Management of the Partial Foot Amputee - PowerPoint PPT Presentation

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Management of the Partial Foot Amputee

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Conclusion Gait analysis on normals provided foundation for our understanding of PFA Gait analysis was used to provide more accurate description of gait and ... – PowerPoint PPT presentation

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Title: Management of the Partial Foot Amputee


1
Management of the Partial Foot Amputee
  • Gait Workshop at
  • Biomechanics Laboratory,
  • U of Sydney
  • July 2005

2
  • 3.2.2 SURGICAL GOALS
  • 'To remove the pathologic condition which
    interferes with function, causes disability or
    threatens life so that rehabilitation can be
    instituted' (Mueller and Sinacore, 1994).

Figure 1 - Lines of standard forefoot/midfoot
amputations (From Vitali, et al., 1978, pp. 128).
3
  • Biomechanical Complications
  • www.gentili.net.amputations
  • An equinus deformity often results from forefoot
    amputations, especially the Lisfranc
    (metatarsocuneiform joint) and the Chopart
    (talonavicular and calcaneocubiod joints)
    amputation (Chang, et al., 1995).
  • In a TMA the tendons of extensor hallucis longus,
    extensor digitorum longus and peroneus tertius
    muscles are sectioned. These muscles act to
    dorsiflex the foot at the ankle, if they are
    sectioned, an imbalance between the anterior and
    posterior muscle groups exists. This leads to the
    Achilles tendon working unopposed, thus creating
    an equinus deformity (Barry, et al., 1993). To
    overcome this, an Achilles tendon lengthening
    procedure is performed.
  • This loss of dorsiflexion range of motion can
    lead to excessive loading at the distal edge of
    the residuum during gait and lead to skin
    breakdown (Chang, et al., 1994).

4
3.2.5 SURGICAL TECHNIQUE The following surgical
technique is summarised from Gregory, Peters and
Harkless, 1992. Figure 5 illustrates a
transmetatarsal amputation procedure.
Figure 5 - Transmetatarsal amputation procedure
(From Sanders, 1986, pp. 102).
5
Partial Foot Gait
  • Dr Michael Dillon
  • Clinical observation suggests
  • Residuum rotates within shoe/prosthesis
  • Prostheses do not have a socket
  • Prostheses do not have a stiff toe lever
  • Triceps surae atrophy
  • Reduced plantarflexion
  • Amputees cant stand on their toes

6
Literature suggests
  • Prostheses restore the lost foot length or
    lever-arm (Condie 1970, Rubin 1984, Pullen 1987,
    Stills 1987, Weber 1991, Mueller and Sinacore
    1994, Saunders 1997, Sobel 2000)
  • Function is improved by maintaining residual foot
    length and ankle motion (Wagner 1985, Mueller et
    al1986, Barry etal 1993, Helm 1994, Pinzur at al
    1997, Sobel 2000)
  • MYTHS??

7
Method
  • Amputee subjects (n8),
  • 5 unilat (TMT, Lisfranc, Chopart)
  • 3 bilat (MTP, Lisfranc, Chopart)
  • Aetiology trauma or gangrene
  • Normal subjects (n8), age, ht, wt, sex matched
  • Apparatus Peak Motus 3D motion analysis system,
    AMTI force platform

8
Partial Foot Gait
  • For all conditions the motion is biased towards
    DF. The forefoot should contribute 10 degrees of
    plantarflexion relative to rearfoot. There is
    none in barefoot PFA in preparation for toe-off
    and closer to normal with boot and CTO.
  • Knee is held at gt10 degrees F throughout the gait
    cycle. Knee F is delayed, amplitude diminished
    in barefoot.
  • Over stance phase the hip moved from a flexed
    position to extended position, and returns to
    flexion during swing phase. Amplitude is
    diminished in barefoot.

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11
Moment
  • Is the rotational version of force. It is the
    turning effect around the centre of rotation. It
    is generated by muscles or an external force
    acting on the segment. Magnitude of a moment
    depends on size of the force and the distance
    from the centre of rotation. (Newton.metres)

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13
Partial Foot Gait
  • Ankle moment in barefoot is toward plantarflexion
    throughout stance. VGRF vector remained
    posterior to the ankle joint centre.
  • Traditional and CTO bring ankle jt moment in
    sagittal plane closer to normal, but only at 30
    stance.
  • Knee has F moment to 20 stance, E moment to 50
    stance, F moment again to 80, then E to toe off.
    Boot is more normal, CTO is further towards
    normal.
  • Hip has extensor moment in first half of stance
    and flexor in the second half. Moments increase
    from barefoot to Traditional to CTO. F moment in
    barefoot is delayed to after toe-off, but before
    toe-off for traditional and CTO.

14
Power
  • Is the rate at which work is done. The moment
    multiplied by the angular velocity of the joint.
    The area under the power curve is the work done
    for that period.

15
Joint Power
  • Is an indication of how hard the muscles around
    that joint are working.
  • Is the rate at which energy is expended or
    absorbed
  • Area under the graph
  • Negative power means muscles are absorbing
    energy.
  • Positive power means energy is generated by the
    muscles around the joint.

16
Partial Foot Gait
  • In barefoot, ankle jt power is () generating
    from 20 90 of stance. The traditional has
    periods of absorption and generation. CTO has
    large absorbing periods early in stance and
    generation prior to toe-off.
  • Knee jt powers are near normal.
  • Hip jt power have increasing amounts in
    traditional and CTO.

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27
Results
  • Once the MT heads had been amputated, the GRF did
    not continue to progress distally along the
    length of the residuum but remained well behind
    the distal end throughout most of stance phase
  • In the TMT and Lisfranc Amputees fitted with toe
    fillers, foot orthoses or slipper sockets, the
    distal end of the residuum was located at 58-65
    of shoe length.
  • The largest VGRF occurred at 45 of the gait
    cycle and did not progress past the distal end of
    the residuum until after contralateral heel
    contact in double limb support.

28
  • Significant reduction in peak power generation
    across the ankle were observed on the affected
    limbs of all amputees except the bilat MTP amp.
  • Bilat MTP amp small reductions in power
    generation, COP excursion, but not joint angular
    velocity or ankle ROM.
  • TMT amp power generation 0.72W/kg
  • Lisfranc amp power generation 0.91W/kg
  • Chopart amp 0.78W/kg (unilat), 0.32W/kg (bilat)
    due to elimination of joint range rather than
    COP.
  • Normal 2.56 to 5.06W/kg
  • Reduced due to diminished ankle moment coupled
    with reduced joint angular velocity.

29
Results
  • Reductions in work across the affected ankles
    were compensated for by increased power
    generation at the hip joint (ipsilateral or
    contralateral). The kinetic patterns observed
    were variable.

30
Results
  • In the Chopart amputees fitted with clamshell
    devices demonstrated the COP was able to progress
    well beyond the distal end of the residual limb
    shoe length commensurate with the 2nd peak VGRF.

31
Discussion
  • The COP remained proximal to the distal end of
    the residuum until contralateral heel contact
  • It is difficult to determine why these amputees
    adopted this gait pattern
  • Spare the distal residuum from extreme forces
  • Reduce the requirement of the triceps surae
  • Toe fillers, foot orthoses, AFOs and slipper
    sockets seemed unable to restore the effective
    foot length
  • The clamshell PTB prosthesis incorporated a
    substantial socket
  • Toe levers were made from carbon fibre plates or
    prosthetic feet

32
Discussion
  • One of the primary functions of the ankle is to
    generate power necessary to walk.
  • Once the metatarsal heads were affected, power
    generation was negligible irrespective of
    residual foot length
  • Lisfranc and TMT amputees, performed as much work
    across the ankle as did the Chopart amputees who
    had no ankle motion.
  • The primary reason for partial foot amputation is
    to capitalize on the ankles contribution to
    walking.
  • There is little benefit to be gained by striving
    to maintain residual foot length and ankle motion.

33
Discussion
  • Once amputation has compromised the metatarsal
    heads, maintaining foot length should no longer
    be the primary surgical objective.
  • Aim for residuum that has good distal skin
    coverage and primary intention healing.
  • Given that the ankle did not contribute greatly
    to the work required to walk and the likelihood
    of complications with fitting most amputees,
    abandon below ankle designs and go for a
    clamshell design where risks are minimized.

34
Conclusion
  • Gait analysis on normals provided foundation
    for our understanding of PFA
  • Gait analysis was used to provide more accurate
    description of gait and prosthetic fitting.
  • Insights from gait analysis challenged
    misconceptions and forced reflection on clinical
    practice
  • Improved understanding of what didnt work has
    led clinicians to pursue advancements in design.
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