Integration of machine learning and mechanistic models accurately predicts variation in cell density of glioblastoma using multiparametric MRI.
Nathan GawAndrea Hawkins-DaarudLeland S HuHyunsoo YoonLujia WangYanzhe XuPamela R JacksonKyle W SingletonLeslie C BaxterJennifer EschbacherAshlyn GonzalesAshley NespodzanyKris A SmithPeter NakajiJoseph Ross MitchellTeresa WuKristin R SwansonJing LiPublished in: Scientific reports (2019)
Glioblastoma (GBM) is a heterogeneous and lethal brain cancer. These tumors are followed using magnetic resonance imaging (MRI), which is unable to precisely identify tumor cell invasion, impairing effective surgery and radiation planning. We present a novel hybrid model, based on multiparametric intensities, which combines machine learning (ML) with a mechanistic model of tumor growth to provide spatially resolved tumor cell density predictions. The ML component is an imaging data-driven graph-based semi-supervised learning model and we use the Proliferation-Invasion (PI) mechanistic tumor growth model. We thus refer to the hybrid model as the ML-PI model. The hybrid model was trained using 82 image-localized biopsies from 18 primary GBM patients with pre-operative MRI using a leave-one-patient-out cross validation framework. A Relief algorithm was developed to quantify relative contributions from the data sources. The ML-PI model statistically significantly outperformed (p < 0.001) both individual models, ML and PI, achieving a mean absolute predicted error (MAPE) of 0.106 ± 0.125 versus 0.199 ± 0.186 (ML) and 0.227 ± 0.215 (PI), respectively. Associated Pearson correlation coefficients for ML-PI, ML, and PI were 0.838, 0.518, and 0.437, respectively. The Relief algorithm showed the PI model had the greatest contribution to the result, emphasizing the importance of the hybrid model in achieving the high accuracy.
Keyphrases
- machine learning
- magnetic resonance imaging
- deep learning
- contrast enhanced
- high resolution
- artificial intelligence
- squamous cell carcinoma
- magnetic resonance
- single cell
- radiation therapy
- big data
- papillary thyroid
- lymph node metastasis
- functional connectivity
- resistance training
- photodynamic therapy
- electronic health record
- cell migration
- resting state
- neural network
- high intensity