Foot Orthotics Assessment: Difference between revisions
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==== 2. Range of Motion ==== | ==== 2. Range of Motion ==== | ||
When testing range of motion to create a foot orthosis, testing should be done a | |||
Weightbearing | # Active | ||
# Passive | |||
# Weightbearing | |||
# Non weightbearing | |||
'''<u>Active and Passive Movements in the Foot and Ankle</u>''' | |||
* Dorsiflexion/ Plantarflexion - Quick test for the Ankle Joint | |||
* Pronation/ Supination – Quick test for the Subtalar joint | |||
* Eversion/ Inversion | |||
* Abduction/ Adduction | |||
* Toe flexion/ extension – Quick test for the Metatarsal Phalangeal joints | |||
'''<u>Non weight bearing assessment</u>''' | '''<u>Non weight bearing assessment</u>''' | ||
* [[Windlass Test]] - can be effective in examining dysfunction of the plantar fascia although specificity has not been proved. | |||
** Passively extend hallux at MTP joint | |||
although specificity has not been proved. | *** Plantar aponeurosis should tighten and reduces dist between calcaneus and Metatarsals. | ||
*** Note angle of extension to initiate arch, can vary | |||
*** Increase MLA | |||
** '''Positive Test''' = A positive test is considered if passive extension is continued to end range or until the patient's pain is reproduced in Plantarfascitis | |||
* Pain in medial calcaneus and plantarfascia on palpation | |||
* '''<u>Hallux Limitus/rigidus</u>''' | |||
* Both affect the windlass mechanism and gait pattern and normal functioning of the foot. | |||
** Hallux Rigidus | |||
*** Very limited dorsiflexion mobility or no mvt. there is crepitation with joint mobilization and pain associated with any movement of the first MTP joint. | |||
** Hallux limitus (FnHL) | |||
*** Reduced dorsiflexion movement, resulting in reduced range of dorsiflexion of the first MTP joint. | |||
*** In gait, loss of metatarsophalangeal joint extension during the second half of the single-support phase, when the weightbearing foot is in maximal dorsiflexion. | |||
==== 3. Muscles around foot/ankle- oxford scale ==== | ==== 3. Muscles around foot/ankle- oxford scale ==== | ||
There are | There are four muscle compartments in the lower leg. These muscles are all tested using the standardized Oxford Scale. | ||
[[File:Posterior superficial muscle compartment.jpg|left|frameless|600x600px]] | [[File:Posterior superficial muscle compartment.jpg|left|frameless|600x600px]] | ||
[[File:Deep Posterior compartment.jpg|left|frameless|600x600px]] | [[File:Deep Posterior compartment.jpg|left|frameless|600x600px]] | ||
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'''<u>Superficial Posterior Muscle Compartment</u>''' | '''<u>Superficial Posterior Muscle Compartment</u>''' | ||
'''Action''': Plantarflexion | '''Action''': [[Manual Muscle Testing: Plantarflexion|Plantarflexion]] | ||
'''Muscles''': Gastrocnemius, Soleus and Plantaris | '''Muscles''': [[Gastrocnemius]], [[Soleus]] and [[Plantaris]] | ||
''' | '''<u>Deep Posterior Muscle Compartment</u>''' | ||
'''Action''': [[Manual Muscle Testing: Plantarflexion|Plantarflexion]], Adduction and [[Manual Muscle Testing: Ankle Inversion|Inversion]] | |||
'''Muscles''': [[Tibialis Posterior]], Flexor Hallicus Longus and Flexor Digitorum Longus | |||
'''<u>Lateral Muscle Compartment</u>''' | |||
'''Action''': [[Manual Muscle Testing: Dorsiflexion|Dorsiflexion]], Abduction and [[Manual Muscle Testing: Ankle Eversion|Eversion]] | |||
'''Muscles''': Peroneus Longus and [[Peroneus Brevis]] | |||
'''<u>Anterior Muscle Compartment</u>''' | |||
'''Action''': [[Manual Muscle Testing: Dorsiflexion|Dorsiflexion]], Abduction and [[Manual Muscle Testing: Ankle Inversion|Inversion]] | |||
'''Muscles''': [[Tibialis Anterior]], Extensor Hallicus Longus and Extensor Digitorum Longus | |||
See the following pages for more information on the muscle testing of: | |||
* [[Manual Muscle Testing: Dorsiflexion|Dorsiflexion]] | |||
* [[Manual Muscle Testing: Plantarflexion|Plantarflexion]] | |||
* [[Manual Muscle Testing: Ankle Eversion|Eversion]] | |||
* [[Manual Muscle Testing: Ankle Inversion|Inversion]] | |||
==== 4. Sensation/Pain ==== | |||
==== 5. Proprioception ==== | |||
==== 6. Biomechanical Analysis ==== | |||
'''<u>Static</u>''' | |||
Biomechanical Analysis | |||
* Overall biomechanics of standing, knees hips pelvis | |||
* STJt alignment – medial/lateral devn- supination | |||
* resistance test | |||
* Too many toes, 1 & 4/5, more lateral more pronated | |||
* Rear foot/forefoot | |||
* Hallux extension – Jacks, Windlass test | |||
* Root V STJt equilibrium | |||
* Sub Talar Joint Equilibrium -K. Kirby | |||
* (2001) | |||
* Spatial location of the subtalar joint | |||
* axis in relation to the weightbearing | |||
* structures of the plantar foot | |||
* • concept of subtalar joint rotational | |||
* equilibrium | |||
* • externally generated forces, such as | |||
* GRF and internally generated forces, | |||
* such as ligamentous and tendon | |||
* tensile forces and joint compression | |||
* forces, affect the mechanical | |||
* behavior of the foot and lower | |||
* extremity | |||
* • Root Theory Model -Root (1954 – 1966) | |||
* • Basis was to classify normal & abnormal foot | |||
* types (osseous alignment). › “ | |||
* • Normal/ideal foot alignment occurs when: | |||
* • Distal 1/3 of leg vertical | |||
* • Calcaneus vertical to supporting surface | |||
* • Plantar forefoot parallel to plantar rearfoot | |||
* • Variations from this “normal’ foot alignment | |||
* (‘intrinsic foot deformities’) lead to abnormal | |||
* foot function | |||
* Sub Talar Joint Equilibruim | |||
* Kirby 2001 | |||
'''<u>Dynamic Normal Walking</u>''' | |||
o Timing- load rate= | * o IC heel strike, | ||
* o Loading response | |||
* o MS mid stance, single | |||
* o Terminal stance, single | |||
* o Pre swing | |||
* o Swing Phase | |||
* o ground clearance, | |||
* o Single 40% / | |||
* double support | |||
* 60% | |||
* o Timing- load rate= | |||
* stress | |||
[[File:Gait Cycle.jpg|center|frameless|1000x1000px]] | |||
==== 7. Leg Length Discrepancy (LLD) ==== | ==== 7. Leg Length Discrepancy (LLD) ==== | ||
Line 280: | Line 237: | ||
# Apparent leg length | # Apparent leg length | ||
# Actual leg length | # Actual leg length | ||
[[File:Leg Length.jpg|center|frameless|800x800px]] | |||
<references /> | <references /> | ||
[[Category:Course Pages]] | [[Category:Course Pages]] |
Revision as of 17:31, 30 December 2021
Top Contributors - Carin Hunter, Jess Bell, Kim Jackson, Lucinda hampton, Ewa Jaraczewska and Tarina van der Stockt
Orthotics is a branch of medicine dealing with the making and fitting of orthotic devices. There are many interchangeable terms for this, a few being foot orthotic/orthosis/insole/shoe insert.
Three Main Types of Foot Orthoses[edit | edit source]
- Off the shelf (OTS) Insoles
- Functional Foot Orthoses (FFO)
- Custom Molded Total Contact Insoles (TCI)
What do foot orthoses do?[edit | edit source]
- Support
- Correct, if mobile
- Accommodate if not
- Shock absorption
- Re-distribute pressure
Basic Foot Anatomy[edit | edit source]
- 28 Bones
- 33 Joints
- Ligaments
- Tendons
- Muscles
- Joints
- Plantar Fascia
Plantar Fascia[edit | edit source]
• The plantar fascia is not a nerve, tendon or muscle, but a strong fibrous tissue. This stiff and relatively impermeable covering helps to protect the muscles of the sole of the foot.
• This tissue originates deep within the plantar surface of the calcaneus fanning out across the met heads, it divides and attaches to the base of the phalanges of each toe.
• During walking, as the toes dorsiflex at push off the plantar fascia wraps around the metatarsal heads and tightens. This pulls the calcaneus towards the metatarsal heads and in turn maintains the shape of the longitudinal arch and supports the foot to enable propulsion. This is a phenomenon known as the windlass mechanism.
Windlass Mechanism[edit | edit source]
Hicks first described the windlass mechanism in 1954 as a one-to-one coupling between metatarsal joint dorsiflexion and medial longitudinal arch rise. Based on an engineering concept of lifting weights via a pulley system. He proposed that dorsiflexion of the toes tightens the plantar aponeurosis and pulls the metatarsal heads towards the calcaneus thereby increasing the structural height of the longitudinal arch. This action occurs naturally at push off in gait cycle as toes dorsiflex and the foot becomes stiffer to aid propulsion. During loading and mid stance the arch will stretch. The human foot is flexible by its nature of many articulations and requires to be flexible at times and rigid at other times to promote normal gait. Important to remember that the plantar fascia will stretch and recoil at different stages of the gait cycle.
Important Joints with regards to Foot Orthosis for ROM in the Foot/Ankle[edit | edit source]
- Hindfoot
- Talocrural Joint
- Sub Talar joint
- Mid Foot
- Tarsometatarsal Joint
- Calcaneocuboid Joint
- Talonavicular Joint
- Fore Foot
- 1st Metatarsal Phalangeal Joint
Terminology used in Orthotics[edit | edit source]
Valgus = Everted
Neutral
Varus = Inverted
Pronation – Eversion, abduction, dorsiflexion & medially rotated subtalar joint
Supination- Inversion, adduction, plantarflexion & laterally rotated subtalar joint
Purpose of human foot[edit | edit source]
“[The human foot] enables propulsion through space, adaptation to uneven terrain, absorption of shock, and support of body weight.”[1]
The human foot is a complex mechanism with a number of theories of biomechanics. The structure, function and position leave the foot exposed to risk of injury. When understanding the foot biomechanics, it is key to assess in non weight bearing, weight bearing and during gait.
Orthotic Foot Ankle Assessment[edit | edit source]
- Patient History
- ROM
- Muscle Power
- Sensation/Pain
- Proprioception
- Biomechanical Analysis
- Leg length
1. Patient History[edit | edit source]
- Gait pattern and biomechanical analysis on entrance
- Type of shoes
- Assistive devices
- History of underlying conditions, foot problems and the primary problem affecting the individual on consultation.
2. Range of Motion[edit | edit source]
When testing range of motion to create a foot orthosis, testing should be done a
- Active
- Passive
- Weightbearing
- Non weightbearing
Active and Passive Movements in the Foot and Ankle
- Dorsiflexion/ Plantarflexion - Quick test for the Ankle Joint
- Pronation/ Supination – Quick test for the Subtalar joint
- Eversion/ Inversion
- Abduction/ Adduction
- Toe flexion/ extension – Quick test for the Metatarsal Phalangeal joints
Non weight bearing assessment
- Windlass Test - can be effective in examining dysfunction of the plantar fascia although specificity has not been proved.
- Passively extend hallux at MTP joint
- Plantar aponeurosis should tighten and reduces dist between calcaneus and Metatarsals.
- Note angle of extension to initiate arch, can vary
- Increase MLA
- Positive Test = A positive test is considered if passive extension is continued to end range or until the patient's pain is reproduced in Plantarfascitis
- Passively extend hallux at MTP joint
- Pain in medial calcaneus and plantarfascia on palpation
- Hallux Limitus/rigidus
- Both affect the windlass mechanism and gait pattern and normal functioning of the foot.
- Hallux Rigidus
- Very limited dorsiflexion mobility or no mvt. there is crepitation with joint mobilization and pain associated with any movement of the first MTP joint.
- Hallux limitus (FnHL)
- Reduced dorsiflexion movement, resulting in reduced range of dorsiflexion of the first MTP joint.
- In gait, loss of metatarsophalangeal joint extension during the second half of the single-support phase, when the weightbearing foot is in maximal dorsiflexion.
- Hallux Rigidus
3. Muscles around foot/ankle- oxford scale[edit | edit source]
There are four muscle compartments in the lower leg. These muscles are all tested using the standardized Oxford Scale.
Superficial Posterior Muscle Compartment
Action: Plantarflexion
Muscles: Gastrocnemius, Soleus and Plantaris
Deep Posterior Muscle Compartment
Action: Plantarflexion, Adduction and Inversion
Muscles: Tibialis Posterior, Flexor Hallicus Longus and Flexor Digitorum Longus
Lateral Muscle Compartment
Action: Dorsiflexion, Abduction and Eversion
Muscles: Peroneus Longus and Peroneus Brevis
Anterior Muscle Compartment
Action: Dorsiflexion, Abduction and Inversion
Muscles: Tibialis Anterior, Extensor Hallicus Longus and Extensor Digitorum Longus
See the following pages for more information on the muscle testing of:
4. Sensation/Pain[edit | edit source]
5. Proprioception[edit | edit source]
6. Biomechanical Analysis[edit | edit source]
Static
- Overall biomechanics of standing, knees hips pelvis
- STJt alignment – medial/lateral devn- supination
- resistance test
- Too many toes, 1 & 4/5, more lateral more pronated
- Rear foot/forefoot
- Hallux extension – Jacks, Windlass test
- Root V STJt equilibrium
- Sub Talar Joint Equilibrium -K. Kirby
- (2001)
- Spatial location of the subtalar joint
- axis in relation to the weightbearing
- structures of the plantar foot
- • concept of subtalar joint rotational
- equilibrium
- • externally generated forces, such as
- GRF and internally generated forces,
- such as ligamentous and tendon
- tensile forces and joint compression
- forces, affect the mechanical
- behavior of the foot and lower
- extremity
- • Root Theory Model -Root (1954 – 1966)
- • Basis was to classify normal & abnormal foot
- types (osseous alignment). › “
- • Normal/ideal foot alignment occurs when:
- • Distal 1/3 of leg vertical
- • Calcaneus vertical to supporting surface
- • Plantar forefoot parallel to plantar rearfoot
- • Variations from this “normal’ foot alignment
- (‘intrinsic foot deformities’) lead to abnormal
- foot function
- Sub Talar Joint Equilibruim
- Kirby 2001
Dynamic Normal Walking
- o IC heel strike,
- o Loading response
- o MS mid stance, single
- o Terminal stance, single
- o Pre swing
- o Swing Phase
- o ground clearance,
- o Single 40% /
- double support
- 60%
- o Timing- load rate=
- stress
7. Leg Length Discrepancy (LLD)[edit | edit source]
- Dipping
- Pelvic Obliquity
- Retraction
- Scoliosis
- Apparent leg length
- Actual leg length
- ↑ Bolgla LA, Malone TR. Plantar fasciitis and the windlass mechanism: a biomechanical link to clinical practice. Journal of athletic training. 2004 Jan;39(1):77.