Optimization and comparative evaluation of nonlinear deformation algorithms for atlas-based segmentation of DBS target nuclei

Ewert, Siobhan; Horn, Andreas; Finkel, Francisca; Li, Ningfei; Kühn, Andrea A.; Herrington, Todd M.

doi:10.1016/j.neuroimage.2018.09.061

Cited by 121 publications

(169 citation statements)

References 63 publications

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“…To minimize this issue, we used a modern neuroimaging pipeline that has been scientifically validated in numerous studies and involved advanced concepts such as brain shift correction 83 , multispectral normalization, subcortical refinement 83 and phantom-validated electrode localizations 84 . The normalization strategy that was applied was found to automatically segment the STN as precisely as manual expert segmentations 85 and each step of the pipeline was carefully assessed and corrected if needed by a team with long-standing expertise in this area 86,87 . Besides, both post-operative CT (thirty-three patients) and post-operative MRI (seven-teen patients) were used for electrode localization in the current dataset.…”

Section: Limitationsmentioning

confidence: 99%

Toward a unified connectomic target for deep brain stimulation in obsessive-compulsive disorder

Baldermann

Kibleur

et al. 2019

Preprint

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Multiple surgical targets have been proposed for treating obsessive-compulsive disorder (OCD) with deep brain stimulation (DBS). However, different targets may modulate the same neural network responsible for clinical improvement. Here we analyzed data from four cohorts of OCD patients (N = 50) that underwent DBS to the anterior limb of the internal capsule (ALIC), the nucleus accumbens (NAcc) or the subthalamic nucleus (STN). Fiber tracts that were predominantly connected to electrodes in good or poor DBS responders were isolated from a normative structural connectome and assigned a predictive value. Strikingly, the same fiber bundle was related to treatment response when independently analyzing two large training cohorts that targeted either ALIC or STN. This discriminative tract is a subsection of the ALIC and connects frontal regions (such as the dorsal anterior cingulate, dACC, and ventral prefrontal, vlPFC, cortices to the STN). When informing the tract solely based on one cohort (e.g. ALIC), clinical improvements in the other (e.g. STN)could be significantly predicted, and vice versa. Finally, clinical improvements of eight patients from a third center with electrodes in the NAcc and six patients from a fourth center in which electrodes had been implanted in both STN and ALIC were significantly predicted based on this novel tract-based DBS target. Results suggest a functional role of a limbic hyperdirect pathway that projects from dACC and vlPFC to anteriomedial STN. Obsessivecompulsive symptoms seem to be tractable by modulating the specific bundle isolated here.Our results show that connectivity-derived improvement models can inform clinical improvement across DBS targets, surgeons and centers. The identified tract is now threedimensionally defined in stereotactic standard space and will be made openly available.

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Section: Limitationsmentioning

confidence: 99%

Toward a unified connectomic target for deep brain stimulation in obsessive-compulsive disorder

Baldermann

Kibleur

et al. 2019

Preprint

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“…The focal template misregistrations we have identified in fMRIPrep with AFIDs are meant to serve as a baseline for refinement in future versions that can be compared transparently and potentially incorporated for testing new versions as part of a continuous integration workflow. Using additional image contrasts (Xiao et al, 2017) or subcortical tissue priors (Ewert et al, 2019) to drive template registration have been demonstrated using conventional voxel overlap techniques to result in more optimal registrations that can also be tested using the AFIDs framework.…”

Section: Subject-to-template Registrationmentioning

confidence: 99%

A framework for evaluating correspondence between brain images using anatomical fiducials

Lau

Parrent

DeMarco

et al. 2018

Preprint

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First Research Excellence Fund to BrainsCAN, Brain Canada, and computational resource through Compute Canada.Abstract: Accurate spatial correspondence between template and subject images is a crucial step in neuroimaging studies and clinical applications like stereotactic neurosurgery. In the absence of a robust quantitative approach, we sought to propose and validate a set of point landmarks, anatomical fiducials (AFIDs), that could be quickly, accurately, and reliably placed on magnetic resonance images of the human brain. Using several publicly available brain templates and individual participant datasets, novice users could be trained to place a set of 32 AFIDs with millimetric accuracy. Furthermore, the utility of the AFIDs protocol is demonstrated for evaluating subject-to-template and template-to-template registration.Specifically, we found that commonly used voxel overlap metrics were relatively insensitive to focal misregistrations compared to AFID point-based measures. Our entire protocol and study framework leverages open resources and tools, and has been developed with full transparency in mind so that others may freely use, adopt, and modify. This protocol holds value for a broad number of applications including alignment of brain images and teaching neuroanatomy.Establishing spatial correspondence between images is a crucial step in neuroimaging studies enabling fusion of multimodal information, analysis of focal morphological differences, and comparison of withinand between-study data in a common coordinate space. Stereotaxy arose as a result of questions raised by scientists and surgeons interested in the physiology and treatment of focal brain structures (A. C. Evans,

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“…In some patients where this strategy failed, a multispectral implementation of the Unified Segmentation approach implemented in Statistical Parametric Mapping software (SPM12;http://www.fil.ion.ucl.ac.uk/spm) was applied. These two methods are available as pre-sets in Lead-DBS and were top-performers to segment the STN with precision comparable to manual expert segmentations in a recent comparative study 22 . DBS contacts were automatically pre-reconstructed using PaCER or the TRAC/CORE approach and manually refined if needed 20 .…”

Section: Localization Of Dbs Electrodesmentioning

confidence: 99%

Left prefrontal impact links subthalamic stimulation with depressive symptoms

Irmen

Horn

Mosley

et al. 2019

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AbstractObjectiveSubthalamic nucleus deep brain stimulation (STN-DBS) in Parkinson’s Disease (PD) not only stimulates focal target structures but also affects distributed brain networks. The impact this network modulation has on non-motor DBS effects is not well characterized. By focusing on the affective domain, we systematically investigate the impact of electrode placement and associated structural connectivity on changes in depressive symptoms following STN-DBS which have been reported to improve, worsen or remain unchanged.MethodsDepressive symptoms before and after STN-DBS surgery were documented in 116 PD patients from three DBS centers (Berlin, Queensland, Cologne). Based on individual electrode reconstructions, the volumes of tissue activated (VTA) were estimated and combined with normative connectome data to identify structural connections passing through VTAs. Berlin and Queensland cohorts formed a training and cross-validation dataset used to identify structural connectivity explaining change in depressive symptoms. The Cologne data served as test-set for which depressive symptom change was predicted.ResultsStructural connectivity was linked to depressive symptom change under STN-DBS. An optimal connectivity map trained on the Berlin cohort could predict changes in depressive symptoms in Queensland patients and vice versa. Furthermore, the joint training-set map predicted changes in depressive symptoms in the independent test-set. Worsening of depressive symptoms was associated with left prefrontal connectivity.InterpretationFibers linking the STN electrode with left prefrontal areas predicted worsening of depressive symptoms. Our results suggest that for the left STN-DBS lead, placement impacting fibers to left prefrontal areas should be avoided to maximize improvement of depressive symptoms.

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Optimization and comparative evaluation of nonlinear deformation algorithms for atlas-based segmentation of DBS target nuclei

Cited by 121 publications

References 63 publications

Toward a unified connectomic target for deep brain stimulation in obsessive-compulsive disorder

Toward a unified connectomic target for deep brain stimulation in obsessive-compulsive disorder

A framework for evaluating correspondence between brain images using anatomical fiducials

Left prefrontal impact links subthalamic stimulation with depressive symptoms

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