Clinical Trial Details
— Status: Enrolling by invitation
Administrative data
| NCT number |
NCT05775835 |
| Other study ID # |
MS2022/032 |
| Secondary ID |
|
| Status |
Enrolling by invitation |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
February 10, 2023 |
| Est. completion date |
March 15, 2024 |
Study information
| Verified date |
March 2023 |
| Source |
Suleyman Demirel University |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Exercise is of great importance in the treatment of hypertension, which is expressed as a
very serious disease, the prevalence of which is increasing day by day in the world and can
cause many complications that are common in society. Exercise methods effective on carotid
intima-media thickness, skeletal muscle architecture, and strength, which are important
markers of hypertension-related organ damage, remain unclear. Strengthening exercises draw
attention as an important approach in the control of hypertension. In order for strengthening
exercises to be effective in the rehabilitation of hypertension, moderate and high-intensity
exercises are recommended. New exercise approach strategies are gaining importance in order
to enable resistance exercise training and to increase muscle mass and strength in the
elderly who have a limitation for the recommended exercise intensity, in patients with
hypertension, and in people with various diseases in which the cardiovascular system is
affected. Whole body vibration (TVV) applications, which have no side effects reported as the
current example of these exercise approaches, attract attention. Many positive effects occur
on the cardiovascular system with the short-term and low-effort application of TVV exercise
approaches, which are frequently used in routine rehabilitation practices. However, when the
literature is examined, the effects of these exercise approaches on carotid intima-media
thickness, which is one of the main markers of hypertension-related organ damage, are
unclear. In addition, the effects of hypertension on quadriceps muscle architecture, which
are expected to be adversely affected as a result of affecting autophagy regulation in
skeletal muscle and causing decreased muscle capillarization, remain unclear. In addition,
there is insufficient data on the effectiveness of strengthening exercises and TVV exercises
on hemodynamic responses and quadriceps muscle strength in hypertensive patients. It will
shed light on the determination of the exercise approach that is most effective on the muscle
architecture, hemodynamic responses and carotid intima-media thickness of hypertensive
patients and that can show these effects without overloading the cardiovascular system.
Description:
Hypertension is a very serious disease that can cause many complications such as stroke,
coronary heart disease, heart failure, kidney failure, and visual impairment, which is more
common in the world. Hypertension-related organ damage (i.e. increased left ventricular mass
index, left atrial dilatation, left ventricular dysfunction, carotid thickening and/or
plaque, increased arterial stiffness, decreased glomerular filtration rate, and urinary
albumin excretion), which is one of the key parameters in linking hypertension with many
diseases, It is considered a strong predictor of cardiovascular disease. As a result of organ
damage associated with hypertension, various changes are encountered in the skeletal and
cardiac muscle and vascular structure. The importance of autophagy regulation specific to
skeletal muscle is known in the structure of skeletal muscle. It has been reported that
hypertension affects autophagy regulation in skeletal muscle, causing a decrease in type I
fiber percentage and size, altered contractive function, and high apoptotic signaling.
Numerous studies have demonstrated an association between vascular status and skeletal muscle
health.In hypertensive patients, the presence of some degenerated capillaries adjacent to the
muscle fibers is interpreted as the beginning of a process of degeneration and reduction in
capillarization. With hypertension, capillaries show morphological changes and the wall
thickness/lumen ratio increases. It is stated that with hypertension, muscle capillarization
and oxygenation decrease and arterial dysfunction in the lower extremities causes decreases
in muscle strength. Considering the data in the literature, it is thought that patients with
hypertension may encounter changes in muscle architecture. Skeletal muscle architecture
(including muscle cross-sectional area, thickness, and angle of fascicle pennation) are key
determinants of a muscle's maximum strength.A tendency to decrease in quadriceps strength has
been described in patients with hypertension. It is thought that this adaptation is probably
related to local changes in the fiber type ratio and area of the VL muscle rather than a
systemic adaptation. In addition, a tissue-specific effect of angiotensin II in skeletal
muscle cell has been described. Accordingly, the release of angiotensin II appears to
contribute to an increase in the lactate/pyruvate ratio caused by an impairment in glucose
supply to skeletal muscle. As a result, hypertension can cause muscle disuse and
deterioration of functional capacity. An increase in carotid intima-media thickness (CIMT),
one of the markers of hypertension-related organ damage, also occurs as a result of changes
in cardiac and vascular structures seen as a result of hypertension. Reversal or reduction of
target organ damage is a valuable parameter in the evaluation of antihypertensive therapy
efficacy, as regression of cardiac and vascular changes has been shown to be associated with
improved prognosis for long-term cardiovascular events. It is important to determine the
necessary treatment approaches to control and reduce these negative changes observed in
hypertensive patients.
Today, lifestyle modifications such as increasing physical activity and regulating nutrition,
as well as antihypertensive drugs, come to the fore in the treatment of hypertension. Regular
exercise has a protective effect in the prevention, treatment and control of hypertension.
Regular exercise as a part of lifestyle change seems to be as effective as drugs in the
treatment of hypertension. With regular exercise, an average of 5 mmHg reduction in blood
pressure can be achieved. With a 5 mmHg decrease in systolic blood pressure, death due to
coronary heart disease decreases by 9%, death due to stroke by 14%, and death due to all
causes by 7%. Muscle capillary enlargement and thus an increased capillary density have also
been reported in hypertensive patients with exercise training. Considering these reasons,
regular exercise should be recommended for all individuals, including normotensives,
prehypertensives and hypertensives.
The importance of strength training, like many exercise approaches, in reducing resting blood
pressure in hypertensive patients is known. It has been reported that a significant reduction
in systolic and diastolic blood pressures was observed in all of the quadriceps, latissimus
dorsi and biceps muscles after strengthening exercises and compared to resting pressure
levels at different exercise intensities. Additionally, it has been shown that the change in
blood pressure is greater when strengthening exercise is given to the quadriceps muscle.
Resistant arterial hypertension can cause muscle disuse and decrease in functional capacity
due to arterial and target organ lesions. In addition to the cardiovascular effects of
strengthening exercises, the effects of increasing muscle strength and reducing high blood
pressure observed during exercise have been reported. It has been stated that the
strengthening exercise program given for the quadriceps in patients with resistant
hypertension effectively increases the quadriceps muscle strength by increasing the maximum
isometric contraction values of the vastus lateralis and vastus medialis without adversely
affecting the cardiovascular variables. In another study, a decrease in the waist
circumference, pre-peritoneal (visceral) and thigh fat thickness, and an increase in the
thigh muscle thickness were reported in exercises such as squats and taking a step forward
for 12 weeks.Strengthening exercises are known to be effective in increasing rectus femoris
muscle thickness and muscle strength in overweight or obese women with metabolic syndrome,
but there is a lack of literature on the effect of strengthening exercises on muscle
architecture in hypertensive patients. The increase in carotid intima-media thickness, which
is one of the important markers associated with hypertension, is due to thickening of the
intima and/or media layer. Atherosclerosis, which is primarily caused by endothelial
dysfunction, is responsible for intimal thickening, and smooth muscle hypertrophy, usually
due to hypertension, is responsible for median thickening. Strengthening exercises combined
with aerobic exercise are known to be effective in reducing carotid intima-media thickness in
overweight and obese, young and old women. In addition, a relationship has been shown between
the change in carotid intima-media thickness and walking speed, which is one of the
parameters of the functional level. It is known that regular exercise also delays carotid
intima-media thickness in hypertensive patients, but the effects of strengthening exercise on
carotid intima-media thickness in hypertensive patients are unclear.
It is recommended that the strengthening exercise, which should be planned to increase muscle
strength in hypertensive patients, should be at an intensity of 70% of 1 maximum repetition
on average. However, people with cardiovascular diseases or hypertension may be at risk of
overloading the cardiovascular system and an increased risk of cardiac events when performing
high-intensity resistance exercises. New exercise approach strategies are gaining importance
in order to enable resistance exercise training and to increase muscle mass and strength in
the elderly who have a limitation for the recommended exercise intensity, in patients with
hypertension, and in people with various diseases in which the cardiovascular system is
affected. A current example of these exercise approaches are exercises with whole body
vibration. Whole body vibration (WBV) exercises are a new exercise training option that can
reduce the time and effort required to achieve significant musculoskeletal and cardiovascular
system gains. WBV exercises are performed while standing on a platform that creates repeated
and rapid swings and supports automatic body adaptations. These dynamic oscillations provide
repeated and intense eccentric-concentric muscle contractions that reinforce the normal
muscle contractions performed. Adding whole body vibration application to strengthening
exercises increases the oxygen demand of the muscle during exercise. In a study evaluating
the acute effects of whole-body vibration in prehypertensive patients, it was reported that
whole-body vibration applications combined with resistance exercise increased post-exercise
hypotension responses and post-exercise oxygen consumption more.Alternatively, whole body
vibration exercise (WBV) training is known to be a potential rehabilitation method for muscle
and artery function. It has been reported that whole body vibration exercise training in
postmenopausal hypertensive women reduces cardiovascular risks by improving aortic wave
reflection, muscle strength, systemic and leg arterial stiffness. In another study, it was
stated that 8-week whole body vibration training was effective in improving semoatovagal
balance and blood pressure. It is predicted that when the body is exposed to vibration, it
induces rhythmic muscle contractions that can cause changes in peripheral arteries. The
expansion of capillaries in the muscles facilitates the exchange of nutrients, metabolic
byproducts and oxygen between cells and capillaries. Whole body vibration applications are
promising in the treatment of deterioration in muscle architecture, which can be seen as a
result of decreased muscle capillarization and oxygenation associated with hypertension. In a
study examining the effects of 6-week whole body vibration and traditional strengthening
exercises on vascular adaptation in healthy adults, it was shown that whole body vibration
was effective in reducing carotid intima-media thickness. However, the effect of whole body
vibration on carotid intima-media thickness, which is also an indicator of arterial
stiffness, is unclear in hypertensive patients. It has been shown that WBV exercises have
similar effects on muscle strength and arterial stiffness as strengthening exercises in a
wide range of populations, with the greatest effect in elderly individuals with limited
muscle function. Similarly, there are various studies showing the effect of whole body
vibration exercises on muscle strength and muscle architecture in different patient groups,
but the literature on the effectiveness in hypertensive patients is insufficient.
When the data in the literature is examined, the importance of determining the effects of
whole body vibration and strengthening exercises on carotid intima media thickness and muscle
architecture in hypertensive patients draws attention. In our study, it is aimed to determine
the effects of whole body vibration (WBV) and strengthening exercises (SE) on hemodynamic
responses, carotid intima-media thickness, quadriceps muscle strength and architecture in
hypertensive patients in the light of information in the literature.
