How tissue T1-variability influences DCE-MRI perfusion parameters estimation of recurrent high-grade glioma after surgery followed by radiochemotherapy

Abstract

Background

Quantification of dynamic contrast-enhanced magnetic resonance imaging (DCE-MRI) kinetic parameters (KPs) requires a determination of native tissue T1. Two approaches are adopted: (i) tissue T1-maps are acquired; and (ii) an a priori T1 value (fT1) is fixed for all patients (fT1-approach). Although it is more attractive, the fT1-approach might bias the results of KP calculations due to tissue T1 variability.

Purpose

To quantify the tissue T1 variability of recurrent high-grade glioma (HGG) and the error in KP estimation when the fT1-approach is adopted.

Material and Methods

We reviewed the postoperative MRI scans of 28 patients with recurrent HGG after radiochemotherapy. MRI study included T1-maps from multiple-dynamic multiple-echo imaging, DCE-MRI, and contrast enhanced T1-weighted images. KPs were calculated using T1-map and fT1-approach.

Results

The tissue T1 variability of recurrent HGG was relevant. The absolute error in KP estimation, as a function of the deviation of fT1 from the true value, was 8% every 100 ms. The difference between the KPs obtained with fT1-approach from fT1 values of 1300, 1390, and 1500 ms and their reference values were mostly within the 95% confidence interval (± 1.96 standard deviation). Conversely, using fT1 values of 900, 1200, 1600, and 1900 ms causes a significant error in KP estimation (P<0.05).

Conclusion

Recurrent HGG is characterized by a substantial T1 variability. Although the fT1-approach does not account for this variability, it results in a minor effect on the KP estimations provided the fT1 value is in the range of 1300–1500 ms.

Keywords

Dynamic contrast-enhanced magnetic resonance imaging high-grade glioma recurrence after treatment T1 relaxation time perfusion brain

Get full access to this article

View all access options for this article.

References

Zhang

Liu

Tong

, et al. Clinical applications of contrast-enhanced perfusion MRI techniques in gliomas: recent advances and current challenges contrast media. Mol Imaging 2017;2017:7064120.

Essig

Shiroishi

Nguyen

, et al. Perfusion MRI: the five most frequently asked technical questions. AJR Am J Roentgenol 2013; 200:24–34.

Thompson

Mills

Coope

, et al . Imaging biomarkers of angiogenesis and the microvascular environment in cerebral tumors. Br J Radiol 2011; 84:127–144.

Murayama

Nishiyama

Hirose

, et al. Differentiating between central nervous system lymphoma and high-grade glioma using dynamic susceptibility contrast and dynamic contrast-enhanced MR Imaging with histogram analysis. Magn Reson Med Sci 2018; 17:42–49.

Tofts

Brix

Buckley

, et al. Estimating kinetic parameters from dynamic contrast-enhanced T(1)-weighted MRI of a diffusable tracer: standardized quantities and symbols. J Magn Reson Imaging 1999; 10:223–232.

Larsson

Kleppestø

Grothe

, et al. T1 in high-grade glioma and the influence of different measurement strategies on parameter estimations in DCE-MRI. J Magn Reson Imaging. 2015; 42:97–104.

Tofts

Berkowitz

Schnall

MD.

Quantitative analysis of dynamic Gd-DTPA enhancement in breast tumors using a permeability model. Magn Reson Med 1995; 33:564–568.

Tietze

Mouridsen

Mikkelsen

IK.

The impact of reliable prebolus T1 measurements or a fixed T1 value in the assessment of glioma patients with dynamic contrast enhancing MRI. Neuroradiology 2015; 57:561–572.

Conte

Altabella

Castellano

, et al. Comparison of T1 mapping and fixed T1 method for dynamic contrast-enhanced MRI perfusion in brain gliomas. Eur Radiol 2019; 29:3467–3479.

10.

Nam

Kang

Choi

, et al. Comparison between the prebolus T1 measurement and the fixed T1 value in dynamic contrast-enhanced MR imaging for the differentiation of true progression from pseudoprogression in glioblastoma treated with concurrent radiation therapy and temozolomide chemotherapy. AJNR Am J Neuroradiol 2017; 38:2243–2250.

11.

Thust

Van den Bent

Smits

Pseudoprogression of brain tumors. J Magn Reson Imaging 2018; 48:571–589.

12.

Tanenbaum

Tsiouris

Johnson

, et al. Synthetic MRI for clinical neuroimaging: results of the Magnetic Resonance Image Compilation (MAGiC) prospective, multicenter, multireader trial. AJNR Am J Neuroradiol 2017; 38:1103–1110.

13.

Warntjes

JBM

Leinhard

West

, et al. Rapid magnetic resonance quantification on the brain: Optimization for clinical usage. Magn Reson Med 2008; 60:320–329.

14.

Larsson

Kleppestø

Grothe

, et al. T1 in High grade glioma and the influence of different measurement strategies on parameter estimations in DCE-MRI. J Magn Reson Imaging 2015; 42:97–104.

15.

Hawkins-Daarud

Wang

, et al. Imaging of intratumoral heterogeneity in high grade glioma. Cancer Letters 2020; 477:97–106.

16.

Jahng

Stables

Ebel

, et al. Sensitive and fast T1 mapping based on two inversion recovery images and a reference image. Med Phys 2005; 32:1524–1528.

17.

Yoo

Choi

Kim

, et al. Dynamic contrast enhanced MR imaging in predicting progression of enhancing lesions persisting after standard treatment in glioblastoma patients: a prospective study. Eur Radiol 2007; 27:3156–3166.

18.

Taunk

Shukla-Dave

, et al. Early post-treatment assessment of MRI perfusion biomarkers can predict long-term response of lung cancer brain metastases to stereotactic radiosurgery. Neuro Oncol 2018; 20:567–575.

19.

Abe

Mizobuchi

Nakajima

, et al. Diagnosis of brain tumors using dynamic contrast-enhanced perfusion imaging with a short acquisition time. Springerplus 2015;4:88.

20.

Lescher

Jurcoane

Veit

, et al. Quantitative T1 and T2 mapping in recurrent glioblastomas under bevacizumab: earlier detection of tumor progression compared to conventional MRI. Neuroradiology 2015; 57:11–12.

21.

Rizzo

Botta

Raimondi

, et al. Radiomics: the facts and the challenges of image analysis. Eur Radiol Exp 2018; 2:36.

22.

Lambin

Rios-Velazquez

Leijenaar

, et al. Radiomics: extracting more information from medical images using advanced feature analysis. Eur J Cancer 2012; 48:441–446.

23.

Choi

Kim

Ahn

, et al. Glioma grading capability: comparisons among parameters from dynamic contrast-enhanced MRI and ADC value on DWI. Korean J Radiol 2013; 14:487–492.

24.

Zhu

Kang

, et al. Glioma grading by microvascular permeability parameters derived from dynamic contrast-enhanced MRI and intratumoral susceptibility signal on susceptibility weighted imaging. Cancer Imaging 2015; 15:4.

25.

Keil

Mädler

Gieseke

, et al. Effects of arterial input function selection on kinetic parameters in brain dynamic contrast-enhanced MRI. Magn Reson Imaging 2017; 40:83–90.