The corticospinal excitability influenced by motor imagery and simultaneous electrical stimulation
Abstract
About the Authors
L. V. YakovlevRussian Federation
Department of Human and Animal Physiology, School of Biology
Leninskiye gory 1–12, Moscow, 119234
N. V. Syrov
Russian Federation
Department of Human and Animal Physiology, School of Biology
Leninskiye gory 1–12, Moscow, 119234
E. Y. Morozova
Russian Federation
Department of Human and Animal Physiology, School of Biology
Leninskiye gory 1–12, Moscow, 119234
A. Y. Kaplan
Russian Federation
Department of Human and Animal Physiology, School of Biology; Center for Bioelectric Interfaces
Leninskiye gory 1–12, Moscow, 119234; Myasnitskaya 13–4, Moscow, 101000
References
1. Pfurtscheller G., Neuper C. Motor imagery activates primary sensorimotor area in humans // Neurosci. Lett. 1997. Vol. 239. N 2–3. P. 65–68.
2. Lotze M., Halsband U. Motor imagery // J. Physiol. Paris. 2006. Vol. 99. N. 4–6. P. 386–395.
3. Mizuguchi N., Nakata, H., Uchida, Y., Kanosue, K. Motor imagery and sport performance // Jpn. J. Phys. Fit. Sport. 2012. Vol. 1. N. 1. P. 103–111.
4. Walsh N.E., Jones L., McCabe C.S. The mechanisms and actions of motor imagery within the clinical setting // Textbook of neuromodulation / Eds. H. Knotkova and D. Rasche. N.Y.: Springer, 2015. P. 151–158.
5. Guerra Z.F., Lucchetti A.L.G., Lucchetti G. Motor imagery training after stroke: a systematic review and meta-analysis of randomized controlled trials // J. Neurol. Phys. Ther. 2017. Vol. 41. N 4. P. 205–214.
6. Li R.Q., Li Z.M., Tan J.Y., Chen G.L., Lin W.Y. Effects of motor imagery on walking function and balance in patients after stroke: a quantitative synthesis of randomized controlled trials // Complement. Ther. Clin. 2017. Vol. 28. P. 75–84.
7. Kaplan A.Ya. Neurophysiological foundations and practical realizations of the brain– machine interfaces in the technology in neurological rehabilitation // Human Physiology. 2016. Vol. 42. N 1. P. 103–110.
8. Kaneko F., Hayami T., Aoyama T., Kizuka T. Motor imagery and electrical stimulation reproduce corticospinal excitability at levels similar to voluntary muscle contraction // J. Neuroeng. Rehabil. 2014. Vol. 11. N. 1: 94.
9. Vogt S., Di Rienzo F., Collet C., Collins A., Guillot A. Multiple roles of motor imagery during action observation // Front. Hum. Neurosci. 2013. Vol. 7: 807.
10. Reynolds C., Osuagwu B.A., Vuckovic A. Influence of motor imagination on cortical activation during functional electrical stimulation // Clin. Neurophysiol. 2015. Vol. 126. N 7. P. 1360– 1369.
11. Kurumadani H., Yoshimura M., Fukae A., Onishi K., Hayashi J., Shinomiya R., Sunagawa T. Long-term disuse of the hand affects motor imagery ability in patients with complete brachial plexus palsy // Neuroreport. 2019. Vol. 30. N 6. P. 452– 456.
12. Saito K., Yamaguchi T., Yoshida N., Tanabe S., Kondo K., Sugawara K. Combined effect of motor imagery and peripheral nerve electrical stimulation on the motor cortex // Exp. Brain Res. 2013. Vol. 227. N. 3. P. 333–342.
13. Kaplan A., Vasilyev A., Liburkina S., Yakovlev L. Poor BCI performers still could benefit from motor imagery training // Foundations of augmented cognition: neuroergonomics and operational neuroscience. AC 2016. Lecture Notes in Computer Science, vol. 9743 / Eds. D. Schmorrow and C. Fidopiastis. Cham: Springer, 2016. P. 46–56
14. Vasilyev A., Liburkina S., Yakovlev L., Perepelkina O., Kaplan A. Assessing motor imagery in brain-computer interface training: psychological and neurophysiological correlates // Neuropsychologia. 2017. Vol. 97. P. 56–65.
15. Liburkina S.P., Vasilyev A.N., Yakovlev L.V., Gordleeva S.Y., Kaplan A.Y. A motor imagerybased brain–computer interface with vibrotactile stimuli // Neurosci. Behav. Physiol. 2018. Vol. 48. N 9. P. 1067–1077.
16. Васильев А.Н., Либуркина С.П., Каплан А.Я. Латерализация паттернов ЭЭГ у человека при представлении движений руками в интерфейсе мозг–компьютер // Ж. высш. нервн. деят. им. И.П. Павлова. 2016. Т. 66. № 3. С. 302.
17. Schalk G., McFarland D.J., Hinterberger T., Birbaumer N., Wolpaw J.R. BCI2000: a generalpurpose brain-computer interface (BCI) system // IEEE T. Biomed. Eng. 2004. Vol. 51. N 6. P. 1034–1043.
18. Hashimoto R., Rothwell J.C. Dynamic changes in corticospinal excitability during motor imagery // Exp. Brain Res. 1999. Vol. 125. N 1. P. 75–81.
19. Mokienko O., Chervyakov A., Kulikova S., Bobrov P., Chernikova L., Frolov A., Piradov M. Increased motor cortex excitability during motor imagery in brain-computer interface trained subjects // Front. Comput. Neurosci. 2013. Vol. 7: 168.
Review
For citations:
Yakovlev L.V., Syrov N.V., Morozova E.Y., Kaplan A.Y. The corticospinal excitability influenced by motor imagery and simultaneous electrical stimulation. Vestnik Moskovskogo universiteta. Seriya 16. Biologiya. 2019;74(3):229-235. (In Russ.)