Title :
Effect of fat and muscle tissue conductivity on cortical currents - a tDCS study
Author :
Shahid, Salman ; Wen, Peng ; Ahfock, Tony
Author_Institution :
Fac. of Eng. & Surveying, Univ. of Southern Queensland, Toowoomba, QLD, Australia
Abstract :
Cortical current density distribution induced by tDCS has been assessed using an anatomically accurate high resolution finite element head model. The study examines the influence of low conductive fat tissue and muscle layers on cortical modulation. Comparison between commonly used 5 layers and proposed 7 layers head model has been carried out using statistical matrices (RDM, MAG and CC). Results indicate that fat and muscle tissue have a profound effect on cortical current distribution. These layers reduce the effective volume of scalp, thus leading to a reduction in the preferential current pathways around scalp. These findings support the need of more complex head models so that more accurate estimates can be made on the effects of cortical current stimulation on neurons.
Keywords :
bioelectric phenomena; brain models; electrical conductivity; finite element analysis; medical computing; muscle; neurophysiology; complex head models; cortical current density distribution; cortical current stimulation; cortical modulation; high resolution finite element head model; low conductive fat tissue layer; muscle layers; muscle tissue conductivity; neurons; statistical matrices; tDCS; transcranial direct current stimulation; Heating; Humans; Magnetic resonance imaging; Modulation; Muscles; Scalp; Workstations; cortical modulation; tDCS; tissue conductivity;
Conference_Titel :
Complex Medical Engineering (CME), 2011 IEEE/ICME International Conference on
Conference_Location :
Harbin Heilongjiang
Print_ISBN :
978-1-4244-9323-4
DOI :
10.1109/ICCME.2011.5876735
