Glioblastoma and Solitary Brain Metastasis: Differentiation by Integrating Demographic‐MRI and Deep‐Learning Radiomics Signatures

Background Studies have shown that deep‐learning radiomics (DLR) could help differentiate glioblastoma (GBM) from solitary brain metastasis (SBM), but whether integrating demographic‐MRI and DLR features can more accurately distinguish GBM from SBM remains uncertain. Purpose To construct and validat...

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Published in:Journal of magnetic resonance imaging 2024-09, Vol.60 (3), p.909-920
Main Authors: Zhang, Yuze, Zhang, Hongbo, Zhang, Hanwen, Ouyang, Ying, Su, Ruru, Yang, Wanqun, Huang, Biao
Format: Article
Language:English
Subjects:
Adult
Aged
Algorithms
Brain
Brain - diagnostic imaging
Brain cancer
Brain Neoplasms - diagnostic imaging
Brain Neoplasms - secondary
Deep Learning
Demographics
Demography
Diagnosis, Differential
Edema
Female
Field strength
Glioblastoma
Glioblastoma - diagnostic imaging
Glioma
Humans
Learning
Magnetic resonance imaging
Magnetic Resonance Imaging - methods
Male
Metastases
Metastasis
Middle Aged
multiparametric
Neuroimaging
Nomograms
Population studies
radiographic features
Radiomics
Retrospective Studies
Signatures
solitary brain metastasis
Statistical analysis
Statistical models
Statistical tests
Support vector machines
Training
Tumors
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Summary:Background Studies have shown that deep‐learning radiomics (DLR) could help differentiate glioblastoma (GBM) from solitary brain metastasis (SBM), but whether integrating demographic‐MRI and DLR features can more accurately distinguish GBM from SBM remains uncertain. Purpose To construct and validate a demographic‐MRI deep‐learning radiomics nomogram (DDLRN) integrating demographic‐MRI and DLR signatures to differentiate GBM from SBM preoperatively. Study Type Retrospective. Population Two hundred and thirty‐five patients with GBM (N = 115) or SBM (N = 120), randomly divided into a training cohort (90 GBM and 98 SBM) and a validation cohort (25 GBM and 22 SBM). Field Strength/Sequence Axial T2‐weighted fast spin‐echo sequence (T2WI), T2‐weighted fluid‐attenuated inversion recovery sequence (T2‐FLAIR), and contrast‐enhanced T1‐weighted spin‐echo sequence (CE‐T1WI) using 1.5‐T and 3.0‐T scanners. Assessment The demographic‐MRI signature was constructed with seven imaging features (“pool sign,” “irregular ring sign,” “regular ring sign,” “intratumoral vessel sign,” the ratio of the area of peritumoral edema to the enhanced tumor, the ratio of the lesion area on T2‐FLAIR to CE‐T1WI, and the tumor location) and demographic factors (age and sex). Based on multiparametric MRI, radiomics and deep‐learning (DL) models, DLR signature, and DDLRN were developed and validated. Statistical Tests The Mann–Whitney U test, Pearson test, least absolute shrinkage and selection operator, and support vector machine algorithm were applied for feature selection and construction of radiomics and DL models. Results DDLRN showed the best performance in differentiating GBM from SBM with area under the curves (AUCs) of 0.999 and 0.947 in the training and validation cohorts, respectively. Additionally, the DLR signature (AUC = 0.938) outperformed the radiomics and DL models, and the demographic‐MRI signature (AUC = 0.775) was comparable to the T2‐FLAIR radiomics and DL models in the validation cohort (AUC = 0.762 and 0.749, respectively). Data Conclusion DDLRN integrating demographic‐MRI and DLR signatures showed excellent performance in differentiating GBM from SBM. Level of Evidence 3 Technical Efficacy Stage 2
ISSN:1053-1807
1522-2586
1522-2586
DOI:10.1002/jmri.29123