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Research ArticleADULT BRAIN
Open Access

Diagnostic Accuracy of T1-Weighted Dynamic Contrast-Enhanced–MRI and DWI-ADC for Differentiation of Glioblastoma and Primary CNS Lymphoma

X. Lin, M. Lee, O. Buck, K.M. Woo, Z. Zhang, V. Hatzoglou, A. Omuro, J. Arevalo-Perez, A.A. Thomas, J. Huse, K. Peck, A.I. Holodny and R.J. Young
American Journal of Neuroradiology March 2017, 38 (3) 485-491; DOI: https://doi.org/10.3174/ajnr.A5023

Abstract

BACKGROUND AND PURPOSE: Glioblastoma and primary CNS lymphoma dictate different neurosurgical strategies; it is critical to distinguish them preoperatively. However, current imaging modalities do not effectively differentiate them. We aimed to examine the use of DWI and T1-weighted dynamic contrast-enhanced–MR imaging as potential discriminative tools.

MATERIALS AND METHODS: We retrospectively reviewed 18 patients with primary CNS lymphoma and 36 matched patients with glioblastoma with pretreatment DWI and dynamic contrast-enhanced–MR imaging. VOIs were drawn around the tumor on contrast-enhanced T1WI and FLAIR images; these images were transferred onto coregistered ADC maps to obtain the ADC and onto dynamic contrast-enhanced perfusion maps to obtain the plasma volume and permeability transfer constant. Histogram analysis was performed to determine the mean and relative ADCmean and relative 90th percentile values for plasma volume and the permeability transfer constant. Nonparametric tests were used to assess differences, and receiver operating characteristic analysis was performed for optimal threshold calculations.

RESULTS: The enhancing component of primary CNS lymphoma was found to have significantly lower ADCmean (1.1 × 10−3 versus 1.4 × 10−3; P < .001) and relative ADCmean (1.5 versus 1.9; P < .001) and relative 90th percentile values for plasma volume (3.7 versus 5.0; P < .05) than the enhancing component of glioblastoma, but not significantly different relative 90th percentile values for the permeability transfer constant (5.4 versus 4.4; P = .83). The nonenhancing portions of glioblastoma and primary CNS lymphoma did not differ in these parameters. On the basis of receiver operating characteristic analysis, mean ADC provided the best threshold (area under the curve = 0.83) to distinguish primary CNS lymphoma from glioblastoma, which was not improved with normalized ADC or the addition of perfusion parameters.

CONCLUSIONS: ADC was superior to dynamic contrast-enhanced–MR imaging perfusion, alone or in combination, in differentiating primary CNS lymphoma from glioblastoma.

ABBREVIATIONS:

AUC
area under the curve
DCE
dynamic contrast-enhanced
-5%tile
5th percentile
GBM
glioblastoma
Ktrans
permeability transfer constant
MGMT
O(6)-methylguanin-DNA-methyltransferase
-90%tile
90th percentile
PCNSL
primary CNS lymphoma
r-
relative or normalized
Ve
extravascular extracellular volume
Vp
blood plasma volume

The standard of care for glioblastoma (GBM) dictates maximum safe resection.1 In contrast, efforts at resection in primary CNS lymphoma (PCNSL) are discouraged due to lack of survival benefits and an increase in postoperative deficits.2,3 Given the distinct prognostic implications and the differing surgical planning and treatment options for PCNSL and GBM, their preoperative differentiation is important in patients presenting with an enhancing brain tumor. MR imaging features of PCNSL and GBM are highly variable and overlapping,4,5 rendering the differentiation difficult when based solely on conventional MR imaging.

Several studies have suggested the usefulness of diffusion-weighted imaging–derived ADC maps in differentiating PCNSL from GBM.6,7 Due to its higher cellularity compared with GBM, PCNSL has been shown to exhibit lower ADC values.6,7 The use of dynamic MR imaging perfusion techniques has also been of growing interest. In pathologic studies, PCNSL and GBM exhibited varying degrees of increased vascular permeability and perfusion.8,9 T2*-weighted DSC studies have suggested the discriminative value of cerebral blood volume; however, the results have been inconsistent.1012 More recent studies have suggested the effectiveness of T1-weighted dynamic contrast-enhanced (DCE) perfusion in differentiating PCNSL from GBM.13,14 DCE-MR imaging measures fractional blood plasma volume per unit volume of tissue (Vp) and time-dependent leakage (permeability transfer constant [Ktrans]), which reflect tissue perfusion and leakiness, respectively.15,16 Compared with DSC, DCE perfusion has the advantages of higher spatial resolution, better quantification of microvascular leakiness and perfusion, and increased resistance to susceptibility artifacts.16,17

In this study, we aimed to examine the use of DCE-MR imaging and DWI-ADC as potential discriminative tools and to define cutoff (threshold) values for DWI-ADC and DCE perfusion parameters that would be sensitive and specific for PCNSL. We hypothesized that PCNSL would have greater diffusion restriction, while GBM would have greater leakiness and perfusion.

Materials and Methods

Patient Selection

This study is an institutional review board–approved retrospective single-institution study performed under a waiver of informed consent. All Health Insurance Portability and Accountability Act regulations were followed. We queried institutional and departmental data bases for all patients with histologically confirmed newly diagnosed PCNSL between January 2011 and December 2014 who had pretreated DWI- and DCE-MR imaging scans available for analysis. As part of our hospital routine practice, all histology was verified by 1 of 2 neuropathologists, both of whom had >8 years of experience in neuropathology. We excluded patients under the following conditions: 1) systemic lymphoma, 2) nonparenchymal PCNSL, 3) having undergone chemotherapy before PCNSL diagnosis, and 4) a known history of testing positive for human immunodeficiency virus. A GBM cohort, matched for age and sex, was selected from an institutional data base of newly diagnosed patients with GBM who had histologic confirmation and preoperative DWI and DCE-MR imaging.

Patient charts were reviewed for demographic characteristics, functional status at initial tumor diagnosis, and clinical outcome data. For patients with PCNSL, we collected serum lactate dehydrogenase results obtained within 1 month of tumor diagnosis; for patients with GBM, we collected the available tumor molecular profile, including O(6)-methylguanin-DNA-methyltransferase (MGMT) methylation, isocitrate dehydrogenase (IDH) mutation, and epidermal growth factor receptor (EGFR) mutation status.

MR Imaging

MR imaging sequences were acquired with a 1.5 or 3T MR imaging scanner (Signa Excite, HDx, and Discovery 750; GE Healthcare, Milwaukee, Wisconsin) and a standard 8-channel head coil. Gadopentetate dimeglumine (Magnevist; Bayer HealthCare Pharmaceuticals, Wayne, New Jersey) was injected via a venous catheter (18–21 ga) at doses based on patient body weight (0.2 mL/kg body weight; maximum, 20 mL) at 2–3 mL/s. DWI was acquired in the transverse plane by using a spin-echo, echo-planar imaging sequence with the following parameters: TR/TE = 8000/ 104.2 ms; diffusion gradient encoding in 3 orthogonal directions; b=1000 s/mm2; FOV = 240 mm; matrix size = 128 × 128 pixels; section thickness = 5 mm; section gap = 1 mm; and number of average = 2. ADC values were calculated with the following parameters: ADC = [ln(S / S0)] / b, where S is the signal intensity of the ROI obtained through 3 orthogonally oriented DWIs or diffusion trace images, S0 is the signal intensity of the ROI acquired through reference T2-weighted images, and b is the gradient b factor with a value of 1000 s/mm2. ADC maps were calculated on a pixel-by-pixel basis.

DCE-MR imaging of the brain was acquired after DWI scans as part of a standard clinical protocol with an axial 3D T1WI echo-spoiled gradient echo sequence (TR = 4–5 ms; TE = 1–2 ms; section thickness = 5 mm; flip angle = 25°; FOV = 24 cm; matrix = 256 × 128; temporal resolution = 5–6 seconds; number of sections = 10–15; and total time = 3.3–4 minutes). Ten phases were acquired preinjection followed by a 30-phase dynamic injection imaging and a 40-mL saline flush. Matching contrast-enhanced T1-weighted (TR/TE = 600/8 ms; thickness = 5 mm) images were also obtained, along with standard sequences including T2-weighted images, FLAIR images, and susceptibility-weighted images. T1 mapping provides a method to calculate the T1 value of each voxel during the noncontrast phase and has been shown not to significantly alter DCE quantification.18,19 Hence, we do not perform T1 mapping for DCE correction at our institution, and it was not available for image processing in this study.

Image Postprocessing and Analysis

ADC maps, DCE-MR imaging perfusion raw data, contrast-enhanced T1WI, and FLAIR images were transferred to an off-line workstation.

Postprocessing

DCE-MR imaging perfusion data were processed with FDA-approved commercial software (nordicICE; NordicNeuroLab, Bergen, Norway). The signal-to-noise ratio and arterial input function were optimized individually for each patient. For the arterial input function, an appropriate artery was semiautomatically selected to characterize the input function curve and concentration-time curve.20 The linear assumption between change in signal intensity and gadolinium concentration was made to convert the signal intensity curve to a concentration-time curve. Curves showing an optimal relationship between arterial input function and the concentration-time curve were selected. We used the perfusion analysis method based on the 2-compartment pharmacokinetic model proposed by Tofts et al20 to calculate pharmacokinetic parameters, including Vp and Ktrans and to display the results as parametric maps.

Image Analysis

Two experienced operators (1 radiology fellow with 3 years and 1 medical student with 1 year of experience) manually outlined a VOI around the enhancing lesion on contrast-enhanced T1WI and the peritumoral nonenhancing lesion on FLAIR images; the 2 operated independently. The VOI was constructed by summing ROIs drawn around the lesion on all axial sections by the 2 operators, and the final VOI was approved by a board-certified neuroradiologist with 10 years of experience in MR imaging and functional imaging. VOIs were transferred to the ADC, Vp, and Ktrans parametric maps, and the corresponding measurements were recorded for the all enhancing and nonenhancing lesions. Minimum values of zero pixels were removed. To reduce variability related to scanner heterogeneity, contrast, and patient physiology (eg, cardiac output), we normalized all parameters to normal brain by placing ROIs (standardized area of 40–60 mm2) in the normal-appearing white matter of the contralateral hemisphere at the midlevel of the tumor.2123 The ROI was placed on the contrast-enhanced T1-weighted images and then transferred to the VP and Ktrans maps and adjusted, if necessary, to avoid potential outlier areas that may harbor subtle microvascular leakage. The ADC, Vp, and Ktrans measurements were binned, and histogram analysis was performed to determine the mean and 90th percentile normalized values for Vp (rVpmean; rVp90%tile) and Ktrans, and the mean and fifth percentile normalized values for ADC (rADCmean, rADC5%tile). The 90th percentile for Vp and Ktrans characterizes the portion of the tumor with the highest perfusion, while the fifth percentile for ADC determines the portion of the tumor with the greatest degree of restricted diffusion. To facilitate comparisons with prior studies, we also recorded absolute (non-normalized) ADCmean and ADC5%tile values.

Statistical Analysis

Wilcoxon rank sum tests were conducted to assess differences between GBM and PCNSL groups for normalized ADC, Ktrans, and Vp parameters. Measurements from enhancing and nonenhancing lesions were analyzed separately. The significance of P values was adjusted by using the false discovery rate approach. Receiver operating characteristic analysis was performed for the parameters with statistically significant differences, and the area under the curve (AUC) was computed.24 Optimal thresholds were estimated with consideration for sensitivity and specificity. Overall survival was estimated by using the Kaplan-Meier method, starting from the date of tumor diagnosis until death. Patients who did not die during the study period were censored at the date of last available follow-up. Statistical analysis was performed by using R statistical and computing software (http://www.r-project.org/), including the “ROCR” and “survival” packages. We retrospectively reviewed all patients with pretreated primary CNS lymphoma who underwent evaluation with DCE-MR imaging at our center and selected a GBM cohort matched for age and sex; hence, a sample size calculation was not performed for this study.

Results

Patient Population

We identified 18 patients with PCNSL (11 men; mean age, 68.7 years) and 36 matched patients with GBM (22 men; mean age, 68.6 years) who met all the inclusion criteria. The patient-selection process and clinical data are summarized in On-line Fig 1 and Table 1, respectively.

View this table:
Table 1:

Patient clinical data

In the PCNSL and GBM cohorts, the median Karnofsky performance status at tumor diagnosis was 70 and 90, respectively. At last follow-up, all except 1 (94.4%) patient with PCNSL were alive, with a median follow-up of 22.1 months. One patient died 21.3 months after diagnosis, and the 12-month overall survival in the PCNSL cohort was 100%. The 12-month overall survival in the GBM cohort was 48.5% (95% CI, 29.6%–64.9%).

In the PCNSL cohort, the mean serum lactate dehydrogenase was 203.1 U/L (range, 117.0–334.0 U/L). Among GBM samples with available MGMT methylation (n = 29), IDH mutation (n = 31), and EGFR mutation (n = 30) status, 10 (34.5%) were MGMT methylated, 1 (3.2%) was IDH mutated, and 22 (73.3%) were EGFR mutant.

Imaging Findings

The imaging results are summarized in Table 2 and Fig 1, and representative PCNSL and GBM cases are shown in Figs 2 and 3.

View this table:
Table 2:

Imaging results

Fig 1.
Fig 1.

Area under the curve for apparent diffusion coefficient and blood plasma volume. Area under the curve for ADCmean, rADCmean, and rVp90%tile demonstrating the highest AUC value for ADCmean. There are no statistically significantly differences among the 3 AUCs.

Fig 2.
Fig 2.

Glioblastoma. Axial FLAIR (A), contrast-enhanced T1-weighted (B), diffusion-weighted (C), ADC (D), permeability transfer constant (E), and plasma volume (F) images reveal a heterogeneously enhancing tumor in the right frontal lobe with peripheral diffusion restriction (low on ADC, D), increased leakiness (E), and increased perfusion (F). These findings suggest areas of cellular tumor with marked neovascularity and areas of necrosis. Micrographs (G and H) show high glial neoplasm with necrosis (G, arrows), microvascular proliferations (H, arrows), and mitotic activity (H, arrowhead), consistent with a diagnosis of glioblastoma. Magnification ×20 (G) and ×40 (H).

Fig 3.
Fig 3.

Primary CNS lymphoma. Axial FLAIR (A), contrast-enhanced T1-weighted (B), diffusion-weighted (C), ADC (D), permeability transfer constant (E), and plasma volume (F) images show an enhancing tumor in the right frontal lobe with diffusion restriction (D), increased leakiness (high on Ktrans, E), and only slightly increased perfusion (slightly high on Vp, F). These findings indicate cellular tumor without marked neovascularity, typical for primary CNS lymphoma. Micrographs (G and H) show high-grade lymphoid proliferation with obvious mitotic activity in the cytology preparation (H, arrowheads). Magnification ×40 (G and H).

ADC

For the enhancing lesions, the median rADCmean was lower for PCNSL than for GBM (PCNSL versus GBM, 1.5 versus 1.9; P < .001). On the basis of receiver operating characteristic analysis, a rADCmean threshold of <1.7 indicated PCNSL with a specificity of 78% and sensitivity of 75%. For the nonenhancing lesions, the rADCmean was not significantly different (P = .21). When tested without normalization to a ratio, the median ADCmean of the enhancing lesions was also lower in PCNSL than in GBM (1.1 × 10−3 mm2/s versus 1.4 × 10−3 mm2/s; P < .001); an ADCmean threshold of <1.3 × 10−3 mm2/s indicated PCNSL with a specificity of 89% and sensitivity of 69%. There was no significant difference in the AUCs for ADCmean and rADCmean (P = .88).

DCE-MR Imaging

For the enhancing lesions, the median rVp90%tile was lower for PCNSL than for GBM (3.7 versus 5.0; P = .006), while the median Ktrans90%tile was not significantly different (P = .83) between the two. For the nonenhancing lesions, neither rVp90%tile nor the rKtrans90%tile was significantly different (P ≥ .16). If one optimized specificity and sensitivity, a rVp90%tile threshold of <4.6 indicated PCNSL with a specificity of 72% and sensitivity of 58%. The AUC for rVp90%tile was not significantly different from that for ADCmean (P = .87) or rADCmean (P = .66).

Combining ADC and DCE-MR Imaging

If one combined ADCmean and rVp90%tile at the enhancing lesion, a binary threshold of ADCmean < 1.3 × 10−3 mm2/s and rVp90%tile < 4.6 predicted PCNSL with a specificity of 61% and a sensitivity of 83%. Conversely, a binary threshold of ADCmean ≥ 1.3 × 10−3 mm2/s and rVp90%tile ≥ 4.6 predicted GBM with a specificity of 94% and sensitivity of 47%.

Discussion

We retrospectively examined the use of ADC and DCE in differentiating pretreated PCNSL from GBM. We found that ADCmean, rADCmean, and rVp90%tile, but not rKtrans in the enhancing regions, distinguished PCNSL and GBM (Table 2). An ADCmean threshold of 1.3 × 10−3 mm2/s discriminated PCNSL and GBM with the best specificity and sensitivity; a binary threshold that combined ADCmean and rVp90%tile values was helpful for predicting GBM but less so for PCNSL.

Our study findings are consistent with previous studies demonstrating significantly lower ADC in PCNSL than in GBM.6,7,25,26 In a subset of these studies, DWI results were correlated with histologic information and showed a clear inverse relationship between ADC and tumor cellularity,6,7,26 suggesting that untreated PCNSL has higher tumor density than untreated GBM. In contrast to these studies, we also studied relative normalized ADC values but did not find any improved discriminative performance with rADCmean over absolute ADCmean. We therefore advocate the use of ADCmean, which is a simpler and more direct measurement than rADCmean, to distinguish PCNSL and GBM.

Our study also examined the use of the DCE-MR imaging technique and showed that rVp was able to distinguish PCNSL from GBM. Vp was not part of the original Tofts model and was introduced later in the modified Tofts model to account for intravascular tracer.15 In gliomas, Vp has been shown to differentiate tumor grade.27 However, Vp has not be shown to be useful in differentiating PCNSL from GBM.14 Our study, to the best of our knowledge, is the first to demonstrate the discriminating value of rVp90%tile; this positive finding may be related to our choice of a normalized parameter to reduce interscanner, interrater, and interpatient variability.

Ktrans is the other commonly measured DCE-MR imaging parameter. It measures the degree of increase in T1 due to contrast accumulation in tissue and can be affected by multiple factors such as blood flow and capillary wall surface area. In general, it is used to represent leakiness due to capillary permeability and blood-brain barrier disruption.16 A study by Kickingereder et al13 showed that PCNSL had significantly higher Ktrans than GBM and further correlated these radiologic findings with histologic demonstration of destroyed vessel architecture in the 11 PCNSLs and intact vascular integrity in the 60 GBMs. With CT perfusion imaging, Ktrans was also shown to be significantly higher in PCNSL than in GBM in one study28 but not in a subsequent study29; this latter negative study was attributed to the use of the Patlak model, which fails to account for backflow of contrast agent from the extravascular extracellular space to the blood plasma, compromising Ktrans measurement. Our study also showed a trend for higher Ktrans in PCNSL than in GBM, but the difference was not statistically significant.

Our results indicated that rVp is not superior to ADC for identifying PCNSL, and a combined model including rVp90%tile and ADCmean is not superior to either technique alone. Perfusion MR imaging has been suggested as a valuable part of the imaging strategy for the differential diagnosis of undiagnosed brain masses.30,31 In addition, perfusion MR imaging has demonstrated additional value in gliomas with correlations to glioma grade, EGFR gene amplification and vIII status, MGMT methylation status, time-to-progression, and overall survival.21,3237 Therefore, while not superior for differential diagnosis purposes, DCE-MR imaging may be helpful to support the presumptive diagnosis of PCNSL when marked hyperperfusion is absent, and it can be considered to provide important prognostic data about tumor vascularity and leakiness independent of data about tumor cellularity.

Unlike previous studies that examined imaging parameters solely at contrast-enhancing regions, we evaluated imaging parameters at both enhancing and nonenhancing regions but failed to show any added discriminative value. This outcome suggests that increases in tumor cellularity, microvascular permeability, and vascular proliferation are less marked in nonenhancing areas of different brain tumors compared with contrast-enhancing regions. Although nonenhancing regions in glioblastomas are known to include a combination of tumor and peritumoral edema,38 quantification of tumor-related imaging characteristics is dependent on the relative abundance of tumor cells and may be diluted by the amount of edema.26

Our study has several potential limitations. First, we did not examine all DCE-MR imaging parameters, including extravascular extracellular volume (Ve), which was shown in 1 study to differentiate PCNSL from other brain tumors.14 This study by Abe et al14 used a DCE-MR imaging sequence with a shorter-than-standard acquisition time, however, which potentially overestimates Ktrans and underestimates Vp and Ve,39 thereby limiting the generalizability of the results. In addition, the physiologic meaning of Ve remains elusive, with conflicting studies demonstrating its correlation with tumor cellularity.7,26,40 The use of Ve is further refuted by an earlier study that failed to show a significant difference in Ve between PCNSL and GBM.13 We did not evaluate Ve in our study and, instead, chose ADC as a more reliable and widely applied marker of tumor cellularity.7,26 Second, we did not evaluate the performance of other conventional MR imaging parameters such as the presence of necrosis and rim enhancement. Previous studies have shown that PCNSL has variable degrees of T1 and T2 intensities, extent of necrosis, and pattern of contrast enhancement—suggesting that these features are unreliable in distinguishing lymphoma from other CNS lesions.41,42 Consequently, in 1 prior study, the use of rim enhancement and central necrosis resulted in misclassification of 3 (17.6%) of 17 PCNSLs and malignant gliomas.30 Given the statistical limitations of our relatively small sample size of patients with PCNSL who underwent DCE-MR imaging, we chose to focus our study on examining ADC, rather than all the other conventional MR imaging parameters. Our small sample size also limited our ability to use cross-validation to assess the operating characteristics and validate the sensitivities and specificities of the cutoff values determined in our study. Third, we did not account for the presence of microbleed, which may confound ADC and DCE-MR imaging results. However, the additional step of eliminating microbleed by using an additional SWI sequence may pose impractical constraints and limit the applicability of our study. Fourth, due to the lack of the routine use of MR spectroscopy in this retrospective study, we were unable to evaluate the utility of MR spectroscopy, which has been shown to distinguish PCNSL from GBM in 1 study with a specificity exceeding 90%.43 The added value of MR spectroscopy in discriminating the diagnoses should be incorporated in future prospective studies. Fifth, the manual drawing and transfer of VOIs to parametric maps could have introduced variability. We sought to reduce the variability by having all VOIs drawn by operators who had at least 1 year of experience and reviewed by an experienced board-certified neuroradiologist and by exploiting the histogram function to interrogate only the most abnormal parts of the tumor.

Conclusions

Pretreatment differentiation of PCNSL and GBM is challenging. Our study suggests that DCE-MR imaging is helpful in identifying PCNSL, though rVp did not outperform ADC and a combined model did not outperform either metric alone. Further prospective studies are needed to confirm these findings.

Acknowledgments

We thank Ms Joanne Chin for her editorial work in the preparation of this manuscript.

Footnotes

  • X. Lin and M. Lee contributed equally to the article as co-first authors.

  • Disclosures: Robert J. Young—UNRELATED: Consultancy: Agios Glioma Advisory Board, Comments: honorarium; Grants/Grants Pending: Dana Foundation.* *Money paid to the institution.

  • This work was supported in part by National Institutes of Health/National Cancer Center Support Grant P30 CA008748. M. Lee's research was funded, in part, through the National Institutes of Health Memorial Sloan Kettering Cancer Center Medical Student Summer Fellowship program.

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References

  1. 1.
    2. Marko NF,
    3. Weil RJ,
    4. Schroeder JL, et al
    . Extent of resection of glioblastoma revisited: personalized survival modeling facilitates more accurate survival prediction and supports a maximum-safe-resection approach to surgery. J Clin Oncol 2014;32:77482 doi:10.1200/JCO.2013.51.8886 pmid:24516010
    Abstract/FREE Full Text
  2. 2.
    2. Bataille B,
    3. Delwail V,
    4. Menet E, et al
    . Primary intracerebral malignant lymphoma: report of 248 cases. J Neurosurg 2000;92:26166 doi:10.3171/jns.2000.92.2.0261 pmid:10659013
    CrossRefPubMed
  3. 3.
    2. DeAngelis LM,
    3. Yahalom J,
    4. Heinemann MH, et al
    . Primary CNS lymphoma: combined treatment with chemotherapy and radiotherapy. Neurology 1990;40:8086 doi:10.1212/WNL.40.1.80 pmid:2296388
    Abstract/FREE Full Text
  4. 4.
    2. Koeller KK,
    3. Smirniotopoulos JG,
    4. Jones RV
    . Primary central nervous system lymphoma: radiologic-pathologic correlation. Radiographics 1997;17:1497526 doi:10.1148/radiographics.17.6.9397461 pmid:9397461
    CrossRefPubMed
  5. 5.
    2. Rees JH,
    3. Smirniotopoulos JG,
    4. Jones RV, et al
    . Glioblastoma multiforme: radiologic-pathologic correlation. Radiographics 1996;16:141338; quiz 62–63 pmid:8946545
    CrossRefPubMed
  6. 6.
    2. Doskaliyev A,
    3. Yamasaki F,
    4. Ohtaki M, et al
    . Lymphomas and glioblastomas: differences in the apparent diffusion coefficient evaluated with high b-value diffusion-weighted magnetic resonance imaging at 3T. Eur J Radiol 2012;81:33944 doi:10.1016/j.ejrad.2010.11.005 pmid:21129872
    CrossRefPubMed
  7. 7.
    2. Guo AC,
    3. Cummings TJ,
    4. Dash RC, et al
    . Lymphomas and high-grade astrocytomas: comparison of water diffusibility and histologic characteristics. Radiology 2002;224:17783 doi:10.1148/radiol.2241010637 pmid:12091680
    CrossRefPubMed
  8. 8.
    2. Molnár PP,
    3. O'Neill BP,
    4. Scheithauer BW, et al
    . The blood-brain barrier in primary CNS lymphomas: ultrastructural evidence of endothelial cell death. Neuro Oncol 1999;1:89100 doi:10.1093/neuonc/1.2.89 pmid:11550310
    Abstract/FREE Full Text
  9. 9.
    2. Jain RK,
    3. di Tomaso E,
    4. Duda DG, et al
    . Angiogenesis in brain tumours. Nat Rev Neurosci 2007;8:61022 doi:10.1038/nrn2175 pmid:17643088
    CrossRefPubMed
  10. 10.
    2. Xing Z,
    3. You RX,
    4. Li J, et al
    . Differentiation of primary central nervous system lymphomas from high-grade gliomas by rCBV and percentage of signal intensity recovery derived from dynamic susceptibility-weighted contrast-enhanced perfusion MR imaging. Clin Neuroradiol 2014;24:32936 doi:10.1007/s00062-013-0255-5 pmid:23994941
    CrossRefPubMed
  11. 11.
    2. Toh CH,
    3. Wei KC,
    4. Chang CN, et al
    . Differentiation of primary central nervous system lymphomas and glioblastomas: comparisons of diagnostic performance of dynamic susceptibility contrast-enhanced perfusion MR imaging without and with contrast-leakage correction. AJNR Am J Neuroradiol 2013;34:114549 doi:10.3174/ajnr.A3383 pmid:23348763
    Abstract/FREE Full Text
  12. 12.
    2. Kickingereder P,
    3. Wiestler B,
    4. Sahm F, et al
    . Primary central nervous system lymphoma and atypical glioblastoma: multiparametric differentiation by using diffusion-, perfusion-, and susceptibility-weighted MR imaging. Radiology 2014;272:84350 doi:10.1148/radiol.14132740 pmid:24814181
    CrossRefPubMed
  13. 13.
    2. Kickingereder P,
    3. Sahm F,
    4. Wiestler B, et al
    . Evaluation of microvascular permeability with dynamic contrast-enhanced MRI for the differentiation of primary CNS lymphoma and glioblastoma: radiologic-pathologic correlation. AJNR Am J Neuroradiol 2014;35:150308 doi:10.3174/ajnr.A3915 pmid:24722313
    Abstract/FREE Full Text
  14. 14.
    2. Abe T,
    3. Mizobuchi Y,
    4. Nakajima K, et al
    . Diagnosis of brain tumors using dynamic contrast-enhanced perfusion imaging with a short acquisition time. Springerplus 2015;4:88 doi:10.1186/s40064-015-0861-6 pmid:25793147
    CrossRefPubMed
  15. 15.
    2. Bergamino M,
    3. Bonzano L,
    4. Levrero F, et al
    . A review of technical aspects of T1-weighted dynamic contrast-enhanced magnetic resonance imaging (DCE-MRI) in human brain tumors. Phys Med 2014;30:63543 doi:10.1016/j.ejmp.2014.04.005 pmid:24793824
    CrossRefPubMed
  16. 16.
    2. Cha S
    . Update on brain tumor imaging: from anatomy to physiology. AJNR Am J Neuroradiol 2006;27:47587 pmid:16551981
    FREE Full Text
  17. 17.
    2. Essig M,
    3. Shiroishi MS,
    4. Nguyen TB, et al
    . Perfusion MRI: the five most frequently asked technical questions. AJR Am J Roentgenol 2013;200:2434 doi:10.2214/AJR.12.9543 pmid:23255738
    CrossRefPubMed
  18. 18.
    2. Haacke EM,
    3. Filleti CL,
    4. Gattu R, et al
    . New algorithm for quantifying vascular changes in dynamic contrast-enhanced MRI independent of absolute T1 values. Magn Reson Med 2007;58:46372 doi:10.1002/mrm.21358 pmid:17763352
    CrossRefPubMed
  19. 19.
    2. Jung SC,
    3. Yeom JA,
    4. Kim JH, et al
    . Glioma: application of histogram analysis of pharmacokinetic parameters from T1-weighted dynamic contrast-enhanced MR imaging to tumor grading. AJNR Am J Neuroradiol 2014;35:110310 doi:10.3174/ajnr.A3825 pmid:24384119
    Abstract/FREE Full Text
  20. 20.
    2. Tofts PS,
    3. Brix G,
    4. Buckley DL, 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;10:22332 pmid:10508281
    CrossRefPubMed
  21. 21.
    2. Arevalo-Perez J,
    3. Thomas AA,
    4. Kaley T, et al
    . T1-weighted dynamic contrast-enhanced MRI as a noninvasive biomarker of epidermal growth factor receptor vIII status. AJNR Am J Neuroradiol 2015;36:225661 doi:10.3174/ajnr.A4484 pmid:26338913
    Abstract/FREE Full Text
  22. 22.
    2. Thomas AA,
    3. Arevalo-Perez J,
    4. Kaley T, et al
    . Dynamic contrast enhanced T1 MRI perfusion differentiates pseudoprogression from recurrent glioblastoma. J Neurooncol 2015;125:18390 doi:10.1007/s11060-015-1893-z pmid:26275367
    CrossRefPubMed
  23. 23.
    2. Zhang M,
    3. Gulotta B,
    4. Thomas A, et al
    . Large-volume low apparent diffusion coefficient lesions predict poor survival in bevacizumab-treated glioblastoma patients. Neuro Oncol 2016;18:73543 doi:10.1093/neuonc/nov268 pmid:26538618
    Abstract/FREE Full Text
  24. 24.
    2. DeLong ER,
    3. DeLong DM,
    4. Clarke-Pearson DL
    . Comparing the areas under two or more correlated receiver operating characteristic curves: a nonparametric approach. Biometrics 1988;44:83745 doi:10.2307/2531595 pmid:3203132
    CrossRefPubMed
  25. 25.
    2. Yamashita K,
    3. Yoshiura T,
    4. Hiwatashi A, et al
    . Differentiating primary CNS lymphoma from glioblastoma multiforme: assessment using arterial spin labeling, diffusion-weighted imaging, and 18F-fluorodeoxyglucose positron emission tomography. Neuroradiology 2013;55:13543 doi:10.1007/s00234-012-1089-6 pmid:22961074
    CrossRefPubMed
  26. 26.
    2. Kono K,
    3. Inoue Y,
    4. Nakayama K, et al
    . The role of diffusion-weighted imaging in patients with brain tumors. AJNR Am J Neuroradiol 2001;22:108188 pmid:11415902
    Abstract/FREE Full Text
  27. 27.
    2. Lüdemann L,
    3. Grieger W,
    4. Wurm R, et al
    . Quantitative measurement of leakage volume and permeability in gliomas, meningiomas and brain metastases with dynamic contrast-enhanced MRI. Magn Reson Imaging 2005;23:83341 doi:10.1016/j.mri.2005.06.007 pmid:16275421
    CrossRefPubMed
  28. 28.
    2. Warnke PC,
    3. Timmer J,
    4. Ostertag CB, et al
    . Capillary physiology and drug delivery in central nervous system lymphomas. Ann Neurol 2005;57:13639 doi:10.1002/ana.20335 pmid:15622544
    CrossRefPubMed
  29. 29.
    2. Schramm P,
    3. Xyda A,
    4. Klotz E, et al
    . Dynamic CT perfusion imaging of intra-axial brain tumours: differentiation of high-grade gliomas from primary CNS lymphomas. Eur Radiol 2010;20:248290 doi:10.1007/s00330-010-1817-4 pmid:20495977
    CrossRefPubMed
  30. 30.
    2. Al-Okaili RN,
    3. Krejza J,
    4. Woo JH, et al
    . Intraaxial brain masses: MR imaging-based diagnostic strategy—initial experience. Radiology 2007;243:53950 doi:10.1148/radiol.2432060493 pmid:17456876
    CrossRefPubMed
  31. 31.
    2. Omuro AM,
    3. Leite CC,
    4. Mokhtari K, et al
    . Pitfalls in the diagnosis of brain tumours. Lancet Neurol 2006;5:93748 doi:10.1016/S1474-4422(06)70597-X pmid:17052661
    CrossRefPubMed
  32. 32.
    2. Arevalo-Perez J,
    3. Peck KK,
    4. Young RJ, et al
    . Dynamic contrast-enhanced perfusion MRI and diffusion-weighted imaging in grading of gliomas. J Neuroimaging 2015;25:79298 doi:10.1111/jon.12239 pmid:25867683
    CrossRefPubMed
  33. 33.
    2. Gupta A,
    3. Young RJ,
    4. Shah AD, et al
    . Pretreatment dynamic susceptibility contrast MRI perfusion in glioblastoma: prediction of EGFR gene amplification. Clin Neuroradiol 2015;25:14350 doi:10.1007/s00062-014-0289-3 pmid:24474262
    CrossRefPubMed
  34. 34.
    2. Jain KK,
    3. Sahoo P,
    4. Tyagi R, et al
    . Prospective glioma grading using single-dose dynamic contrast-enhanced perfusion MRI. Clinical Radiol 2015;70:112835 doi:10.1016/j.crad.2015.06.076 pmid:26152879
    CrossRefPubMed
  35. 35.
    2. Ahn SS,
    3. Shin NY,
    4. Chang JH, et al
    . Prediction of methylguanine methyltransferase promoter methylation in glioblastoma using dynamic contrast-enhanced magnetic resonance and diffusion tensor imaging. J Neurosurg 2014;121:36773 doi:10.3171/2014.5.JNS132279 pmid:24949678
    CrossRefPubMed
  36. 36.
    2. Choi HS,
    3. Kim AH,
    4. Ahn SS, et al
    . Glioma grading capability: comparisons among parameters from dynamic contrast-enhanced MRI and ADC value on DWI. Korean J Radiol 2013;14:48792 doi:10.3348/kjr.2013.14.3.487 pmid:23690718
    CrossRefPubMed
  37. 37.
    2. Law M,
    3. Young RJ,
    4. Babb JS, et al
    . Gliomas: predicting time to progression or survival with cerebral blood volume measurements at dynamic susceptibility-weighted contrast-enhanced perfusion MR imaging. Radiology 2008;247:49098 doi:10.1148/radiol.2472070898 pmid:18349315
    CrossRefPubMed
  38. 38.
    2. Wen PY,
    3. Macdonald DR,
    4. Reardon DA, et al
    . Updated response assessment criteria for high-grade gliomas: Response Assessment in Neuro-Oncology working group. J Clin Oncol 2010;28:196372 doi:10.1200/JCO.2009.26.3541 pmid:20231676
    Abstract/FREE Full Text
  39. 39.
    2. Larsson C,
    3. Kleppesto M,
    4. Rasmussen I Jr., et al
    . Sampling requirements in DCE-MRI based analysis of high grade gliomas: simulations and clinical results. J Magn Reson Imaging 2013;37:81829 doi:10.1002/jmri.23866 pmid:23086710
    CrossRefPubMed
  40. 40.
    2. Mills SJ,
    3. Soh C,
    4. Rose CJ, et al
    . Candidate biomarkers of extravascular extracellular space: a direct comparison of apparent diffusion coefficient and dynamic contrast-enhanced MR imaging–derived measurement of the volume of the extravascular extracellular space in glioblastoma multiforme. AJNR Am J Neuroradiol 2010;31:54953 doi:10.3174/ajnr.A1844 pmid:19850765
    Abstract/FREE Full Text
  41. 41.
    2. Johnson BA,
    3. Fram EK,
    4. Johnson PC, et al
    . The variable MR appearance of primary lymphoma of the central nervous system: comparison with histopathologic features. AJNR Am J Neuroradiol 1997;18:56372 pmid:9090424
    Abstract
  42. 42.
    2. Slone HW,
    3. Blake JJ,
    4. Shah R, et al
    . CT and MRI findings of intracranial lymphoma. AJR Am J Roentgenol 2005;184:167985 doi:10.2214/ajr.184.5.01841679 pmid:15855138
    CrossRefPubMed
  43. 43.
    2. Aburano H,
    3. Ueda F,
    4. Yoshie Y, et al
    . Differences between glioblastomas and primary central nervous system lymphomas in 1H-magnetic resonance spectroscopy. Jpn J Radiol 2015;33:392403 doi:10.1007/s11604-015-0430-5 pmid:25966997
    CrossRefPubMed
  • Received July 22, 2016.
  • Accepted after revision October 7, 2016.
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Diagnostic Accuracy of T1-Weighted Dynamic Contrast-Enhanced–MRI and DWI-ADC for Differentiation of Glioblastoma and Primary CNS Lymphoma
X. Lin, M. Lee, O. Buck, K.M. Woo, Z. Zhang, V. Hatzoglou, A. Omuro, J. Arevalo-Perez, A.A. Thomas, J. Huse, K. Peck, A.I. Holodny, R.J. Young
American Journal of Neuroradiology Mar 2017, 38 (3) 485-491; DOI: 10.3174/ajnr.A5023
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