Differentiation of Skull Base Chondrosarcomas, Chordomas, and Metastases: Utility of DWI and Dynamic Contrast-Enhanced Perfusion MR Imaging

Study Population

This retrospective single-center study was approved by University of Michigan institutional review board, and the requirement of informed consent was waived. Data were acquired and de-identified before any analysis, in compliance with all applicable Health Insurance Portability and Accountability Act regulations. We reviewed the medical records of 368 patients, including 68 patients diagnosed with chondrosarcomas, 60 patients with chordomas, and 240 patients with skull base metastases from January 2015 to October 2021 in a single center. Patients with chondrosarcomas and classic chondromas were diagnosed pathologically. Skull base metastases were diagnosed by biopsy or on the basis of the clinical evidence of confirmed primary cancers, other biopsied-confirmed metastatic lesions, and skull base lesions detected on conventional CT/MR imaging and FDG-PET/CT. Cases without pretreatment DWI or DCE-MR imaging (including biopsy, surgery, or radiation therapy) (n = 295) or poor image quality (n = 14) were excluded.

All 30 patients with skull base metastases had confirmed primary cancers. Six of 30 patients underwent a biopsy (3 lung cancers, 2 breast cancers, and 1 renal cell carcinoma), and 24 of 30 patients were clinically diagnosed on the basis of all 24 patients having histories of confirmed primary cancers, biopsy-confirmed metastatic lesions in the other regions, and positive conventional head and neck CT/MR imaging and PET/CT findings in the skull base. For patients diagnosed with skull base metastases, the treatment response of the skull base lesions following chemotherapy or chemotherapy plus radiation therapy was confirmed on follow-up CT or MR imaging. Corresponding treatments such as chemotherapy (n = 18) or chemotherapy plus radiation therapy (n = 12) were used, and a decrease in size was observed on CT or MR imaging.

In total, 59 patients (20 men, 39 women; median age, 61 years; interquartile range [IQR], 45–70 years) with 15 chondrosarcomas, 14 chordomas, and 30 skull base metastases were included in this study. Patient demographics such as age and sex for all tumor types and primary cancers for skull base metastases were reviewed from medical records.

MR Imaging Protocol

Head and neck MR imaging examinations were performed using a 1.5T or 3T system (Ingenia; Philips Healthcare) with patients in the supine position. The acquired sequences were axial plane T1WI, T2WI, FLAIR, and contrast-enhanced fat-saturated T1WI and coronal plane contrast-enhanced fat-saturated T1WI. DWI was performed using echo-planar imaging with the following DWI parameters: TE range, 58–106 ms; TR range, 5000–9500 ms; number of excitations, 1; section thickness and gap, 3.5–4 and 0–1 mm; FOV, 220–240 mm; matrix size, 128 × 128 to 200 × 200; and 3 diffusion directions. Sensitizing diffusion gradients were sequentially applied. B values were 0 and 1000 s/mm².

A DCE-MR imaging sequence was performed using a 3D T1-weighted fast-field echo technique with a 16-channel Neurovascular coil. Twenty milliliters of gadobenate dimeglumine (MultiHance; Bracco Diagnostics) was administered through a peripheral arm vein using a power injector at a flow rate of 5.0 mL/s and followed by a 20-mL saline flush. DCE-MR imaging was sequentially acquired with the following parameters of 3D-T1 fast-field echo: TE, 1.86 ms; TR, 4.6 ms; flip angle, 30°; section thickness, 5.0 mm; FOV, 240 × 240 mm²; voxel size, 1.0 × 1.0 × 5.0 mm³; number of excitations, 1; number of slices per dynamic scan, 48; temporal resolution, 8.4 seconds; dynamic phase, 30 dynamics; total acquisition time, 4 minutes 24 seconds.

Imaging Processing and Analysis

Two board-certified radiologists with 7 and 10 years of experience independently performed DWI and DCE-MR imaging analyses. The same board-certified radiologist with 7 years of experience reviewed conventional MR imaging. The 2 readers were blinded to the histologic results.

Conventional Imaging

The maximum axial diameter was measured using contrast-enhanced axial and coronal fat-saturated T1WI. As conventional MR imaging features, the main skull base location was identified using axial and coronal contrast-enhanced fat-saturated T1WI and recorded as the clivus or petrous bone. In addition, both radiologists evaluated the following imaging characteristics with consensus and recorded them as binary variables:

1. Cystic changes, defined as focal areas with nonenhancing, predominantly T2-hyperintense areas and necrotic changes defined as focal areas with nonenhancing, predominantly T1-hypointense and heterogeneously T2-hyperintense areas.

2. T2 hyperintensity or iso-/hypointensity in the lesion relative to the brain parenchyma, evaluated on T2WI, excluding the areas of cystic/necrotic changes.

3. Enhancement patterns (homogeneous or heterogeneous), evaluated on postcontrast fat-saturated T1-weighted images.

4. Other metastatic lesions in the FOV of the head and neck scan, evaluated on T1WI, T2WI, and postcontrast T1WI.

DWI Analysis

The same 2 board-certified radiologists with 7 and 10 years of experience manually delineated a single freehand ROI on the axial contrast-enhanced fat-saturated T1WI. ADC maps were constructed using commercially available software (Olea Sphere, Version 3.0; Olea Medical). On the ADC maps, the corresponding ROIs were again contoured with reference to the ROIs delineated on axial postcontrast T1WI. The 2 readers adhered to the following procedure:

1. ROIs were encompassed in the areas on axial postcontrast fat-saturated T1WI where the tumors showed solid enhancing components, excluding necrotic or cystic regions. When the lesions extended beyond the clivus into surrounding soft tissues, both the bony and soft structures were included in a ROI.

2. The peripheral 2 mm of the lesions were excluded from an ROI to avoid volume averaging.

3. The ROIs were manually adjusted on the ADC map if geometric artifacts were observed.

4. An ROI was placed within the medulla oblongata as an internal control. The mean ADC values of the tumor were divided by the mean ADC values of the medulla oblongata, and the normalized mean ADC (nADCmean) was calculated.

DCE-MR Imaging Analysis

Quantitative analyses were performed using the Olea Sphere 3.0 software. An arterial input function was automatically computed. While this process was automated, the corresponding time-intensity curves that demonstrated a rapid increase in attenuation with sharp peaks were deemed appropriate and accurate for analysis. The permeability module was based on the extended Tofts model, and pixel-based parameter maps were calculated from time-intensity curves. ROIs were placed by means of the method used for the DWI analysis. Quantitative parameters, Vp, Ve, and K^trans, were calculated.

Statistical Analysis

nADCmean and Ve, K^trans, and Vp were compared among the 3 tumor types using the Kruskal-Wallis H test and the post hoc test with Bonferroni correction and were described as medians (IQR). The conventional MR imaging features were compared between each pair of tumor types by the Fisher exact test. For each pair of tumor type (chondrosarcomas and chordomas, chondrosarcomas and metastases, and chordomas and metastases), the parameters from DWI and DCE-MR imaging analyses were compared using the Mann-Whitney U test with a Bonferroni correction and described as median (IQR). For statistically significant diagnostic parameters, receiver operating characteristic analysis was performed with the optimal cutoff values, which were determined to maximize the Youden index (sensitivity + specificity-1). The intraclass correlation coefficient was used to assess the interobserver agreement for DWI and DCE-MR imaging parameters. All statistical calculations were conducted using R statistical and computing software (http://www.r-project.org/). Variables with P values < .05 were considered statistically significant.