WBV Reflex Latency and Mechanical Load (WBV-BMR)

Selim Sezikli

Status

Completed

Conditions

Whole-body Vibration

Postural Balance

Muscle Contraction

Healthy Volunteers (HV)

Electromyography

Treatments

Device: Whole-Body Vibration

Study type

Interventional

Funder types

Other

Identifiers

NCT07170709

2017.124.IRB2.038 (Other Identifier)

WBV-BMR-2025-01

Details and patient eligibility

About

This study aims to investigate how the magnitude of mechanical loading affects reflex latency patterns induced by whole-body vibration (WBV). WBV can trigger two types of reflexes: the tonic vibration reflex (TVR) and the bone myoregulation reflex (BMR), which may be influenced by load-bearing condition. The study will include healthy adult volunteers aged 20-50 years. Reflex responses will be recorded from the soleus muscle using surface EMG during both WBV. Different conditions of mechanical loading (i.e., standing on one foot, both feet) and vibration frequencies (30-36 Hz) will be tested. The main outcome will be the latency of the reflex responses, which will help distinguish between TVR and BMR activation. The goal is to better understand how mechanical load modifies reflex response timing and to characterize the underlying afferent pathways. This knowledge may contribute to optimizing vibration-based rehabilitation strategies.

Full description

This study investigates how the magnitude of mechanical loading alters reflex latency patterns during whole-body vibration (WBV), focusing specifically on the tonic vibration reflex (TVR) and the bone myoregulation reflex (BMR). Experimental data suggest that WBV may activate different reflex mechanisms depending on the level of postural loading, frequency, and amplitude of the vibration. Previous studies have shown that low-amplitude WBV tends to activate TVR under voluntary contraction, while higher mechanical loads and neutral standing posture are more likely to induce BMR.

Surface electromyography (sEMG) recordings will be obtained from the soleus muscle during vibration stimuli applied at different frequencies (30, 32, 34, and 36 Hz). Recordings will be taken under multiple loading conditions: standing on both feet, standing on one foot. Reflex latency will be calculated using cumulative averaging techniques, and data will be analyzed offline using Spike2 software.

Findings from this study may contribute to a deeper understanding of reflex integration during vibratory stimulation and inform future neurorehabilitation protocols that utilize WBV as a therapeutic modality.

Enrollment

36 patients

Sex

All

Ages

18 to 45 years old

Volunteers

Accepts Healthy Volunteers

Inclusion criteria

Aged between 18 and 40 years
Healthy adult volunteers with no known neurological or musculoskeletal disorders
Able to provide informed consent
Willing to comply with the procedures of the study, including EMG and vibration exposure

Exclusion criteria

History of any neurological condition (e.g., peripheral neuropathy, spinal cord injury, stroke)
Musculoskeletal injury or surgery involving the lower extremities
Use of medications affecting neuromuscular function
Pregnancy
Presence of implanted electronic devices (e.g., pacemaker)
Known intolerance to vibration exposure

Trial design

Primary purpose

Basic Science

Allocation

N/A

Interventional model

Single Group Assignment

Masking

None (Open label)

36 participants in 1 patient group

Whole-Body Vibration in Healthy Volunteers

Experimental group

Description:

Participants will receive whole-body vibration (WBV) under mechanical loading conditions. Surface EMG recordings from the soleus muscle will be used to evaluate reflex latency at vibration frequencies of 30, 32, 34, and 36 Hz. All interventions will be applied in a single-session experimental design in healthy adult volunteers.

Treatment:

Device: Whole-Body Vibration

Trial contacts and locations

Central trial contact

Ilhan Karacan, Prof; Selim Sezikli, MD

Data sourced from clinicaltrials.gov

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