H-Reflex Suppression by Bone Myoregulation Reflex During Mechanical Loading in Standing Humans (BMR-HREF)

Istanbul Physical Medicine Rehabilitation Training and Research Hospital

Status

Completed

Conditions

Neuromuscular Physiology

Spinal Reflexes

Weight-Bearing

Posture

H-reflex

Treatments

Procedure: Whole-Body Vibration (WBV)

Study type

Interventional

Funder types

Other

Identifiers

NCT07043595

HReflexBMR2025

Details and patient eligibility

About

This study aims to investigate how standing posture and mechanical loading affect reflex responses in the lower limb. Specifically, it focuses on the H-reflex-a type of spinal cord reflex-and how it changes during quiet standing and whole-body vibration. Ten healthy adult volunteers will participate. Researchers will record electrical responses from the calf muscle (soleus) while participants stand still or are exposed to gentle vibration. The goal is to better understand how the nervous system and skeletal system interact in regulating balance and movement.

Full description

This study investigates the neural mechanisms responsible for suppression of the H-reflex-a spinal monosynaptic reflex-during mechanical loading in the standing position. Previous research has shown that H-reflex amplitude decreases with increasing postural demand, such as during walking or standing compared to lying down. One hypothesis suggests that this suppression may be mediated not only by vestibular and cutaneous afferents, but also by a bone-derived reflex mechanism called the Bone Myoregulation Reflex (BMR).

In this study, 10 healthy adult volunteers will undergo H-reflex measurements while standing in various loading conditions, including quiet standing and during whole-body vibration (WBV). Participants will stand with one foot isolated from vibration while the other foot is on a vibrating platform. H-reflexes will be recorded from the soleus muscle using standard surface electromyography.

The primary aim is to determine whether BMR contributes to H-reflex suppression during loading. The findings may provide insight into the interaction between skeletal loading and spinal reflex modulation, with potential relevance to balance, gait, and rehabilitation science.

Enrollment

10 patients

Sex

All

Ages

20 to 45 years old

Volunteers

Accepts Healthy Volunteers

Inclusion criteria

Healthy adults aged 20 to 45 years
Able to stand independently for at least 10 minutes
No known neurological, orthopedic, or balance disorders
Willingness to participate and provide informed consent

Exclusion criteria

History of spinal cord injury, peripheral neuropathy, or muscle disease
Recent lower limb surgery or musculoskeletal trauma
Current use of medications affecting neuromuscular function
Pregnancy
Any contraindications to exposure to mechanical vibration

Trial design

Primary purpose

Basic Science

Allocation

N/A

Interventional model

Single Group Assignment

Masking

None (Open label)

10 participants in 1 patient group

Postural Loading and Vibration Arm

Experimental group

Description:

Participants in this arm will undergo a sequence of experimental conditions involving postural and mechanical loading. The protocol includes standing quietly on both feet, standing on one foot (right or left), and standing during whole-body vibration (WBV). H-reflex recordings will be obtained from the soleus muscle during each condition to assess changes in spinal reflex excitability.

Treatment:

Procedure: Whole-Body Vibration (WBV)

Trial contacts and locations

Central trial contact

Ilhan Karacan, Prof; Selim Sezikli, MD

Data sourced from clinicaltrials.gov

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