Towards Differentiation of Brain Tumor from Radiation Necrosis Using Multi-parametric MRI: Preliminary Results at 4.7 T Using Rodent Models

Overview

Journal Magn Reson Imaging

Publisher Elsevier

Specialty Radiology

Date 2022 Oct 9

PMID 36209946

Authors

Sean P Devan

Xiaoyu Jiang

Hakmook Kang

Guozhen Luo

Jingping Xie

Zhongliang Zu

Ashley M Stokes

John C Gore

Colin D McKnight

Austin N Kirschner

Junzhong Xu

Affiliations

Soon will be listed here.

Abstract

Background: It remains a clinical challenge to differentiate brain tumors from radiation-induced necrosis in the brain. Despite significant improvements, no single MRI method has been validated adequately in the clinical setting.

Methods: Multi-parametric MRI (mpMRI) was performed to differentiate 9L gliosarcoma from radiation necrosis in animal models. Five types of MRI methods probed complementary information on different scales i.e., T (relaxation), CEST based APT (probing mobile proteins/peptides) and rNOE (mobile macromolecules), qMT (macromolecules), diffusion based ADC (cell density) and SSIFT iAUC (cell size), and perfusion based DSC (blood volume and flow).

Results: For single MRI parameters, iAUC and ADC provide the best discrimination of radiation necrosis and brain tumor. For mpMRI, a combination of iAUC, ADC, and APT shows the best classification performance based on a two-step analysis with the Lasso and Ridge regressions.

Conclusion: A general mpMRI approach is introduced to choosing candidate multiple MRI methods, identifying the most effective parameters from all the mpMRI parameters, and finding the appropriate combination of chosen parameters to maximize the classification performance to differentiate tumors from radiation necrosis.

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