Abstract
BackgroundMachine learning (ML) algorithms are increasingly explored in glioma prognostication. Random survival forest (RSF) is a common ML approach in analyzing time-to-event survival data. However, it is controversial which method between RSF and traditional cornerstone method Cox proportional hazards (CPH) is better fitted. The purpose of this study was to compare RSF and CPH in predicting tumor progression of high-grade glioma (HGG) after particle beam radiotherapy (PBRT).MethodsThe study enrolled 82 consecutive HGG patients who were treated with PBRT at Shanghai Proton and Heavy Ion Center between 6/2015 and 11/2019. The entire cohort was split into the training and testing set in an 80/20 ratio. Ten variables from patient-related, tumor-related and treatment-related information were utilized for developing CPH and RSF for predicting progression-free survival (PFS). The model performance was compared in concordance index (C-index) for discrimination (accuracy), brier score (BS) for calibration (precision) and variable importance for interpretability.ResultsThe CPH model demonstrated a better performance in terms of integrated C-index (62.9%) and BS (0.159) compared to RSF model (C-index = 61.1%, BS = 0.174). In the context of variable importance, CPH model indicated that age (P = 0.024), WHO grade (P = 0.020), IDH gene (P = 0.019), and MGMT promoter status (P = 0.040) were significantly correlated with PFS in the univariate analysis; multivariate analysis showed that age (P = 0.041), surgical completeness (P = 0.084), IDH gene (P = 0.057), and MGMT promoter (P = 0.092) had a significant or trend toward the relation with PFS. RSF showed that merely IDH and age were of positive importance for predicting PFS. A final nomogram was developed to predict tumor progression at the individual level based on CPH model.ConclusionsIn a relatively small dataset with HGG patients treated with PBRT, CPH outperformed RSF for predicting tumor progression. A comprehensive criterion with accuracy, precision, and interpretability is recommended in evaluating ML prognostication approaches for clinical deployment.
Highlights
High-grade glioma (HGG), including WHO grade III and IV class, is the most common and lethal primary cancer in central nervous system [1]
The entire study cohort consisted of 82 consecutive HGG patients, who underwent particle beam radiotherapy (PBRT) at Shanghai Proton and Heavy
According to the Cox proportional hazards (CPH) model (Table 2), univariate analysis documented that age (P = 0.024), WHO grade (P = 0.020), Isocitrate dehydrogenase (IDH) gene (P = 0.019), and methylguanine-DNA methyltransferase (MGMT) promoter status (P = 0.040) were significantly correlated with Progression-free survival (PFS); multivariate analysis showed that age (P = 0.041), surgical completeness (P = 0.084), IDH gene (P = 0.057), and MGMT promoter (P = 0.092) had a significant or trend toward the relation with PFS
Summary
High-grade glioma (HGG), including WHO grade III and IV class, is the most common and lethal primary cancer in central nervous system [1]. It is still controversial that which methods among ML algorithms and conventional modeling can achieve better performance in survival analysis, in terms of time-to-event censored data [14,15,16]. It is a critical need to explore which model can contribute to higher accuracy and precision of survival prediction at patient-level for HGG with PBRT. Random survival forest (RSF) is a common ML approach in analyzing time-to-event survival data. It is controversial which method between RSF and traditional cornerstone method Cox proportional hazards (CPH) is better fitted. The purpose of this study was to compare RSF and CPH in predicting tumor progression of high-grade glioma (HGG) after particle beam radiotherapy (PBRT)
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