The use of electrical stimulation for denervated muscles is still considere
d to be a controversial issue by many rehabilitation facilities and medical
professionals because prior clinical experience has shown that treating de
nervated muscle tissue using exponential current over a long time period co
nstitutes an impossible task. Despite this fact, we managed to evoke tetani
c contractions in denervated muscle using a long duration stimulation with
anatomically shaped electrodes and sufficiently high amplitudes. The pulse
amplitudes, which were being used for this purpose, exceeded by far the MED
-GV and EC regulations (300 mJ/impulse). For this reason, an application ha
s recently been submitted to have the EC regulations changed accordingly. I
t takes a tetanic contraction to achieve the desired muscle fiber tension,
constituting a hypertrophic stimulus. It is also an appropriate means of ex
ercise, which is capable of creating the metabolic and structural condition
s needed (e.g, increased mitochondrial volume and capillary density) to obt
ain satisfactory muscle performance. With patients suffering from a complet
e spinal cord injury at level D12/L1, having motor and sensory loss in both
lower extremities, we were able to train denervated muscle using long-dura
tion stimulation, evoking single muscle contractions at first, soon followe
d by tetanic contractions against gravity. To increase the efficacy of this
functional electrical stimulation (FES) strengthening program, we used ank
le weights. With daily FES training over a period of 1-2 years, denervated
muscle was exercised until it produced torques between 16 and 38 Nm in the
m. quadriceps. With that muscle force, it is possible to stand up from a si
tting position in parallel bars. Our results show that denervated muscle in
humans is indeed trainable and can perform functional activities with FES.
Furthermore, this method of stimulation can assist in decubitus prevention
and significantly improve the mobility of paraplegics.