Standard Non-Personalized Electric Field Modeling of Twenty Typical tDCS Electrode Configurations via the Computational Finite Element Method: Contributions and Limitations of Two Different Approaches

Molero‐Chamizo, Andrés; Nitsche, Michael A.; Lérida, Carolina Gutiérrez; Sánchez, Ángeles Salas; Riquel, Raquel Martín; Barroso, Rafael Tomás Andújar; Bailén, José Ramón Alameda; Palomeque, Jesús Carlos García; Rivera-Urbina, Guadalupe Nathzidy

doi:10.3390/biology10121230

Cited by 4 publications

(3 citation statements)

References 113 publications

(197 reference statements)

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“…This approach mirrors Datta et al’s (2009) development of 4 × 1 high definition (HD)-tDCS, in which E-field modeling demonstrated how HD-tDCS produces more focal stimulation prior to human application 43 . Similarly, here we used E-field modeling to provide a theoretical basis for tDCS electrode optimization, building on prior work demonstrating that tDCS electrode positioning matters 44 , 45 , and that the highest E-field is often midway between electrodes 34 , 46 . Drawing on this concept, Mikkonen et al (2020) designed conventional tDCS with electrodes placed with the target in the middle 47 .…”

Section: Introductionmentioning

confidence: 99%

Optimized APPS-tDCS electrode position, size, and distance doubles the on-target stimulation magnitude in 3000 electric field models

Caulfield

George

2022

Sci Rep

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Transcranial direct current stimulation (tDCS) is a widely used noninvasive brain stimulation technique with mixed results to date. A potential solution is to apply more efficient stimulation to ensure that each participant receives sufficient cortical activation. In this four-part study, we used electric field (E-field) modeling to systematically investigate the cortical effects of conventional and novel tDCS electrode montages, with the goal of creating a new easily adoptable form of tDCS that induces higher and more focal E-fields. We computed 3000 anatomically accurate, MRI-based E-field models using 2 mA tDCS to target the left primary motor cortex in 200 Human Connectome Project (HCP) participants and tested the effects of: 1. Novel Electrode Position, 2. Electrode Size, and 3. Inter-Electrode Distance on E-field magnitude and focality. In particular, we examined the effects of placing electrodes surrounding the corticomotor target in the anterior and posterior direction (anterior posterior pad surround tDCS; APPS-tDCS). We found that electrode position, electrode size, and inter-electrode distance all significantly impact the cortical E-field magnitude and focality of stimulation (all p < 0.0001). At the same 2 mA scalp stimulation intensity, APPS-tDCS with smaller than conventional 1 × 1 cm electrodes surrounding the neural target deliver more than double the on-target cortical E-field (APPS-tDCS: average of 0.55 V/m from 2 mA; M1-SO and bilateral M1: both 0.27 V/m from 2 mA) while stimulating only a fraction of the off-target brain regions; 2 mA optimized APPS-tDCS produces 4.08 mA-like cortical E-fields. In sum, this new optimized APPS-tDCS method produces much stronger cortical stimulation intensities at the same 2 mA scalp intensity. APPS-tDCS also more focally stimulates the cortex at the intended target, using simple EEG coordinate locations and without MRI scans. This APPS-tDCS method is adoptable to any existing, commercially available tDCS device and can be used to ensure sufficient cortical activation in each person. Future directions include testing whether APPS-tDCS produces larger and more consistent therapeutic tDCS effects.

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Section: Introductionmentioning

confidence: 99%

Optimized APPS-tDCS electrode position, size, and distance doubles the on-target stimulation magnitude in 3000 electric field models

Caulfield

George

2022

Sci Rep

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“…Despite adequate design methods, current tDCS research for TBI-related cognitive impairments provides only preliminary insights supporting that tDCS may improve physiologic and behavioral cognitive function after TBI. Importantly, these results support that it is safe, inexpensive, and prudent to further research the use of tDCS for cognition across all TBI acuities and severities using biomarkers including electrical-field modeling (Evans et al, 2020 ; Molero-Chamizo et al, 2021 ; Mizutani-Tiebel et al, 2022 ; Nasimova and Huang, 2022 ).…”

Section: Discussionmentioning

confidence: 68%

A map of evidence using transcranial direct current stimulation (tDCS) to improve cognition in adults with traumatic brain injury (TBI)

Schwertfeger,

Beyer,

Hung

et al. 2023

Front. Neuroergonomics

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IntroductionCognition impairments often occur after a traumatic brain injury and occur at higher rates in military members. Cognitive symptoms impair daily function, including balance and life quality, years after the TBI. Current treatments to regain cognitive function after TBI, including medications and cognitive rehabilitation, have shown limited effectiveness. Transcranial direct current stimulation (tDCS) is a low-cost, non-invasive brain stimulation intervention that improves cognitive function in healthy adults and people with neuropsychologic diagnoses beyond current interventions. Despite the available evidence of the effectiveness of tDCS in improving cognition generally, only two small TBI trials have been conducted based on the most recent systematic review of tDCS effectiveness for cognition following neurological impairment. We found no tDCS studies that addressed TBI-related balance impairments.MethodsA scoping review using a peer-reviewed search of eight databases was completed in July 2022. Two assessors completed a multi-step review and completed data extraction on included studies using a priori items recommended in tDCS and TBI research guidelines.ResultsA total of 399 results were reviewed for inclusion and 12 met the criteria and had data extracted from them by two assessors using Google Forms. Consensus on combined data results included a third assessor when needed. No studies using tDCS for cognition-related balance were found.DiscussionGuidelines and technology measures increase the identification of brain differences that alter tDCS effects on cognition. People with mild-severe and acute-chronic TBI tolerated and benefited from tDCS. TBI-related cognition is understudied, and systematic research that incorporates recommended data elements is needed to advance tDCS interventions to improve cognition after TBI weeks to years after injury.

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“…To obtain more detailed data about the location of the effects, stimulation protocols which allow more specific targeting of only the left, or right DLPFC would be warranted in future studies. A relevant point to consider here is that we used 5 × 5 cm, and such relatively large electrodes, which likely affect also brain areas beyond the left and right DLPFC, as suggested by computational modeling studies (Molero‐Chamizo et al, 2021; Salehinejad, Nejati, Mosayebi‐Samani, et al, 2020). Respective mechanisms should be explored directly in future studies with a design that can compare the specific contribution of the left, right and both DLPFC, and physiological measures such as neuroimaging methods.…”

Section: Discussionmentioning

confidence: 99%

The impact of prefrontal transcranial direct current stimulation (tDCS) on theory of mind, emotion regulation and emotional‐behavioral functions in children with autism disorder: A randomized, sham‐controlled, and parallel‐group study

et al. 2022

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Advances in our knowledge about the neuropsychological mechanisms underlying core deficits in autism spectrum disorder (ASD) have produced several novel treatment modalities. One of these approaches is modulation of activity of the brain regions involved in ASD symptoms. This study examined the effects of transcranial direct current stimulation (tDCS) over the dorsolateral prefrontal cortex (DLPFC) on autism symptom severity, theory of mind, emotion regulation strategies, and emotional‐behavioral functions in children with ASD. Thirty‐two children (Mage = 10.16, SD = 1.93, range 7–12 years) diagnosed with ASD were randomly assigned to active (N = 17) or sham stimulation (N = 15) groups in a randomized, sham‐controlled, parallel‐group design. Participants underwent 10 sessions of active (1.5 mA, 15 min, bilateral left anodal/right cathodal DLPFC, 2 sessions per week) or sham tDCS. Autism symptom severity, theory of mind, emotion regulation strategies, and emotional‐behavioral functioning of the patients were assessed at baseline, immediately after the intervention, and 1 month after the intervention. A significant improvement of autism symptom severity (i.e., communication), theory of mind (i.e., ToM 3), and emotion regulation strategies was observed for the active as compared to the sham stimulation group at the end of the intervention, and these effects were maintained at the one‐month follow‐up. The results suggest that repeated tDCS with anodal stimulation of left and cathodal stimulation of right DLPFC improves autism symptom severity as well as social cognition and emotion regulation in ASD. Lay Summary Previous research has suggested that targeting core mechanisms underlying cognitive‐emotional and behavioral deficits of autistic children might improve symptoms of ASD. Deficient social and behavioral functioning, impaired theory of mind, and emotional regulation deficits have been identified as core treatment targets for this group. Specific subregions of the prefrontal cortex are involved in these deficits, including hypoactivity of the dorsolateral prefrontal cortex (DLPFC). Upregulation of this area with non‐invasive brain stimulation, namely anodal transcranial direct current stimulation (tDCS), results in improved social and behavioral functioning in children with ASD. Very few studies have however examined the effects of this intervention on theory of mind, emotional regulation, and emotional‐behavioral problems. We examined the effects of anodal tDCS over the left DLPFC (F3), combined with cathodal tDCS over the right DLPFC (F4) on autism symptom severity as well as theory of mind, emotional regulation, and emotional‐behavioral problems of children with ASD. This intervention improved autism symptom severity, specific domains of theory of mind, and emotion regulation. These findings have clinical implications for the treatment of ASD and suggest that targeting core mechanisms underlying socio‐cognitive‐emotional deficits of autistic children using tDCS might improve symptoms of ASD.

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Standard Non-Personalized Electric Field Modeling of Twenty Typical tDCS Electrode Configurations via the Computational Finite Element Method: Contributions and Limitations of Two Different Approaches

Cited by 4 publications

References 113 publications

Optimized APPS-tDCS electrode position, size, and distance doubles the on-target stimulation magnitude in 3000 electric field models

Optimized APPS-tDCS electrode position, size, and distance doubles the on-target stimulation magnitude in 3000 electric field models

A map of evidence using transcranial direct current stimulation (tDCS) to improve cognition in adults with traumatic brain injury (TBI)

The impact of prefrontal transcranial direct current stimulation (tDCS) on theory of mind, emotion regulation and emotional‐behavioral functions in children with autism disorder: A randomized, sham‐controlled, and parallel‐group study

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