Diagnostic role of apparent diffusion coefficient combined with intratumoral susceptibility signals in differentiating high-grade gliomas from brain metastases

Abstract

Objective

The aim of this study was to assess whether tumoral and peritumoral apparent diffusion coefficient values and intratumoral susceptibility signals on susceptibility-weighted imaging could distinguish between high-grade gliomas and brain metastases, and to investigate their associations with the Ki-67 proliferation index.

Materials and methods

Fifty-seven patients with pathologically confirmed diagnoses of either high-grade glioma or brain metastasis were enrolled in this study (23 with high-grade gliomas and 34 with brain metastases). The minimum and mean apparent diffusion coefficients in the enhancing tumoral region (ADC_min and ADC_mean) and the minimum apparent diffusion coefficient in the peritumoral region (ADC_edema) were measured from apparent diffusion coefficient maps, and intratumoral susceptibility signal grades acquired by susceptibility-weighted imaging were calculated. Ki-67 proliferation index values were obtained from the hospital database. These parameters were evaluated using the Mann-Whitney U test, independent-sample t-test, Spearman correlation analysis, receiver operating characteristic curve, and logistic regression analyses.

Results

ADC_mean, ADC_min values, and intratumoral susceptibility signal grades in brain metastases were significantly lower than those in high-grade gliomas (all p < 0.05). Ki-67 proliferation index values showed significant correlations with ADC_mean, ADC_min, and intratumoral susceptibility signal grade in brain metastases (all p < 0.05), but no correlation was found in high-grade gliomas (all p > 0.05). According to receiver operating characteristic curve analysis, ADC_mean achieved the highest diagnostic performance for discriminating high-grade gliomas from brain metastases. Furthermore, the combination of tumoral apparent diffusion coefficient parameters with intratumoral susceptibility signal grade provided a higher area under the curve than univariate parameters.

Conclusion

The combination of tumoral apparent diffusion coefficient with intratumoral susceptibility signal grade can offer better diagnostic performances for differential diagnosis. Apparent diffusion coefficient and intratumoral susceptibility signal may reflect cellular proliferative activity in brain metastases, but not in high-grade gliomas.

Keywords

Apparent diffusion coefficient brain metastases high-grade glioma intratumoral susceptibility signal Ki-67

Get full access to this article

View all access options for this article.

References

Cha

Aiken

, et al. Quantitative apparent diffusion coefficients and T2 relaxation times in characterizing contrast enhancing brain tumors and regions of peritumoral edema. J Magn Reson Imaging 2005; 21: 701–708.

Yamasaki

Kurisu

Satoh

, et al. Apparent diffusion coefficient of human brain tumors at MR imaging. Radiology 2005; 235: 985–991.

Chen

Liu

Bao

, et al. The correlation between apparent diffusion coefficient and tumor cellularity in patients: A meta-analysis. PLoS One 2013; 8: 1–9.

Lee

TerBrugge

Mikulis

, et al. Diagnostic value of peritumoral minimum apparent diffusion coefficient for differentiation of glioblastoma multiforme from solitary metastatic lesions. AJR Am J Roentgenol 2011; 196: 71–79.

Kono

Inoue

Nakayama

, et al. The role of diffusion-weighted imaging in patients with brain tumors. AJNR Am J Neuroradiol 2001; 22: 1081–1088.

Rollin

Guyotat

Streichenberger

, et al. Clinical relevance of diffusion and perfusion magnetic resonance imaging in assessing intra-axial brain tumors. Neuroradiology 2006; 48: 150–159.

Han

Huang

Guo

, et al. Use of a high b-value for diffusion weighted imaging of peritumoral regions to differentiate high-grade gliomas and solitary metastases. J Magn Reson Imaging 2015; 42: 80–86.

Krabbe

Gideon

Wagn

, et al. MR diffusion imaging of human intracranial tumors. Neuroradiology 1997; 39: 483–489.

Chiang

Kuo

, et al. Distinction between high-grade gliomas and solitary metastases using peritumoral 3-T magnetic resonance spectroscopy, diffusion, and perfusion imagings. Neuroradiology 2004; 46: 619–627.

10.

Server

Kulle

Maehlen

, et al. Quantitative apparent diffusion coefficients in the characterization of brain tumors and associated peritumoral edema. Acta Radiol 2009; 50: 682–689.

11.

Caravan

Ciortea

Contis

, et al. Diagnostic value of apparent diffusion coefficient in differentiating between high-grade gliomas and brain metastases. Acta Radiol 2018; 59: 599–605.

12.

Neska-Matuszewska

Bladowska

Sąsiadek

, et al. Differentiation of glioblastoma multiforme, metastases and primary central nervous system lymphomas using multiparametric perfusion and diffusion MR imaging of a tumor core and a peritumoral zone: Searching for a practical approach. PLoS One 2018; 13: e0191341.

13.

Haacke

Mittal

, et al. Susceptibility weighted imaging: Technical aspects and clinical applications, part 1. AJNR Am J Neuroradiol 2009; 30: 19–30.

14.

Robinson

Bhuta

Susceptibility-weighted imaging of the brain: Current utility and potential applications. J Neuroimaging 2011; 21: e189–204.

15.

Chen

Jiang

Zheng

, et al. Differentiating intracranial solitary fibrous tumor/hemangiopericytoma from meningioma using diffusion-weighted imaging and susceptibility-weighted imaging. Neuroradiology 2020; 62: 175–184.

16.

Park

Kim

Jahng

, et al. Semiquantitative assessment of intratumoral susceptibility signals using non-contrast-enhanced high-field high-resolution susceptibility-weighted imaging in patients with gliomas: Comparison with MR perfusion imaging. AJNR Am J Neuroradiol 2009; 30: 1402–1408.

17.

Kim

Jahng

Ryu

, et al. Added value and diagnostic performance of intratumoral susceptibility signals in the differential diagnosis of solitary enhancing brain lesions: Preliminary study. AJNR Am J Neuroradiol 2009; 30: 1574–1579.

18.

Louis

Perry

Reifenberger

, et al. The 2016 World Health Organization classification of tumors of the central nervous system: A summary. Acta Neuropathol 2016; 131: 803–820.

19.

Pope

Mirsadraei

Lai

, et al. Differential gene expression in glioblastoma defined by ADC histogram analysis: A relationship to extracellular matrix molecules and survival. AJNR Am J Neuroradiol 2012; 33: 1059–1064.

20.

Tsougos

Svolos

Kousi

, et al. Differentiation of glioblastoma multiforme from metastatic brain tumor using proton magnetic resonance spectroscopy, diffusion and perfusion metrics at 3 T. Cancer Imaging 2012; 12: 423–436.

21.

Meyer

Fiedler

Kornhuber

, et al. Comparison of diffusion-weighted imaging findings in brain metastases of different origin. Clin Imaging 2015; 39; 965–969.

22.

Bozdağ

Çinkooğlu

Histogram analysis of ADC maps for differentiating brain metastases from different histological types of lung cancers. Can Assoc Radiol J 2020. Epub ahead of print 30 June 2020. DOI: 10.1177/0846537120933837.

23.

Bertossi

Virgintino

Maiorano

, et al. Ultrastructural and morphometric investigation of human brain capillaries in normal and peritumoral tissues. Ultrastruct Pathol 1997; 21: 41–49.

24.

Ding

Xing

Liu

, et al. Differentiation of primary central nervous system lymphoma from high-grade glioma and brain metastases using susceptibility-weighted imaging. Brain Behav 2014; 4: 841–849.

25.

Scholzen

Gerdes

The Ki-67 protein: From the known and the unknown. J Cell Physiol 2000; 182: 311–322.

26.

Yan

Haopeng

Xiaoyuan

, et al. Non-Gaussian diffusion MR imaging of glioma: Comparisons of multiple diffusion parameters and correlation with histologic grade and MIB-1 (Ki-67 labeling) index. Neuroradiology 2016; 58: 121–132.

27.

Chen

Lou

, et al. Diagnostic value of minimum apparent diffusion coefficient values in prediction of neuroepithelial tumor grading. J Magn Reson Imaging 2010; 31: 1331–1338.

28.

Basirjafari

Poureisa

Shahhoseini

, et al. Apparent diffusion coefficient values and non-homogeneity of diffusion in brain tumors in diffusion-weighted MRI. Acta Radiol 2020; 61: 244–252.

29.

Belli

Busoni

Ciccarone

, et al. Quality assurance multicenter comparison of different MR scanners for quantitative diffusion-weighted imaging. J Magn Reson Imaging 2016; 43: 213–219.