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Review
. 2024 Dec;313(3):e232555.
doi: 10.1148/radiol.232555.

The QIBA Profile for Dynamic Susceptibility Contrast MRI Quantitative Imaging Biomarkers for Assessing Gliomas

Mark S Shiroishi #  1 Bradley J Erickson #  1 Leland S Hu  1 Daniel P Barboriak  1 Lino Becerra  1 Laura C Bell  1 Michael A Boss  1 Jerrold L Boxerman  1 Steven Cen  1 Lisa Cimino  1 Zhaoyang Fan  1 Kathryn E Keenan  1 John E Kirsch  1 Nima Ameli  1 Sina Nazemi  1 C Chad Quarles  1 Mark A Rosen  1 Luis Rodriguez  1 Kathleen M Schmainda  1 Gudrun Zahlmann  1 Yuxiang Zhou  1 Nancy Obuchowski  1 Ona Wu  1 RSNA QIBA Dynamic Susceptibility Contrast MRI Biomarker Committee  1
Collaborators, Affiliations
Review

The QIBA Profile for Dynamic Susceptibility Contrast MRI Quantitative Imaging Biomarkers for Assessing Gliomas

Mark S Shiroishi et al. Radiology. 2024 Dec.

Abstract

The dynamic susceptibility contrast (DSC) MRI measures of relative cerebral blood volume (rCBV) play a central role in monitoring therapeutic response and disease progression in patients with gliomas. Previous investigations have demonstrated promise of using rCBV in classifying tumor grade, elucidating tumor viability after therapy, and differentiating pseudoprogression and pseudoresponse. However, the quantification and reproducibility of rCBV measurements across patients, devices, and software remain a critical barrier to routine or clinical trial use of longitudinal DSC MRI in patients with gliomas. To address this limitation, the RSNA DSC MRI Biomarker Committee of the Quantitative Imaging Biomarkers Alliance developed a Profile that defines statistics-based claims for the precision of longitudinal measurements. Although rCBV is the clinical marker of interest, the Profile focused on the reproducibility of the measured quantitative imaging biomarker, which is the area under the contrast agent concentration-time curve (AUC) normalized by the mean value of normal-appearing contralateral white matter tissue (tissue-normalized AUC values). Based on previous reports of within-subject coefficient of variation (wCV) in the tissue-normalized AUC values for enhancing gliomas (wCV = 0.31), an increase of 182% or more with respect to the baseline tissue-normalized AUC value indicates that an increase has occurred with 95% confidence. In contrast, a decrease of 64% or more with respect to baseline suggests that a decrease has occurred with 95% confidence. Similarly, an increase of 399% or more in the tissue-normalized AUC values in normal brain gray matter tissue (wCV = 0.40) suggests that an increase has occurred with 95% confidence, whereas a decrease of 80% or more with respect to baseline suggests that a decrease has occurred with 95% confidence. This article provides the rationale for these claims and the compliance activities needed to achieve these claims. Potential updates to incorporate new data based on advances in technology and clinical care in the Profile are also discussed.

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Conflict of interest statement

Disclosures of conflicts of interest: M.S.S. Co-chair of the DSC-MRI Biomarker Committee for the RSNA Quantitative Imaging Biomarkers Alliance (QIBA). B.J.E. Chair of the Research Committee for SIIM. L.S.H. Grants from NIH (CA221938, CA220378, CA264992, CA250481); consulting (CNS Advisory board member) and speaker fees from Bayer; patents planned, issued, or pending for System and Method for Tissue Characterization Based on Texture Information Using Multi-Parametric MRI, Leland S. Hu MD, Jing Li, J. Ross Mitchell PhD, Teresa Wu 10909675 USA (10/2016 02/2021); Systems and Methods for Quantifying Multiscale Competitive Landscapes of Clonal Diversity in Glioblastoma Leland S. Hu MD, Jing Li, J. Ross Mitchell PhD, Kristin R. Swanson PhD, Nhan L. Tran PhD, Teresa Wu USA (11341649 08/2020 05/2022); Methods for Using Machine Learning and Mechanist Models for Cell Density Mapping of Glioblastoma with Multiparametric MRI Leland S. Hu, Jing Li, Kristin R. Swanson, Teresa Wu, Nathan Gaw, Hyunsoo Yoon, Andrea Hawkins-Daarud 11861475 USA (01/2024 01/2024); U.S. patent: 10909675 U.S. patent app: 16/975,647 (allowed 4/12/22); 16/764,837; 63/112,496; 62/684,096; 62/635,276; 62/588,096; 62/351,129; 62/239,642 International app: PCT/US2019/019687; PCT/US2018/061887; 19757457.7; 18878374.0; Medical Advisory Board member and stock options in Imaging Biometrics; co-founder of Precision Oncology Insights. D.P.B. No relevant relationships. L.B. No relevant relationships. L.C.B. Employee, shareholder, and has stock options at Roche/Genentech. M.A.B. NIBIB founded groundwork projects through QIBQ; co-chair of the MR Coordinating Committee, co-chair of the DWI Biomarker Committee, and vice-chair of the Process Committee for the RSNA Quantitative Imaging Biomarkers Alliance (QIBA). J.L.B. No relevant relationships. S.C. No relevant relationships. L.C. No relevant relationships. Z.F. No relevant relationships. K.E.K. No relevant relationships. J.E.K. No relevant relationships. N.A. No relevant relationships. S.N. No relevant relationships. C.C.Q. Received NIH grant. M.A.R. No relevant relationships. L.R. No relevant relationships. K.M.S. Institution received grants from NIH/NCI, U01CA176110 NIH/NCI R01CA264992, grants or contract from NIH/NCI R01CA255123, co-inventor of several patents but owned by Medical College of Wisconsin, board member of Prism Clinical Imaging (unpaid), ownership interest in IQ-AI Ltd and Prism Clinical Imaging, financial interest in Imaging Biometrics. G.Z. Received stipend and fee to attend Annual Meeting from RSNA, QIBA VC. Y.Z. No relevant relationships. N.O. Statistical support to institution from RSNA; statistical consulting through contracts from Siemens Medical Solutions, QURE, Takeda, and Pulsenmore and the institution; royalties from Wiley & Sons; honoraria from the RSNA for lectures and travel to Annual Meeting; member of the NCI Clinical Imaging Steering Committee; patent pending for automated identification of vascular pathology in CT images; participation on a data safety monitoring board for Eastern Cooperative Oncology Group–American College of Radiology Imaging Network, TMIST. O.W. Royalty payments from GE, Siemens, Imaging Biometrics, and Olea Medical; payments from RSNA to attend the RSNA QIBA Annual Meeting; co-inventor “Delay-compensated calculation of tissue blood flow,” U.S. patent (assigned to institution) 7,512,435 (March 31, 2009); co-chair (unpaid) of the RSNA QIBA DSC-MRI Biomarker Committee, vice-chair (unpaid) of the ASNR AI Ad Hoc Committee, chair (unpaid) of the Research Subcommittee of the ASNR Diversity and Inclusion Committee.

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