Your search keyword '"Ricardo Salvador"' showing total 5 results

1. High permeability cores to optimize the stimulation of deeply located brain regions using transcranial magnetic stimulation

Author

Ricardo Salvador, Yiftach Roth, Abraham Zangen, and Pedro C. Miranda

Subjects

Quality Control, Materials science, medicine.medical_treatment, Transducers, Stimulation, Models, Biological, Sensitivity and Specificity, Magnetics, Nuclear magnetic resonance, Electric field, Electric Impedance, medicine, Humans, Computer Simulation, Radiology, Nuclear Medicine and imaging, Radiological and Ultrasound Technology, Brain, Reproducibility of Results, Equipment Design, Transcranial Magnetic Stimulation, Finite element method, Computational physics, Equipment Failure Analysis, Transcranial magnetic stimulation, Inductance, Transducer, Permeability (electromagnetism), Electromagnetic coil, Therapy, Computer-Assisted, Computer-Aided Design, Head

Abstract

Efficient stimulation of deeply located brain regions with transcranial magnetic stimulation (TMS) poses many challenges, arising from the fact that the induced field decays rapidly and becomes less focal with depth. We propose a new method to improve the efficiency of TMS of deep brain regions that combines high permeability cores, to increase focality and field intensity, with a coil specifically designed to induce a field that decays slowly with increasing depth. The performance of the proposed design was investigated using the finite element method to determine the total electric field induced by this coil/core arrangement on a realistically shaped homogeneous head model. The calculations show that the inclusion of the cores increases the field's magnitude by as much as 25% while also decreasing the field's decay with depth along specific directions. The focality, as measured by the area where the field's norm is greater than 1/sq.rt.2 of its maximum value, is also improved by as much as 15% with some core arrangements. The coil's inductance is not significantly increased by the cores. These results show that the presence of the cores might make this specially designed coil even more suited for the effective stimulation of deep brain regions.

Published

2009

2. Tissue heterogeneity as a mechanism for localized neural stimulation by applied electric fields

Author

L. Correia, Ricardo Salvador, Peter J. Basser, and Pedro C. Miranda

Subjects

Neurons, Membrane potential, Materials science, Radiological and Ultrasound Technology, medicine.medical_treatment, Models, Neurological, Action Potentials, Context (language use), Stimulation, Depolarization, Electric Stimulation, Transcranial magnetic stimulation, Electromagnetic Fields, Nuclear magnetic resonance, Electromagnetic coil, Electrical resistivity and conductivity, Electric field, Biophysics, medicine, Animals, Humans, Computer Simulation, Radiology, Nuclear Medicine and imaging, Nerve Net

Abstract

We investigate the heterogeneity of electrical conductivity as a new mechanism to stimulate excitable tissues via applied electric fields. In particular, we show that stimulation of axons crossing internal boundaries can occur at boundaries where the electric conductivity of the volume conductor changes abruptly. The effectiveness of this and other stimulation mechanisms was compared by means of models and computer simulations in the context of transcranial magnetic stimulation. While, for a given stimulation intensity, the largest membrane depolarization occurred where an axon terminates or bends sharply in a high electric field region, a slightly smaller membrane depolarization, still sufficient to generate action potentials, also occurred at an internal boundary where the conductivity jumped from 0.143 S m(-1) to 0.333 S m(-1), simulating a white-matter-grey-matter interface. Tissue heterogeneity can also give rise to local electric field gradients that are considerably stronger and more focal than those impressed by the stimulation coil and that can affect the membrane potential, albeit to a lesser extent than the two mechanisms mentioned above. Tissue heterogeneity may play an important role in electric and magnetic 'far-field' stimulation.

Published

2007

3. Temperature control in TTFields therapy of GBM: impact on the duty cycle and tissue temperature.

Author

Nichal Gentilal, Ricardo Salvador, and Pedro Cavaleiro Miranda

Subjects

*BLOOD-brain barrier, *GLIOBLASTOMA multiforme, *CEREBRAL circulation, *TEMPERATURE distribution, *FINITE element method, *BLOOD volume, *TEMPERATURE control, *DUTY

Abstract

In TTFields therapy, Optune® is used to deliver the electric field to the tumor via 4 transducer arrays. This device monitors the temperature of the transducers and reduces the current whenever a transducer reaches 41 °C. Our aim is to quantify Optune’s duty cycle and to predict the steady-state temperature distribution in the head during GBM treatment. We used a realistic head model and the finite element method to solve Pennes equation and to simulate how Optune operates considering that current reduces to zero when the thermal limit is reached. The thermal impact was evaluated considering the maximum temperature reached by each tissue and using the CEM 43 °C metric. We observed that Optune switches the current on and off intermittently. In our model, one transducer reached the temperature limit quicker than the others and consequently it was the one that controlled current injection. This led to different duty cycles for the anterior–posterior and left–right array pairs. The thermal analysis indicated that the highest temperature in the model, 41.7 °C, was reached on the scalp under a transducer. However, TTFields may lead to significant changes only at the brain level such as BBB permeability increase, cerebral blood flow variation and changes in the concentration of some neurotransmitters. The duty cycle may be increased, e.g. by controlling the current at the transducer level. These predictions should be validated by comparison with experimental data and reconciled with the lack of evidence of thermal impact in clinical trials. [ABSTRACT FROM AUTHOR]

Published

2019

4. Transcutaneous spinal direct current stimulation of the lumbar and sacral spinal cord: a modelling study.

Author

Sofia R Fernandes, Ricardo Salvador, Cornelia Wenger, Mamede de Carvalho, and Pedro C Miranda

Published

2018

5. The electric field distribution in the brain during TTFields therapy and its dependence on tissue dielectric properties and anatomy: a computational study.

Author

Cornelia Wenger, Ricardo Salvador, Peter J Basser, and Pedro C Miranda

Subjects

*GLIOBLASTOMA multiforme, *TUMOR treatment, *ELECTRIC fields, *BRAIN diseases, *DIELECTRIC properties

Abstract

Tumor treating fields (TTFields) are a non-invasive, anti-mitotic and approved treatment for recurrent glioblastoma multiforme (GBM) patients. In vitro studies have shown that inhibition of cell division in glioma is achieved when the applied alternating electric field has a frequency in the range of 200 kHz and an amplitude of 1–3 V cm−1. Our aim is to calculate the electric field distribution in the brain during TTFields therapy and to investigate the dependence of these predictions on the heterogeneous, anisotropic dielectric properties used in the computational model.A realistic head model was developed by segmenting MR images and by incorporating anisotropic conductivity values for the brain tissues. The finite element method (FEM) was used to solve for the electric potential within a volume mesh that consisted of the head tissues, a virtual lesion with an active tumour shell surrounding a necrotic core, and the transducer arrays.The induced electric field distribution is highly non-uniform. Average field strength values are slightly higher in the tumour when incorporating anisotropy, by about 10% or less. A sensitivity analysis with respect to the conductivity and permittivity of head tissues shows a variation in field strength of less than 42% in brain parenchyma and in the tumour, for values within the ranges reported in the literature. Comparing results to a previously developed head model suggests significant inter-subject variability.This modelling study predicts that during treatment with TTFields the electric field in the tumour exceeds 1 V cm−1, independent of modelling assumptions. In the future, computational models may be useful to optimize delivery of TTFields. [ABSTRACT FROM AUTHOR]

Published

2015