The “Exo hand-2” complex in the rehabilitation of the upper limb in cerebral palsy using the non-invasive interface “brain-computer”

Improving the function of the upper limb in cerebral palsy is one of the main tasks of rehabilitation treatment and socialization of the patient.

The purpose of the study was to evaluate the effectiveness of the “Exo hand-2” complex with the non-invasive interface “brain-computer” for correcting the motor function of the upper limb in cerebral palsy.

The study involved 50 male and female with cerebral palsy (main group n = 30, control group n = 20) aged 12–18 years old. The level of motor activity according to the criteria of classification of large motor functions (GMFCS) was not more than III. All patients received a standard course of spa rehabilitation for 21 days. Patients of the main group were additionally rehabilitated using the “Exo hand-2” complex with the non-invasive interface “brain-computer”. As a result of treatment in the main group, spasticity in the paretic hand on the Modified Ashworth Scale decreased from 3 (2; 3) to 2 (1; 2) points (p <0.002); according to Tardieu, spasticity decreased from the level of 3 (2; 3) to 2 (1; 2) (p <0.002). Half of the patients had paretic arm muscle strength in the Medical Research Counsil Weakness Scale sums core from 2.3 (2; 3) to 3 (2; 3) points after treatment (p = 0.002); assessment of household skills on the Modified Franchay Scale showed an improvement from 37 (22.75; 63.75) to 45 (30; 72.75) points after therapy.

1. Batysheva T.T., Krapivkin A.I., Tsaregorodtsev A.D. et al. Rehabilitation of children with damage to the central nervous system. Rossiyskiy vestnik perinatologii i pediatrii = Russian bulletin of perinatology and Pediatrics 2017;62(6):7–15. (In Russ.). DOI: 10.21508/1027-4065-2017-62-6-7-15.

2. Semenova K.A., Mastyu kova E.M., Smuglin M.Ya. Clinic and rehabilitation therapy for cerebral palsy. Moscow: Medicine, 1972. 328 p. (In Russ.).

3. Dan B., Mayston M., Paneth N., Rosenbloom L. Cerebral palsy: science and clinical practice. London: Mac Keith Press, 2014. 692 р.

4. Kurenkov A.L., Batysheva T.T., Vinogradov A.V., Zyuzyaeva E.K. Spasticity in cerebral palsy: diagnosis and treatment strategies. Zhurnal nevrologii i psikhiriatrii = Journal of neurology and psychiatry 2012;7(2):24–8. (In Russ.).

5. Damulin I.V., Ekusheva E.V. The processes of neuroplasticity after a stroke. Nevrologiya, psikhiatriya, psikhosomatika = Neurology, neuropsychiatry, psychosomatics 2014;3:69–74. (In Russ.).

6. Neuper C., Scherer R., Reiner M., Pfurtscheller G. Imagery of motor actions: differential effects of kinesthetic and visualmotor mode of imagery in singletrial EEG. Cogn Brain Res 2005;25(3):668. PMID: 16236487. DOI: 10.1016/j.cogbrainres.2005.08.014.

7. Dimyan M.A., Cohen L.G. Neuroplasticity in the context of motor rehabilitation after stroke. Nature Reviews Neurology 2011;7(2):76–85. PMID: 21243015. DOI: 10.1038/nrneurol.2010.200.

8. Mokienko O.A., Lyukmanov R.Kh., Chernikova L.A. et al. Brain-computer interface: first experience in clinical practice in Russia. Fiziologiya cheloveka = Human physiology 2016;42(1):31–9. (In Russ.).

9. Monge-Pereira E., Ibañez-Pereda J., Alguacil-Diego I.M. et al. Use of Electroencephalography braincomputer interface systems as a rehabilitative approach for upper limb function after a stroke: a systematic review. PM and R 2017;9(9):918–32. PMID: 28512066. DOI: 10.1016/j.pmrj.2017.04.016.

10. Stavsky М., Mor О., Mastrolia S.А. et al. Cerebral palsy – trends in epidemiology and recent development in prenatal mechanisms of disease, treatment, and prevention. Front Pediatr 2017;5:21. PMID: 28243583. DOI: 10.3389/fped.2017.00021.

11. Graham H.K., Rosenbaum P., Paneth N. et al. Cerebral palsy. Nat Rev Dis Primers 2016;2:15082. PMID: 27188686. DOI: 10.1038/nrdp.2015.82.

12. Bulekbaeva Sh.A., Daribaev J.R., Rizvanova A.R. et al. Features of robotic kinesitherapy in children with cerebral palsy in preschool age. Cerebral palsy and other movement disorders in children: proceedings of the III Interdisciplinary Scientific and Practical Conference with international participation, October 31 – November 1, 2013, Moscow. P. 18–19. (In Russ.).

13. Tkachenko E.S., Goleva O.P., Scherbakov D.V., Halikova A.R. Cerebral palsy: a state of knowledge of the problem(review). Mat’ i ditya v Kuzbasse = Mother and child in Kuzbass 2019;2:4–9. (In Russ.).

14. Levchenkova V.D., Batysheva T.T., Matveeva I.A., Semenova K.A. Pathogenetic basis for the treatment of patients with cerebral palsy. Cerebral palsy and other movement disorders in children: proceedings of the III Interdisciplinary Scientific and Practical Conference with international participation, October 31 – November 1, 2013, Moscow. P. 55–56. (In Russ.).

15. Petukhova M.L., Nikitin S.E. The optimal model of orthopedic care and prevention of deformations of the segments of the musculoskeletal system in children with CP. Cerebral palsy and other movement disorders in children: proceedings of the III Interdisciplinary Scientific and Practical Conference with international participation, October 31 – November 1, 2013, Moscow. P. 71. (In Russ.).

16. Potapova G.V. Diagnosis and correction of motor development disorders in children with Little disease from the position of systemogenesis. Cerebral palsy and other movement disorders in children: proceedings of the III Interdisciplinary Scientific and Practical Conference with international participation, October 31 – November 1, 2013, Moscow. P. 75–76. (In Russ.).

17. McGinley J.L., Dobson F., Ganeshalingam R. et al. Single-event multilevel surgery for children with cerebral palsy: a systematic review. Dev Med Child Neurol 2012;54(2):117–28. PMID: 22111994. DOI: 10.1111/j.1469-8749.2011.04143.x.