Towards patient-specific modeling of brain tumor growth and formation of secondary nodes guided by DTI-MRI

Angeli, Stelios; Emblem, Kyrre E.; Due‐Tønnessen, Paulina; Stylianopoulos, Triantafyllos

doi:10.1016/j.nicl.2018.08.032

Cited by 38 publications

(34 citation statements)

References 69 publications

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“…Similar patterns of increased integration within the ipsilesional hemisphere have been reported in cerebral glioma cases, with one study finding increased functional integration of the hippocampus ( Esposito et al , 2012 ). However, from a structural connectivity standpoint, though consistent with previous findings of increased ipsilesional count, these results are inconsistent with the anatomical effects of glioma presence, which include tract displacement ( Schonberg et al , 2006 ; Angeli et al , 2018 ). With respect to the structural integrity of integration and modularity measures, we observed an ipsilesional decline.…”

Section: Discussionsupporting

confidence: 49%

“…One possible explanation attributes this to the cortical neuroplasticity described earlier, primarily the idea of recruitment of contralesional brain regions to aid its ipsilesional counterparts, a phenomenon noted in functional recovery of stroke patients ( Small et al , 2002 ). Another could be mass effect concentrating surrounding fibres, providing the fibre tracking algorithm to read an increase in connectivity between two lesion proximal nodes ( Schonberg et al , 2006 ; Angeli et al , 2018 ). Finally, the presence of oedema could be affecting fibre tracking, feigning the presence of increased connectivity while also showing an decrease in FA and increase mean diffusivity ( Field and Alexander, 2004 ; Wu et al , 2004 ; Bulakbaşı, 2009 ).…”

Section: Discussionmentioning

confidence: 99%

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Retrospective analysis of hemispheric structural network change as a function of location and size of glioma

D’Souza

Hirt

Ormond

et al. 2020

Brain Communications

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Gliomas are neoplasms that arise from glial cell origin and represent the largest fraction of primary malignant brain tumours (77%). These highly infiltrative malignant cell clusters modify brain structure and function through expansion, invasion and intratumoral modification. Depending on the growth rate of the tumour, location and degree of expansion, functional reorganization may not lead to overt changes in behaviour despite significant cerebral adaptation. Studies in simulated lesion models and in patients with stroke reveal both local and distal functional disturbances, using measures of anatomical brain networks. Investigations over the last two decades have sought to use diffusion tensor imaging tractography data in the context of intracranial tumours to improve surgical planning, intraoperative functional localization, and post-operative interpretation of functional change. In this study, we used diffusion tensor imaging tractography to assess the impact of tumour location on the white matter structural network. To better understand how various lobe localized gliomas impact the topology underlying efficiency of information transfer between brain regions, we identified the major alterations in brain network connectivity patterns between the ipsilesional versus contralesional hemispheres in patients with gliomas localized to the frontal, parietal or temporal lobe. Results were indicative of altered network efficiency and the role of specific brain regions unique to different lobe localized gliomas. This work draws attention to connections and brain regions which have shared structural susceptibility in frontal, parietal and temporal lobe glioma cases. This study also provides a preliminary anatomical basis for understanding which affected white matter pathways may contribute to preoperative patient symptomology.

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Section: Discussionsupporting

confidence: 49%

Section: Discussionmentioning

confidence: 99%

Retrospective analysis of hemispheric structural network change as a function of location and size of glioma

D’Souza

Hirt

Ormond

et al. 2020

Brain Communications

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“…In this study, we did not directly measure tract displacement, since we did not use a normal control for comparison. However, previous studies have demonstrated that the degree of mechanical displacement of brain tissue caused by mass effect is reflected by a change in diffusion coefficients [65]. To control for the relative difference in sampled voxels between the two hemispheres and to assess whether tumor mass correlated with any of the measured diffusion coefficients, we compared the lesion volume, as a fraction of total intracranial volume, with the percent difference in diffusion coefficient between the hemispheres (Fig 3).…”

Section: Discussionmentioning

confidence: 99%

Fiber-tract localized diffusion coefficients highlight patterns of white matter disruption induced by proximity to glioma

et al. 2019

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Gliomas account for 26.5% of all primary central nervous system tumors. Recent studies have used diffusion tensor imaging (DTI) to extract white matter fibers and the diffusion coefficients derived from MR processing to provide useful, non-invasive insights into the extent of tumor invasion, axonal integrity, and gross differentiation of glioma from metastasis. Here, we extend this work by examining whether a tract-based analysis can improve non-invasive localization of tumor impact on white matter integrity. This study retrospectively analyzed preoperative magnetic resonance sequences highlighting contrast enhancement and DTI scans of 13 subjects that were biopsy-confirmed to have either high or low-grade glioma. We reconstructed the corticospinal tract and superior longitudinal fasciculus by applying atlas-based regions of interest to fibers derived from whole-brain deterministic streamline tractography. Within-subject comparison of hemispheric diffusion coefficients (e.g., fractional anisotropy and mean diffusivity) indicated higher levels of white matter degradation in the ipsilesional hemisphere. Novel application of along-tract analyses revealed that tracts traversing the tumor region showed significant white matter degradation compared to the contralesional hemisphere and ipsilesional tracts displaced by the tumor.

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“…DTI data have been used successfully in the context of glioma evaluation in several regards. For example, they have been used to adapt target volume definitions for GBM treatment planning [24][25][26], for modeling of brain tumor growth [27][28][29][30], to detect early malignant transformation of low-grade glioma [31], to differentiate between GBM and brain metastases [32], to use DTI-derived fiber tracking in surgery planning [33], and to detect the infiltration of the corpus callosum [34]. Our inability to properly connect most primary and secondary tumors does not diminish the value of DTI for these applications.…”

Section: Discussionmentioning

confidence: 99%

On PTV definition for glioblastoma based on fiber tracking of diffusion tensor imaging data

et al. 2020

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Radiotherapy (RT) is commonly applied for the treatment of glioblastoma multiforme (GBM). Following the planning target volume (PTV) definition procedure standardized in guidelines, a 20% risk of missing non-local recurrences is present. Purpose of this study was to evaluate whether diffusion tensor imaging (DTI)-based fiber tracking may be beneficial for PTV definition taking into account the prediction of distant recurrences. 56 GBM patients were examined with magnetic resonance imaging (MRI) including DTI performed before RT after resection of the primary tumor. Follow-up MRIs were acquired in three month intervals. For the seven patients with a distant recurrence, fiber tracking was performed with three algorithms and it was evaluated whether connections existed from the primary tumor region to the distant recurrence. It depended strongly on the used tracking algorithm and the used tracking parameters whether a connection was observed. Most of the connections were weak and thus not usable for PTV definition. Only in one of the seven patients with a recurring tumor, a clear connection was present. It seems unlikely that DTIbased fiber tracking can be beneficial for predicting distant recurrences in the planning of PTVs for glioblastoma multiforme.

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Towards patient-specific modeling of brain tumor growth and formation of secondary nodes guided by DTI-MRI

Cited by 38 publications

References 69 publications

Retrospective analysis of hemispheric structural network change as a function of location and size of glioma

Retrospective analysis of hemispheric structural network change as a function of location and size of glioma

Fiber-tract localized diffusion coefficients highlight patterns of white matter disruption induced by proximity to glioma

On PTV definition for glioblastoma based on fiber tracking of diffusion tensor imaging data

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