Ignite Creation Date:
2024-10-25 @ 7:58 PM
Last Modification Date:
2024-10-26 @ 3:42 PM
Study NCT ID:
NCT06627296
Status:
ACTIVE_NOT_RECRUITING
Last Update Posted:
None
First Post:
2024-10-01
Brief Title:
The Effect of Combined Exercise and NMES on Strength Proprioception and Reaction Time in Scapholunate Instability
Sponsor:
None
Organization:
None
Study Overview
Official Title:
The Effect of Combined Exercise Training With Neuromuscular Electrical Stimulation on Muscle Strength Proprioceptive Sense Reaction Time and Functionality in Patients Diagnosed With Scapholunate Instability
Status:
ACTIVE_NOT_RECRUITING
Status Verified Date:
2024-10
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
No
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
None
Brief Summary:
In our study which we conducted to investigate the effect of exercise training combined with neuromuscular electrical stimulation on muscle strength proprioceptive sensation reaction time and functionality in patients with scapholunate SL instability individuals with SL instability who meet the inclusion criteria and volunteer to participate in the study will participate After the approval of the ethics committee it is planned to include as many individuals with SL instability as the number to be obtained following the power analysis to be performed as a result of the pilot study The pain of the subjects will be evaluated with the VAS pain scale during rest-activity-exercise All participants will be evaluated with the isokinetic cybex device for isokinetic muscle strength of the wrist grip strength with the JAMAR hand held dynometer NEH evaluation goniometer proprioceptive sensation with ACUMAR and isokinetic device reaction time with blazepod trainer wrist pain transfer with a digital scale assessment of upper extremity functional status pwre patient rated wrist evaluation modified mayo wrist score DASH EL20 questionnaire SF-12 questionnaires
In this randomized controlled study the first group will receive NMES and exercise training 3 days a week for a total of 8 weeks and the other group will receive only exercise training The evaluations will be done at the beginning and twice in total after the 8-week rehabilitation program The exercises given to the patients in both groups will be similar for 8 weeks and they will receive a total of 24 sessions of exercise programs with 15 repetitions per day 3 days a week accompanied by a physiotherapist Both groups will also be given home exercises to continue at home NMES and exercise trainings will be applied in such a way that activation of SL-friendly extensor carpi radialis longus ECRL extensor carpi radialis brevis ECRB flexor carpi radialis FCR and abductor pollicis longus APL muscles will be followed by inhibition of non-friendly extensor carpi ulnaris ECU
After the completion of the thesis it is planned to add to the literature by examining the effects of exercise training combined with NMES on muscle strength proprioceptive sensation reaction time and functionality in individuals diagnosed with SL instability and the superiorities if any between the methods
In this randomized controlled study the first group will receive NMES and exercise training 3 days a week for a total of 8 weeks and the other group will receive only exercise training The evaluations will be done at the beginning and twice in total after the 8-week rehabilitation program The exercises given to the patients in both groups will be similar for 8 weeks and they will receive a total of 24 sessions of exercise programs with 15 repetitions per day 3 days a week accompanied by a physiotherapist Both groups will also be given home exercises to continue at home NMES and exercise trainings will be applied in such a way that activation of SL-friendly extensor carpi radialis longus ECRL extensor carpi radialis brevis ECRB flexor carpi radialis FCR and abductor pollicis longus APL muscles will be followed by inhibition of non-friendly extensor carpi ulnaris ECU
After the completion of the thesis it is planned to add to the literature by examining the effects of exercise training combined with NMES on muscle strength proprioceptive sensation reaction time and functionality in individuals diagnosed with SL instability and the superiorities if any between the methods
Detailed Description:
Among upper extremity injuries handwrist injuries are frequently observed The hand is an important organ that enables individuals to perform daily life activities Hand and wrist problems can cause limitations in the persons activities and prevent the person from fulfilling daily life roles This can lead to a decrease in quality of life
n terms of biomechanical properties extrinsic ligaments of wrist show greater elasticity but are less resistant to traction resulting in lower durability compared to most intrinsic ligaments As a result extrinsic ligaments are prone to rupture in the medial portions whereas intrinsic ligaments are more prone to rupture injuries rather than a complete tear 1
The scapholunate SL joint relationship is provided by several carpal ligaments The most important of these is the scapholunate interosseous ligament SLIL scapholunate interosseous ligament 2 SLIL injury results in scapholunate joint instability 3 Scapholunate instability is the most common carpal instability 4 When this instability is left untreated the mechanical relationship between the carpal bones is permanently disrupted resulting in progressive degenerative changes in the radiocarpal and midcarpal joints 5 These degenerative changes are called scapholunate advanced collapse SLAC and are the most common cause of wrist osteoarthritis 6 In SL instability extension and falling on the hand in ulnar deviation typically constitute the mechanism of injury The combined pattern of carpal instability and degenerative arthritis is called scapholunate advanced collapse SLAC 7
The fact that the scaphoid and lunate have different articular structures allows them to rotate at different rates during wrist flexion and extension movements In addition the dorsal fibers of the SLIL are short and thick and the palmar fibers are loose and elastic allowing different rotations of the scaphoid and lunate during flexion and extension movements With loading the scaphoid tends to go into flexion and the lunate tends to go into extension These different movement patterns of the scaphoid and lunate result in a high potential energy stored in the SLIL ligament When ligament rupture occurs the carpal bones are expected to move to the opposite side due to this energy Therefore after SLIL rupture the scaphoid flexes and the lunate goes into extension due to the pulling effect of the triquetrum through the lunatriquetral interosseal ligament LTIL This instability pattern is called dorsal intercalary segment instability DISI 7
Until recently most biomechanical theories suggested that wrist stability was mainly determined by the shape of the joint and the interaction between ligaments and capsules The dynamic stabilization mechanisms of other joints such as the knee or shoulder have been extensively investigated Less emphasis has been placed on understanding how muscles and tendons contribute to wrist stability However over the last 15 years increasing interest and research has started to shed light on this topic In fact more than 350 articles on wrist proprioception have been published since 2011 One of the triggers for this fact was the description of mechanoreceptors in the wrist ligaments by Hagert et al Proprioception is related to joint stability The term wrist stability refers to the ability of the wrist to maintain balance under load kinetic andor during movement kinematic and can persist strongly without twisting and becoming symptomatic A stable wrist does not twist under physiological load and can adjust its internal alignment to become a solid block from which forces can be distributed Kinetic stability of the wrist requires many contributing factors including bone morphology robust static ligaments and strong dynamic stabilizers forearm muscles and tendons crossing the wrist preserved articulating surfaces and a competent sensory and motor system that includes nerves connecting the static and dynamic stabilizers Failure of any of these five factors can lead to wrist instability 13
SL instability occurs as a result of disruption of the normal alignment of the bones forming the wrist due to damage to the SLIL ligaments It is often overlooked because it may be associated with other handwrist problems 1415 SL instabilities are usually characterized by wrist pain that occurs during loading The pain pattern developing due to SL instability increases during activity Pain may lead to loss of normal joint movements and decreased grip strength This leads to incompetence in activities of daily living and self-care and a decrease in functional level 16-18 Different factors are considered in the treatment of SL instability problems
In recent years studies on carpal kinetics kinematics and ligament properties have shed light on conservative treatment approaches 21-23 Different rehabilitation approaches have been developed especially by investigating the ligaments and muscles that contribute to carpal stability 2425 In a study by Hagert et al 26 it was reported that one of the most important factors contributing to carpal stability is proprioceptive and neuromuscular control of the wrist joint In their study investigating the structural and neural properties of the wrist ligaments they noted that the ligaments adhering to the dorsal and tricuetrum especially the scapholunate interosseous ligament SLIL were rich in mechanoreceptors 27 In addition the presence of ligamentomuscular reflexes that cause activity in the forearm muscles as a result of electrical stimulation of the SLIL has been demonstrated
It has been shown that especially the flexor carpi ulnaris FCU flexor carpi radialis FCR extensor carpi radialis longus ECRL extensor carpi ulnaris ECU and extensor carpi radialis brevis ECRB muscles play an effective role in dynamic stabilization of the wrist In a study by Garcia-Ellias et al 29 it was shown that these muscles change the distance between the carpal bones by making the carpal bones pronate or supinate As a result of these studies the idea that further injuries can be prevented by activating the right muscles after ligament damage has emerged 29
In their study on cadavers Salva-Coll et al investigated the movement patterns of the FCU FCR ECRL ECU and Abductor Pollicis Longus APL muscles on the carpal bones It was noted that the FCU ECRL and APL muscles caused supination of both carpal rows especially flexion of the proximal carpal row 30 It has been observed that the FCR muscle supinates the scaphoideum and pronates the tricuetrum and capitatum The ECU muscle was found to pronate both the distal and proximal carpal row significantly 31 It was noted that carpal supination narrowed the scapholunate interval while pronation widened it Therefore the ECRL APL and FCR muscles which are defined as scapholunate friendly after SLL injuries have gained importance in the rehabilitation of carpal instability because they narrow the scapholunate space 32 It has also been reported that ECU activity should be avoided
Studies have reported that simultaneous excitation of the ECR FCR and FCU and their muscles can provide global stability of the wrist joint Therefore co-activation exercises are recommended to be included in the rehabilitation program to increase dynamic stability 7 Electrical stimulation is widely used for skeletal muscle strengthening
Neuromuscular electrical stimulation NMES is a method that reorganizes the central nervous system causes biochemical physiological and histological changes in muscle fibers prevents muscle atrophy and facilitates the recovery of muscle strength and function in patients with central nervous system lesions 33 Studies have shown that NMES applied to the unilateral extremity provides an increase in muscle strength 34
In the literature it has been reported that NMES causes an increase in the pennation angle and physiological cross-sectional area PCSA values of muscles as a result of some physiologic processes 3536 Especially currents below 50 Hz are suitable for muscles with short fiber length and high PCSA values because they contain long durations In other words low frequency long duration selections will be appropriate for pennate muscles For muscles with low PCSA and high fiber length values the selection parameters will be different For these muscles frequencies above 70 Hz and very short approximately 200 µsec durations should be preferred and stimulation times should be kept short 35-37
Shardong et al 38 showed that muscle strength increased after eight weeks of NMES intervention in patients with chronic renal failure but muscle 2 thickness and pennation angle did not change Variable NMES parameters frequency amplitude duration electrode placement etc have been shown as the reason for these conflicting results regarding the effects of NMES 39
In the current literature published by Salva-Coll et al in 2023 it is thought that there may be an imbalance of flexor and extensor muscles of the forearm muscles due to damage to the ligamentomuscular reflex mechanism arising from the SLL after SLL injury It has been reported that the above-mentioned ECRL ECRB APL FCR muscles are important in the rehabilitation of carpal instability because they narrow the scapholunate space and ECU activity should be avoided In case reports it is described that neuromuscular rehabilitation of dynamic stabilizers of this wrist which is thought to be SL joint friendly is applied The use of an arc of motion called the dart throwing motion has also become widespread in rehabilitation It has been shown to minimize the load on the SLIL and is a widely used application in postoperative SLIL rehabilitation 40 These approaches have been derived from basic science literature rehabilitation concepts available for other anatomical locations and biomechanical investigations of the wrist However there is limited evidence to explain the effectiveness of these practices There are no randomized clinical trials or guidelines in the literature that recommend ideal conservative rehabilitation strategies for SLIL injuries Given the paucity of literature it is still inevitable that rehabilitation clinicians intervene in patients with SLIL injuries
The effect of NMES on isokinetic muscle strength grip strength joint proprioception in scapholunate patients is unknown in the literature It is important to understand the effect of NMES on the muscles mentioned above as SL joint friendly in order to achieve a more effective treatment outcome in patients
There are no studies in the literature that apply NMES to SL friendly muscles in patients with SL instability In the existing studies there are studies that include general wrist exercise training after surgery Among these studies there were no studies investigating wrist extensor and flexor isokinetic muscle strength and endurance after exercise training In addition in the existing studies randomized controlled studies measuring upper extremity reaction time proprioceptive sensation and wrist pain transfer power were not found in SL patients after injury However proprioceptive sensation reaction speed and reaction time are very important for upper extremity functionality In addition it is obvious that having an idea about the muscle strength of extensors and flexors with isokinetic measurements will shape rehabilitation protocols differently
In this study we aimed to investigate the effect of exercise training combined with neuromuscular electrical stimulation on muscle strength proprioceptive sensation reaction time and functionality in patients with scapholunate instability
n terms of biomechanical properties extrinsic ligaments of wrist show greater elasticity but are less resistant to traction resulting in lower durability compared to most intrinsic ligaments As a result extrinsic ligaments are prone to rupture in the medial portions whereas intrinsic ligaments are more prone to rupture injuries rather than a complete tear 1
The scapholunate SL joint relationship is provided by several carpal ligaments The most important of these is the scapholunate interosseous ligament SLIL scapholunate interosseous ligament 2 SLIL injury results in scapholunate joint instability 3 Scapholunate instability is the most common carpal instability 4 When this instability is left untreated the mechanical relationship between the carpal bones is permanently disrupted resulting in progressive degenerative changes in the radiocarpal and midcarpal joints 5 These degenerative changes are called scapholunate advanced collapse SLAC and are the most common cause of wrist osteoarthritis 6 In SL instability extension and falling on the hand in ulnar deviation typically constitute the mechanism of injury The combined pattern of carpal instability and degenerative arthritis is called scapholunate advanced collapse SLAC 7
The fact that the scaphoid and lunate have different articular structures allows them to rotate at different rates during wrist flexion and extension movements In addition the dorsal fibers of the SLIL are short and thick and the palmar fibers are loose and elastic allowing different rotations of the scaphoid and lunate during flexion and extension movements With loading the scaphoid tends to go into flexion and the lunate tends to go into extension These different movement patterns of the scaphoid and lunate result in a high potential energy stored in the SLIL ligament When ligament rupture occurs the carpal bones are expected to move to the opposite side due to this energy Therefore after SLIL rupture the scaphoid flexes and the lunate goes into extension due to the pulling effect of the triquetrum through the lunatriquetral interosseal ligament LTIL This instability pattern is called dorsal intercalary segment instability DISI 7
Until recently most biomechanical theories suggested that wrist stability was mainly determined by the shape of the joint and the interaction between ligaments and capsules The dynamic stabilization mechanisms of other joints such as the knee or shoulder have been extensively investigated Less emphasis has been placed on understanding how muscles and tendons contribute to wrist stability However over the last 15 years increasing interest and research has started to shed light on this topic In fact more than 350 articles on wrist proprioception have been published since 2011 One of the triggers for this fact was the description of mechanoreceptors in the wrist ligaments by Hagert et al Proprioception is related to joint stability The term wrist stability refers to the ability of the wrist to maintain balance under load kinetic andor during movement kinematic and can persist strongly without twisting and becoming symptomatic A stable wrist does not twist under physiological load and can adjust its internal alignment to become a solid block from which forces can be distributed Kinetic stability of the wrist requires many contributing factors including bone morphology robust static ligaments and strong dynamic stabilizers forearm muscles and tendons crossing the wrist preserved articulating surfaces and a competent sensory and motor system that includes nerves connecting the static and dynamic stabilizers Failure of any of these five factors can lead to wrist instability 13
SL instability occurs as a result of disruption of the normal alignment of the bones forming the wrist due to damage to the SLIL ligaments It is often overlooked because it may be associated with other handwrist problems 1415 SL instabilities are usually characterized by wrist pain that occurs during loading The pain pattern developing due to SL instability increases during activity Pain may lead to loss of normal joint movements and decreased grip strength This leads to incompetence in activities of daily living and self-care and a decrease in functional level 16-18 Different factors are considered in the treatment of SL instability problems
In recent years studies on carpal kinetics kinematics and ligament properties have shed light on conservative treatment approaches 21-23 Different rehabilitation approaches have been developed especially by investigating the ligaments and muscles that contribute to carpal stability 2425 In a study by Hagert et al 26 it was reported that one of the most important factors contributing to carpal stability is proprioceptive and neuromuscular control of the wrist joint In their study investigating the structural and neural properties of the wrist ligaments they noted that the ligaments adhering to the dorsal and tricuetrum especially the scapholunate interosseous ligament SLIL were rich in mechanoreceptors 27 In addition the presence of ligamentomuscular reflexes that cause activity in the forearm muscles as a result of electrical stimulation of the SLIL has been demonstrated
It has been shown that especially the flexor carpi ulnaris FCU flexor carpi radialis FCR extensor carpi radialis longus ECRL extensor carpi ulnaris ECU and extensor carpi radialis brevis ECRB muscles play an effective role in dynamic stabilization of the wrist In a study by Garcia-Ellias et al 29 it was shown that these muscles change the distance between the carpal bones by making the carpal bones pronate or supinate As a result of these studies the idea that further injuries can be prevented by activating the right muscles after ligament damage has emerged 29
In their study on cadavers Salva-Coll et al investigated the movement patterns of the FCU FCR ECRL ECU and Abductor Pollicis Longus APL muscles on the carpal bones It was noted that the FCU ECRL and APL muscles caused supination of both carpal rows especially flexion of the proximal carpal row 30 It has been observed that the FCR muscle supinates the scaphoideum and pronates the tricuetrum and capitatum The ECU muscle was found to pronate both the distal and proximal carpal row significantly 31 It was noted that carpal supination narrowed the scapholunate interval while pronation widened it Therefore the ECRL APL and FCR muscles which are defined as scapholunate friendly after SLL injuries have gained importance in the rehabilitation of carpal instability because they narrow the scapholunate space 32 It has also been reported that ECU activity should be avoided
Studies have reported that simultaneous excitation of the ECR FCR and FCU and their muscles can provide global stability of the wrist joint Therefore co-activation exercises are recommended to be included in the rehabilitation program to increase dynamic stability 7 Electrical stimulation is widely used for skeletal muscle strengthening
Neuromuscular electrical stimulation NMES is a method that reorganizes the central nervous system causes biochemical physiological and histological changes in muscle fibers prevents muscle atrophy and facilitates the recovery of muscle strength and function in patients with central nervous system lesions 33 Studies have shown that NMES applied to the unilateral extremity provides an increase in muscle strength 34
In the literature it has been reported that NMES causes an increase in the pennation angle and physiological cross-sectional area PCSA values of muscles as a result of some physiologic processes 3536 Especially currents below 50 Hz are suitable for muscles with short fiber length and high PCSA values because they contain long durations In other words low frequency long duration selections will be appropriate for pennate muscles For muscles with low PCSA and high fiber length values the selection parameters will be different For these muscles frequencies above 70 Hz and very short approximately 200 µsec durations should be preferred and stimulation times should be kept short 35-37
Shardong et al 38 showed that muscle strength increased after eight weeks of NMES intervention in patients with chronic renal failure but muscle 2 thickness and pennation angle did not change Variable NMES parameters frequency amplitude duration electrode placement etc have been shown as the reason for these conflicting results regarding the effects of NMES 39
In the current literature published by Salva-Coll et al in 2023 it is thought that there may be an imbalance of flexor and extensor muscles of the forearm muscles due to damage to the ligamentomuscular reflex mechanism arising from the SLL after SLL injury It has been reported that the above-mentioned ECRL ECRB APL FCR muscles are important in the rehabilitation of carpal instability because they narrow the scapholunate space and ECU activity should be avoided In case reports it is described that neuromuscular rehabilitation of dynamic stabilizers of this wrist which is thought to be SL joint friendly is applied The use of an arc of motion called the dart throwing motion has also become widespread in rehabilitation It has been shown to minimize the load on the SLIL and is a widely used application in postoperative SLIL rehabilitation 40 These approaches have been derived from basic science literature rehabilitation concepts available for other anatomical locations and biomechanical investigations of the wrist However there is limited evidence to explain the effectiveness of these practices There are no randomized clinical trials or guidelines in the literature that recommend ideal conservative rehabilitation strategies for SLIL injuries Given the paucity of literature it is still inevitable that rehabilitation clinicians intervene in patients with SLIL injuries
The effect of NMES on isokinetic muscle strength grip strength joint proprioception in scapholunate patients is unknown in the literature It is important to understand the effect of NMES on the muscles mentioned above as SL joint friendly in order to achieve a more effective treatment outcome in patients
There are no studies in the literature that apply NMES to SL friendly muscles in patients with SL instability In the existing studies there are studies that include general wrist exercise training after surgery Among these studies there were no studies investigating wrist extensor and flexor isokinetic muscle strength and endurance after exercise training In addition in the existing studies randomized controlled studies measuring upper extremity reaction time proprioceptive sensation and wrist pain transfer power were not found in SL patients after injury However proprioceptive sensation reaction speed and reaction time are very important for upper extremity functionality In addition it is obvious that having an idea about the muscle strength of extensors and flexors with isokinetic measurements will shape rehabilitation protocols differently
In this study we aimed to investigate the effect of exercise training combined with neuromuscular electrical stimulation on muscle strength proprioceptive sensation reaction time and functionality in patients with scapholunate instability
Study Oversight
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