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The Leg, Foot and Ankle

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Chapter 19 The Leg, Foot and Ankle Overview The ankle and foot is a complex structure comprised of 28 bones (including 2 sesamoid bones) and 55 articulations ... – PowerPoint PPT presentation

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Title: The Leg, Foot and Ankle


1
Chapter 19
  • The Leg, Foot and Ankle

2
Overview
  • The ankle and foot is a complex structure
    comprised of 28 bones (including 2 sesamoid
    bones) and 55 articulations (including 30
    synovial joints), interconnected by ligaments and
    muscles
  • In addition to sustaining substantial forces, the
    foot and ankle serve to convert the rotational
    movements that occur with weight bearing
    activities into sagittal, frontal, and transverse
    movements

3
Anatomy
  • Anatomically and biomechanically, the foot is
    often subdivided into
  • The rearfoot or hindfoot (the talus and
    calcaneus)
  • The midfoot (the navicular, cuboid and the 3
    cuneiforms)
  • The forefoot (the 14 bones of the toes, the 5
    metatarsals, and the medial and lateral
    sesamoids)

4
Anatomy
  • Distal Tibiofibular Joint
  • Classified as a syndesmosis
  • Consists of a concave tibial surface and a convex
    or plane surface on the medial distal end of the
    fibula

5
Anatomy
  • The talocrural (ankle) joint
  • Formed between the saddle-shaped talus and the
    distal tibia
  • Classified as a synovial hinge or a modified
    sellar joint

6
Anatomy
  • Subtalar (talocalcaneal) joint
  • The subtalar joint is a synovial, bicondylar
    compound joint consisting of two separate,
    modified ovoid surfaces with their own joint
    cavities (one male and one female)
  • This relationship ensures that the anterior and
    posterior aspects can move in opposite directions
    to each other during functional movements (while
    the anterior aspect is moving medially, the
    posterior aspect is moving laterally)

7
Anatomy
  • Talocalcaneal joint ligaments
  • A number of ligaments provide support to this
    joint, although some confusion exist in the
    descriptions and nomenclature of these ligaments
  • The two superficial ligaments are the lateral and
    posterior talocalcaneal ligaments
  • The deep ligaments include the interosseous,
    cervical, and axial ligaments, often referred
    together as the interosseous ligaments

8
Anatomy
  • The midtarsal joint complex
  • Consists of the talonavicular and calcaneocuboid
    articulations
  • The talonavicular joint is classified as a
    synovial, compound, modified ovoid joint
  • Formed by components of the talus, navicular,
    calcaneus and plantar calcaneonavicular (spring)
    ligament
  • The calcaneocuboid joint is classified as a
    simple, synovial modified sellar joint

9
Anatomy
  • Ligaments of the mid-tarsal joints
  • A number of ligaments help provide support to
    this region
  • The spring ligament (plantar calcaneonavicular)
    connects the navicular bone to the sustentaculum
    tali on the calcaneus
  • The ligaments of the calcaneocuboid joint include
    the long plantar ligament and a portion of the
    bifurcate ligament dorsally

10
Anatomy
  • The cuneonavicular joint
  • Classified as a compound, synovial, modified
    ovoid joint

11
Anatomy
  • Intercuneiform and Cuneocuboid Joints
  • These joints are classified as compound,
    synovial, modified ovoid joints

12
Anatomy
  • Cubometatarsal joint
  • When considered alone, this joint is classified
    as a compound modified ovoid, synovial joint

13
Anatomy
  • The cubonavicular joint
  • Classified as a syndesmosis, or a plane surfaced
    joint

14
Anatomy
  • Intermetatarsal joints
  • The first intermetatarsal joint is classified as
    a simple, synovial, modified ovoid joint, while
    the 2nd, 3rd and 4th are classified as compound
    joints

15
Anatomy
  • The metatarsophalangeal (MTP) joints
  • Classified as simple, synovial, modified ovoid
    joints

16
Anatomy
  • The interphalangeal (IP) joints
  • Classified as simple, synovial modified sellar
    joints

17
Anatomy
  • Plantar fascia/aponeurosis
  • The plantar fascia is the investing fascial layer
    of the plantar aspect of the foot that originates
    from the os calcis and inserts through a complex
    network to the plantar forefoot
  • A tough, fibrous layer, composed histologically
    of both collagen and elastic fibers
  • Three portions

18
Anatomy
  • Plantar fascia/aponeurosis
  • With standing and weightbearing, the plantar
    fascia plays a major role in the support of the
    weight of the body by virtue of its attachments
    across the longitudinal arch.

19
Anatomy
  • Retinacula
  • There are four important ankle retinacula, which
    function to tether the leg tendons as they cross
    the ankle to enter the foot

20
Anatomy
  • The extrinsic muscles of the foot
  • Can be divided into anterior, posterior
    superficial, posterior deep, and lateral
    compartments

21
Anatomy
  • The extrinsic muscles of the foot
  • Anterior compartment
  • This compartment contains the dorsiflexors
    (extensors) of the foot. These include the
    tibialis anterior, extensor digitorum longus,
    extensor hallucis longus, and peroneus tertius
  • Posterior superficial compartment
  • This compartment, located posterior to the
    interosseous membrane, contains the calf muscles
    which plantarflex (flex) the foot. These include
    the gastrocnemius, soleus, and the plantaris
    muscle

22
Anatomy
  • The extrinsic muscles of the foot
  • Posterior deep compartment
  • This compartment contains the flexors of the
    foot. These muscles include the posterior
    tibialis, flexor digitorum longus, and flexor
    hallucis longus
  • Lateral compartment
  • This compartment contains the peroneus longus and
    brevis

23
Anatomy
  • The intrinsic muscles of the foot
  • Subdivided into 4 layers
  • 1st layer
  • Abductor hallucis
  • Abductor digiti minimis
  • Flexor digitorum brevis
  • 2nd layer
  • Flexor digitorum accessorius (quadratus plantae)
  • Lumbricales

24
Anatomy
  • The intrinsic muscles of the foot
  • 3rd layer
  • Flexor hallucis brevis
  • Flexor digiti minimis
  • Adductor hallucis
  • 4th layer
  • Dorsal interossei
  • Plantar interossei

25
Anatomy
  • The dorsal intrinsic muscles of the foot
  • Consist of the extensor hallucis brevis (EHB) and
    extensor digitorum brevis (EDB) muscles

26
Anatomy
  • Arches of the foot
  • There are 3 main arches
  • The medial longitudinal
  • The lateral longitudinal
  • The transverse

27
Anatomy
  • Neurology
  • The saphenous nerve, the largest cutaneous branch
    of the femoral nerve, provides cutaneous
    distribution to the medial aspect of the foot
  • The sciatic nerve provides the sensory and motor
    innervation for the foot and leg
  • It divides into the common peroneal and tibial
    nerves. The common peroneal nerve in turn
    divides into the superficial peroneal, deep
    peroneal nerves. The tibial nerve divides into
    the sural, medial calcaneal, medial plantar, and
    lateral plantar nerves

28
Anatomy
  • Vascular supply
  • Two branches of the popliteal artery, the
    anterior tibial artery and the posterior tibial
    artery, form the main blood supply to the foot

29
Biomechanics
  • Terminology
  • Motions of the leg foot and ankle consist of
    single plane and multi-plane movements. The
    single plane motions include
  • The frontal plane motions of inversion and
    eversion
  • The sagittal plane motions of dorsiflexion and
    plantarflexion
  • The horizontal plane motions of adduction and
    abduction

30
Biomechanics
  • A triplane motion describes a movement about an
    obliquely oriented axis through all three body
    planes.
  • Triplanar motions occur at the talocrural,
    subtalar, and midtarsal, joints, and at the first
    and fifth rays.
  • Pronation and supination are considered triplanar
    motions

31
Biomechanics
  • Pronation
  • The three body plane motions in pronation are
    abduction in the transverse plane, dorsiflexion
    in the sagittal plane, and eversion in the
    frontal plane

32
Biomechanics
  • Supination
  • The three body plane motions in supination are a
    combined movement of adduction, plantarflexion,
    and inversion

33
Biomechanics
  • Proximal tibiofibular joint
  • Because of the interaction between the proximal
    and distal tibiofibular joints with the knee and
    the ankle function, the clinician should always
    evaluate the functional mobility of both these
    complexes when treating one or the other

34
Biomechanics
  • Talocrural Joint
  • The primary motions at this joint are
    dorsiflexion and plantar flexion, with a total
    range of 70-80
  • Theoretically, the capsular pattern of the ankle
    joint is more restriction of plantarflexion than
    dorsiflexion, although clinically this appears to
    be reversed
  • The close-packed position is weight-bearing
    dorsiflexion, while the open-packed position is
    midway between supination and pronation.

35
Biomechanics
  • The subtalar joint
  • Subtalar joint supination and pronation are
    measured clinically by the amount of calcaneal or
    hindfoot inversion and eversion
  • In normal individuals, there is an inversion to
    eversion ratio of 23 to 13, which amounts to
    approximately 20 of inversion and 10 of
    eversion

36
Biomechanics
  • Subtalar joint
  • The capsular pattern of this joint varies. In
    chronic arthritic conditions, there is an
    increasing limitation of inversion, but with
    traumatic arthritis, eversion appears most
    limited clinically
  • The close-packed position for this joint is full
    inversion, while the open-packed position is
    inversion/plantarflexion

37
Biomechanics
  • The midtarsal joint complex
  • Provides the foot with an additional mechanism
    for raising and lowering the arch, and to absorb
    some of the horizontal plane tibial motion that
    is transmitted to the foot during stance
  • The talonavicular joint two degrees of freedom
    plantar flexion/dorsiflexion and
    inversion/eversion, with motion occurring around
    a longitudinal and oblique axis, both of which
    are independent of each other
  • The capsular pattern is a limitation of
    dorsiflexion, plantar flexion, adduction and
    internal rotation
  • The close packed position is pronation
  • The open packed position is midway between
    extremes of range of motion

38
Biomechanics
  • The midtarsal joint complex
  • The capsular pattern for the calcaneocuboid joint
    is a limitation of dorsiflexion, plantar flexion,
    adduction and internal rotation

39
Biomechanics
  • The cuneonavicular joint
  • Has one to two degrees of freedom
    plantar/dorsiflexion, inversion/eversion
  • The capsular pattern is a limitation of
    dorsiflexion, plantar flexion, adduction and
    internal rotation
  • The close-packed position is supination
  • The open-packed position is considered to be
    midway between the extremes of range of motion

40
Biomechanics
  • Intercuneiform and Cuneocuboid Joints
  • Due to their very plane curvature, these joints
    have only one degree of freedom
    inversion/eversion
  • The close packed position for these joints is
    supination
  • The open packed position is considered to be
    midway between extremes of range of motion

41
Biomechanics
  • Cubometatarsal Joint
  • The capsular pattern of this joint is a
    limitation of dorsiflexion, plantar flexion,
    adduction and internal rotation
  • The close-packed position is pronation.
  • The open-packed position is considered to be
    midway between extremes of range of motion

42
Biomechanics
  • Cubonavicular Joint
  • The close-packed position for this joint is
    supination
  • The open-packed position is midway between
    extremes of range of motion

43
Biomechanics
  • Intermetatarsal Joints
  • The close-packed position for these joints is
    supination
  • The open-packed position is midway between
    extremes of range of motion

44
Biomechanics
  • Metatarsophalangeal Joints
  • The MTP joints have two degrees of freedom
    flexion/extension and abduction/adduction.
  • Range of motion of these joint is variable,
    ranging from 40 to 100 dorsiflexion (with a
    mean of 84), 3 to 43 (mean, 23) plantar
    flexion, and 5 to 20 varus and valgus
  • The closed-packed position for the MTP joints is
    full extension
  • The capsular pattern for these joints is
    variable, with more limitation of extension than
    flexion
  • The open-packed position is 10º of extension.

45
Biomechanics
  • 1st Metatarsophalangeal Joint
  • The function of the great toe is to provide
    stability to the medial aspect of the foot, and
    to provide for normal propulsion during gait.
    Normal alignment of the 1st MTP joint varies
    between 5 varus and 15 valgus
  • The great toe is characterized by having a
    remarkable discrepancy between active and passive
    motion. Approximately 30 of active plantar
    flexion is present, and at least 50 of active
    extension, which can be frequently increased
    passively to between 70-90.

46
Biomechanics
  • Interphalangeal (IP) Joints
  • Each of the IP joints has one degree of freedom
    flexion/extension
  • The capsular pattern is more limitation of
    flexion than of extension
  • The close-packed position is full extension
  • The open-packed position is slight flexion

47
Examination
  • The examination is used to identify static and
    dynamic, structural or mechanical foot
    abnormalities
  • The clinical diagnosis is based on an assessment
    of the changes in joint mobility and tissue
    changes at the foot and ankle, and the effect
    these have on the function of the remainder of
    the lower kinetic chain

48
Examination
  • History
  • The primary purposes of the history are to
  • Determine the severity of the condition
  • Determine the area, nature and behavior of the
    symptoms
  • Help determine the specific structure at fault
  • Detect systemic conditions (collagen disease,
    neuropathy, radiculopathy, and vascular
    problems), or the presence of serious pathology

49
Examination
  • Systems Review
  • As symptoms can be referred distally to the leg,
    foot and ankle from a host of other joints and
    conditions, the clinician must be able to
    differentially diagnose from the presenting signs
    and symptoms
  • The cause of the referred symptoms may be
    neurological or systemic in origin. If a
    disorder involving a specific nerve root (L 4, L
    5, S1, or S 2) is suspected, the necessary
    sensory, motor and reflex testing should be
    performed
  • Peripheral nerve entrapments, although not
    common, may also occur in this region and often
    go unrecognized

50
Examination
  • Systems Review
  • Systemic problems that may involve the leg, foot
    and ankle include diabetes mellitus (peripheral
    neuropathy), osteomyelitis, gout and pseudogout,
    sickle cell disease, complex regional pain
    syndrome, peripheral vascular disease, and
    rheumatoid arthritis

51
Examination
  • Observation
  • Observation of the lower extremity is extensive.
    It is extremely important to observe the entire
    kinetic chain when assessing the leg, foot, and
    ankle. Weight bearing and non-weight bearing
    postures of the foot are compared.
  • Observing the patient while they move from sit to
    stand, and walk to the treatment area, gives the
    clinician a sense of the patients functional
    ability in weight bearing, and provides the first
    opportunity for gait analysis.

52
Examination
  • Palpation
  • Careful palpation should be performed around the
    leg, foot, and ankle to differentiate tenderness
    of specific ligaments and other structures
  • Areas of localized swelling and ecchymosis over
    the ligaments on the medial or lateral aspects of
    the foot and ankle should be noted

53
Examination
  • Active and Passive Range of Motion
  • AROM tests are used to assess the patients
    willingness to move and the presence of movement
    restriction patterns such as a capsular on
    non-capsular pattern
  • General active range of motion of the foot and
    ankle in the non-weight bearing position is
    assessed first, with painful movements being
    performed last
  • In addition to the foot and ankle tests, the
    clinician should also assess hip and knee range
    of motion

54
Examination
  • Strength testing
  • Isometric tests are carried out in the extreme
    range, and if positive, in the neutral range
  • The straight plane motions of ankle dorsiflexion,
    plantar flexion, inversion and eversion are
    tested initially. Pain with any of these tests
    requires a more thorough examination of the
    individual muscles

55
Examination
  • Strength testing
  • The individual isometric muscle tests can give
    the clinician information about patterns of
    weakness other than from spinal nerve root or
    peripheral nerve palsies and can also help to
    isolate the pain generators
  • A painful weakness is invariably a sign of
    serious pathology, and depending on the pattern,
    could indicate a fracture or a tumor. However,
    if a single motion is painfully weak this could
    indicate muscle inhibition due to pain.

56
Examination
  • Strength testing
  • Weakness on isometric testing needs to be
    analyzed for the type
  • Increasing weakness with repeated contractions of
    the same resistance indicating a palsy
  • Consistent weakness with repeated contractions
    which could suggest a deconditioned muscle, or a
    significant muscle tear), and the pattern of
    weakness (spinal nerve root, nerve trunk or
    peripheral nerve)

57
Examination
  • Passive articular mobility
  • Passive articular mobility tests assess the
    accessory motions available between the joint
    surfaces. These include tests of the joint
    glides, joint compression and joint distraction
    tests. As with any other joint complex, the
    quality and quantity of joint motion must be
    assessed to determine the level of joint
    involvement

58
Examination
  • Special tests
  • Special tests are merely confirmatory tests
  • Selection for their use is at the discretion of
    the clinician and is based on a complete patient
    history
  • The results from these tests are used in
    conjunction with the other clinical findings and
    should not be used alone to form a diagnosis
  • To assure accuracy with these tests, both sides
    should be tested for comparison

59
Examination
  • Neurological tests
  • Important neurological structures that pass
    through the ankle and terminate in the foot are
    the saphenous, superficial peroneal, deep
    peroneal, posterior and anterior tibial nerves,
    and the sural nerve
  • Symptoms can be referred to the foot and ankle
    from the L 4-S 2 nerve roots (sciatic) and from a
    host of non-neurological conditions

60
Examination
  • Neurological tests
  • Common reflexes tested in this area are the
    Achilles reflex (S 1-2), and the posterior tibial
    reflex (L 4-5)
  • The pathological reflexes (Babinski, and
    Oppenheim), tested when an upper motor neuron
    lesion is suspected

61
Intervention
62
Intervention
  • Acute phase goals
  • Decrease pain, inflammation and swelling
  • Protect the healing area from re-injury
  • Re-establish pain-free range of motion
  • Prevent muscle atrophy
  • Increase neuromuscular control
  • Maintain fitness levels
  • Patient to be independent with home exercise
    program

63
Intervention
  • Functional phase goals
  • Restore normal joint kinematics
  • Attain full range of pain free motion
  • Improve neuromuscular control of the lower
    extremity in a full weight bearing posture on
    both level and uneven surfaces
  • Regain and improve lower extremity strength and
    endurance through integration of local and
    kinetic chain exercises

64
Intervention
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