Title: Dimitar Stefanov
1Lecture 16
2Functional Neural Stimulation for Movement
Restoration (FNS)
FNS activation of skeletal muscles in attempts
to restore useful movement in upper and lower
extremities of people with impairments of the
central nervous system.
1./ Unimpaired pathways to the muscle fibers
Muscle fibers
excitation an electrical stimulus
32./ Impaired pathways to the muscle fibers
Electric source
Muscle fibers
- Examples of the FES
- Cardiac pace makers
- Moe and Post (1962) first application of the
FES as a functional orthosis
FES solution of the problem of restoring of the
human locomotion and manipulation.
Best results among people with incomplete
paraplegia and people, moderately affected with
hemiplegia.
- Best results to restoration of the grip and
release functions. - Successful FES control of two type grasping
lateral prehension (e.g. key grip) and palmar
grip (e.g. three-jaw pinch). - Elbow extension control people with C4 lesions
- Incensement of the movement range people with
C5/C6 lesions.
4- Three techniques for FES
- Surface stimulators - electrodes, placed on the
skin surface over the muscle or nerve to be
stimulated (transcutaneous electrodes) - Percutaneous stimulators permanently implanted
electrodes with wires chronically penetrating the
skin which connect to to an external pulse
generator (intramuscular electrodes or
percutaneous electrodes) - Implantable stimulators
- both the electrodes and the biocompatible
enclosure are permanently implanted in the body,
near the excitable tissue. - A transmitting antenna on the skin surface
delivers power and information to the multiple
simulation sites. - Excitation with minimal energy activation of
deep located muscle and nerve tissues.
5- Stimulation with transcutaneous electrodes
- Widely used (no surgical intervention is
required) - Poor selectivelity and reachibility of deep
located muscles - Great values of the stimulation voltage is
required.
Example for an implantable multichannel FNS system
- Functions of the wearable processor
- Processing of biomechanical parameters (joint
angles, foot contact) - Generation of control signals
- Maintain joint force against the muscle fatigue.
6- Problems, which should be solved for efficient
gait - Choice of simulation patterns and voltages
- Development of stimulus for full knee extension
during certain phases of the gait cycle - Coordinated control and graded contraction of
different muscle groups.
Selective simulation of nerve fibers
- Special electrodes for selective stimulation
- Tension control through starting with the slowest
to the fastest twitch motor units - More physiologically based control
- Very useful solution in case of upper-limb FES.
7Electrode for selective stimulation. The tube is
placed around a motor nerve.
Slow twitch motor units provide less tension than
fast twitch motor units but they do not fatigue
as rapidly.
Unimpaired motor control Slow twitch fibers are
recruited in activities which require low forces
fast twitch fibers are recruited for activities
requiring high speed and/or high force. Slow
twitch fibers are recruited for frequently
occurring activities which require low forces.
8- FES strategy for efficient gait restoration with
electrodes for selective stimulation (example) - Slow twitch fibers could be recruited to maintain
the postural stability during standing - Fast twitch fibers could be used for joint
movements (to initiate and generate steps).
- FES strategy for efficient upper limb movement
with electrodes for selective stimulation
(example) - Slow twitch fibers could be recruited to maintain
the postural stability of the upper limb - Fast twitch fibers could be used for object
lifting.
9Response of the locomotor system to the FES
Individual character (black box)
Methods for parameters identification
A./ gripping force/electrical stimulus
10B./ Elbow flexion force/FES
C./ Experimental parameterization of lower
extremity for FES control
11Development of the strategies for FES based on
the modeling of the anatomical structure and
location of muscles and tendons
Knowing the location of the stimulated muscles
and the average force, produced during their
stimulation, an efficient FES strategy can be
developed.
(a) Anatomical location of the muscle to be
stimulated (b) Simple model of the Rectus
femoris muscle (c) mechanical model of the
Rectus femoris muscle.
12Some research institutions where significant FES
research results are achieved
University and Medical Center in Ljubljana,
Slovenia peritoneal nerve stimulators, applied
to over 2500 people gait simulators (four
channels), applied to over 100 people with spinal
cord injuries Case Western Reserve University,
the Cleveland Metro Health Center, and Cleveland
Veterans Affairs Medical Center development of
peritoneal and implanted systems for functional
grasp, applied to 50 people with
quadriplegia Cleveland Metro Health Center and
Cleveland Veterans Affairs Medical Center
complex gait for about 30 people with paraplegia.
13Description of the FNS signal
Pulse repetition rate (frequency) pulse width
(duration), amplitude.
Stimulus strength is related to the charge
density.
charge density current time/area
range of 10-300 mC cm2
The current of the FNS depends on the proximity
of the electrodes to the target muscle
tissue. Typically 1-50 mA.
14- Pulsed waveform
- Monophasic or biphasic pulses
- Burst (carrier) signal reduction of the
potential pain - Sufficient current in the target area for a
length of time (100 600 mS) - Pulse amplitude depends on the size of the
electrode and the degree of current spread
between the electrode and targets.
- Current generator
- Produce regulated current between 0 and 60 mA
- Voltage from 0 to 180 V
- Maximum 50 pulses per second to prevent the fast
fatigue - Low duty-cycle to maintain the charge balance
and to minimize the risk of tissue damage
Optimal stimulation of the concrete muscle group
very important condition for successful FNS.
Requires knowledge of the response of each
muscle to stimulation and knowledge of the muscle
fatigue.
15- Systems for FNS
- Open loop control time pattern stimulation.
Sensitive to external disturbances, the muscle
fatigue cannot be considered. - Closed loop control (non-linear and adaptive
controllers fuzzy-controllers). - Problems
- It is difficult to be obtained meaningful
physiological feedback from the stimulated
muscle-joint system time delay between the
stimulation and force production nonlinear
characteristics between the muscle length and the
muscle force. - It is difficult to be found precise model of the
muscle recruitment for the concrete patient.
Increased burst time is applied in case of muscle
fatigue.
16Block diagram of FNS model
The time delay between muscle stimulation and
muscle activation is called the neural dynamics.
Non-linear relationship between input activation
and generated joint torque (depends on the joint
angle, the joint velocity and acceleration).
Limb dynamics depends on the mass and inertia
characteristics of the limb.