Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT05478447 |
| Other study ID # |
SSTWBVR |
| Secondary ID |
|
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
September 9, 2022 |
| Est. completion date |
September 30, 2022 |
Study information
| Verified date |
October 2022 |
| Source |
Istanbul Physical Medicine Rehabilitation Training and Research Hospital |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Whole body vibration (WBV) is a therapeutic modality in the form of exercise on a vibrating
platform with an amplitude of 2-4 mm at a frequency of 25-50 Hz, which is used with increased
popularity in sports medicine and rehabilitation due to its beneficial effects on muscle
strength, balance, postural control, bone formation, and circulation. Beneficial effects on
muscle strength and athletic performance have been reported. Spinal reflexes explain these
beneficial neuromuscular effects. However, the neuronal circuit and receptors of the reflex
response have not been defined precisely. A group of researchers propose that the reflex
system underlying the neuromuscular effects of WBV is the Tonic vibration reflex (TVR), whose
receptor is the muscle spindle; other researchers claim that the reflex latency induced by
WBV is 4-5 ms longer than the TVR latency, so it is a bone myoregulation reflex whose
receptor is osteocytes.
The muscle spindle has sympathetic innervation. It has been reported that in case of
increased sympathetic activity, muscle spindle sensitivity may increase and short-latency
stretch reflex may be facilitated. The variation of muscle spindle activity with sympathetic
activity may provide an opportunity to define the nature of the reflex response during WBV.
Muscle spindles are more sensitive to vibrations around 100 Hz. This study has two
hypotheses: According to the first hypothesis, WBV activates muscle spindles and the reflex
latency induced by WBV is the same as TVR latency, and the latency does not change with
increased sympathetic activity. According to the alternative hypothesis, WBV activates
osteocytes, and WBV-induced reflex latency is longer than TVR latency. With increased
sympathetic activity, the WBV reflex becomes dominant and the WBV-induced reflex latency
becomes shorter. The aim of this research is to determine which of these two hypotheses is
valid.
Description:
22 healthy males between the ages of 20 and 45 will be recruited for this study. All subjects
will receive pre-study informed consent. All experimental procedures were designed with the
Helsinki declaration in mind and approved by the local ethics committee. In all subjects,
whole body vibration(WBV) and isolated tendon vibration will be applied before, after, and
during sympathetic activation maneuvers. Reflex responses induced by WBV and isolated tendon
vibration will be recorded by surface electromyography (EMG) from the right soleus muscle.
Latency calculation will be made using the "Cumulative averaging method".
Mental arithmetic task and cold stress test will be applied as sympathetic activation
maneuver. For the mental arithmetic task, the subject is asked to mentally subtract a
two-digit number from a four-digit number and respond within five seconds. This arithmetic
calculation is repeated for different numbers. This test is continued for two minutes. For
the cold stimulation test, subjects are asked to dip their right hand into 2-4 degrees cold
water up to the elbow and hold it in the water for two minutes. At this time, either WBV or
tendon vibration will be applied. After a ten-minute break, a cold stimulation test will be
applied to the left hand and the subject will be asked to do mental arithmetic calculations
simultaneously. Meanwhile, other vibrations will be used. The sympathetic response will be
evaluated by heart rate and sympathetic skin response.
Whole body vibration will be applied to the right leg while subjects are sitting with their
knee, hip, and ankle joints in a 90-degree position.
The left leg will rest on a vibration-isolated platform. During this position, he will be
asked not to voluntarily contract the calf muscle. The vibration will be applied with the
PowerPlate® Pro5 WBV (London UK) device. The vibration amplitude will be 2.2 mm. The
vibration frequency will be 30, 35, 40, and 45 Hz. Each vibration frequency will be applied
for 30 seconds. A 5-second rest period will be applied between 30-second vibrations.
Piezo-electric accelerometer (LIS344ALH, full-scale of ± 6 g, linear accelerometer, ECOPACK®,
Mansfield, TX, USA) will be fixed on the WBV device platform for reflex latency calculation.
For tonic vibration 100, 135, 150, and 180 Hz vibrations will be applied to the Achilles
tendon. 30 seconds of vibration will be applied at each frequency. A direct current (DC)
motor vibrator will be used to apply this vibration (Bosch™, amplitude 2 mm, motor speed
5000-20000 / min). A piezo-electric accelerometer (LIS344ALH, full-scale of ± 6 g, linear
accelerometer, ECOPACK®, Mansfield, TX, USA) will be placed on the skin of the Achilles
tendon to calculate the tonic vibration reflex latency. Superficial EMG recordings will be
taken from the right soleus muscle with the bipolar technique. A pair of self-adhesive
Ag/AgCl (KENDALL® Coviden, Massachusetts, USA) electrodes will be attached to the skin. The
electrodes on the soleus will be positioned according to the SENIAM protocol. The ground
electrode will have adhered to the right lateral malleolus. Before the electrodes are
attached to the skin, if there are hairs on the skin, they will be shaved and the oil layer
on the skin will be cleaned with alcohol cotton. In order to increase the moisture of the
skin, ECG gel will be applied to the skin area where the electrode will be attached.
Superficial EMG recordings will be taken with a PowerLab ® (ADInstrument ADInstruments,
Oxford, UK) data recorder with a sample rate of 40 kHz.
EMG recordings will be analyzed offline with LabChart7 Pro® version 7.3.8 (ADInstrument,
Oxford, UK). The acceleration measurement data will be recorded with the PowerLab
(ADInstrument London) data logger simultaneously with the EMG recording. Acceleration
recording will be made with a sample rate of 40 kHz. Simultaneously, heart rate and
sympathetic skin response will be captured with a Biopac (Biopac System Inc CA) data recorder
at a rate of 20 kHz.
