intelligence
KW - Biomarker
KW - Imaging
KW - Prognosis
KW - Solid tumour
UR - http://www.scopus.com/inward/record.url?scp=85135922804&partnerID=8YFLogxK
U2 - 10.1016/j.ejca.2022.06.055
DO - 10.1016/j.ejca.2022.06.055
M3 - Article
C2 - 35985252
AN - SCOPUS:85135922804
SN - 0959-8049
VL - 174
SP - 90
EP - 98
JO - European Journal of Cancer
JF - European Journal of Cancer
ER -