Add to ORKGIn brain imaging, the accuracy involved in calculating scalp potentials due to cerebral electric sources depends on the realism of the head model. Existing methods assume homogeneous conductivity throughout each component tissue. This assumption introduces inaccuracies in computing the potentials. This paper proposes a new approach based on the use of pseudo-conductivity values in place of the uniform conductivity values assigned to tissues. Simulation results reveal that the conductivity values have a significant effect on the computed potentials, thereby invalidating the uniform conductivity assumption
Abstract Background The structure of the anatomical surfaces, e.g., CSF and gray and white matter, c...
Transcranial current stimulation (tCS) is a non-invasive brain stimulation technique based ...
Electromagnetic source characterisation requires accurate volume conductor models representing head ...
In brain imaging, the accuracy involved in calculating scalp potentials due to cerebral electric sou...
Human head models for the forward computation of EEG using FEM require a large set of elements to re...
Engineering in Medicine and Biology and Biomedical Engineering SocietyTwo issues relating to the mod...
The aim of the study is to testify the effects of different inhomogeneous tissues on computed electr...
The electroencephalogram (EEG) is a measurement of neuronal activity inside the brain over a period ...
Monitoring the electrical activity inside the human brain using electrical and magnetic field measur...
International audienceThe skull conductivity strongly influences the accuracy of EEG source localiza...
Areas of activity within the human brain can result from a variety of external stimuli. This pape...
International audienceBioelectric source analysis in the human brain from scalp electroencephalograp...
Electroencephalography (EEG) benefits from accurate head models. Dipole source modelling errors can ...
The function and structure of the human brain is immensely complex and, at the same time, the key to...
Most of the human head models used in dipole localisation research, which have been reported in the ...
Abstract Background The structure of the anatomical surfaces, e.g., CSF and gray and white matter, c...
Transcranial current stimulation (tCS) is a non-invasive brain stimulation technique based ...
Electromagnetic source characterisation requires accurate volume conductor models representing head ...
In brain imaging, the accuracy involved in calculating scalp potentials due to cerebral electric sou...
Human head models for the forward computation of EEG using FEM require a large set of elements to re...
Engineering in Medicine and Biology and Biomedical Engineering SocietyTwo issues relating to the mod...
The aim of the study is to testify the effects of different inhomogeneous tissues on computed electr...
The electroencephalogram (EEG) is a measurement of neuronal activity inside the brain over a period ...
Monitoring the electrical activity inside the human brain using electrical and magnetic field measur...
International audienceThe skull conductivity strongly influences the accuracy of EEG source localiza...
Areas of activity within the human brain can result from a variety of external stimuli. This pape...
International audienceBioelectric source analysis in the human brain from scalp electroencephalograp...
Electroencephalography (EEG) benefits from accurate head models. Dipole source modelling errors can ...
The function and structure of the human brain is immensely complex and, at the same time, the key to...
Most of the human head models used in dipole localisation research, which have been reported in the ...
Abstract Background The structure of the anatomical surfaces, e.g., CSF and gray and white matter, c...
Transcranial current stimulation (tCS) is a non-invasive brain stimulation technique based ...
Electromagnetic source characterisation requires accurate volume conductor models representing head ...