Introduction to Complex Orthoses: Difference between revisions
No edit summary |
No edit summary |
||
| Line 45: | Line 45: | ||
=== Derotation Orthosis (Twister) === | === Derotation Orthosis (Twister) === | ||
A derotation orthosis is used to control internal and external rotation. This orthosis consists of an AFO section, a free knee joint and a pelvic section to influence rotation at the hip. These devices are most commonly used for persons with neural-tube defect.<ref name=":0" /> External tibial torsion is commonly seen in people with [[Spina Bifida|spina bifida]]. Compensatory motions resulting from external tibial torsion include: | A derotation orthosis is used to control internal and external rotation. This orthosis consists of an AFO section, a free knee joint and a pelvic section to influence rotation at the hip. These devices are most commonly used for persons with neural-tube defect.<ref name=":0" /> External tibial torsion is commonly seen in people with [[Spina Bifida|spina bifida]]. Compensatory motions resulting from external tibial torsion include:<ref>Rupcich M, Bravo RJ. [http://www.antpublisher.com/index.php/CSRC/article/view/320/437 Spina Bifida: alternative approaches and treatment, based on evidence through gait analysis.] Clinical Surgery Research Communications. 2021 Mar 29;5(1):01-12.</ref> | ||
* Trunk lean | * Trunk lean towards stance phase | ||
* Dynamic pelvic internal rotation | * Dynamic pelvic rotation internal hip rotation | ||
* Knee flexion during stance phase | * Knee flexion during stance phase | ||
* | * Valgus at the ankle and hindfoot | ||
Additionally, children with [[Spina Bifida Occulta| | Additionally, children with [[Spina Bifida Occulta|spina bifida]] typically present with hip extensor and abductor weakness resulting in compensatory motion elsewhere. This weakness and excessive motion lead to increased energy expenditure and decreased gait speed compared to age-matched peers without disability.<ref>Bent MA, Ciccodicola EM, Rethlefsen SA, Wren TA. [https://www.mdpi.com/2073-8994/13/9/1595/htm Increased Asymmetry of Trunk, Pelvis, and Hip Motion during Gait in Ambulatory Children with Spina Bifida. Symmetry]. 2021 Sep;13(9):1595.</ref> | ||
=== KAFO (Knee Ankle Foot Orthosis) === | === KAFO (Knee Ankle Foot Orthosis) === | ||
Knee-ankle-foot orthoses(KAFOs) are used for stance control. These types of orthoses are generally prescribed for the following: | Knee-ankle-foot orthoses (KAFOs) are used for stance control. These types of orthoses are generally prescribed for the following reasons:<ref name=":0" /> | ||
* Instability of the knee | * Instability of the knee | ||
* Muscle weakness at the ankle/knee/hip | * Muscle weakness at the ankle / knee / hip | ||
* Knee contracture | * Knee contracture | ||
* Knee hyperextension | * Knee hyperextension | ||
* Foot and ankle control | * Foot and ankle control | ||
* | * To provide some hip support | ||
An important aspect of fitting a KAFO is assessing the strength of the | An important aspect of fitting a KAFO is assessing the strength of the [[Quadriceps Muscle|quadriceps]]. Quadriceps strength of 3 or less on the [[Muscle Strength Testing|Oxford scale]] indicates that the patient cannot keep their knee in extension and support their body weight during gait. Therefore, the KAFO would need to have a locked knee joint. If quadriceps strength is greater three, a KAFO with a free knee joint will allow the patient to flex their knee and provide some mediolateral support during stance.<ref name=":0" /> | ||
==== Different types of KAFOs | ==== Different types of KAFOs ==== | ||
===== One- | ===== One-Piece KAFO ===== | ||
One-piece | One-piece KAFOs have the following features: | ||
* No moving parts | * No moving parts | ||
| Line 76: | Line 76: | ||
* Passive device<ref name=":0" /> | * Passive device<ref name=":0" /> | ||
<nowiki>**</nowiki> | <nowiki>**</nowiki> This type of device might be utilised in conditions such as: [[Cerebral Palsy Introduction|cerebral palsy]], neural-tube defect or [[Blount's Disease|Blount's disease]]. Infantile [[Blount's Disease|Blount's disease]] is seen in children between 2-5 years old and presents as pathologic genu varum. Adolescent [[Blount's Disease|Blount's disease]] is typically less severe and seen in children aged over 10 years.<ref>De Leucio A. [https://www.ncbi.nlm.nih.gov/books/NBK560923/ Blount Disease]. InStatPearls [Internet] 2021 Jul 28. StatPearls Publishing. | ||
</ref> | </ref> | ||
===== Jointed KAFO ===== | ===== Jointed KAFO ===== | ||
There are two types of jointed | There are two types of jointed KAFOs: non-weight bearing and weight-bearing. Both of these orthoses can have a rigid or semi-flexible ankle. | ||
===== Non- | ===== Non-Weight Bearing KAFOs ===== | ||
Non-weight bearing | Non-weight bearing KAFOs are used for knee instability where the knee moves into a flexion, hyperextension, varus or [[Valgus Knee|valgus]] position.<ref name=":0" /> | ||
<nowiki>**</nowiki> | <nowiki>**</nowiki> This device might be prescribed for: polio, nerve damage, knee instability and neural-tube defect. Post-polio patients are at high risk for falls; the frequency of falls in individuals with post-polio syndrome is believed to be around 70%.<ref name=":1" /> This is due to extensive weakness in the affected leg (mainly the knee extensors). These patients will display an asymmetrical gait, reduced proprioceptive input, balance issues, contractures and musculoskeletal deformities.<ref name=":1">Ofran Y, Schwartz I, Shabat S, Seyres M, Karniel N, Portnoy S. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8614826/ Falls in post-polio patients: prevalence and risk factors.] Biology. 2021 Nov;10(11):1110.</ref> | ||
===== Weight- | ===== Weight-Bearing KAFOs ===== | ||
Weight-bearing KAFOs are used to provide | Weight-bearing KAFOs are used to provide hip and knee support. These orthoses have an ischial seat for weight-bearing, thus accommodating weakness in the hip abductor muscles.<ref name=":0" /> | ||
<nowiki>**</nowiki> | <nowiki>**</nowiki> This type of KAFO is commonly used for: polio, [[Trendelenburg Gait|Trendelenburg gait]], neural-tube defect and [[Arthrogryposis Multiplex Congenita|arthrogryposis]]. [[Arthrogryposis Multiplex Congenita|Arthgroyposis]] is a disorder characterised by multiple congenital joint contractures with weakness in the hip and knee extensors. Children who present with [[Arthrogryposis Multiplex Congenita|arthrogryposis]] commonly have [[Clubfoot Content Development Project|clubfoot]], equinovarus foot and plantar flexor muscle weakness.<ref>Perotti L, Church C, Santiago C, Lennon N, Henley J, Nicholson K, Salazar-Torres J, Donohoe M, Fazio K, Miller F, Nichols LR. [https://www.jlimblengthrecon.org/article.asp?issn=2455-3719;year=2019;volume=5;issue=1;spage=4;epage=10;aulast=Perotti#:~:text=Children%20with%20arthrogryposis%20showed%20foot,suggested%20recurrence%20of%20clubfoot%20deformities. Foot deformities and gait deviations in children with arthrogryposis.] Journal of Limb Lengthening & Reconstruction. 2019 Jan 1;5(1):4.</ref><ref>Naukudkar, D., Thakre, D. [https://www.ijsr.net/archive/v11i1/SR211229141836.pdf Orthotic Management of Patient with Arthrogryposis Multiplex Congenita - A Case Study]. International Journal of Science and Research (IJSR). 2022. Jan; 1(12):17-19.</ref> | ||
Revision as of 09:00, 8 May 2022
Top Contributors - Robin Tacchetti, Jess Bell and Kim Jackson
Introduction[edit | edit source]
Complex orthoses are devices designed to assist multiple joints. These orthoses are not as common as ankle-foot orthoses (AFOs). They are designed for patients with extensive weakness in the lower limbs. The purpose of these complex orthoses are:
- Provide support and protection
- Optimally align the joints
- Maintain a functional position
- Provide stability
- Reduce pain
Two types of complex orthoses will be discussed in this page: the knee-ankle-foot orthisis (KAFO) and the hip-knee-ankle-foot orthosis (HKAFO).[1]
Orthotic Assessment[edit | edit source]
Complex orthosis are a more substantial orthosis and more skill and experience is required to fit these devices. When fitting a complex orthosis, the main components of an orthotic assessment include:
- Medical/physical: it is necessary to know the medical condition
- Range of motion (ROM) /muscle power: to better understand what joints need support:[1]
- For ROM:
- Foot/ankle: dorsiflexion / plantarflexion, inversion / eversion
- Knee: extension / flexion, instability
- Hip: extensors / flexors, adductors/ abductors
- Look at any fixed contractures: hip, knee or ankle
- For muscle power:
- Oxford Scale
- Which joints are affected by weakness?
- Power < 3 not functional
- Determines design/type of joints
- For ROM:
- Biomechanical: in order to understand the biomechanics of each patient and where they need additional support
- Proprioception: when patients put an orthosis on that might cover the ankle, foot, knee and hip, they lose some compensatory ability - proprioception is essential to ensure that they patient can stand / walk while wearing the brace[1]
- Sensation: be aware of potential skin breakdown or discomfort
- Leg length: it may be necessary to compensate for leg length discrepancy
** Contractures can be a contraindication to some complex orthoses when using a rigid or locked section because the compensatory mechanism might be taken away.[1]
Types of Complex Orthosis[edit | edit source]
Derotation Orthosis (Twister)[edit | edit source]
A derotation orthosis is used to control internal and external rotation. This orthosis consists of an AFO section, a free knee joint and a pelvic section to influence rotation at the hip. These devices are most commonly used for persons with neural-tube defect.[1] External tibial torsion is commonly seen in people with spina bifida. Compensatory motions resulting from external tibial torsion include:[2]
- Trunk lean towards stance phase
- Dynamic pelvic rotation internal hip rotation
- Knee flexion during stance phase
- Valgus at the ankle and hindfoot
Additionally, children with spina bifida typically present with hip extensor and abductor weakness resulting in compensatory motion elsewhere. This weakness and excessive motion lead to increased energy expenditure and decreased gait speed compared to age-matched peers without disability.[3]
KAFO (Knee Ankle Foot Orthosis)[edit | edit source]
Knee-ankle-foot orthoses (KAFOs) are used for stance control. These types of orthoses are generally prescribed for the following reasons:[1]
- Instability of the knee
- Muscle weakness at the ankle / knee / hip
- Knee contracture
- Knee hyperextension
- Foot and ankle control
- To provide some hip support
An important aspect of fitting a KAFO is assessing the strength of the quadriceps. Quadriceps strength of 3 or less on the Oxford scale indicates that the patient cannot keep their knee in extension and support their body weight during gait. Therefore, the KAFO would need to have a locked knee joint. If quadriceps strength is greater three, a KAFO with a free knee joint will allow the patient to flex their knee and provide some mediolateral support during stance.[1]
Different types of KAFOs [edit | edit source]
One-Piece KAFO[edit | edit source]
One-piece KAFOs have the following features:
- No moving parts
- Straight leg in walking
- Typically used for contracture control or as a night splint
- Passive device[1]
** This type of device might be utilised in conditions such as: cerebral palsy, neural-tube defect or Blount's disease. Infantile Blount's disease is seen in children between 2-5 years old and presents as pathologic genu varum. Adolescent Blount's disease is typically less severe and seen in children aged over 10 years.[4]
Jointed KAFO[edit | edit source]
There are two types of jointed KAFOs: non-weight bearing and weight-bearing. Both of these orthoses can have a rigid or semi-flexible ankle.
Non-Weight Bearing KAFOs[edit | edit source]
Non-weight bearing KAFOs are used for knee instability where the knee moves into a flexion, hyperextension, varus or valgus position.[1]
** This device might be prescribed for: polio, nerve damage, knee instability and neural-tube defect. Post-polio patients are at high risk for falls; the frequency of falls in individuals with post-polio syndrome is believed to be around 70%.[5] This is due to extensive weakness in the affected leg (mainly the knee extensors). These patients will display an asymmetrical gait, reduced proprioceptive input, balance issues, contractures and musculoskeletal deformities.[5]
Weight-Bearing KAFOs[edit | edit source]
Weight-bearing KAFOs are used to provide hip and knee support. These orthoses have an ischial seat for weight-bearing, thus accommodating weakness in the hip abductor muscles.[1]
** This type of KAFO is commonly used for: polio, Trendelenburg gait, neural-tube defect and arthrogryposis. Arthgroyposis is a disorder characterised by multiple congenital joint contractures with weakness in the hip and knee extensors. Children who present with arthrogryposis commonly have clubfoot, equinovarus foot and plantar flexor muscle weakness.[6][7]
Amyoplasia, muscle weakness primarily in the hip and knee extensor muscles, i
See the video below by OrthoMedics for a demonstration of a locked vs. unlocked KAFO
HKAFO[edit | edit source]
HKAFOs (hip-knee-ankle-foot orthosis) are complex orthoses which control all joints of the lower limb, pelvis and spine. With an HFAFO, the hip, knee and ankle are all locked or rigid making it a static device. The HKAFO aims to provide support for the trunk and lower limbs. Patients that would use an HKAFO are typically wheelchair users and unable to walk without these devices. Advantages to using HKAFOs include the following:
- standing/walking
- Control of joints/contractures
- Ability to be at the height of peers
- Aids in bone density
- Weight control/fitness
- Bladder/bowel development
Walking with HKAFOs creates huge energy expenditure, therefore, most patients discontinue by age 14. Additionally, gait is slow with an HKAFO making it difficult to keep up with peers, whereby using a wheelchair is faster.[1]
** Typically HKAFOs will be used with pediatric patients, neural-tube defects and paraplegia.[1]
RGO[edit | edit source]
A unique type of HKAFO is a reciprocating gait orthosis (RGO). This type of orthosis allows more of a normalized reciprocating gait pattern. With a RGO, one leg can pass in front of the other using a more normal pelvic rotation. Populations that would benefit from an RGO would include patients with weakness in lower limbs and the following:
- good upper limb strength
- good motivation to walk
- parental support and
- no joint contractures.
** Typical common diagnoses where you might see an RGO would include paraplegia or neural-tube defect.[1]
Watch the video below by Kare Prosthetics and ORthotics to see two examples of HKAFO with RGO.
Resources[edit | edit source]
- Foundations for Ankle Foot Orthoses
- Introduction to Foot Orthoses
- Introduction to Knee Ankle Foot Orthoses
- Orthotics
References[edit | edit source]
- ↑ 1.00 1.01 1.02 1.03 1.04 1.05 1.06 1.07 1.08 1.09 1.10 1.11 1.12 Fisher, D. Introduction to Complex Orthoses. Course. Physioplus. 2022
- ↑ Rupcich M, Bravo RJ. Spina Bifida: alternative approaches and treatment, based on evidence through gait analysis. Clinical Surgery Research Communications. 2021 Mar 29;5(1):01-12.
- ↑ Bent MA, Ciccodicola EM, Rethlefsen SA, Wren TA. Increased Asymmetry of Trunk, Pelvis, and Hip Motion during Gait in Ambulatory Children with Spina Bifida. Symmetry. 2021 Sep;13(9):1595.
- ↑ De Leucio A. Blount Disease. InStatPearls [Internet] 2021 Jul 28. StatPearls Publishing.
- ↑ 5.0 5.1 Ofran Y, Schwartz I, Shabat S, Seyres M, Karniel N, Portnoy S. Falls in post-polio patients: prevalence and risk factors. Biology. 2021 Nov;10(11):1110.
- ↑ Perotti L, Church C, Santiago C, Lennon N, Henley J, Nicholson K, Salazar-Torres J, Donohoe M, Fazio K, Miller F, Nichols LR. Foot deformities and gait deviations in children with arthrogryposis. Journal of Limb Lengthening & Reconstruction. 2019 Jan 1;5(1):4.
- ↑ Naukudkar, D., Thakre, D. Orthotic Management of Patient with Arthrogryposis Multiplex Congenita - A Case Study. International Journal of Science and Research (IJSR). 2022. Jan; 1(12):17-19.
