Effect of the Maximum Dose on White Matter Fiber Bundles Using Longitudinal Diffusion Tensor Imaging

Zhu, Tong; Chapman, Christopher H.; Tsien, Christina; Kim, Michelle; Spratt, Daniel E.; Lawrence, Theodore S.; Cao, Yue

doi:10.1016/j.ijrobp.2016.07.010

Cited by 30 publications

(25 citation statements)

References 32 publications

(42 reference statements)

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“…In patients with MCI, changes within the ventral cingulum are predictive of (and detectable prior to) hippocampal volume loss and memory performance [35]. While a previous study of radiation effects on white matter found dose sensitivity to DTI changes in the parahippocampal cingulum [36], we did not detect robust dose-sensitivity in this structure. Indeed the distinction between the dorsal and ventral aspects of the cingulum are rather arbitrary, and may vary by DTI atlas [25,32].…”

Section: Discussioncontrasting

confidence: 66%

“…With respect to dose, a recent DTI study found that elongated white matter tracts after partial brain RT responded more to maximum dose rather than mean dose [36]. The possibility of serial structure response carries important implications for RT planning, as this suggests that limiting hot spots within a tract is more important than limiting the mean dose delivered to the entire structure.…”

Section: Discussionmentioning

confidence: 99%

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Regional susceptibility to dose-dependent white matter damage after brain radiotherapy

Connor

Karunamuni

McDonald

et al. 2017

Radiotherapy and Oncology

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Background and Purpose Regional differences in sensitivity to white matter damage after brain radiotherapy (RT) are not well-described. We characterized the spatial heterogeneity of dose-response across white matter tracts using diffusion tensor imaging (DTI). Materials and Methods Forty-nine patients with primary brain tumors underwent MRI with DTI before and 9–12 months after partial-brain RT. Maps of fractional anisotropy (FA), mean diffusivity (MD), axial diffusivity (AD), and radial diffusivity (RD) were generated. Atlas-based white matter tracts were identified. A secondary analysis using skeletonized tracts was also performed. Linear mixed-model analysis of the relationship between mean and max dose and percent change in DTI metrics was performed. Results Tracts with the strongest correlation of FA change with mean dose were the fornix (−0.46 percent/Gy), cingulum bundle (−0.44 percent/Gy), and body of corpus callosum (−0.23 percent/Gy), p<.001. These tracts also showed dose-sensitive changes in MD and RD. In the skeletonized analysis, the fornix and cingulum bundle remained highly dose-sensitive. Maximum and mean dose were similarly predictive of DTI change. Conclusions The corpus callosum, cingulum bundle, and fornix show the most prominent dose-dependent changes following RT. Future studies examining correlation with cognitive functioning and potential avoidance of critical white matter regions are warranted.

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Section: Discussioncontrasting

confidence: 66%

Section: Discussionmentioning

confidence: 99%

Regional susceptibility to dose-dependent white matter damage after brain radiotherapy

Connor

Karunamuni

McDonald

et al. 2017

Radiotherapy and Oncology

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“…Studies on tissue-dose interaction, as the current one, aid in understanding radiation-induced cognitive decline, which may be the consequence of, but not restricted to, demyelination and loss of axonal integrity with increasing radiation doses. Research in neuroscience, especially on aging [47,48] and cognitive impairment [49,50] ROIs receiving certain dose levels or aim to avoid PVE by restricting the masking to connected voxels that only include WM structure by excluding voxels with FA lower than 0.2 [17,29,55].…”

Section: Discussionmentioning

confidence: 99%

“…We further assumed that tissue change relates linearly to the applied dose. While this framework is widely applied by the RT-community [17,29,55,75], these assumptions may only approximate the true underlying relations. Further biophysical modeling is .…”

Section: Discussionmentioning

confidence: 99%

Dose-dependent degeneration of non-cancerous brain tissue in post-radiotherapy patients: A diffusion tensor imaging study

Dávid

Mesri

Bodiut

et al. 2019

Preprint

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Background and purpose: Radiation-induced changes in brain tissue may relate to post-radiotherapy (RT) cognitive decline. Our aim is to investigate changes of the brain microstructural properties after exposure to radiation during clinical protocols of RT using diffusion MRI (dMRI). Methods and Materials: The susceptibility of tissue changes to radiation was investigated in a clinically heterogenic cohort (age, pathology, tumor location, type of surgery) consisting of 121 scans of 18 patients (10 females). The imaging dataset included 18 planning CTs and 103 dMRI scans (range 2-14, median = 6 per patient) assessing pre-operative, post-operative pre-RT and post-RT states. Diffusion tensor imaging (DTI) metrics were estimated from all scans for a region-of-interest based linear relation analysis between mean dose and change in DTI metrics, while partial volume effects were regressed out. Results: The largest regional dose dependency with mean diffusivity appear in the white matter of the frontal pole in the left hemisphere by an increase of 2.61 %/(Gy x year). Full brain-wise, pooled results for white matter show fractional anisotropy to decrease by 0.85 %/(30Gy x year); mean diffusivity increase by 9.17 %/(30Gy x year); axial diffusivity increase by 7.30%/(30Gy x year) and radial diffusivity increases by 10.63%/(30Gy x year). Conclusions: White matter is susceptible to radiation with some regional variability where diffusivity metrics demonstrate the largest relative sensitivity. This suggests that dMRI is a promising tool in assessing microstructural changes after RT, which can help in understanding treatment-induced cognitive decline.

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“…Another recent study found that diffusion changes in individual white matter bundles were associated with maximum dose to those tracts, implying serial radiation injury. 149 There also appears to be regional susceptibility of white matter damage. A study of medulloblastoma survivors found greater diffusion changes in the frontal versus parietal lobes.…”

Section: Neuroimaging Evidence For Radiation Induced Cns Changesmentioning

confidence: 99%

Mechanisms of radiotherapy-associated cognitive disability in patients with brain tumours

et al. 2016

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Standard treatment of primary and metastatic brain tumors includes high dose megavoltage radiation to the cranial vault. About half of patients survive >6 months, many attain long term control or cure, but 50-90% of survivors overall exhibit disabling cognitive dysfunction. The radiation cognitive syndrome is poorly understood and there is no effective prevention or long-term treatment. Attention has primarily focused on mechanisms of disability appearing at six months to one year after radiotherapy. However, a range of studies have revealed that CNS alterations and dysfunction develop much earlier than 6 months following radiation exposure. This has prompted the recent hypothesis that relatively subtle early forms of radiation induced CNS damage may drive chronic pathophysiology leading to permanent cognitive decline. Within this perspective, the present review presents evidence of acute CNS irradiation triggered inflammation, and injury to neuronal lineages, accessory cells and their progenitors, and loss of supporting structure integrity. Moreover, injury related processes set in motion soon after intracranial irradiation may interact and synergize to alter the neuronal and supporting cell progenitor signaling environment in stem cell niches in the brain, and specifically in the hippocampus, a structure critical to memory and cognition. Changed niche conditions may cause a sustained decline in neurons and progressive deterioration of cognition. The concluding discussion addresses, (1) what further data is needed, and (2) potential treatment interventions, identified via recent findings on acute CNS radiation injury, that may reverse degenerative processes before they can cause permanent cognitive disability.

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Effect of the Maximum Dose on White Matter Fiber Bundles Using Longitudinal Diffusion Tensor Imaging

Cited by 30 publications

References 32 publications

Regional susceptibility to dose-dependent white matter damage after brain radiotherapy

Regional susceptibility to dose-dependent white matter damage after brain radiotherapy

Dose-dependent degeneration of non-cancerous brain tissue in post-radiotherapy patients: A diffusion tensor imaging study

Mechanisms of radiotherapy-associated cognitive disability in patients with brain tumours

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