Acute Effects of Neurodynamic Stretching on Muscle-tendon Complex (ELASTRETCH)
December 12, 2025 updated by: Nicolas Babault, University of Burgundy
The Acute Effects of Neurodynamic Stretching the Shear Wave Velocity: on Application on Muscle and Nerve Tissues
Neurodynamic mobilization techniques are widely applied in rehabilitation and physiotherapy to enhance the mobility and function of peripheral nerves.
Two main approaches are distinguished.
Nerve tensioning and nerve flossing.
They both involve proximal and distal joint movements to induce greater neural sliding while avoiding excessive tensile stress.
However, contradictory findings on neurodynamic techniques highlighted the current lack of consensus regarding these techniques.
Moreover, neurodynamic techniques are of interest for patients, it appeared it could also be applied in healthy individuals and more particularly in athletes.
Accordingly, the primary objective of the present study was to determine the immediate effect of two neurodynamic mobilization techniques (flossing vs. tensioning) on the sciatic nerve and hamstring tissues using the shear wave elastography (SWE, a form of ultrasonography).
Study Overview
Status
Status
Completed
Conditions
Conditions
Intervention / Treatment
Intervention / Treatment
Detailed Description
Neurodynamic mobilization techniques are frequently applied in rehabilitation settings to enhance the mobility and function of peripheral nerves, particularly in the management of neuropathic pain such as carpal tunnel syndrome, radiculopathies, or sciatica.
Two main approaches are distinguished.
Nerve tensioning involves maintaining the nerve stretched at the end of the joint range of motion with relatively limited excursion.
It is similar to a static stretching intervention but with distal (ankle) and proximal (cervical) tensions.
Nerve flossing (also termed gliding or sliders), consists of alternating proximal and distal joint movements to induce greater neural sliding while avoiding excessive tensile stress.
However, contradictory findings on neurodynamic techniques highlighted the current lack of consensus regarding the acute effects of the different possible neurodynamic techniques on sciatic nerves, particularly in healthy tissues.
Moreover, neurodynamic techniques are of interest for patients, it appeared it could also be applied in healthy individuals and more particularly in athletes.
Performed in patients, healthy or athletes, no study has compared both tensioning or flossing techniques.
Moreover, because these techniques involved nerve mobilisation, the intensity should have a main effect of its efficiency.
Accordingly, the primary objective of the present study was to determine the immediate effect of two neurodynamic mobilization techniques (flossing vs. tensioning) on the sciatic nerve and hamstring tissues using the shear wave elastography (SWE).
This method has been shown reliable to provide non-invasive real-time assessments of soft tissues elastic properties.
The secondary aim was to determine the effects of stretching intensity (at the point of pain threshold or below).
Study Type
Study Type
Interventional
Enrollment (Actual)
Enrollment
21
Phase
Phase
- Not Applicable
Contacts and Locations
This section provides the contact details for those conducting the study, and information on where this study is being conducted.
Study Locations
-
-
-
Dijon, France
- Universite Bourgogne Europe - faculty of sports sciences
-
-
Participation Criteria
Researchers look for people who fit a certain description, called eligibility criteria. Some examples of these criteria are a person's general health condition or prior treatments.
Eligibility Criteria
Eligibility Criteria
Ages Eligible for Study
- Adult
- Older Adult
Accepts Healthy Volunteers
Yes
Description
Inclusion Criteria:
- healthy
- physical active
- no injuries (lower limb or back pain) in the past 3 months
Exclusion Criteria:
- Specific lower limb (hamstring) injuries in the past 2 years
- Not restraining activity 24h before participation
Study Plan
This section provides details of the study plan, including how the study is designed and what the study is measuring.
How is the study designed?
Design Details
- Primary Purpose: Other
- Allocation: Randomized
- Interventional Model: Crossover Assignment
- Masking: Single
Number of Arms
7
Arms and Interventions
Participant Group / ArmParticipant Group / Arm |
Intervention / TreatmentIntervention / Treatment |
|---|---|
|
No Intervention: Control
Seated at rest during the same duration than the interventions
|
|
|
Active Comparator: Static stretching at pain threshold
Static stretching at pain threshold of the right hamstring muscles 5x60s with 20s rest
|
Static stretching was applied at pain threshold on hamstring muscles and repeated 5 times during 60s at the point of pain.
Static stretching mainly focused muscle-tendon tissues.
|
|
Experimental: Neurodynamic tensioning at pain threshold
Neurodynamic tensioning of the right hamstring muscles 5x60s with 20s rest at pain threshold
|
Neurodynamic tensioning was applied at pain threshold on hamstring muscles and repeated 5 times during 60s at the point of pain.
During the neurodynamic conditions, head and ankle movement permitted to mobilize nerve tissues.
Tensioning is maintaining the position.
|
|
Experimental: Neurodynamic flossing at pain threshold
Neurodynamic flossing of the right hamstring muscles 5x60s with 20s rest at pain threshold
|
Neurodynamic flossing was applied at pain threshold on hamstring muscles and repeated 5 times during 60s at the point of pain.
During the neurodynamic conditions, head and ankle movement permitted to mobilize nerve tissues.
Flossing is the alternation of these movements every 2 seconds.
|
|
Active Comparator: Static stretching at submaximal intensity
Static stretching of the right hamstring muscles 5x60s with 20s rest at 10% below pain threshold
|
Static stretching was applied 10% below pain threshold on hamstring muscles and repeated 5 times during 60s at the point of pain.
Static stretching mainly focused muscle-tendon tissues.
|
|
Active Comparator: Neurodynamic tensioning at submaximal intensity
Neurodynamic tensioning stretching of the right hamstring muscles 5x60s with 20s rest at 10% below pain threshold
|
Neurodynamic tensioning was applied 10% below pain threshold on hamstring muscles and repeated 5 times during 60s at the point of pain.
During the neurodynamic conditions, head and ankle movement permitted to mobilize nerve tissues.
Tensioning is maintaining the position.
|
|
Active Comparator: Neurodynamic flossing at submaximal intensity
Neurodynamic flossing stretching of the right hamstring muscles 5x60s with 20s rest at 10% below pain threshold
|
Neurodynamic flossing was applied 10% below pain threshold on hamstring muscles and repeated 5 times during 60s at the point of pain.
During the neurodynamic conditions, head and ankle movement permitted to mobilize nerve tissues.
Flossing is the alternation of these movements every 2 seconds.
|
What is the study measuring?
Primary Outcome Measures
Primary Outcome Measures
Outcome Measure |
Measure Description |
Time Frame |
|---|---|---|
|
Nerve shear wave velocity using elastography
Time Frame: Before the intervention and at the end (immediately after) the intervention
|
Shear wave velocity of the sciatic nerve will be evaluated by using an ultrasound (echography) device with a specific mode called "shear wave elastography".
Briefly, the ultrasound probe will deliver an ultrasound wave.
The propagation speed (called '"shear wave velocity") will be measured by the same probe.
The greater the velocity is, the harder the tissue is.
|
Before the intervention and at the end (immediately after) the intervention
|
Secondary Outcome Measures
Secondary Outcome Measures
Outcome Measure |
Measure Description |
Time Frame |
|---|---|---|
|
Muscle shear wave velocity using elastography
Time Frame: Before the intervention and at the end (immediately after) the intervention
|
Shear wave velocity of the biceps femoris muscle will be evaluated by using an ultrasound (echography) device with a specific mode called "shear wave elastography".
Briefly, the ultrasound probe will deliver an ultrasound wave.
The propagation speed (called '"shear wave velocity") will be measured by the same probe.
The greater the velocity is, the harder the tissue is.
|
Before the intervention and at the end (immediately after) the intervention
|
|
Hamstring force
Time Frame: Before the intervention and at the end (immediately after) the intervention
|
Maximal torque during a maximal voluntary hamstring contraction
|
Before the intervention and at the end (immediately after) the intervention
|
|
Biceps femoris activity
Time Frame: Before the intervention and at the end (immediately after) the intervention
|
Electromyographic activity of biceps femoris muscle
|
Before the intervention and at the end (immediately after) the intervention
|
|
Semitendinosus activity
Time Frame: Before the intervention and at the end (immediately after) the intervention
|
Electromyographic activity of semitendinosus
|
Before the intervention and at the end (immediately after) the intervention
|
|
passive knee extension
Time Frame: Before the intervention and at the end (immediately after) the intervention
|
The final passive range of motion of the hamstring muscles
|
Before the intervention and at the end (immediately after) the intervention
|
|
Global flexibility
Time Frame: Before the intervention and at the end (immediately after) the intervention
|
the stand and reach test to evaluate flexibility (in centimeters)
|
Before the intervention and at the end (immediately after) the intervention
|
|
Slump test
Time Frame: Before the intervention and at the end (immediately after) the intervention
|
Seated flexibility using the slump test (in degrees)
|
Before the intervention and at the end (immediately after) the intervention
|
|
discomfort
Time Frame: At the end (immediately after) the intervention
|
rating of perceived discomfort during the intervention (from 1 to 10, no discomfort to maximal discomfort, respectively)
|
At the end (immediately after) the intervention
|
Collaborators and Investigators
This is where you will find people and organizations involved with this study.
Sponsor
Sponsor
Investigators
Investigators
- Principal Investigator: Nicolas Babault, PhD, Universite Bourgogne Europe - Sport Science Faculty
Study record dates
These dates track the progress of study record and summary results submissions to ClinicalTrials.gov. Study records and reported results are reviewed by the National Library of Medicine (NLM) to make sure they meet specific quality control standards before being posted on the public website.
Study Major Dates
Study Start (Actual)
Study Start
September 1, 2023
Primary Completion (Actual)
Primary Completion
May 20, 2024
Study Completion (Actual)
Study Completion
June 15, 2024
Study Registration Dates
First Submitted
First Submitted
December 1, 2025
First Submitted That Met QC Criteria
First Submitted That Met QC Criteria
December 12, 2025
First Posted (Actual)
First Posted
December 26, 2025
Study Record Updates
Last Update Posted (Actual)
Last Update Posted
December 26, 2025
Last Update Submitted That Met QC Criteria
Last Update Submitted That Met QC Criteria
December 12, 2025
Last Verified
Last Verified
December 1, 2025
More Information
Terms related to this study
Keywords
Other Study ID Numbers
Other Study ID Numbers
- CEP2204
Plan for Individual participant data (IPD)
Plan to Share Individual Participant Data (IPD)?
YES
IPD Plan Description
data freely available in online websites
Drug and device information, study documents
Studies a U.S. FDA-regulated drug product
No
Studies a U.S. FDA-regulated device product
No
This information was retrieved directly from the website clinicaltrials.gov without any changes. If you have any requests to change, remove or update your study details, please contact register@clinicaltrials.gov. As soon as a change is implemented on clinicaltrials.gov, this will be updated automatically on our website as well.
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