Litcius/Paper detail

Radiomics-based neural network predicts recurrence patterns in glioblastoma using dynamic susceptibility contrast-enhanced MRI

Ka Young Shim, Sung Won Chung, Jae Hak Jeong, Inpyeong Hwang, Chul‐Kee Park, Tae Min Kim, Sung‐Hye Park, Jae‐Kyung Won, Joo Ho Lee, Soon‐Tae Lee, Roh‐Eul Yoo, Koung Mi Kang, Tae Jin Yun, Ji‐hoon Kim, Chul‐Ho Sohn, Kyu Sung Choi, Seung Hong Choi

2021Scientific Reports50 citationsDOIOpen Access PDF

Abstract

Glioblastoma remains the most devastating brain tumor despite optimal treatment, because of the high rate of recurrence. Distant recurrence has distinct genomic alterations compared to local recurrence, which requires different treatment planning both in clinical practice and trials. To date, perfusion-weighted MRI has revealed that perfusional characteristics of tumor are associated with prognosis. However, not much research has focused on recurrence patterns in glioblastoma: namely, local and distant recurrence. Here, we propose two different neural network models to predict the recurrence patterns in glioblastoma that utilizes high-dimensional radiomic profiles based on perfusion MRI: area under the curve (AUC) (95% confidence interval), 0.969 (0.903-1.000) for local recurrence; 0.864 (0.726-0.976) for distant recurrence for each patient in the validation set. This creates an opportunity to provide personalized medicine in contrast to studies investigating only group differences. Moreover, interpretable deep learning identified that salient radiomic features for each recurrence pattern are related to perfusional intratumoral heterogeneity. We also demonstrated that the combined salient radiomic features, or "radiomic risk score", increased risk of recurrence/progression (hazard ratio, 1.61; p = 0.03) in multivariate Cox regression on progression-free survival.

Topics & Concepts

GlioblastomaHazard ratioRadiomicsProportional hazards modelMedicineConfidence intervalMultivariate statisticsInternal medicineOncologyRadiologyComputer scienceMachine learningCancer researchRadiomics and Machine Learning in Medical ImagingGlioma Diagnosis and TreatmentMRI in cancer diagnosis