Use of Modalities in Upper Limb Management in Tetraplegia: Difference between revisions
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# To reduce muscle fatigue | # To reduce muscle fatigue | ||
The following are the mechanisms of TENS: | The following are the mechanisms of TENS:<ref>Barroso FO, Pascual-Valdunciel A, Torricelli D, Moreno JC, Ama-Espinosa AD, Laczko J, Pons JL. Noninvasive Modalities Used in Spinal Cord Injury Rehabilitation. Spinal Cord Injury Therapy. 2019. Available from https://docs.google.com/viewerng/viewer?url=https://digital.csic.es/bitstream/10261/213986/1/65272.pdf [last access 10.12.2022]</ref> | ||
* It activates sensory nerves | * It activates sensory nerves | ||
* Sensory nerves activate inhibitory interneurons | * Sensory nerves activate inhibitory interneurons <ref name=":3" /> | ||
* Spastic muscle activity is inhibited | * Spastic muscle activity is inhibited | ||
* It may involve the stimulation of large diameter afferent fibers <ref>Jozefczyk PB. The management of focal spasticity. Clin Neuropharmacol. 2002 May-Jun;25(3):158-73.</ref> | * It may involve the stimulation of large diameter afferent fibers <ref>Jozefczyk PB. The management of focal spasticity. Clin Neuropharmacol. 2002 May-Jun;25(3):158-73.</ref> | ||
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# To improve cardiovascular fitness | # To improve cardiovascular fitness | ||
The FES training can produce the following metabolic benefits:<ref>Martin R, Sadowsky C, Obst K, Meyer B, McDonald J. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3584753/pdf/sci-18-028.pdf Functional electrical stimulation in spinal cord injury:: from theory to practice]. Top Spinal Cord Inj Rehabil. 2012 Winter;18(1):28-33. </ref> | The FES training can produce the following metabolic benefits:<ref name=":3">Martin R, Sadowsky C, Obst K, Meyer B, McDonald J. [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3584753/pdf/sci-18-028.pdf Functional electrical stimulation in spinal cord injury:: from theory to practice]. Top Spinal Cord Inj Rehabil. 2012 Winter;18(1):28-33. </ref> | ||
* Increases in lean muscle mass | * Increases in lean muscle mass | ||
Revision as of 23:30, 10 December 2022
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Top Contributors - Ewa Jaraczewska, Jess Bell and Tarina van der Stockt
Introduction[edit | edit source]
A wide range of therapeutic modalities addressing upper limb function in patients with tetraplegia is available in spinal cord injury rehabilitation. This article provides an overview of most commonly used modalities in the treatment of clients with upper and lower tetraplegia.
Vibration[edit | edit source]
Muscle vibration is a technique that has potential to reduce muscle tone and spasticity in individuals with neurological disorders. Direct effect of muscle vibrations include an increase in corticospinal excitability and inhibition of neuronal activity in the antagonistic muscle. The use of focal vibration as a modality in spinal cord injury facilitates a contraction of the agonist muscle. [1] Isometric contraction in triceps brachii were induced with the application of vibratory stimuli at 80 Hz on the muscle. [1]
Three motor effects achieved through muscle vibration are as follow:
- Sustained contraction of the vibrated muscle via tonic vibration reflex
- Depression of the motor neurones innervating the antagonistic muscles via reciprocal inhibition or antagonistic inhibition
- Suppression of the monosynaptic stretch reflexes of the vibrated muscle while being vibrated.
The sustained effect of vibration remains under investigation. According to Laessøe et al. [2], lower limb spasticity was reduced up to 3 hours following vibratory stimulation at 100 Hz.
Two different vibration frequencies can be chosen and applied directly to the muscle or tendon: high frequency and low frequency vibration.
High Frequency Vibration
- Frequency of 100 - 200 Hz and
- Amplitude of 1 – 2 mA.
- Produce facilitation of muscle contraction through a tonic vibration reflex.
- The effect is brief after application
Low Frequency Vibration
- 5 -50 Hz
- Inhibitory effect on muscle through its activation of spindle secondary endings and the Golgi tendon organs.
General Precautions
- Heat generation at the point of application when high amplitude is used can cause skin damage
- Unstable health conditions (unstable spine, fractures)
Potential concerns related to use of vibration therapy
- Increased the risk of thrombosis [3]
- Tissue damage from acute or severe edema
- Increased cardiac issue
- Dislodgement of a thrombus [3]
- Increased damage from peripheral vascular disease
- Effects to spinal stimulators
- Skin injury from friction[3]
You can read more about self-applied vibration here.
Surface Stimulation[edit | edit source]
Two the most commonly used forms of surface stimulation are:
- Transcutaneous Electrical Nerve Stimulation (TENS)
- Functional Electrical Stimulation(FES).
TENS[edit | edit source]
Goals:
- To reduce spasticity
- To alleviates pain
- To reduce muscle fatigue
The following are the mechanisms of TENS:[4]
- It activates sensory nerves
- Sensory nerves activate inhibitory interneurons [5]
- Spastic muscle activity is inhibited
- It may involve the stimulation of large diameter afferent fibers [6]
Examples for treatment protocols:
Spasticity management:high-frequency (50–150 Hz) and low-intensity (below motor threshold) surface electrical current
FES[edit | edit source]
Goals:
- To prevent lower limb muscle atrophy
- To increase muscle strength
- To increase endurance
- To improve cardiovascular fitness
The FES training can produce the following metabolic benefits:[5]
- Increases in lean muscle mass
- Increases in capillary number
- Decreases in adipose tissue
Other benefits include lowering the blood glucose and insulin levels, [7]improvement in muscles size, strength, and composition, improved fatigue resistance and oxidative capacities, proportional increases in fiber area and capillary number. [8]
FES can be used as a modality in the treatment of the upper limb in person with tetraplegia to:[9]
- Replace function (i.e., as an orthotic device)
- Retrain function (i.e., as a therapeutic device)
Replacing function[edit | edit source]
- A specific movement facilitation (neuroprosthesis)
- Neuroprosthesis components include electrical stimulator, stimulation delivering electrodes, sensors for user or automatic control of the stimulation, and ian orthosis that provides additional assistance to perform the desired movement
Retraining function[edit | edit source]
- Short-term treatment modality
- The patient is expected to regain voluntary function
- Kapadia et al.[9]described a protocol for transcutaneous FES to retrain reaching and grasping in individuals with spinal cord injury:[9]
- Upper extremity retraining program is designed based on the level and extent of injury
- The patient with upper tetraplegia will start with retraining proximal function followed by distal function training
- The patient with lower tetraplegia will retrain distal function from the beginning
- The patient with little to no voluntary movement at the wrist and fingers can perform simple tasks while being stimulated with the FES
- The number of repetitions is based on each of the participant’s strength and endurance
- 30–45 min out of 1-h session patient performs activities of daily living with FES
- The following parameters are used: balanced, biphasic, current regulated electrical pulse, pulse amplitude from 8 to 50 mA , pulse width 250 μs; and pulse frequency 40 Hz
- During the session, therapist guides the patient's hand to make the movement functional
- Typical FES session is conducted for 45–60 min, 3–5 days a week, for 8–16 weeks, for a total of about 40 sessions
Sub Heading 3[edit | edit source]
Resources[edit | edit source]
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References[edit | edit source]
- ↑ 1.0 1.1 Murillo N, Valls-Sole J, Vidal J, Opisso E, Medina J, Kumru H. Focal vibration in neurorehabilitation. Eur J Phys Rehabil Med. 2014 Apr;50(2):231-42.
- ↑ Laessøe L, Nielsen JB, Biering-Sørensen F, Sønksen J. Antispastic effect of penile vibration in men with spinal cord lesion. Arch Phys Med Rehabil. 2004 Jun;85(6):919-24.
- ↑ 3.0 3.1 3.2 Poenaru D, Cinteza D, Petrusca I, Cioc L, Dumitrascu D. Local Application of Vibration in Motor Rehabilitation - Scientific and Practical Considerations. Maedica (Bucur). 2016 Sep;11(3):227-231.
- ↑ Barroso FO, Pascual-Valdunciel A, Torricelli D, Moreno JC, Ama-Espinosa AD, Laczko J, Pons JL. Noninvasive Modalities Used in Spinal Cord Injury Rehabilitation. Spinal Cord Injury Therapy. 2019. Available from https://docs.google.com/viewerng/viewer?url=https://digital.csic.es/bitstream/10261/213986/1/65272.pdf [last access 10.12.2022]
- ↑ 5.0 5.1 Martin R, Sadowsky C, Obst K, Meyer B, McDonald J. Functional electrical stimulation in spinal cord injury:: from theory to practice. Top Spinal Cord Inj Rehabil. 2012 Winter;18(1):28-33.
- ↑ Jozefczyk PB. The management of focal spasticity. Clin Neuropharmacol. 2002 May-Jun;25(3):158-73.
- ↑ Jeon JY, Weiss CB, Steadward RD, Ryan E, Burnham RS, Bell G, Chilibeck P, Wheeler GD. Improved glucose tolerance and insulin sensitivity after electrical stimulation-assisted cycling in people with spinal cord injury. Spinal Cord. 2002 Mar;40(3):110-7.
- ↑ Chilibeck PD, Jeon J, Weiss C, Bell G, Burnham R. Histochemical changes in muscle of individuals with spinal cord injury following functional electrical stimulated exercise training. Spinal Cord. 1999 Apr;37(4):264-8.
- ↑ 9.0 9.1 9.2 Kapadia N, Moineau B, Popovic MR. Functional Electrical Stimulation Therapy for Retraining Reaching and Grasping After Spinal Cord Injury and Stroke. Front Neurosci. 2020 Jul 9;14:718.
