Joint Range of Motion During Gait

Introduction[edit | edit source]

Merriam-Webster dictionary defines gait as “a manner of walking or moving on foot."^[1] It involves the interaction between the nervous, musculoskeletal, and cardiorespiratory systems and is heavily impacted by human age, personality, mood, and sociocultural factors.^[2][3] Normal gait function is determined by the optimal operation of the following: “locomotor function (for initiating and sustaining rhythmic gait), balance, postural reflexes, sensory function and sensorimotor integration, motor control, the musculoskeletal apparatus and cardiopulmonary functions."^[2][4]

Stance Versus Swing Phase[edit | edit source]

The normal forward stride consists of two phases: the stance phase and the swing phase.^[5]

• The stance phase occupies 0-60% of the gait cycle, during which one leg and foot are bearing most or all of the body weight.^[6]
• The swing phase occupies 60-100% (total 40%) of the gait cycle, during which the foot is not touching the walking surface and the bodyweight is borne by the other leg and foot.^[7]
• In a complete two-step cycle, both feet are in contact with the floor at the same time for about 25% of the time. This part of the cycle is called the double-support phase.^[6]
• Gait cycle phases: the stance phase and the swing phase involves a combination of open and close chain activities.^[8][9]

Read more: The Gait Cycle

Phases of Gait[edit | edit source]

The stance and swing phases of gait can be subdivided into eight sub-phases.^[6][9]

1. Initial contact (Heel strike)
2. Foot flat (Loading response)
3. Midstance (Single-leg support)
4. Heel off (Terminal stance)
5. Toe off (Preswing)
6. Initial swing
7. Mid swing
8. Late swing (Deceleration)

See below for a diagram of the gait cycle:

The video below shares a 90-second description of the basics of the gait cycle:

^[10]

Range of Motion Involved in Gait Phases[edit | edit source]

Initial contact (Heel strike)

• 0% of gait cycle
• previously referred to as "heel strike", but in some pathological gaits heel strike may not be the initial instant^[6]

• Function:
  • To establish contact with surface and initiate weight acceptance^[11]

Range of Motion (ROM) at Initial Contact

Body part	ROM requirements
Ankle	0° (neutral position)
Knee	0° (full extension)
Hip	average 20° of flexion

Foot flat (Loading response)

• 8-10% of gait cycle

• Function:
  • weight acceptance and shock absorption

Range of Motion (ROM) Requirements during Foot Flat

Body part	ROM requirements
Ankle	0-5° plantarflexion
Knee	15° of flexion
Hip	15° of flexion (hip is moving into extension)

Midstance (Single-leg support)

• The greater trochanter is vertically above the mid-point of the foot

• Function:
  • Single limb support and stability

Range of Motion (ROM) Requirements during Midstance

Body part	ROM requirements
Ankle	5° of dorsiflexion
Knee	5° of flexion
Hip	0° of flexion (neutral position)

Heel off (Terminal stance)

• 30-40% of gait cycle

• Function
  • Single limb support, stability, and propulsion

Range of Motion (ROM) Requirements during Heel Off

Body part	ROM requirements
Ankle	0° (neutral position)
Knee	0° of flexion (complete extension)
Hip	10-20° of hyperextension

Toe off (Preswing)

• 60% of gait cycle (final phase of stance)

• Function
  • Final burst of propulsion to propel the body forward

Range of Motion Requirements During Toe Off

Body part	ROM requirements
Ankle	20° of plantarflexion
Knee	30° of flexion
Hip	10-20° of hyperextension

Early swing

• 60-75% of gait cycle (beginning of swing phase)
• Toe off until the swinging limb is even with the stance limb

• Function
  • To propel the lower extremity forward and shorten the stance limb

Range of Motion Requirements during Early Swing

Body part	ROM requirements
Ankle	10° of plantarflexion
Knee	60° of flexion
Hip	moves into 20° of flexion

Mid swing

• 75-85% of gait cycle
• Swinging limb is opposite the stance limb

• Function
  • To clear lower extremity from the ground in order to advance into initial contact

Range of Motion (ROM) Requirements during Mid Swing

Body part	ROM requirements
Ankle	0° (neutral position)
Knee	moves into 30° of flexion
Hip	30° of flexion (hip is moving into extension)

Late swing

• 85-100% of gait cycle
• Tibia vertical to initial contact
• Function
  • To decelerate lower extremity to establish contact with the ground

Range of Motion (ROM) Requirements during Late Swing

Body part	ROM requirements
Ankle	0° (neutral position)
Knee	0° (complete extension)
Hip	30° of flexion

The following video describes the range of motion requirements involved in the different gait phases:

Range of Motion during Gait ^[12]

Maximum Values[edit | edit source]

It is important for clinicians to be aware of the maximum range of motion values necessary as the minimum prerequisites for a normal gait pattern.^[13]It is also important to know during which subphase of the gait cycle these ranges of motion occur as this will aid in gait analysis and observing for specific gait pathology.

Maximum Range of Motion (ROM) at Lower Extremity Joints during the Gait Cycle

Body part	Maximum ROM values
Hip	20° of extension; 20° of flexion
Knee	0° (complete extension); 60° of flexion
Ankle	5° of dorsiflexion; 20° of plantarflexion

Gait Kinetics[edit | edit source]

Definitions[edit | edit source]

• Ground reaction force (GRF) = forces applied by the ground to the foot, when the foot is in contact with the ground^[14]
  • creates an external plantarflexion or dorsiflexion torque
  • If GRF is anterior to the joint axis - this causes an anterior motion of the proximal segment
  • If GRF is posterior to the joint axis - this causes a posterior motion of the proximal segment
  • Read more: Ground Reaction Forces

• Lower extremity gait musculature - creates an internal torque
• Centre of pressure - point of application of pressure to the foot segment
• Read more: Gait Definitions

Initial contact (Heel strike)[edit | edit source]

• Ankle
  • At initial contact - lateral calcaneus strikes the ground first.
  • Ground reaction forces are slightly posterior to the axis of rotation of the foot and ankle joint - creates a plantarflexion moment at the ankle.^[9]
  • Ankle dorsiflexors oppose this plantarflexor torque - internal torque controlled by tibialis anterior, extensor digitorum longus and extensor hallucis.^[6]

• Knee
  • At initial contact - GRF is anterior to the knee joint creating anterior rotation of the femur.^[9]
  • GRF wants to move into extension.
  • Utilise flexor musculature - hamstrings - in order to control progression.

• Hip
  • GRF is anterior to hip joint - creating an external torque (anterior rotation) at the pelvis.^[9]
  • Utilise extensor musculature - gluteal musculature - to oppose/control the progression or external torque.

Foot flat (Loading response)

• Ankle
  • Centre of pressure remains at the posterior calcaneus - GRF remains posterior to the ankle.^[9]
  • Utilise dorsiflexors to prevent plantarflexion from occurring at the ankle.

• Hip
  • Centre of pressure and GRF remains the same - anterior to the axis of rotation.^[9]
  • Anterior pelvic tilt creates a flexion torque.
  • Utilise extensor musculature to control this torque.

• Knee
  • Range of motion moves from 0-15°
  • GRF posterior to the axis of rotation of the knee joint - creates a flexion torque.^[9]
  • Utilise extensor musculature to control knee from moving into flexion.

Mid-stance

• Ankle
  • GRF creates a clockwise torque of the proximal segment (on top of distal segment) - causing a dorsiflexion moment at the talocrural joint.^[9]
  • Utilise plantarflexors to oppose the external torque.

• Knee
  • GRF creates an anterior (clockwise) torque of proximal segment (on top of distal segment) - wants to move into extension by femur moving anteriorly on tibia.^[9]
  • Utilise flexors to oppose this torque - activates hamstrings.

• Hip
  • GRF is posterior to the axis of rotation - wants pelvis to move into a posterior pelvic tilt (extension).^[9]
  • Utilise flexors to oppose extension torque.

Heel off

• Ankle
  • GRF is anterior to the axis of rotation of ankle joint - wants tibia to flex on talus.^[9]
  • Creates external dorsiflexion moment at talocrural joint.
  • Utilise plantarflexors to oppose this moment.

• Knee
  • GRF is anterior to knee joint - pulls femur into extension, creating an external extensor torque.^[9]
  • Counteracted by internal flexor torque.

• Hip
  • GRF is posterior to hip joint - creates an external extensor moment.^[9]
  • Counteracted by internal flexor moment.

Toe off

• Ankle
  • Centre of pressure/GRF stay anterior to axis of rotation of ankle joint.^[9]
  • Creates an external dorsiflexion moment.
  • Counteracted by internal plantarflexion moment.

• Knee
  • GRF is posterior to axis of rotation of knee joint as knee is moving into flexion.^[9]
  • Creates an external flexion moment.
  • Counteracted by an internal extensor (quadricep musculature) moment.

• Hip
  • GRF is posterior to axis of rotation of hip joint as hip is moving into extension.^[9]
  • Creates a posterior pelvic tilt.
  • Utilise flexor musculature (iliopsoas) to counteract this moment.

Internal Torque Peaks[edit | edit source]

Hip:

• Foot flat - extensor torque
• Heel off - flexor torque

Knee:

• Initial contact - flexor torque (hamstring musculature active)
• Foot flat - extensor torque (quadriceps musculature active)
• Heel off - flexor torque (hamstring musculature active)

Ankle:

• Initial contact/Foot flat - dorsiflexion torque
• Heel off - plantarflexion torque (gastrocnemius/soleus active)

References[edit | edit source]