Gas-phase infrared spectroscopy of glycans and glycoconjugates

A realistic human head model consisting of six tissue layers was modelled to investigate the behavior of temperature profile and magnitude when applying electroconvulsive therapy stimulation and different biological properties. The thermo-electrical model was constructed with the use of bio-heat transfer equation and Laplace equation. Three different electrode montages were analyzed as well as the influence of blood perfusion, metabolic heat and electric and thermal conductivity in the scalp. Also, the effect of including the fat layer was investigated. The results showed that temperature increase is inversely proportional to electrical and thermal conductivity increase. Furthermore, the inclusion of blood perfusion slightly drops the peak temperature. Finally, the inclusion of fat is highly recommended in order to acquire more realistic results from the thermo-electrical models.

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Heat transfer due to electroconvulsive therapy: Influence of anisotropic thermal and electrical skull conductivity

Oliveira

Wen

Ahfock

2016

Computer Methods and Programs in Biomedicine

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Use of electric field orientation as an index for estimating the contribution of model complexity in transcranial direct current stimulation forward head model development

Shahid

Song

Salman

et al. 2015

IET Science, Measurement & Technology

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Feasibility of functional magnetic resonance imaging of ocular dominance and orientation preference in primary visual cortex

et al. 2019

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A recent hemodynamic model is extended and applied to simulate and explore the feasibility of detecting ocular dominance (OD) and orientation preference (OP) columns in primary visual cortex by means of functional magnetic resonance imaging (fMRI). The stimulation entails a short oriented bar stimulus being presented to one eye and mapped to cortical neurons with corresponding OD and OP selectivity. Activated neurons project via patchy connectivity to excite other neurons with similar OP in nearby visual fields located preferentially along the direction of stimulus orientation. The resulting blood oxygen level dependent (BOLD) response is estimated numerically via the model’s spatiotemporal hemodynamic response function. The results are then used to explore the feasibility of detecting spatial OD-OP modulation, either directly measuring BOLD or by using Wiener deconvolution to filter the image and estimate the underlying neural activity. The effect of noise is also considered and it is estimated that direct detection can be robust for fMRI resolution of around 0.5 mm, whereas detection with Wiener deconvolution is possible at a broader range from 0.125 mm to 1 mm resolution. The detection of OD-OP features is strongly dependent on hemodynamic parameters, such as low velocity and high damping reduce response spreads and result in less blurring. The short-bar stimulus that gives the most detectable response is found to occur when neural projections are at 45 relative to the edge of local OD boundaries, which provides a constraint on the OD-OP architecture even when it is not fully resolved.

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Human Head Modelling Simulation Applied to Electroconvulsive Therapy

Oliveira

Song

Ahfock

et al. 2018

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A Preliminary Study of the Impact of Lateral Head Orientations on the Current Distributions During tDCS

Song

Oliveira

Wang

et al. 2019

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Marília Menezes de Oliveira

Bio-heat transfer model of electroconvulsive therapy: Effect of biological properties on induced temperature variation

Heat transfer due to electroconvulsive therapy: Influence of anisotropic thermal and electrical skull conductivity

Use of electric field orientation as an index for estimating the contribution of model complexity in transcranial direct current stimulation forward head model development

Feasibility of functional magnetic resonance imaging of ocular dominance and orientation preference in primary visual cortex

Human Head Modelling Simulation Applied to Electroconvulsive Therapy

A Preliminary Study of the Impact of Lateral Head Orientations on the Current Distributions During tDCS

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