Upper Limb Prostheses PDF

Summary

This document provides an overview of upper limb prostheses, covering various types, components, and considerations for amputees.  It discusses cosmetic and functional prostheses, body-powered and myoelectric systems, as well as fitting and training techniques.

Full Transcript

Upper limb prostheses
Types Upper Limb Prostheses

Cosmetic Functional

Body Externally
Hybrid
powered powered

Myoelectric

Switch
control
Cosmetic prostheses
They are usually constructed of light weight plastics, and are designed
to match the color and shape of the patients intact hand.
Disadvantages
More difficult to keep clean
Usually expensive
Sacrifice some function for the increase the cosmetic appearance.
Functional prostheses
 I.Body power prostheses:(cable controlled)

The prosthetic is powered
through the tension of a cable,
where the tension is generated
through the mechanical
transmission of muscular
effort generated elsewhere in
the body, remote from the
amputation site.
 Components of
body powered prothesis
Terminal Cosmetic Control-
Units Socket Suspension
device gloves cable
system
Wrist

Elbow

Shoulder
 Terminal device

Active
Passive
(prehensor)

Voluntary Functional Cosmetic
opening

voluntary
Child mitt
closing

Ball handle

Child mitt Ball handle
Terminal devices:
1) Passive
Has no moving part, cables or batteries for operation
Eg: children's mittens
2) Active or Prehensors
Offer active grasp, based on how they work: it can be
classified into
A. Voluntary-opening: At rest held closed by a spring
or rubber band and opens when the control cable is
pulled.
B. Voluntary-closing : Devices operate in a converse
manner. This type of mechanism usually is heavier
and less durable than a voluntary opening
mechanism.
 Voluntary-closing
Voluntary-opening
prehensor terminal
Hook terminal device
device
 2. Cosmetic gloves
A rubberized covering that determines the external
appearance of the prosthesis.
Applied over the shell of a passive hand or over the
mechanism of an active prehensor
Can be replaced when it deteriorates from use
 3) Units

A. Wrist units
Prosthetic wrist units have two basic functions:
1. Attach the terminal device to the forearm of the prosthesis
2. Permit pre-positioning of the terminal device before operation (to
substitute supination and pronation).
N.B
Above elbow transhumeral amputee has lost all ability to
supinate and pronate the prosthetic forearm.
Transradial amputee with a short residual forearm no longer
retains active transmissible supination and pronation.
 Types
1. Friction wrist units
Commercially available wrist units permit the amputee
to substitute for supination and pronation by
manually rotating the terminal devices with the
remaining normal hand.
2. Quick change wrist unit

Designed to facilitate rapid interchange of different terminal
devices (usually a hook and hand).
It permit the amputee to do the followings:
Remove the terminal device from the wrist unit
Replace the terminal device with different terminal
device
Manually position the terminal device in supination and
pronation and lock the terminal device in supination or
pronation.
3. Wrist flexion unit:
→Provide wrist flexion
→Requires pressing a button to allow moving the
wrist joint
It can provide an amputee, especially a bilateral
upper limb amputee, with improved function for
midline activities (shaving, manipulating
buttons).It usually is employed on only one side,
most often the longer of the two residual limbs.
 4. Electric wrist

Electric wrist rotator
B. Elbow units
Below elbow amputation
*Flexible hinge: suitable for long below elbow
amputation, allows transmission of the residual forearm
supination and pronation to the terminal device.
*Rigid hinge: in case of short below elbow or above
elbow amputation, supination and pronation is no long
available. It must be associated with rotatable wrist unit
to allow positioning of the terminal device
Above elbow amputation

*Body-powered elbows, controlled by the same cable that
operates the terminal device with an additional attachment
or button that operates elbow lock.
When elbow is unlocked, pulling on the cable will flex the
elbow.
When the elbow is locked or fully flexed, pulling on the
cable will operate the Terminal device.
*Electronic powered elbows: Elbow lock is operated
electronically.
 C. Shoulder units
Bulkhead

The simplest

Allow no motion at the shoulder

Passive shoulder

Can be positioned passively

Further classified into single axis units permit only abduction

Double axis units allow abduction and flexion
Sockets
an important connection between the individual and prosthesis
Enable optimum ROM of the remaining anatomic joints
resist torques and forces that act to twist or move the prosthesis relative to the
residual limb.
Protect the skin of the residual limb
The socket should also be a rigid platform for distal components, such as the
forearm and terminal device.
The socket should be designed to be able to distribute the pressure so that it
doesn’t add overpressure to fragile tissues.
 The primary interface between the residual limb and prosthetic socket is
one of the following methods:

Skin-fit
The skin may contact the inside of the socket directly.
This method offers the most direct control of the prosthetic limb
Suitable for myoelectric prosthetics to receive electrical signals from the
underlying muscles.
The limitation is potentially exposing the skin to areas of high pressures and
sheering forces.
Prosthetic sock,
socks provide an easy method to don the socket and provide some cushioning
between the skin and the socket.
However, this method requires additional means to suspend the socket, normally
through the harness of a body-powered control system.
Silicone liner.
rolled onto the residual limb and inserted into the socket.
Silicone liners may be prefabricated or custom-made for the individual and offer a
superior way to protect the skin (especially for those with skin grafts or fragile
skin)
 4) Suspension

Harnessed- Self-suspending Suction
based systems sockets sockets
A) Harnessed-based
systems

Transradial
*Axillary loop: serves as the primary anchor
from which two other straps originates. It
encircles the shoulder girdle on the
nonamputated side.
*Anterior support strap: or inverted Y
shape suspensor. It originates at the axilla
loop passes over the shoulder on the
amputated side and is attached to the anterio-
proximal margins of the triceps pad of the
prosthesis. which in turn supports the socket
through the flexible elbow hinges
The primary function of this strap is to resist
displacement of the socket on the residual
limb when the prosthesis is subjected to
heavy loading.
The control attachment strap: originates at the axilla loop and
terminates at the proximal end of prosthetic control cable.
it acts as an extension of the control cable.
Its position is between the spine and the inferior angle of scapula; it
permits the use of scapular abduction and shoulder flexion to operate
the terminal device.
The posterior junction of the axilla loop with the anterior support and
the control attachment straps can be sewn together or connected by a
stainless steel ring which is called O-ring is formed stainless steel
which allow alternation of the length of strap.
transhumeral
Like the standard transradial harness, the transhumeral
harness consists of
→Axilla loop,
→Anterior support strap,
→Lateral support strap,
→Control attachment strap
→Elbow lock control strap
5-Control-cable system
Cable is firmly attached
at its proximal end to the
straps of the harness.
Distally, it terminates at
the terminal device
Control-cable system
Transradial control system: a one-cable or "single-
control" system which allow perhension movement
and grasping.

Transhumeral control system : operated by two
distinctly separate cables.
→One serves to flex the prosthetic elbow joint and to
operate the terminal device.
→ A second cable permits locking and unlocking the
prosthetic elbow.
 Two cables systems

Cable responsible
for locking and
unlocking elbow
Cable
responsible to
flex elbow and Cable
close terminal responsible to
flex elbow and
device
close terminal
device
Cable responsible
for locking and
unlocking elbow
In standard transradial harness the single cable
originated proximally from the straps , and inserted distally
in the terminal device, the patient use body movement to
produce tension on the cable and allow movement of the
terminal device:
Common body movement
1: shoulder flexion for open the terminal device and back
to neutral to the relaxed position closes the device..
2: Scapular abduction →open terminal device , scapular
adduction → close terminal device.
In standard transhumeral harness:
Dual cable movement:
→One cable serves to flex the prosthetic elbow joint and operate the
terminal device.
→A second cable permits the amputee to lock and unlock the
prosthetic elbow.
The elbow flexion/terminal device control cable
Originates at the control attachment strap of the harness. Passing
through the proximal portion of the split housing, the control cable
is anterior to the mechanical elbow axis so it flex the elbow joint
The housing through which the elbow flexion/terminal device cable
passes is split into two separate parts,
The proximal portion of the split housing is attached to the posterior
surface of the humeral section of the prosthesis (cross bar
assembly).
The distal portion of the split housing is fixed to the prosthetic
forearm by a device called an “Elbow flexion attachment.
The elbow flexion/terminal device control cable continues through
the distal portion of the split housing and terminates with its
attachment at the terminal device,
The flexion is limited to the gap between the two cable
housings. The ease with which the amputee can operate the
elbow unit and terminal device depends on the location of
the elbow flexion attachment.
Greater force and less cable excursion are required
when: The elbow flexion attachment is closest to the
elbow axis.

Conversely, A more distal placement of the attachment
requires less force but greater cable excursion.
2) Elbow lock control cable:

The proximal end of the elbow lock control cable
originates at:
→The anterior suspension strap,
→Passing down the anteromedial surface of the humeral
section of the prosthesis,
→The distal end of the cable engages the elbow locking
mechanism. The elbow lock works on an alternator
principle: pull and release to lock, pull and release to
unlock.
B) self-suspending and suction sockets

Capable of providing adequate prosthetic suspension without the
use of a harness.
However, either design can also be used with a harness
suspension to provide for a more secure suspension of the
prosthesis.
Self-suspending sockets are largely limited to wrist or elbow
disarticulations and to transradial amputations.
Advantages and disadvantage of body power
prostheses:
Advantages:
Durable and simple
Positional and control awareness through proprioception.
Can operate in wet, dirty or dusty environments.
Low cost and light weight
Disadvantages:
Bad cosmetic due to exposed cable and hooks.
It depend on the muscle effort.
Harness may restrict the amputees work.
Requirements for using body power
prostheses

→Muscle control of gross body movement:
→Glenohumeral flexion
→Scapular abduction or adduction
→Shoulder depression and elevation
→Chest expansion
 II.Myoelectrically controlled prosthesis:

Is an externally powered prosthesis that uses EMG signals from
residual voluntary counteracted muscles in the limb. Electrode
sensors are embedded in prosthetic socket make contact with the
surface of the skin. Uses muscle contractions as a signal to activate
the prosthesis. It detect electrical activity from selected residual limb
muscles through a surface electrodes.
 The 2-site/2-function (dual-site) system has separate
electrodes for paired prosthetic activity, such as
flexion/extension. This is more physiologic and easier to
control.
1-site/2-function (single-site) when limited control sites
(muscles) in a residual limb are available. This system uses 1
electrode to control both functions of a paired activity.
The patient uses muscle contractions of different degrees to
differentiate between flexion and extension. For instance, a
strong contraction opens the device, and a weak
contraction closes it.
Switch-controlled, externally powered prostheses:
Utilize small switches, rather than muscle signals, to operate
the electric motors.
Switches are enclosed inside the socket or incorporated into
the suspension harness of the prosthesis.
Switch can be activated by the movement of a digit or part
of a bony prominence against the switch or by a pull on a
suspension harness (similar to a movement a patient might
make when operating a body-powered prosthesis).
This can be a good option to provide control for external
power when myoelectric control sites are not available or
when the patient cannot master myoelectric control.
Externally powered prostheses

Advantages Disadvantages

Electric motors
may provide Heavy
more proximal
function.

Expensive
Greater grip
strength
Uses batteries
and motors

Improved
cosmetics less sensory
feedback

Require more
maintenance.
Physical therapy management
for Upper limb amputation
 Rehabilitation program
Goals:
Residual limb shrinkage and shaping.
Residual limb desensitization.
Pain management
Scar mobilization
Maintain the normal ROM.
Increase muscle strength.
Maximize independence.
Myoelectric site testing.
Residual limb shrinking and shaping:

Started once wounds are sufficiently healed and are
able to tolerate increased shearing forces.
Compression by bandaging in figure of 8 from distal
to proximal.
Decreasing the amount of compression as we progress
proximally. Thus fluids will be moved proximally
Reapplied every few hours
Worn full-time except during bathing
Intermittent positive pressure compression
Below Elbow
Above
elbow
 Gentle massage and
tapping techniques.
Residual limb
desensitization:
Vibration.
Minimize the
physical or
psychological Constant touch.
over responses
to a stimulus.
Input of various textures
to the sensitive area
Pain management
Phantom sensation: sensations perceived as
originating from the amputated limb.
Phantom pain: sensations of pain perceived as
originating from the amputated limb.
Residual limb pain: pain in the part of the limb left
after the amputation.
Vibration therapy.
Ultrasound.
Analgesics.
Mirror therapy.
Virtual reality.
 Mirror therapy.

The use of a mirror box in which the uninvolved side is visually reflected as the
missing side, has been shown to decrease phantom limb pain
Scar Mobilization.

This technique is done to keep the skin and scar tissue on
your residual limb loose.
Scar adherence to underlying tissue can be a source of
pain when using your prosthesis
It is best performed when you are not wearing your
compression dressing.
 Technique

Place two fingers over a bony portion of your residual limb.
Press firmly and, keeping your fingertips in the same place on the
skin, move your fingers in a circular fashion across the bone for
about 1 minute.
Continue this procedure on all of the skin and underlying tissue
around the bone of your residual limb.
 Maintain the normal ROM and improve muscle
strength
Increase effective gross motor movements and appropriate
mechanics.
This helps reduce the use of compensation strategies that
may lead to injuries.
Normal scapular mobility and residual joint mobility should
be restored
Once ROM is addressed, overall strengthening, postural
exercises, and cardiovascular endurance are introduced
Treatment focuses on individual activation of the targeted
muscles and progresses to motor control exercises.
identify potential muscles which can be used to control
electrodes that control the prosthesis.
 Body symmetry postural awareness training
begins with observation of static postures in front of a mirror
progressed to dynamic postural awareness by incorporating the use of a
mirror during therapeutic dynamic activities.
performing exercises and tasks in front of a mirror and the therapist
provides additional verbal and tactile cues as necessary.
Isometric and isotonic strengthening exercises are initiated with the use
of a mirror to provide visual feedback.
Strengthening equipment is modified as necessary to allow the use of
the residual limb.
Scapular stabilization exercises and core strengthening are also
introduced to support good posture.
Myoelectric site testing and training
Using myotester to pick the electric potential generated by
the muscle.

1-Simulation
and training
product
2-Provides
biofeedback
 Maximize independence

Change of the dominant hand in case of dominant side amputation
Interventions are directed at increasing fine motor coordination, and reaction
time, improving handwriting, and developing one-handed typing skills.
Fine motor activities used according to the nature of the ADLs of the patient

Teaching one-handed activities
Ensuring independence with and without the prosthesis is an important
component of overall function in variable situations throughout life.
Training on one-handed keyboarding to facilitate success in computer
operations.
 Fitting
A recommended wear schedule is three 30-minute sessions
per day with advancement of 30 minutes each day.
The residual limb should be examined after removal, and
prosthetic wear should be discontinued should any redness
persists for more than 20 minutes.
The goal is to tolerate wearing a prosthesis for 8 to 10 hours
daily for functional activities.
The patient is educated on limb inspection and donning and
doffing the prosthesis
Next, the focus shifts to the accommodation of the weight of
the prosthesis while standing and moving the extremities.
Donning methods for
transradial amputee
a) The roll on silicon liner is inverted and rolled onto the residual limb.
b) The residual limb is placed through the harness (note the locking pin at
the distal end of the liner).
c) The limb is guided into the socket with slight pressure to secure the pin
into the pin lock within the socket.
d) Instructing in the jacket method of donning, the harness is pulled across
the back and the residual limb is placed through the remaining figure-
of-eight harness.
e) Instructing in the over the head method, the residual limb is placed
through the figure-of-eight harness anteriorly before guiding the
harness overhead.
f) The completed figure-of-eight body-powered prosthetic system is
donned.
transhumeral amputee
a. the elbow is locked into 90 degrees flexion and the prosthesis is laid out
with the harness system toward the outside of the body.
b. The residual limb is placed into the socket using downward force with
the prosthesis stabilized using the remaining limb.
c. The harness is donned across the back and under the residual arm. The
harness is secured to the anterior portion of prosthesis with snaps,
buckles, or Velcro (Velcro USA Inc, Manchester, NH).
 Bilateral amputation donning
Body Powered Myoelectric

If each prosthesis has an independent harness system, Self-suspending sockets are often donned using a reduced
the longer of the residual limbs is donned first. This friction donning sock.
prosthesis is then used to assist with donning the second The patient will use the lower extremities or the other
prosthesis. prosthesis to pull the sock through the pull tube that pulls the
If the prostheses are connected by harnessing, the soft tissue into the socket providing an intimate fit with skin
shorter residual limb prosthesis will be donned first. traction.
The two most common methods of donning attached Suction sockets are donned using an evaporative moisture
prostheses is to don the prostheses as you would a coat technique.
or to place both limbs simultaneously in the prostheses Air is expelled through the valve as the limb is pushed into the
and don them overhead like a T- shirt. socket creating a suction fit.
If the prosthesis is donned using the jacket or T-shirt To doff a self-suspending type of prosthesis, patients will
method, the prosthesis is doffed using the method in typically use their lower extremities or the environment to
reverse. assist in removing the prosthesis.
In the case of a suction suspension, patients will often use an
object in their environment to assist them in pressing the
button on the valve that will release the suction. The donning
stand can also be used as needed
Training

After the patient becomes familiar with the weight of the prosthesis, the
rehabilitation transitions to control and operation of the prosthetic limb.
The tasks should be simple
Training should include objects of various shapes, sizes, textures,
densities, and weights.
The focus of the training of the control should include joint positioning to
place the prosthesis in the proper position
The patient should be able to start to control the amount of force needed
to accomplish a task
The patient can be positioned in front of a mirror for increased body
awareness during movement and learn to self-correct body asymmetry
and awkward postures caused by the weight of the prosthesis.
Second stage

There is less focus on the repetition of basic functions and more
emphasis on completing ADLs and valued functional activities.
The patient is trained to incorporate the prosthesis as the assisting
limb for a unilateral amputation.
Third stage

The patient should be encouraged to select
personally meaningful tasks
The patient should try various terminal devices and
adaptive tools to decide what tools and techniques
best meet his or her specific needs.
Training tasks should be multistep and challenging.
More complicated tasks depending on the nature of
the work or sport
Body control motions

In all proximal levels of upper-limb loss, body-powered.
→Elbow flexion is facilitated by a forearm lift assist
that counterbalances the weight of the forearm.
→Elbow extension is accomplished by gravity if the elbow
unit is unlocked.
→Elbow lock/unlock is perhaps one of the most difficult tasks
to learn in the operation of a transhumeral prosthesis. The
pattern of "down, back, and out" is often stated to the
amputee in an effort for him to repeat the shoulder depression,
extension, and abduction pattern.
Thank you