Abstract
Transcranial magnetic stimulation (TMS) is a promising, non-invasive approach in the diagnosis and treatment of several neurological conditions. However, the specific results in the cortex of the magnitude and spatial distribution of the secondary electrical field (E-field) resulting from TMS at different stimulation sites/orientations and varied TMS parameters are not clearly understood. The objective of this study is to identify the impact of TMS stimulation site and coil orientation on the induced E-field, including spatial distribution and the volume of activation in the cortex across brain areas, and hence demonstrate the need for customized optimization, using a three-dimensional finite element model (FEM). A considerable difference was noted in E-field values and distribution at different brain areas. We observed that the volume of activated cortex varied from 3000 to 7000 mm3 between the selected nine clinically relevant coil locations. Coil orientation also changed the induced E-field by a maximum of 10%, and we noted the least optimal values at the standard coil orientation pointing to the nose. The volume of gray matter activated varied by 10% on average between stimulation sites in homologous brain areas in the two hemispheres of the brain. This FEM simulation model clearly demonstrates the importance of TMS parameters for optimal results in clinically relevant brain areas. The results show that TMS parameters cannot be interchangeably used between individuals, hemispheres, and brain areas. The focality of the TMS induced E-field along with its optimal magnitude should be considered as critical TMS parameters that should be individually optimized.
Highlights
Transcranial magnetic stimulation (TMS) is used to study brain function by applying localized magnetic fields in a noninvasive manner
Our results indicate that the TMS parameters derived from the motor cortex very likely underestimate both the magnitude and extent of electrical field (E-field) delivered at the dorsolateral prefrontal cortex
Using a 3D, finite element method (FEM) of the standard Montreal Neurological Institute (MNI) brain in the open-source simulation platform, SimNIBS, we demonstrated the importance of TMS parameters of intensity and orientation in clinically relevant brain areas
Summary
Transcranial magnetic stimulation (TMS) is used to study brain function by applying localized magnetic fields in a noninvasive manner. The E-field magnitude and its distribution are influenced by TMS parameters such as the type of coil, its orientation, rate, and intensity and individual parameters such as the columnar organization and the cortical folding pattern at the site of stimulation and interactions between the two types of parameters. These factors have to be taken into consideration to accurately estimate the magnitude and the spatial distribution of the induced E-field [4,5,6,7]. To the best of our knowledge, no prior studies evaluate the volume of activated cortex in correlation to different TMS parameters and determine any relationship between the volume of activation and optimal TMS induced E-field
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