Non-invasive assessment of glioma microstructure using VERDICT MRI: correlation with histology

Zaccagna, Fulvio; Riemer, Frank; Priest, Andrew N.; McLean, Mary A.; Allinson, Kieren; Grist, James T.; Dragos, Carmen; Matys, Tomasz; Gillard, Jonathan H.; Watts, Colin; Price, Stephen J.; Graves, Martin J.; Gallagher, Ferdia A.

doi:10.1007/s00330-019-6011-8

Cited by 36 publications

(31 citation statements)

References 25 publications

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“…Such approaches showed enhanced ability over ADC to explain the diffusion measurements and differentiate between benign and malignant tumors in various cancer types such as xenograft colorectal tumors, 33 prostate cancer, 37,41-44 breast cancer, 40 and gliomas. 45,46 Moreover, the estimated dMRI parameters for restriction size and volume fraction correlated well with histology measurements. 33,41,47 Compartment models have also been employed in a preliminary study to characterize diffusion in lymph node tissue ex vivo, 48 showing that models that include restriction and anisotropy provide the best fit to the data; however, only 3 samples were included, and a direct link to tissue microstructure through histological validation was not presented.…”

Section: Introductionmentioning

confidence: 52%

“…To further enhance the specificity of dMRI‐derived parameters to the underlying microstructure, recently proposed higher‐order dMRI techniques employ biophysical compartment models of various (assumed) tissue features to fit the dMRI measurements, usually acquired at multiple b ‐values and diffusion times. Such approaches showed enhanced ability over ADC to explain the diffusion measurements and differentiate between benign and malignant tumors in various cancer types such as xenograft colorectal tumors, prostate cancer, breast cancer, and gliomas . Moreover, the estimated dMRI parameters for restriction size and volume fraction correlated well with histology measurements .…”

Section: Introductionmentioning

confidence: 92%

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Higher‐order diffusion MRI characterization of mesorectal lymph nodes in rectal cancer

Ianuş

Santiago

Galzerano

et al. 2019

Magnetic Resonance in Med

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Purpose Mesorectal lymph node staging plays an important role in treatment decision making. Here, we explore the benefit of higher‐order diffusion MRI models accounting for non‐Gaussian diffusion effects to classify mesorectal lymph nodes both 1) ex vivo at ultrahigh field correlated with histology and 2) in vivo in a clinical scanner upon patient staging. Methods The preclinical investigation included 54 mesorectal lymph nodes, which were scanned at 16.4 T with an extensive diffusion MRI acquisition. Eight diffusion models were compared in terms of goodness of fit, lymph node classification ability, and histology correlation. In the clinical part of this study, 10 rectal cancer patients were scanned with diffusion MRI at 1.5 T, and 72 lymph nodes were analyzed with Apparent Diffusion Coefficient (ADC), Intravoxel Incoherent Motion (IVIM), Kurtosis, and IVIM‐Kurtosis. Results Compartment models including restricted and anisotropic diffusion improved the preclinical data fit, as well as the lymph node classification, compared to standard ADC. The comparison with histology revealed only moderate correlations, and the highest values were observed between diffusion anisotropy metrics and cell area fraction. In the clinical study, the diffusivity from IVIM‐Kurtosis was the only metric showing significant differences between benign (0.80 ± 0.30 μm2/ms) and malignant (1.02 ± 0.41 μm2/ms, P = .03) nodes. IVIM‐Kurtosis also yielded the largest area under the receiver operating characteristic curve (0.73) and significantly improved the node differentiation when added to the standard visual analysis by experts based on T2‐weighted imaging. Conclusion Higher‐order diffusion MRI models perform better than standard ADC and may be of added value for mesorectal lymph node classification in rectal cancer patients.

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Section: Introductionmentioning

confidence: 52%

Section: Introductionmentioning

confidence: 92%

Higher‐order diffusion MRI characterization of mesorectal lymph nodes in rectal cancer

Ianuş

Santiago

Galzerano

et al. 2019

Magnetic Resonance in Med

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“…As a limitation of the study we should note not an optimal choice of adjusting variable α . A more accurate model fitted to the tumour microstructure [33] might increase feasibility of GK approach and its performance in the case of glioma grading. Addtionally, advanced diffusion techniques including fast kurtosis [34], isotropic diffusion weighting [35], [36], [37] and multidimensional diffusion imaging [38], [39] might help clinicians to perform a robust, fast and non-invasive glioma differentiation.…”

Section: Discussionmentioning

confidence: 99%

Feasibility of generalised DKI approach for brain glioma grading

Pogosbekyan

Pronin

Захарова

et al. 2020

Preprint

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Purpose: An accurate differentiation of brain glioma grade constitutes an important clinical issue. Powerful non-invasive approach based on diffusion MRI has already demonstrated its feasibility in glioma grade stratification. However, the conventional diffusion tensor (DTI) and kurtosis imaging (DKI) demonstrated moderate sensitivity and performance in glioma grading. In the present work, we apply generalised DKI (gDKI) approach in order to assess its diagnostic accuracy and potential application in glioma grading. Methods: Diffusion scalar metrics were obtained from 50 patients with different glioma grades confirmed by histological tests following biopsy or surgery. All patients were divided into two groups with low- and high-grade gliomas as II grade versus III and IV grades, respectively. For a comparison, trained radiologists segmented the brain tissue into three regions with solid tumour, oedema, and normal appearing white matter. For each region we estimated the conventional and gDKI metrics including DTI maps. Results: We found high correlations between DKI and gDKI metrics in high-grade glioma. Further, gDKI metrics enabled introduction of a complementary measure for glioma differentiation based on correlations between the conventional and generalised approaches. Both conventional and generalised DKI metrics showed quantitative maps of tumour heterogeneity and oedema behaviour. gDKI approach demonstrated largely similar sensitivity and specificity in low-high glioma differentiation as in the case of conventional DKI method. Conclusion: The generalised diffusion kurtosis imaging enables differentiation of low and high grade gliomas at the same level as the conventional DKI. Additionally, gDKI exhibited higher tissue contrast between tumour and healthy tissue and, thus, may contribute as a complementary source of information on tumour heterogeneity.

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“…VERDICT [ 119 ] assumes an anisotropic vascular compartment, an extracellular compartment with isotropic hindered diffusion, and an intracellular compartment with restricted diffusion, and it also estimates cell radius. Originally optimized for prostate neoplasms, it was recently applied to gliomas [ 120 ]. A recent study [ 120 ] employed a clinically feasible VERDICT sequence (5 min 30 s) and compared VERDICT-metrics in IDH mut -LGG and IDH wt -HGG.…”

Section: Biophysical Models: Toward Microstructural Dmrimentioning

confidence: 99%

“…Originally optimized for prostate neoplasms, it was recently applied to gliomas [ 120 ]. A recent study [ 120 ] employed a clinically feasible VERDICT sequence (5 min 30 s) and compared VERDICT-metrics in IDH mut -LGG and IDH wt -HGG. A significant difference in the “intracellular compartment” was found between groups, with this metric being higher in IDH wt -HGG, whereas no significant ADC differences were seen in this cohort.…”

Section: Biophysical Models: Toward Microstructural Dmrimentioning

confidence: 99%

Advancements in Neuroimaging to Unravel Biological and Molecular Features of Brain Tumors

Sanvito

Castellano

Falini

2021

Cancers

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In recent years, the clinical assessment of primary brain tumors has been increasingly dependent on advanced magnetic resonance imaging (MRI) techniques in order to infer tumor pathophysiological characteristics, such as hemodynamics, metabolism, and microstructure. Quantitative radiomic data extracted from advanced MRI have risen as potential in vivo noninvasive biomarkers for predicting tumor grades and molecular subtypes, opening the era of “molecular imaging” and radiogenomics. This review presents the most relevant advancements in quantitative neuroimaging of advanced MRI techniques, by means of radiomics analysis, applied to primary brain tumors, including lower-grade glioma and glioblastoma, with a special focus on peculiar oncologic entities of current interest. Novel findings from diffusion MRI (dMRI), perfusion-weighted imaging (PWI), and MR spectroscopy (MRS) are hereby sifted in order to evaluate the role of quantitative imaging in neuro-oncology as a tool for predicting molecular profiles, stratifying prognosis, and characterizing tumor tissue microenvironments. Furthermore, innovative technological approaches are briefly addressed, including artificial intelligence contributions and ultra-high-field imaging new techniques. Lastly, after providing an overview of the advancements, we illustrate current clinical applications and future perspectives.

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Non-invasive assessment of glioma microstructure using VERDICT MRI: correlation with histology

Cited by 36 publications

References 25 publications

Higher‐order diffusion MRI characterization of mesorectal lymph nodes in rectal cancer

Higher‐order diffusion MRI characterization of mesorectal lymph nodes in rectal cancer

Feasibility of generalised DKI approach for brain glioma grading

Advancements in Neuroimaging to Unravel Biological and Molecular Features of Brain Tumors

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