Abstract
ICIs are a standard of care in several malignancies; however, according to overall response rate (ORR), only a subset of eligible patients benefits from ICIs. Thus, an ability to predict ORR could enable more rational use. In this study a ML-based ORR prediction model was built, with patient-reported symptom data and other clinical data as inputs, using the extreme gradient boosting technique (XGBoost). Prediction performance for unseen samples was evaluated using leave-one-out cross-validation (LOOCV), and the performance was evaluated with accuracy, AUC (area under curve), F1 score, and MCC (Matthew’s correlation coefficient). The ORR prediction model had a promising LOOCV performance with all four metrics: accuracy (75%), AUC (0.71), F1 score (0.58), and MCC (0.4). A rather good sensitivity (0.58) and high specificity (0.82) of the model were seen in the confusion matrix for all 63 LOOCV ORR predictions. The two most important symptoms for predicting the ORR were itching and fatigue. The results show that it is possible to predict ORR for patients with multiple advanced cancers undergoing ICI therapies with a ML model combining clinical, routine laboratory, and patient-reported data even with a limited size cohort.
Highlights
Immune checkpoint inhibitors (ICIs) are standard-of-care treatments in several malignancies, both in adjuvant and advanced settings [1,2,3,4,5,6,7,8,9,10,11,12]
The aim of this study was to create a machine learning (ML)-based model for predicting the presence of complete response (CR) or partial response (PR) based on evolving digitally collected patient-reported symptoms, the presence of physician-confirmed immune-related adverse events (irAEs), and laboratory values collected in a prospective manner from cancer patients receiving ICI therapies in the KISS trial [26]
Assessed treatment responses (n = 63) by the study physicians were retrieved from the eCRF
Summary
Immune checkpoint inhibitors (ICIs) are standard-of-care treatments in several malignancies, both in adjuvant and advanced settings [1,2,3,4,5,6,7,8,9,10,11,12]. While only a subset of patients responds to ICIs, novel tools to assess the treatment response are needed when aiming to improve patient care and the clinical value of ICIs. Artificial intelligence (AI)-based analytics have gained growing interest in the field of cancer care. Machine learning models have been shown to predict responses to a variety of standard-of-care chemotherapy regimens from gene expression profiles of individual patients with high accuracy [14,15]. Deep learning systems have shown promising results, especially in cancer diagnostics [16]. AI-based methods can be used to analyze vast data pools to create predictive and prognostic analytics for generating value-based healthcare assets.
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