Imaging of current flow in the human head during transcranial electrical therapy

Kasinadhuni, Aditya K.; Indahlastari, Aprinda; Chauhan, Munish; Schär, Michael; Mareci, Thomas H.; Sadleir, Rosalind

doi:10.1016/j.brs.2017.04.125

Cited by 42 publications

(59 citation statements)

References 49 publications

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“…Effects on neuronal excitability depend on the electric field (E-field) distribution [2]. However, and despite recent advances in in-vivo measuring techniques [3], the only approach to predict the E-field in the head with a high spatial resolution is via numerical methods, such as the finite element method (FEM) [4]. Such FEM requires geometric information about the tissues in the head, which is obtained from structural images, such as MRIs [5,6], and relies on knowledge about the electrical conductivity of the different tissues in the brain and the electrode montage (position, geometry and currents) [7].…”

Section: Importance Of Numerical Head Modeling In Tcsmentioning

confidence: 99%

“…This dataset includes 422 3D T1-w MRI scans from the ADNI dataset 2 with 166x256x256 voxels and size 1.2x0.9x0.9 mm 3 and also 108 3D T1-w MRI scans from the IXI dataset (see 3 for details of scanner parameters) with 256x256x150 voxels and size 0.9x0.9x1.2 mm 3 . Both datasets are normalized to an intensity range of 0 to 255 and converted to 256 3 dimensions and 1 3 mm 3 voxel size.…”

Section: The Ixi+adni Datasetmentioning

confidence: 99%

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Convolutional neural network MRI segmentation for fast and robust optimization of transcranial electrical current stimulation of the human brain

Sendra-Balcells¹,

Salvador²,

Pedro

et al. 2020

Preprint

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The segmentation of structural MRI data is an essential step for deriving geometrical information about brain tissues. One important application is in transcranial direct current stimulation (e.g., tDCS), a non-invasive neuromodulatory technique where head modeling is required to determine the electric field (E-field) generated in the cortex to predict and optimize its effects. Here we propose a deep learning-based model (StarNEt) to automatize white matter (WM) and gray matter (GM) segmentation and compare its performance with FreeSurfer, an established tool. Since good definition of sulci and gyri in the cortical surface is an important requirement for E-field calculation, StarNEt is specifically designed to output masks at a higher resolution than that of the original input T1w-MRI. StarNEt uses a residual network as the encoder (ResNet) and a fully convolutional neural network with U-net skip connections as the decoder to segment an MRI slice by slice. Slice vertical location is provided as an extra input. The model was trained on scans from 425 patients in the open-access ADNI+IXI datasets, and using FreeSurfer segmentation as ground truth. Model performance was evaluated using the Dice Coefficient (DC) in a separate subset (N=105) of ADNI+IXI and in two extra testing sets not involved in training. In addition, FreeSurfer and StarNEt were compared to manual segmentations of the MRBrainS18 dataset, also unseen by the model. To study performance in real use cases, first, we created electrical head models derived from the FreeSurfer and StarNEt segmentations and used them for montage optimization with a common target region using a standard algorithm (Stimweaver) and second, we used StarNEt to successfully segment the brains of minimally conscious state (MCS) patients having suffered from brain trauma, a scenario where FreeSurfer typically fails. Our results indicate that StarNEt matches FreeSurfer performance on the trained tasks while reducing computation time from several hours to a few seconds, and with the potential to evolve into an effective technique even when patients present large brain abnormalities.

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Section: Importance Of Numerical Head Modeling In Tcsmentioning

confidence: 99%

Section: The Ixi+adni Datasetmentioning

confidence: 99%

Convolutional neural network MRI segmentation for fast and robust optimization of transcranial electrical current stimulation of the human brain

Sendra-Balcells¹,

Salvador²,

Pedro

et al. 2020

Preprint

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“…Performing simulation studies based on such data can 52 become difficult due to challenges in the segmentation of low-contrast tissue such as skull using 53 standard segmentation approaches. Following the image segmentation, a surface-based meshing 54 approach is commonly used to create the head volume mesh. The advantage of this approach is a 55 maximum of control over the approximation of the boundaries of the sub-compartments of the head 56 model, which, on the other hand, must not intersect, restricting the topology of the included structures 57 and complicating the inclusion of irregular tissue such as lesioned tissue.…”

Section: Introductionmentioning

confidence: 99%

“…Promising approaches are electrical current density measurements obtained by the means of magnetic 590 resonance electrical impedance tomography (54) or in-vivo recordings of the electrical potential by 591 intracranial electrodes. TDCS simulations have been validated using intracranial recordings of epilepsy 592 patients before (55), (56).…”

mentioning

confidence: 99%

A flexible workflow for simulating transcranial electric stimulation in healthy and lesioned brains

Kalloch

Bazin

Villringer

et al. 2020

Preprint

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AbstractSimulating transcranial electric stimulation is actively researched as knowledge about the distribution of the electrical field is decisive for understanding the variability in the elicited stimulation effect. Several software pipelines comprehensively solve this task in an automated manner for standard use-cases. However, simulations for non-standard applications such as uncommon electrode shapes or the creation of head models from non-optimized T1-weighted imaging data and the inclusion of irregular structures are more difficult to accomplish.We address these limitations and suggest a comprehensive workflow to simulate transcranial electric stimulation based on open-source tools. The workflow covers the head model creation from MRI data, the electrode modeling, the modeling of anisotropic conductivity behavior of the white matter, the numerical simulation and visualization.Skin, skull, air cavities, cerebrospinal fluid, white matter, and gray matter are segmented semi-automatically from T1-weighted MR images. Electrodes of arbitrary number and shape can be modeled. The meshing of the head model is implemented in a way to preserve feature edges of the electrodes and is free of topological restrictions of the considered structures of the head model. White matter anisotropy can be computed from diffusion-tensor imaging data.Our solver application was verified analytically and by contrasting tDCS simulation results with another simulation pipeline (SimNIBS 3.0). An agreement in both cases underlines the validity of our workflow.Our suggested solutions facilitate investigations of irregular structures in patients (e.g. lesions, implants) or of new electrode types. For a coupled use of the described workflow, we provide documentation and disclose the full source code of the developed tools.

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“…In MREIT, electric currents are injected into body through surface electrodes, in coordination with pulse sequences . Over the last decade, MREIT has advanced from phantom studies, to canine whole body imaging with disease models, to in vivo human imaging of lower leg and knee, to current flow and conductivity in the human brain . All these experiments have been aimed at clinical translation and were primarily performed at main magnetic field strengths of 3T.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of magnetohydrodynamic effects in magnetic resonance electrical impedance tomography at ultra‐high magnetic fields

Minhas

Chauhan

et al. 2018

Magnetic Resonance in Med

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Purpose Artifacts observed in experimental magnetic resonance electrical impedance tomography images were hypothesized to be because of magnetohydrodynamic (MHD) effects. Theory and Methods Simulations of MREIT acquisition in the presence of MHD and electrical current flow were performed to confirm findings. Laminar flow and (electrostatic) electrical conduction equations were bidirectionally coupled via Lorentz force equations, and finite element simulations were performed to predict flow velocity as a function of time. Gradient sequences used in spin‐echo and gradient echo acquisitions were used to calculate overall effects on MR phase images for different electrical current application or phase‐encoding directions. Results Calculated and experimental phase images agreed relatively well, both qualitatively and quantitatively, with some exceptions. Refocusing pulses in spin echo sequences did not appear to affect experimental phase images. Conclusion MHD effects were confirmed as the cause of observed experimental phase changes in MREIT images obtained at high fields. These findings may have implications for quantitative measurement of viscosity using MRI techniques. Methods developed here may be also important in studies of safety and in vivo artifacts observed in high field MRI systems.

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Imaging of current flow in the human head during transcranial electrical therapy

Cited by 42 publications

References 49 publications

Convolutional neural network MRI segmentation for fast and robust optimization of transcranial electrical current stimulation of the human brain

Convolutional neural network MRI segmentation for fast and robust optimization of transcranial electrical current stimulation of the human brain

A flexible workflow for simulating transcranial electric stimulation in healthy and lesioned brains

Evaluation of magnetohydrodynamic effects in magnetic resonance electrical impedance tomography at ultra‐high magnetic fields

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