Upper and Lower Motoneuron Lesions in Tetraplegia - Diagnostic and Therapeutic Implications of Electrical Stimulation
Abstract
The overall objective of this thesis was to improve outcomes and predictability of the treatment of upper extremity function in patients with cervical spinal cord injury and tetraplegia by advancing the diagnostic and therapeutic tools employed in upper and lower motor neuron lesions. An overview is presented of the current knowledge about the principles of electrical stimulation and its usefulness and proven effects on the upper limb. Initially a technique was developed to map the topographic distribution of the motor points of extensor and flexor forearm muscles in able-persons. The mapping system for selected muscles on the dorsal and palmar aspect of the forearm led to remarkable findings when electrical stimulation was applied to patients with cervical spinal cord injuries. One of the main findings was that flexors are noticeably more often denervated than extensors due to lower motoneuron lesions. The findings may explain the clinical observation of better functional outcome after surgical nerve transfer to extensors compared to relatively disappointing results after nerve transfer to the flexors. The continuation of the research project was an interventional study to investigate the possibility to increase the thickness and to influence the structure in denervated forearm and hand muscles by direct electrical muscle stimulation. The case series report showed that this was possible. A reasonable interpretation is that the viability of the motor end-plate pool can be maintained through direct electrical muscle stimulation and that it is likely that an early onset of stimulation improves the conditions for successful reinnervation after nerve transfer. In addition, the time between spinal cord injury and nerve transfer may be prolonged without impairing the outcome. In order to identify the effect of electrical stimulation on neuromodulation it was analysed how robotic-controlled exercises combined with functional electrical stimulation could increase the voluntary strength of movements in people with spinal cord injury. The only available system for robotically controlled training is adapted to the lower limbs and therefore this study was performed on the lower extremities. The combination of electrical stimulation and robot-controlled, voluntary initiated training increased the recruitment of motor units and muscle strength in the legs.
Parts of work
Bersch I, Fridén J.
Role of functional electrical stimulation in tetraplegia hand surgery
Archives of Physical Medicine and Rehabilitation 2016;97(6 Suppl 2):S154-9
::DOI::10.1016/j.apmr.2016.01.035 Bersch I, Koch-Borner S, Fridén J.
Electrical stimulation - a mapping system for hand dysfunction in tetraplegia
Spinal Cord. 2018 May;56(5):516-522
::DOI::10.1038/s41393-017-0042-2 Bersch I, Koch-Borner S, Fridén J.
Motor point topography of fundamental grip actuators in tetraplegia
- implications in nerve transfer surgery
Journal of Neurotrauma. 2019 Jun 25. ::DOI::10.1089/neu.2019.6444 Bersch I, Fridén J.
Electrical stimulation of denervated upper limb muscles
- effect on muscle morphological properties - a case series report
Manuscript Bersch I, Koch-Borner S, Brust AK, Fridén J, Frotzler A.
Robot assisted training in combination with functional electrical stimulation for improving lower limb function after spinal cord injury
Accepted for publication in Artificial Organs
Degree
Doctor of Philosophy (Medicine)
University
University of Gothenburg. Sahlgrenska Academy
Institution
Institute of Clinical Sciences. Department of Orthopaedics
Disputation
Fredagen den 25 oktober 2019, kl. 13.00, Aulan, R-huset, Sahlgrenska Universitetssjukhus/Mölndals sjukhus, Mölndal
Date of defence
2019-10-25
inulf.bersch@bluewin.ch
inesbersch@gmail.com
Date
2019-09-25Author
Bersch, Ines
Keywords
Electrical stimulation, Tetraplegia
Upper motoneuron lesion
Lower motoneuron lesion
Motor point topography
Nerve transfer
Publication type
Doctoral thesis
ISBN
978-91-7833-408-7 (print)
978-91-7833-409-4 (pdf)
Language
eng