Multimodal 7T Imaging of Thalamic Nuclei for Preclinical Deep Brain Stimulation Applications

Xiao, Yi Zi; Zitella, Laura M.; Duchin, Yuval; Teplitzky, Benjamin A.; Kastl, Daniel; Adriany, Gregor; Yacoub, Essa; Harel, Noam; Johnson, Matthew D.

doi:10.3389/fnins.2016.00264

Cited by 27 publications

(30 citation statements)

References 128 publications

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“…45 We have used an asterisk to denote the ZI to visually emphasize that this structure is better defined by bordering structures and changes in shape at different points along the neuroaxis. The superior portion of the ZI appears as a thin hyperintense band on the TSE sequence superomedial to the inferior portion of the genu of the internal capsule (79), superior to the lenticular fasciculus (58), inferior to the thalamic fasciculus (27) (Figs 3 and 5B), and anterolateral to (Table 2) in the inferior portion of the zona incerta (asterisk), which corresponds with a better therapeutic profile according to Plaha et al 22 FIG 4. Selected images illustrating the hippocampal-thalamic pathways.…”

Section: Zona Incertamentioning

confidence: 84%

“…48,49 This structure appears continuous with the anterior inferior thalamic peduncle, appearing as a sheet-like vertically oriented structure lateral to the postcommissural fornix, anterosuperior to the ansa lenticularis, posteroinferior to the anterior commissure, and su- Selected images illustrating the pallidothalamic tracts. Sagittal, oblique axial (the dashed line in A represents the oblique imaging plane for B), and coronal images illustrating the complex 3D shapes and spatial relationships of the ansa lenticularis (5), lenticular fasciculus (58), and thalamic fasciculus (27). B, The ansa lenticularis originates from the inferomedial globus pallidus internus (17) and joins the lenticular fasciculus (H2 field of Forel) in the very hypointense prerubral H Fields of Forel (78).…”

Section: Pallidothalamic Tractsmentioning

confidence: 99%

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3T MRI Whole-Brain Microscopy Discrimination of Subcortical Anatomy, Part 2: Basal Forebrain

Hoch

Bruno²,

Faustin³

et al. 2019

AJNR Am J Neuroradiol

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BACKGROUND AND PURPOSE: The basal forebrain contains multiple structures of great interest to emerging functional neurosurgery applications, yet many neuroradiologists are unfamiliar with this neuroanatomy because it is not resolved with current clinical MR imaging. MATERIALS AND METHODS: We applied an optimized TSE T2 sequence to washed whole postmortem brain samples (n ϭ 13) to demonstrate and characterize the detailed anatomy of the basal forebrain using a clinical 3T MR imaging scanner. We measured the size of selected internal myelinated pathways and measured subthalamic nucleus size, oblique orientation, and position relative to the intercommissural point. RESULTS: We identified most basal ganglia and diencephalon structures using serial axial, coronal, and sagittal planes relative to the intercommissural plane. Specific oblique image orientations demonstrated the positions and anatomic relationships for selected structures of interest to functional neurosurgery. We observed only 0.2-to 0.3-mm right-left differences in the anteroposterior and superoinferior length of the subthalamic nucleus (P ϭ .084 and .047, respectively). Individual variability for the subthalamic nucleus was greatest for angulation within the sagittal plane (range, 15°-37°), transverse dimension (range, 2-6.7 mm), and most inferior border (range, 4-7 mm below the intercommissural plane). CONCLUSIONS: Direct identification of basal forebrain structures in multiple planes using the TSE T2 sequence makes this challenging neuroanatomy more accessible to practicing neuroradiologists. This protocol can be used to better define individual variations relevant to functional neurosurgical targeting and validate/complement advanced MR imaging methods being developed for direct visualization of these structures in living patients. ABBREVIATIONS: DBS ϭ deep brain stimulation; DRT ϭ dentatorubrothalamic tract; PLIC ϭ posterior limb of the internal capsule; STN ϭ subthalamic nucleus; SUDC ϭ sudden unexplained death of childhood; Vim ϭ thalamic ventrointermedius nucleus; ZI ϭ zona incerta D eep to the cortical surface, the basal ganglia, thalamus, and subthalamus are vital basal forebrain structures involved in the regulation of autonomic, motor, sensory, limbic, and endocrine functions. 1,2 The metabolic demand of the basal forebrain exceeds the cerebral cortex in the resting state. 3 Focal pathologic functional or structural changes can have serious clinical consequences due to the compact organization of the basal forebrain. The thalamus is a complex hub receiving subcortical sensory and motor input that projects to both the cortex and striatum. 4 Thalamic infarction, demyelination, tumors, and other pathologies can cause chronic pain, 5 sensory loss in multiple modalities, amnesia, 6 dystonia, 7 and other disorders. 8,9 The subthalamus modulates basal ganglia output. 10 Ischemic and hyperglycemic injuries of the subthalamic nucleus can result in hemiballism. 11,12 The basal ganglia have complex connections to the cortical motor areas, including the...

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Section: Zona Incertamentioning

confidence: 84%

Section: Pallidothalamic Tractsmentioning

confidence: 99%

3T MRI Whole-Brain Microscopy Discrimination of Subcortical Anatomy, Part 2: Basal Forebrain

Hoch

Bruno²,

Faustin³

et al. 2019

AJNR Am J Neuroradiol

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“…It is currently unknown whether modifications of the SWI phase‐magnitude combination, in particular, could enhance its ability to image non‐venous tissues such as the thalamus. Previous reports have found promising results for thalamic mapping using the conventional, venography‐oriented SWI contrast, but to our knowledge none have proposed or explored potential dedicated improvements . A main reason for this shortcoming could be the fact that, to our knowledge, the SWI combination parameters are typically fixed and cannot be modified by users directly on the console (“online”), requiring dedicated expertise in MRI data reconstruction to explore such modifications.…”

Section: Introductionmentioning

confidence: 99%

Improved susceptibility‐weighted imaging for high contrast and resolution thalamic nuclei mapping at 7T

Jorge

Gretsch

Najdenovska

et al. 2020

Magnetic Resonance in Med

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Purpose:The thalamus is an important brain structure and neurosurgical target, but its constituting nuclei are challenging to image non-invasively. Recently, susceptibility-weighted imaging (SWI) at ultra-high field has shown promising capabilities for thalamic nuclei mapping. In this work, several methodological improvements were explored to enhance SWI quality and contrast, and specifically its ability for thalamic imaging. Methods: High-resolution SWI was performed at 7T in healthy participants, and the following techniques were applied: (a) monitoring and retrospective correction of head motion and B 0 perturbations using integrated MR navigators, (b) segmentation and removal of venous vessels on the SWI data using vessel enhancement filtering, and (c) contrast enhancement by tuning the parameters of the SWI phase-magnitude combination. The resulting improvements were evaluated with quantitative metrics of image quality, and by comparison to anatomo-histological thalamic atlases. Results: Even with sub-millimeter motion and natural breathing, motion and field correction produced clear improvements in both magnitude and phase data quality (76% and 41%, respectively). The improvements were stronger in cases of larger motion/field deviations, mitigating the dependence of image quality on subject performance. Optimizing the SWI phase-magnitude combination yielded substantial improvements in image contrast, particularly in the thalamus, well beyond previously reported SWI results. The atlas comparisons provided compelling evidence of anatomical correspondence between SWI features and several thalamic nuclei, for | 1219 JORGE Et al.

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“…Recently, technical advances in both hardware and software of high‐field MRI has enabled 7T MRI systems to become commercially available for human study. A number of MRI techniques, 3D anatomical and angiographic sequences in particular, have been developed and optimized at 7T to enable high‐resolution acquisition by making use of the increased signal‐to‐noise ratio (SNR) at ultrahigh‐field . ASL theoretically benefits from ultrahigh‐field with the dual benefits of increased SNR and prolonged longitudinal relaxation times .…”

mentioning

confidence: 99%

“…A number of MRI techniques, 3D anatomical and angiographic sequences in particular, have been developed and optimized at 7T to enable high-resolution acquisition by making use of the increased signal-to-noise ratio (SNR) at ultrahighfield. [17][18][19][20][21] ASL theoretically benefits from ultrahigh-field with the dual benefits of increased SNR and prolonged longitudinal relaxation times. 22 A prolonged bolus of the labeled blood is expected in NCE 4D MRA at 7T.…”

mentioning

confidence: 99%

Noncontrast‐enhanced time‐resolved 4D dynamic intracranial MR angiography at 7T: A feasibility study

Cong

Zhuo

et al. 2017

Magnetic Resonance Imaging

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Multimodal 7T Imaging of Thalamic Nuclei for Preclinical Deep Brain Stimulation Applications

Cited by 27 publications

References 128 publications

3T MRI Whole-Brain Microscopy Discrimination of Subcortical Anatomy, Part 2: Basal Forebrain

3T MRI Whole-Brain Microscopy Discrimination of Subcortical Anatomy, Part 2: Basal Forebrain

Improved susceptibility‐weighted imaging for high contrast and resolution thalamic nuclei mapping at 7T

Noncontrast‐enhanced time‐resolved 4D dynamic intracranial MR angiography at 7T: A feasibility study

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