Magnetic resonance image features identify glioblastoma phenotypic subtypes with distinct molecular pathway activities

Itakura, Haruka; Achrol, Achal S.; Mitchell, Lex A.; Loya, Joshua; Liu, Tiffany; Westbroek, Erick M.; Feroze, Abdullah H.; Rodriguez, Scott; Echegaray, Sebastian; Azad, Tej D.; Yeom, Kristen W.; Napel, Sandy; Rubin, Daniel L.; Chang, Steven D.; Harsh, Griffith R.; Gevaert, Olivier

doi:10.1126/scitranslmed.aaa7582

Cited by 234 publications

(172 citation statements)

References 47 publications

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“…Moreover, characteristics of noninvasive magnetic resonance (MR) imaging (most importantly, the apparent diffusion coefficient [ADC] derived from diffusion-weighted MR imaging and the relative cerebral blood volume [CBV] derived from perfusion-weighted MR imaging) also have been shown to be reliable prognostic biomarkers for stratification of patients with glioblastoma (4,5). More recently, the field of radiomics has been introduced to extend the noninvasive study of oncologic tissue beyond established MR imaging metrics, and a large number of quantitative descriptors that reflect textural variations in image intensity, among other features, have been derived from imaging data (6)(7)(8)(9)(10)(11). In the present study, we adopted such a radiomics approach and extracted a large number of radiomic features NEURORADIOLOGY: Radiomic Profiling of Glioblastoma Kickingereder et al and dynamic susceptibility-weighted MR imaging raw data were thresholded to determine regions of prohibitive signal intensity loss near susceptibility interfaces such as the skull base, and the T1 subtraction volume tumor segmentation was modified by means of removal of low-signal regions.…”

Section: Author Contributionsmentioning

confidence: 99%

Radiomic Profiling of Glioblastoma: Identifying an Imaging Predictor of Patient Survival with Improved Performance over Established Clinical and Radiologic Risk Models

Kickingereder¹,

Burth²,

et al. 2016

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Purpose To evaluate whether radiomic feature-based magnetic resonance (MR) imaging signatures allow prediction of survival and stratification of patients with newly diagnosed glioblastoma with improved accuracy compared with that of established clinical and radiologic risk models. Materials and Methods Retrospective evaluation of data was approved by the local ethics committee and informed consent was waived. A total of 119 patients (allocated in a 2:1 ratio to a discovery [n = 79] or validation [n = 40] set) with newly diagnosed glioblastoma were subjected to radiomic feature extraction (12 190 features extracted, including first-order, volume, shape, and texture features) from the multiparametric (contrast material-enhanced T1-weighted and fluid-attenuated inversion-recovery imaging sequences) and multiregional (contrast-enhanced and unenhanced) tumor volumes. Radiomic features of patients in the discovery set were subjected to a supervised principal component (SPC) analysis to predict progression-free survival (PFS) and overall survival (OS) and were validated in the validation set. The performance of a Cox proportional hazards model with the SPC analysis predictor was assessed with C index and integrated Brier scores (IBS, lower scores indicating higher accuracy) and compared with Cox models based on clinical (age and Karnofsky performance score) and radiologic (Gaussian normalized relative cerebral blood volume and apparent diffusion coefficient) parameters. Results SPC analysis allowed stratification based on 11 features of patients in the discovery set into a low- or high-risk group for PFS (hazard ratio [HR], 2.43; P = .002) and OS (HR, 4.33; P < .001), and the results were validated successfully in the validation set for PFS (HR, 2.28; P = .032) and OS (HR, 3.45; P = .004). The performance of the SPC analysis (OS: IBS, 0.149; C index, 0.654; PFS: IBS, 0.138; C index, 0.611) was higher compared with that of the radiologic (OS: IBS, 0.175; C index, 0.603; PFS: IBS, 0.149; C index, 0.554) and clinical risk models (OS: IBS, 0.161, C index, 0.640; PFS: IBS, 0.139; C index, 0.599). The performance of the SPC analysis model was further improved when combined with clinical data (OS: IBS, 0.142; C index, 0.696; PFS: IBS, 0.132; C index, 0.637). Conclusion An 11-feature radiomic signature that allows prediction of survival and stratification of patients with newly diagnosed glioblastoma was identified, and improved performance compared with that of established clinical and radiologic risk models was demonstrated. (©) RSNA, 2016 Online supplemental material is available for this article.

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Section: Author Contributionsmentioning

confidence: 99%

Radiomic Profiling of Glioblastoma: Identifying an Imaging Predictor of Patient Survival with Improved Performance over Established Clinical and Radiologic Risk Models

Kickingereder¹,

Burth²,

et al. 2016

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“…Numerous correlative studies have evaluated other imaging features as potential biomarkers of genetic status. 5,11,[13][14][15][16][17][18][19][20][21] Yet, most have used nonlocalizing biopsies (typically from a small representative subregion) to determine a single genetic profile for an entire tumor. Unfortunately, this technique fails to inform of intratumoral heterogeneity as a whole since the genetic profiles from one biopsy location may not accurately reflect those from other tumor subregions.…”

Section: Discussionmentioning

confidence: 99%

“…A major reason is that most groups use nonlocalizing biopsies to determine a single representative profile for an entire tumor. 11,[13][14][15][16][17][18][19][20][21] By definition, this does not account for the genetic diversity throughout the various tumor subregions. Also, most biopsies originate from MRI enhancement per routine surgical practice, so tumor profiles from the nonenhancing BAT are typically under-represented.…”

Section: Introductionmentioning

confidence: 99%

“…The textural patterns between voxel intensities and their surrounding neighbors provide further insight to tissue microstructure and the local environment. 11,12 Numerous studies have correlated both MRI signal and texture analysis with genetic profiles in GBM, 5,11,[13][14][15][16][17][18][19][20][21] yet these have been limited in resolving the challenge of GBM's intratumoral heterogeneity. A major reason is that most groups use nonlocalizing biopsies to determine a single representative profile for an entire tumor.…”

Section: Introductionmentioning

confidence: 99%

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Radiogenomics to characterize regional genetic heterogeneity in glioblastoma

et al. 2016

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Background. Glioblastoma (GBM) exhibits profound intratumoral genetic heterogeneity. Each tumor comprises multiple genetically distinct clonal populations with different therapeutic sensitivities. This has implications for targeted therapy and genetically informed paradigms. Contrast-enhanced (CE)-MRI and conventional sampling techniques have failed to resolve this heterogeneity, particularly for nonenhancing tumor populations. This study explores the feasibility of using multiparametric MRI and texture analysis to characterize regional genetic heterogeneity throughout MRI-enhancing and nonenhancing tumor segments. Methods. We collected multiple image-guided biopsies from primary GBM patients throughout regions of enhancement (ENH) and nonenhancing parenchyma (so called brain-around-tumor, [BAT]). For each biopsy, we analyzed DNA copy number variants for core GBM driver genes reported by The Cancer Genome Atlas. We co-registered biopsy locations with MRI and texture maps to correlate regional genetic status with spatially matched imaging measurements. We also built multivariate predictive decision-tree models for each GBM driver gene and validated accuracies using leave-one-out-cross-validation (LOOCV). Results. We collected 48 biopsies (13 tumors) and identified significant imaging correlations (univariate analysis) for 6 driver genes: EGFR, PDGFRA, PTEN, CDKN2A, RB1, and TP53. Predictive model accuracies (on LOOCV) varied by driver gene of interest. Highest accuracies were observed for PDGFRA (77.1%), EGFR (75%), CDKN2A (87.5%), and RB1 (87.5%), while lowest accuracy was observed in TP53 (37.5%). Models for 4 driver genes (EGFR, RB1, CDKN2A,

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“…All lesions of tumor shapes and many concavities along the tumor outlines, regular and well-circumscribed edges, and central hypointensity encompassed by a hyperintense rim (29) (Figs 1-3 and E1-E3 [online]). The mean maximum lesion diameter was 40 mm (range, 24-63 mm) (Table).…”

Section: Overview Of Patient Populationmentioning

confidence: 99%

Contrast-enhanced MR Imaging versus Contrast-enhanced US: A Comparison in Glioblastoma Surgery by Using Intraoperative Fusion Imaging

et al. 2017

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Supported by the Seventh Framework Programme (grant 602 923).q RSNA, 2017 Purpose:To compare contrast material enhancement of glioblastoma multiforme (GBM) with intraoperative contrast-enhanced ultrasonography (US) versus that with preoperative gadolinium-enhanced T1-weighted magnetic resonance (MR) imaging by using real-time fusion imaging. Materials andMethods:Ten patients with GBM were retrospectively identified by using routinely collected, anonymized data. Navigated contrastenhanced US was performed after intravenous administration of contrast material before tumor resection. All patients underwent tumor excision with navigated intraoperative US guidance with use of fusion imaging between real-time intraoperative US and preoperative MR imaging. With use of fusion imaging, glioblastoma contrast enhancement at contrast-enhanced US (regarding location, morphologic features, margins, dimensions, and pattern) was compared with that at gadolinium-enhanced T1-weighted MR imaging. Results:Fusion imaging for virtual navigation enabled matching of realtime contrast-enhanced US scans to corresponding coplanar preoperative gadolinium-enhanced T1-weighted MR images in all cases, with a positional discrepancy of less than 2 mm. Contrast enhancement of gadolinium-enhanced T1-weighted MR imaging and contrast-enhanced US was superimposable in all cases with regard to location, margins, dimensions, and morphologic features. The qualitative analysis of contrast enhancement pattern demonstrated a similar distribution in contrast-enhanced US and gadolinium-enhanced T1-weighted MR imaging in nine patients: Seven lesions showed peripheral inhomogeneous ring enhancement, and two lesions showed a prevalent nodular pattern. In one patient, the contrast enhancement pattern differed between the two modalities: Contrast-enhanced US showed enhancement of the entire bulk of the tumor, whereas gadolinium-enhanced T1-weighted MR imaging demonstrated peripheral contrast enhancement. Conclusion:Glioblastoma contrast enhancement with contrast-enhanced US is superimposable on that provided with preoperative gadolinium-enhanced T1-weighted MR imaging regarding location, margins, morphologic features, and dimensions, with a similar enhancement pattern in most cases. Thus, contrast-enhanced US is of potential use in the surgical management of GBM.q RSNA, 2017

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Magnetic resonance image features identify glioblastoma phenotypic subtypes with distinct molecular pathway activities

Cited by 234 publications

References 47 publications

Radiomic Profiling of Glioblastoma: Identifying an Imaging Predictor of Patient Survival with Improved Performance over Established Clinical and Radiologic Risk Models

Radiomic Profiling of Glioblastoma: Identifying an Imaging Predictor of Patient Survival with Improved Performance over Established Clinical and Radiologic Risk Models

Radiogenomics to characterize regional genetic heterogeneity in glioblastoma

Contrast-enhanced MR Imaging versus Contrast-enhanced US: A Comparison in Glioblastoma Surgery by Using Intraoperative Fusion Imaging

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