Introduction to Gait Rehabilitation in Spinal Cord Injury: Difference between revisions
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'''Original Editor '''- [[User: | '''Original Editor '''- [[User:Ewa Jaraczewska|Ewa Jaraczewska]] based on the course by Maha Tayseer Mohammad | ||
'''Top Contributors''' - {{Special:Contributors/{{FULLPAGENAME}}}} | '''Top Contributors''' - {{Special:Contributors/{{FULLPAGENAME}}}} | ||
</div> | </div> | ||
== Introduction == | == Introduction == | ||
The walking recovery for patients with spinal cord injury is a target of various rehabilitative approaches. | The walking recovery for patients with spinal cord injury is a target of various rehabilitative approaches. Understanding prognostic factors influencing recovery is necessary when choosing the most appropriate therapeutic intervention.<ref name=":1" />This article discusses two approaches in gait rehabilitation and factors that help to predict ambulation recovery for patients with a spinal cord injury. | ||
== Plasticity-Based Approach == | == Plasticity-Based Approach == | ||
The plasticity-based approach in gait rehabilitation in spinal cord injury (SCI) arises from | The plasticity-based approach in gait rehabilitation in spinal cord injury (SCI) arises from activity-dependent neural adaptation and training research. The afferent input influences the activity-dependent plasticity of the spinal cord, which affects the neurobiological control of walking. <ref>Van de Crommert HW, Mulder T, Duysens J. Neural control of locomotion: sensory control of the central pattern generator and its relation to treadmill training. Gait Posture. 1998 May 1;7(3):251-263.</ref> The examples can be found in the studies by Sherrington<ref>Sherrington CS. Flexion-reflex of the limb, crossed extension-reflex, and reflex stepping and standing. J Physiol. 1910 Apr 26;40(1-2):28-121. </ref>, Grillner and Rossignol <ref>Grillner S, Rossignol S. On the initiation of the swing phase of locomotion in chronic spinal cats. Brain Res. 1978 May 12;146(2):269-77. </ref> who looked at the input of hip position and the effect of load on retraining walking after SCI. As the result of these studies, the rehabilitation strategies to regain the ability to ambulate by the patient with a spinal cord injury focused on hip extension, load and other sensory elements to facilitate walking. | ||
In plasticity-based approach a specific task, like locomotion undergoes intensive practice in a specific training environment | In a plasticity-based approach, a specific task, like locomotion, undergoes intensive practice in a specific training environment while an appropriate sensory input is provided. The training environment may include a treadmill with body-weight support (BWS), a lokomat, or an Exoskeleton. The sensory input can be offered in a form of limb loading and unloading, trunk posture, hip extension, or limb kinematics. | ||
Example: Locomotor training using a Lokomat. | Example: Locomotor training using a Lokomat. | ||
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== Compensatory-Based Approach == | == Compensatory-Based Approach == | ||
Compensation is "a rehabilitation strategy for non-remediable deficits of strength (force-generating capacity), voluntary motor control, sensation, and balance."<ref name=":0">Behrman AL, Bowden MG, Nair PM. [https://academic.oup.com/ptj/article/86/10/1406/2805283?login=false Neuroplasticity after spinal cord injury and training: an emerging paradigm shift in rehabilitation and walking recovery.] Phys Ther. 2006 Oct;86(10):1406-25.</ref>It is based on the principles that patients use their remaining abilities (compensate) to complete the task, or the task or environment | Compensation is "a rehabilitation strategy for non-remediable deficits of strength (force-generating capacity), voluntary motor control, sensation, and balance."<ref name=":0">Behrman AL, Bowden MG, Nair PM. [https://academic.oup.com/ptj/article/86/10/1406/2805283?login=false Neuroplasticity after spinal cord injury and training: an emerging paradigm shift in rehabilitation and walking recovery.] Phys Ther. 2006 Oct;86(10):1406-25.</ref>It is based on the principles that patients use their remaining abilities (compensate) to complete the task, or the task or environment is modified to achieve the established goal.<ref name=":0" /> | ||
In compensatory-based approach a task of walking is accomplished with the use of orthosis and assistive devices, and the outcome depends on the degree of motor and sensory loss. | In compensatory-based approach a task of walking is accomplished with the use of orthosis and assistive devices, and the outcome depends on the degree of motor and sensory loss. | ||
| Line 27: | Line 27: | ||
=== General Definitions === | === General Definitions === | ||
'''Functional ambulation''' is | '''Functional ambulation''' is “the ability to walk, with or without the aid of appropriate assistive devices (such as prostheses, orthoses, canes or walkers), safely and sufficiently to carry out mobility-related activities of daily living.”<ref>Stroke Engine. Glossary of Terms. Available from [[/www.medicine.mcgill.ca/strokengine/definitions-en.html|http://www.medicine.mcgill.ca/strokengine/definitions-en.html]]. [last access 11.01.2023]</ref> | ||
'''Ambulatory capacity''' is "the highest level of walking function achieved within a standardised environment."<ref>Lam T, Noonan VK, Eng JJ; SCIRE Research Team. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3095631/pdf/nihms1749.pdf A systematic review of functional ambulation outcome measures in spinal cord injury.] Spinal Cord. 2008 Apr;46(4):246-54.</ref> '''Community ambulation''' is defined as “independent mobility outside the home, which includes the ability to confidently negotiate uneven terrain, private venues, shopping centres, and other public venues.”<ref>Lord SE, McPherson K, McNaughton HK, Rochester L, Weatherall M. Community ambulation after stroke: how important and obtainable is it and what measures appear predictive? Arch Phys Med Rehabil. 2004 Feb;85(2):234-9. </ref> | '''Ambulatory capacity''' is "the highest level of walking function achieved within a standardised environment."<ref>Lam T, Noonan VK, Eng JJ; SCIRE Research Team. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3095631/pdf/nihms1749.pdf A systematic review of functional ambulation outcome measures in spinal cord injury.] Spinal Cord. 2008 Apr;46(4):246-54.</ref> '''Community ambulation''' is defined as “independent mobility outside the home, which includes the ability to confidently negotiate uneven terrain, private venues, shopping centres, and other public venues.”<ref>Lord SE, McPherson K, McNaughton HK, Rochester L, Weatherall M. Community ambulation after stroke: how important and obtainable is it and what measures appear predictive? Arch Phys Med Rehabil. 2004 Feb;85(2):234-9. </ref> | ||
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** Gait velocity, cadence, step length, and step time. | ** Gait velocity, cadence, step length, and step time. | ||
* Speed | * Speed | ||
** Crosswalk speed requirements range from .44 to 1.32m/s, | ** Crosswalk speed requirements range from .44 to 1.32m/s, vary by country and increase with increasing population size.<ref name=":3" /> | ||
* Ambient conditions | * Ambient conditions | ||
** Lighting, air temperature, weather condition | ** Lighting, air temperature, weather condition | ||
* Terrain | * Terrain | ||
** Temporal spatial characteristics of ''ambulatory participants with SCI'' are dramatically affected by the surfaces they walk on.<ref name=":4">Promkeaw D, Arrayawichanon P, Thaweewannakij T, Mato L, Amatachaya P, Amatachaya S. [https://www.nature.com/articles/s41393-019-0282-4#citeas Various surfaces challenge gait characteristics of ambulatory patients with spinal cord injury]. Spinal Cord 2019; 57: 805–813.</ref> | ** Temporal spatial characteristics of ''ambulatory participants with SCI'' are dramatically affected by the surfaces they walk on.<ref name=":4">Promkeaw D, Arrayawichanon P, Thaweewannakij T, Mato L, Amatachaya P, Amatachaya S. [https://www.nature.com/articles/s41393-019-0282-4#citeas Various surfaces challenge gait characteristics of ambulatory patients with spinal cord injury]. Spinal Cord 2019; 57: 805–813.</ref> | ||
** Average stride length, cadence, and walking speed of a ''patient with SCI'' are decreased while walking on | ** Average stride length, cadence, and walking speed of a ''patient with SCI'' are decreased while walking on artificial grass, soft, and pebble surfaces compared to a hard surface.<ref name=":4" /> | ||
* Physical load | * Physical load | ||
** Poor roads condition, side-walks with cracks, pot-holes | ** Poor roads condition, side-walks with cracks, pot-holes | ||
| Line 62: | Line 62: | ||
# Requires supervision to walk indoors and is wheelchair-dependent outdoors: a minimal speed requirement of 0.09 ± 0.01 m/s. | # Requires supervision to walk indoors and is wheelchair-dependent outdoors: a minimal speed requirement of 0.09 ± 0.01 m/s. | ||
# Can walk indoors | # Can walk indoors but is wheelchair-dependent outdoors: a minimal speed requirement of 0.15 ± 0.08 m/s. | ||
# Requires a walking aid outdoors (“assisted walker”): a minimal speed requirement of 0.44 ± 0.14 m/s. | # Requires a walking aid outdoors (“assisted walker”): a minimal speed requirement of 0.44 ± 0.14 m/s. | ||
# Walks without | # Walks without aid: a minimal speed requirement of 0.70 ± 0.13 m/s. | ||
</blockquote> | </blockquote> | ||
* '''Outdoor walking''' is defined "as the self-reported ability to walk more than 100 m outside using one cane, leg orthosis only, or no assistive devices."<ref name=":2" /> | * '''Outdoor walking''' is defined "as the self-reported ability to walk more than 100 m outside using one cane, leg orthosis only, or no assistive devices."<ref name=":2" /> | ||
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* Moon et al. have found that hip flexors strength followed by knee extensors are the most important contributors to regain an independent walking in patients with incomplete SCI.<ref>Moon J, Yu J, Choi J, Kim M, Min K. [https://synapse.koreamed.org/articles/1150318 Degree of contribution of motor and sensory scores to predict gait ability in patients with incomplete spinal cord injury.] Annals of Rehabilitation Medicine. 2017 Dec 28;41(6):969-78.</ref> | * Moon et al. have found that hip flexors strength followed by knee extensors are the most important contributors to regain an independent walking in patients with incomplete SCI.<ref>Moon J, Yu J, Choi J, Kim M, Min K. [https://synapse.koreamed.org/articles/1150318 Degree of contribution of motor and sensory scores to predict gait ability in patients with incomplete spinal cord injury.] Annals of Rehabilitation Medicine. 2017 Dec 28;41(6):969-78.</ref> | ||
* A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury | * A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury includes motor scores of the quadriceps femoris (L3), gastrocsoleus (S1) muscles, and light touch sensation of dermatomes L3 and S1. <ref>van Middendorp JJ, Hosman AJ, Donders AR, Pouw MH, Ditunno JF, Curt A, Geurts AC, Van de Meent H. A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury: a longitudinal cohort study. The Lancet. 2011 Mar 19;377(9770):1004-10.</ref> | ||
* The score greater than 33 for the motor scores of the quadriceps (L3), big toe extensors (L5), and the light touch sensory score (S1) indicate the likehood of the patient to regain outdoor walking ability one year after spinal cord injury.<ref name=":2">Draganich C, Weber KA 2nd, Thornton WA, Berliner JC, Sevigny M, Charlifue S, Tefertiller C, Smith AC. [https://journals.lww.com/jnpt/fulltext/2023/07000/predicting_outdoor_walking_1_year_after_spinal.4.aspx Predicting Outdoor Walking 1 Year After Spinal Cord Injury: A Retrospective, Multisite External Validation Study.] J Neurol Phys Ther. 2023 Jul 1;47(3):155-161. </ref> | * The score greater than 33 for the motor scores of the quadriceps (L3), big toe extensors (L5), and the light touch sensory score (S1) indicate the likehood of the patient to regain outdoor walking ability one year after spinal cord injury.<ref name=":2">Draganich C, Weber KA 2nd, Thornton WA, Berliner JC, Sevigny M, Charlifue S, Tefertiller C, Smith AC. [https://journals.lww.com/jnpt/fulltext/2023/07000/predicting_outdoor_walking_1_year_after_spinal.4.aspx Predicting Outdoor Walking 1 Year After Spinal Cord Injury: A Retrospective, Multisite External Validation Study.] J Neurol Phys Ther. 2023 Jul 1;47(3):155-161. </ref> | ||
* According to Cathomen and colleagues<ref>Cathomen A, Maier D, Kriz J, Abel R, Röhrich F, Baumberger M, Scivoletto G, Weidner N, Rupp R, Jutzeler CR, Steeves JD; EMSCI study group; Curt A, Bolliger M. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10272624/pdf/10.1177_15459683231166937.pdf Walking Outcome After Traumatic Paraplegic Spinal Cord Injury: The Function of Which Myotomes Makes a Difference?] Neurorehabil Neural Repair. 2023 May;37(5):316-327. </ref> | * According to Cathomen and colleagues<ref>Cathomen A, Maier D, Kriz J, Abel R, Röhrich F, Baumberger M, Scivoletto G, Weidner N, Rupp R, Jutzeler CR, Steeves JD; EMSCI study group; Curt A, Bolliger M. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10272624/pdf/10.1177_15459683231166937.pdf Walking Outcome After Traumatic Paraplegic Spinal Cord Injury: The Function of Which Myotomes Makes a Difference?] Neurorehabil Neural Repair. 2023 May;37(5):316-327. </ref> The motor score of the myotomes L2 and L3 allow us to differentiate between walkers and non-walkers. The motor score of myotomes L4-S1 are considered prognostic factors for indoor versus outdoor walkers (with and without aids). | ||
=== Severity of the Lesion === | === Severity of the Lesion === | ||
The first examination of the patient with the SCI is performed using The International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI). It allows to determine the neurological level of injury | The first examination of the patient with the SCI is performed using The International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI). It allows us to determine the neurological level of injury and the severity of the lesion. The [[American Spinal Injury Association (ASIA) Impairment Scale|ASIA Impairment Scale]] (AIS) A through D defines the complete and incomplete lesions. | ||
Patients with the following levels of injury may or may not recover walking ability: | Patients with the following levels of injury may or may not recover their walking ability: | ||
* AIS A:<ref name=":1" /> | * AIS A:<ref name=":1" /> | ||
| Line 87: | Line 87: | ||
** 14% of patients who converted to incomplete injury recovered some walking function. | ** 14% of patients who converted to incomplete injury recovered some walking function. | ||
** Patients with spinal cord injury at the ''thoracic or lumbar levels'' (T12-L3) who regain some walking abilities will need the support of braces and devices to walk. | ** Patients with spinal cord injury at the ''thoracic or lumbar levels'' (T12-L3) who regain some walking abilities will need the support of braces and devices to walk. | ||
** Gait is characterised by slow average velocities and great energy expenditure which may not be functional for the patient. | ** Gait is characterised by slow average velocities and great energy expenditure, which may not be functional for the patient. | ||
* AIS B:<ref name=":1" /> | * AIS B:<ref name=":1" /> | ||
** About 33% of patients will recover the ability to ambulate. | ** About 33% of patients will recover the ability to ambulate. | ||
** Pinprick preservation is a positive factor in walking recovery as | ** Pinprick preservation is a positive factor in walking recovery as compared with a light touch only (less extensive damage to the spinothalamic tracts and posterior column) | ||
* AIS C: <ref name=":1" /> | * AIS C: <ref name=":1" /> | ||
** About 75% of patient have a positive prognosis for walking recovery. | ** About 75% of patient have a positive prognosis for walking recovery. | ||
** It | ** It affects patients converted to AIS D and patients with AIS C who achieve some walking function | ||
** Walking recovery affects mostly patients with ''low thoracic or lumbar lesions'' | ** Walking recovery affects mostly patients with ''low thoracic or lumbar lesions'' | ||
** Patients will be able to ambulate with braces and devices | ** Patients will be able to ambulate with braces and devices | ||
Revision as of 00:58, 12 January 2024
This article or area is currently under construction and may only be partially complete. Please come back soon to see the finished work! (12/01/2024)
Original Editor - Ewa Jaraczewska based on the course by Maha Tayseer Mohammad
Top Contributors - Ewa Jaraczewska, Jess Bell and Kim Jackson
Introduction[edit | edit source]
The walking recovery for patients with spinal cord injury is a target of various rehabilitative approaches. Understanding prognostic factors influencing recovery is necessary when choosing the most appropriate therapeutic intervention.[1]This article discusses two approaches in gait rehabilitation and factors that help to predict ambulation recovery for patients with a spinal cord injury.
Plasticity-Based Approach[edit | edit source]
The plasticity-based approach in gait rehabilitation in spinal cord injury (SCI) arises from activity-dependent neural adaptation and training research. The afferent input influences the activity-dependent plasticity of the spinal cord, which affects the neurobiological control of walking. [2] The examples can be found in the studies by Sherrington[3], Grillner and Rossignol [4] who looked at the input of hip position and the effect of load on retraining walking after SCI. As the result of these studies, the rehabilitation strategies to regain the ability to ambulate by the patient with a spinal cord injury focused on hip extension, load and other sensory elements to facilitate walking.
In a plasticity-based approach, a specific task, like locomotion, undergoes intensive practice in a specific training environment while an appropriate sensory input is provided. The training environment may include a treadmill with body-weight support (BWS), a lokomat, or an Exoskeleton. The sensory input can be offered in a form of limb loading and unloading, trunk posture, hip extension, or limb kinematics.
Example: Locomotor training using a Lokomat.
- The goal is to generate stepping in response to specific afferent input associated with the task of walking
- The general guidelines focus on maximising loading of the lower limbs through body-weight support systems or overground walking with assistive devices
Compensatory-Based Approach[edit | edit source]
Compensation is "a rehabilitation strategy for non-remediable deficits of strength (force-generating capacity), voluntary motor control, sensation, and balance."[5]It is based on the principles that patients use their remaining abilities (compensate) to complete the task, or the task or environment is modified to achieve the established goal.[5]
In compensatory-based approach a task of walking is accomplished with the use of orthosis and assistive devices, and the outcome depends on the degree of motor and sensory loss.
Definitions of Walking Recovery in Spinal Cord Injury[edit | edit source]
General Definitions[edit | edit source]
Functional ambulation is “the ability to walk, with or without the aid of appropriate assistive devices (such as prostheses, orthoses, canes or walkers), safely and sufficiently to carry out mobility-related activities of daily living.”[6]
Ambulatory capacity is "the highest level of walking function achieved within a standardised environment."[7] Community ambulation is defined as “independent mobility outside the home, which includes the ability to confidently negotiate uneven terrain, private venues, shopping centres, and other public venues.”[8]
Eight dimensions of community ambulation include the following:
- Ability to manage distances
- Walk distance from 16 to 677m, depending on the community destination.[9]
- Temporal characteristics
- Gait velocity, cadence, step length, and step time.
- Speed
- Crosswalk speed requirements range from .44 to 1.32m/s, vary by country and increase with increasing population size.[9]
- Ambient conditions
- Lighting, air temperature, weather condition
- Terrain
- Temporal spatial characteristics of ambulatory participants with SCI are dramatically affected by the surfaces they walk on.[10]
- Average stride length, cadence, and walking speed of a patient with SCI are decreased while walking on artificial grass, soft, and pebble surfaces compared to a hard surface.[10]
- Physical load
- Poor roads condition, side-walks with cracks, pot-holes
- Attentional demands
- Gait alteration in response to obstacles within the path of travel
- Postural transitions
- Ability to maintain dynamic balance
- Density
- The number of people and objects in the immediate surroundings
Definitions of Ambulation in Spinal Cord Injury Research[edit | edit source]
There is no consistent definition of walking recovery after spinal cord injury. The following definitions are used in the publications that discuss predictors for functional outcome of walking:
- Walking recovery is defined as "regained ability to walk independently in the community, with or without the use of devices and braces."[1]
- Functional ambulation is defined as:
Four categories of functional ambulation in spinal cord injury and gait speed requirements:[13]
- Requires supervision to walk indoors and is wheelchair-dependent outdoors: a minimal speed requirement of 0.09 ± 0.01 m/s.
- Can walk indoors but is wheelchair-dependent outdoors: a minimal speed requirement of 0.15 ± 0.08 m/s.
- Requires a walking aid outdoors (“assisted walker”): a minimal speed requirement of 0.44 ± 0.14 m/s.
- Walks without aid: a minimal speed requirement of 0.70 ± 0.13 m/s.
- Outdoor walking is defined "as the self-reported ability to walk more than 100 m outside using one cane, leg orthosis only, or no assistive devices."[14]
- The ability to manage curbs is considered a critical task for independent community ambulation
Predictors for Functional Outcome of Walking[edit | edit source]
Motor and Sensory Loss[edit | edit source]
- Moon et al. have found that hip flexors strength followed by knee extensors are the most important contributors to regain an independent walking in patients with incomplete SCI.[15]
- A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury includes motor scores of the quadriceps femoris (L3), gastrocsoleus (S1) muscles, and light touch sensation of dermatomes L3 and S1. [16]
- The score greater than 33 for the motor scores of the quadriceps (L3), big toe extensors (L5), and the light touch sensory score (S1) indicate the likehood of the patient to regain outdoor walking ability one year after spinal cord injury.[14]
- According to Cathomen and colleagues[17] The motor score of the myotomes L2 and L3 allow us to differentiate between walkers and non-walkers. The motor score of myotomes L4-S1 are considered prognostic factors for indoor versus outdoor walkers (with and without aids).
Severity of the Lesion[edit | edit source]
The first examination of the patient with the SCI is performed using The International Standards for Neurological Classification of Spinal Cord Injury (ISNCSCI). It allows us to determine the neurological level of injury and the severity of the lesion. The ASIA Impairment Scale (AIS) A through D defines the complete and incomplete lesions.
Patients with the following levels of injury may or may not recover their walking ability:
- AIS A:[1]
- Achieving functional walking is very limited.
- 14% of patients who converted to incomplete injury recovered some walking function.
- Patients with spinal cord injury at the thoracic or lumbar levels (T12-L3) who regain some walking abilities will need the support of braces and devices to walk.
- Gait is characterised by slow average velocities and great energy expenditure, which may not be functional for the patient.
- AIS B:[1]
- About 33% of patients will recover the ability to ambulate.
- Pinprick preservation is a positive factor in walking recovery as compared with a light touch only (less extensive damage to the spinothalamic tracts and posterior column)
- AIS C: [1]
- About 75% of patient have a positive prognosis for walking recovery.
- It affects patients converted to AIS D and patients with AIS C who achieve some walking function
- Walking recovery affects mostly patients with low thoracic or lumbar lesions
- Patients will be able to ambulate with braces and devices
- Age is a strong prognostic factor. 80-90% of patients younger than 50 can walk functionally
Lower Extremities Range of Motion[edit | edit source]
Skin Condition[edit | edit source]
Cardiovascular Endurance[edit | edit source]
Age[edit | edit source]
Body Size[edit | edit source]
Pain[edit | edit source]
Motivation[edit | edit source]
Assistive Devices[edit | edit source]
Orthosis[edit | edit source]
Ambulatory Devices[edit | edit source]
Resources[edit | edit source]
- bulleted list
- x
or
- numbered list
- x
References[edit | edit source]
- ↑ 1.0 1.1 1.2 1.3 1.4 Scivoletto G, Tamburella F, Laurenza L, Torre M, Molinari M. Who is going to walk? A review of the factors influencing walking recovery after spinal cord injury. Frontiers in human neuroscience. 2014 Mar 13;8:141.
- ↑ Van de Crommert HW, Mulder T, Duysens J. Neural control of locomotion: sensory control of the central pattern generator and its relation to treadmill training. Gait Posture. 1998 May 1;7(3):251-263.
- ↑ Sherrington CS. Flexion-reflex of the limb, crossed extension-reflex, and reflex stepping and standing. J Physiol. 1910 Apr 26;40(1-2):28-121.
- ↑ Grillner S, Rossignol S. On the initiation of the swing phase of locomotion in chronic spinal cats. Brain Res. 1978 May 12;146(2):269-77.
- ↑ 5.0 5.1 Behrman AL, Bowden MG, Nair PM. Neuroplasticity after spinal cord injury and training: an emerging paradigm shift in rehabilitation and walking recovery. Phys Ther. 2006 Oct;86(10):1406-25.
- ↑ Stroke Engine. Glossary of Terms. Available from http://www.medicine.mcgill.ca/strokengine/definitions-en.html. [last access 11.01.2023]
- ↑ Lam T, Noonan VK, Eng JJ; SCIRE Research Team. A systematic review of functional ambulation outcome measures in spinal cord injury. Spinal Cord. 2008 Apr;46(4):246-54.
- ↑ Lord SE, McPherson K, McNaughton HK, Rochester L, Weatherall M. Community ambulation after stroke: how important and obtainable is it and what measures appear predictive? Arch Phys Med Rehabil. 2004 Feb;85(2):234-9.
- ↑ 9.0 9.1 Salbach NM, O'Brien K, Brooks D, Irvin E, Martino R, Takhar P, Chan S, Howe JA. Speed and distance requirements for community ambulation: a systematic review. Arch Phys Med Rehabil. 2014 Jan;95(1):117-128.e11.
- ↑ 10.0 10.1 Promkeaw D, Arrayawichanon P, Thaweewannakij T, Mato L, Amatachaya P, Amatachaya S. Various surfaces challenge gait characteristics of ambulatory patients with spinal cord injury. Spinal Cord 2019; 57: 805–813.
- ↑ Hussey RW, Stauffer ES. Spinal cord injury: requirements for ambulation. Arch Phys Med Rehabil. 1973 Dec;54(12):544-7.
- ↑ Brehm MA, Ploeger HE, Nollet F. Self-reported functional ambulation is related to physical mobility status in polio survivors; a cross-sectional observational study. Ann Phys Rehabil Med. 2021 Jul;64(4):101428.
- ↑ van Hedel HJ; EMSCI Study Group. Gait speed in relation to categories of functional ambulation after spinal cord injury. Neurorehabil Neural Repair. 2009 May;23(4):343-50.
- ↑ 14.0 14.1 Draganich C, Weber KA 2nd, Thornton WA, Berliner JC, Sevigny M, Charlifue S, Tefertiller C, Smith AC. Predicting Outdoor Walking 1 Year After Spinal Cord Injury: A Retrospective, Multisite External Validation Study. J Neurol Phys Ther. 2023 Jul 1;47(3):155-161.
- ↑ Moon J, Yu J, Choi J, Kim M, Min K. Degree of contribution of motor and sensory scores to predict gait ability in patients with incomplete spinal cord injury. Annals of Rehabilitation Medicine. 2017 Dec 28;41(6):969-78.
- ↑ van Middendorp JJ, Hosman AJ, Donders AR, Pouw MH, Ditunno JF, Curt A, Geurts AC, Van de Meent H. A clinical prediction rule for ambulation outcomes after traumatic spinal cord injury: a longitudinal cohort study. The Lancet. 2011 Mar 19;377(9770):1004-10.
- ↑ Cathomen A, Maier D, Kriz J, Abel R, Röhrich F, Baumberger M, Scivoletto G, Weidner N, Rupp R, Jutzeler CR, Steeves JD; EMSCI study group; Curt A, Bolliger M. Walking Outcome After Traumatic Paraplegic Spinal Cord Injury: The Function of Which Myotomes Makes a Difference? Neurorehabil Neural Repair. 2023 May;37(5):316-327.
