TY - JOUR
T1 - Functional neuronal anisotropy assessed with neuronavigated transcranial magnetic stimulation
AU - Kallioniemi, Elisa
AU - Könönen, Mervi
AU - Säisänen, Laura
AU - Gröhn, Heidi
AU - Julkunen, Petro
N1 - Publisher Copyright:
© 2015 Elsevier B.V..
PY - 2015/12/30
Y1 - 2015/12/30
N2 - Background: Transcranial magnetic stimulation (TMS) can evaluate cortical excitability and integrity of motor pathways via TMS-induced responses. The responses are affected by the orientation of the stimulated neurons with respect to the direction of the TMS-induced electric field. Therefore, besides being a functional imaging tool, TMS may potentially assess the local structural properties. Yet, TMS has not been used for this purpose. New method: A novel principle to evaluate the relation between function and structure of the motor cortex is presented. This functional anisotropy is evaluated by an anisotropy index (AI), based on motor evoked potential amplitudes induced with different TMS coil orientations, i.e. different electric field directions at a cortical target. To compare the AI with anatomical anisotropy in an explorative manner, diffusion tensor imaging-derived fractional anisotropy (FA) was estimated at different depths near the stimulation site. Results: AI correlated inversely with cortical excitability through the TMS-induced electric field at motor threshold level. Further, there was a trend of negative correlation between AI and FA. Comparison with existing methods: None of the existing methods alone can detect the relationship between direct motor cortex activation and local neuronal structure. Conclusions: The AI appears to provide information on the functional neuronal anisotropy of the motor cortex by coupling neurophysiology and neuroanatomy within the stimulated cortical region. The AI could prove useful in the evaluation of neurological disorders and traumas involving concurrent structural and functional changes in the motor cortex. Further studies on patients are needed to confirm the usability of AI.
AB - Background: Transcranial magnetic stimulation (TMS) can evaluate cortical excitability and integrity of motor pathways via TMS-induced responses. The responses are affected by the orientation of the stimulated neurons with respect to the direction of the TMS-induced electric field. Therefore, besides being a functional imaging tool, TMS may potentially assess the local structural properties. Yet, TMS has not been used for this purpose. New method: A novel principle to evaluate the relation between function and structure of the motor cortex is presented. This functional anisotropy is evaluated by an anisotropy index (AI), based on motor evoked potential amplitudes induced with different TMS coil orientations, i.e. different electric field directions at a cortical target. To compare the AI with anatomical anisotropy in an explorative manner, diffusion tensor imaging-derived fractional anisotropy (FA) was estimated at different depths near the stimulation site. Results: AI correlated inversely with cortical excitability through the TMS-induced electric field at motor threshold level. Further, there was a trend of negative correlation between AI and FA. Comparison with existing methods: None of the existing methods alone can detect the relationship between direct motor cortex activation and local neuronal structure. Conclusions: The AI appears to provide information on the functional neuronal anisotropy of the motor cortex by coupling neurophysiology and neuroanatomy within the stimulated cortical region. The AI could prove useful in the evaluation of neurological disorders and traumas involving concurrent structural and functional changes in the motor cortex. Further studies on patients are needed to confirm the usability of AI.
KW - Diffusion tensor imaging
KW - Motor cortex
KW - Motor evoked potential
KW - Neuroanatomy
KW - Neurophysiology
KW - Transcranial magnetic stimulation
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U2 - 10.1016/j.jneumeth.2015.08.028
DO - 10.1016/j.jneumeth.2015.08.028
M3 - Article
C2 - 26335800
AN - SCOPUS:84941312623
SN - 0165-0270
VL - 256
SP - 82
EP - 90
JO - Journal of Neuroscience Methods
JF - Journal of Neuroscience Methods
ER -