Using TMS to Measure Motor Excitability During Action Observation

Overview

Source: Laboratories of Jonas T. Kaplan and Sarah I. Gimbel—University of Southern California

Transcranial Magnetic Stimulation (TMS) is a non-invasive brain stimulation technique that involves passing current through an insulated coil placed against the scalp. A brief magnetic field is created by current in the coil, and because of the physical process of induction, this leads to a current in the nearby neural tissue. Depending on the duration, frequency, and magnitude of these magnetic pulses, the underlying neural circuitry can be affected in many different ways. Here, we demonstrate the technique of single-pulse TMS, in which one brief magnetic pulse is used to stimulate the neocortex.

One observable effect of TMS is that it can produce muscle twitches when applied over the motor cortex. Due to the somatotopic organization of the motor cortex, different muscles can be targeted depending on the precise placement of the coil. The electrical signals that cause these muscle twitches, called motor evoked potentials, or MEPs, can be recorded and quantified by electrodes placed on the skin over the targeted muscle. The amplitude of MEPs can be interpreted to reflect the underlying excitability of the motor cortex; for example, when the motor cortex is activated, observed MEPs are larger.

In this experiment, based on a study originally performed by Fadiga and colleagues¹ and since replicated by many others,² we use single-pulse TMS to test the excitability of motor cortex during action observation. It is known that motor cortex can be activated not only when we move, but when we watch others perform movements. A common interpretation of this phenomenon is that it reflects a simulation process that may play a role in the understanding of others' actions. Here we will record MEPs evoked by TMS over the primary motor cortex while subjects observe the movements of others compared with control stimuli.

Procedure

1. Recruit 20 participants.

Participants should be right-handed and have no history of neurological or psychological disorders.
Participants should have normal or corrected-to-normal vision to ensure that they will be able to see the visual stimuli properly.

2. Pre-experiment procedures

Obtain written consent from the participant and explain what is involved in the experiment.
Explain that the participant will watch a series of short videos wh

Results

A comparison of MEP amplitudes reveals a facilitation effect (Figure 1). MEP amplitude recorded from the FDI muscle is significantly greater during the hand action videos compared with control videos. This result suggests that the motor cortex increases in excitability during action observation.

Figure 1: MEP amplitude duri

Application and Summary

The single-pulse TMS technique lends itself well to the study of the motor cortex, both because of the accessible location of this cortex on the frontal surface of the brain, and also because of the directly observable reaction produced in the muscle in the form of MEPs. The measurement of cortico-spinal motor excitability has provided support further for the phenomenon of motor simulation during action observation in humans. This resonant motor activity may have implications for social behavior, for example in contribut

References

Fadiga, L., Fogassi, L., Pavesi, G. & Rizzolatti, G. Motor facilitation during action observation: a magnetic stimulation study. J Neurophysiol 73, 2608-2611 (1995).
Fadiga, L., Craighero, L. & Olivier, E. Human motor cortex excitability during the perception of others' action. Curr Opin Neurobiol 15, 213-218 (2005).
Gangitano, M., Mottaghy, F.M. & Pascual-Leone, A. Phase-specific modulation of cortical motor output during movement observation. Neuroreport 12, 1489-1492 (2001).
Wright, D.J., Williams, J. & Holmes, P.S. Combined action observation and imagery facilitates corticospinal excitability. Front Hum Neurosci 8, 951 (2014).
Aglioti, S.M., Cesari, P., Romani, M. & Urgesi, C. Action anticipation and motor resonance in elite basketball players. Nat Neurosci 11, 1109-1116 (2008).
Koski, L., Lin, J.C., Wu, A.D. & Winstein, C.J. Reliability of intracortical and corticomotor excitability estimates obtained from the upper extremities in chronic stroke. Neurosci Res 58, 19-31 (2007).