A novel image signature-based radiomics method to achieve precise diagnosis and prognostic stratification of gliomas.
Huigao LuoQiyuan ZhuangYuanyuan WangAibaidula AbudumijitiKuangyu ShiAxel RomingerHong ChenZhong YangVanessa TranGuoqing WuZeju LiZhen FanZengxin QiYuxiao GuoJinhua YuZhifeng ShiPublished in: Laboratory investigation; a journal of technical methods and pathology (2020)
Radiomics has potential advantages in the noninvasive histopathological and molecular diagnosis of gliomas. We aimed to develop a novel image signature (IS)-based radiomics model to achieve multilayered preoperative diagnosis and prognostic stratification of gliomas. Herein, we established three separate case cohorts, consisting of 655 glioma patients, and carried out a retrospective study. Image and clinical data of three cohorts were used for training (N = 188), cross-validation (N = 411), and independent testing (N = 56) of the IS model. All tumors were segmented from magnetic resonance (MR) images by the 3D U-net, followed by extraction of high-throughput network features, which were referred to as IS. IS was then used to perform noninvasive histopathological diagnosis and molecular subtyping. Moreover, a new IS-based clustering method was applied for prognostic stratification in IDH-wild-type lower-grade glioma (IDHwt LGG) and triple-negative glioblastoma (1p19q retain/IDH wild-type/TERTp-wild-type GBM). The average accuracies of histological diagnosis and molecular subtyping were 89.8 and 86.1% in the cross-validation cohort, while these numbers reached 83.9 and 80.4% in the independent testing cohort. IS-based clustering method was demonstrated to successfully divide IDHwt LGG into two subgroups with distinct median overall survival time (48.63 vs 38.27 months respectively, P = 0.023), and two subgroups in triple-negative GBM with different median OS time (36.8 vs 18.2 months respectively, P = 0.013). Our findings demonstrate that our novel IS-based radiomics model is an effective tool to achieve noninvasive histo-molecular pathological diagnosis and prognostic stratification of gliomas. This IS model shows potential for future routine use in clinical practice.
Keyphrases
- wild type
- magnetic resonance
- high grade
- clinical practice
- deep learning
- contrast enhanced
- high throughput
- lymph node metastasis
- low grade
- magnetic resonance imaging
- squamous cell carcinoma
- prognostic factors
- single molecule
- single cell
- risk assessment
- newly diagnosed
- computed tomography
- machine learning
- electronic health record
- human health
- patients undergoing
- artificial intelligence
- convolutional neural network