The goal of this observational study is to examine the effects of traditional respiratory rehabilitation and respiratory muscle strengthening training added to this program at the genetic level in asthma. The main questions it aims to answer are: * Does respiratory muscle strengthening exercise added to respiratory rehabilitation in asthmatic patients have additional benefits on rehabilitation outcome measures such as exercise capacity, shortness of breath, and muscle strength? * Does the gain obtained with respiratory muscle strengthening in asthmatic patients increase the quality of life of patients and have a positive effect on their psychological state? * Does respiratory rehabilitation applied to asthmatic patients have an effect on genetic changes? * Does respiratory muscle strengthening training applied in addition to respiratory rehabilitation in asthmatic patients have an effect on genetic changes? * Participants will be included in two different respiratory rehabilitation programs with and without respiratory muscle training, and pre- and post-treatment rehabilitation criteria and genetic changes will be compared.
Asthma is the most common chronic respiratory disease worldwide, characterized by inflammation in the respiratory tract accompanied by bronchoconstriction, edema, and increased mucosa. Oxidative stress causes smooth muscle contraction, proliferation, and hypersensitivity of the airways, while hypoxia and systemic inflammation weaken the respiratory muscles. Lung hyperinflation in asthmatic patients causes an increase in the work of breathing. The increased workload on the respiratory muscles increases the respiratory frequency and causes dyspnea. Pharmacological agents, allergen avoidance, lifestyle modification, anti-IgE antibodies and selectively alternative/complementary drugs or non-pharmacological methods (including breathing exercises, pulmonary rehabilitation, yoga and inspiratory muscle training) are applied in the treatment of asthma. Exercise training; it has been reported to improve asthma symptoms, quality of life, exercise capacity, bronchial hyperresponsiveness, exercise-induced bronchoconstriction and cardiopulmonary fitness and reduce airway inflammation and nighttime symptoms in asthmatic patients. In addition, asthma control can be increased with appropriate timing and intensity of exercise-based PR. The physiological effect of inspiratory muscle training is to weaken the metaboreflex mechanism, possibly reducing the activity of chemosensitive afferents and sympathetic nerve stimulation. Inspiratory muscle training stimulates structural and biochemical adaptations within the inspiratory muscles. It is stated in the literature that physiotherapy approaches such as breathing exercises and respiratory muscle training provide clinical benefits by increasing inspiratory muscle strength and reducing symptoms and the need for bronchodilators. In recent years, the role of lncRNAs has also been emphasized in studies conducted on asthma patients. LncRNAs are long non-coding RNAs and there are studies indicating that they play an important role in the regulation of asthma. However, there is no study in the literature examining the effect of exercise training on lncRNA MALAT1 in asthmatic patients. Asthma is the most common chronic respiratory disease worldwide, characterized by inflammation in the respiratory tract accompanied by bronchoconstriction, edema, and increased mucosa. Oxidative stress causes smooth muscle contraction, proliferation, and hypersensitivity of the airways, while hypoxia and systemic inflammation weaken the respiratory muscles. Lung hyperinflation in asthmatic patients causes an increase in the work of breathing. The increased workload on the respiratory muscles increases the respiratory frequency and causes dyspnea. Pharmacological agents, allergen avoidance, lifestyle modification, anti-IgE antibodies and selectively alternative/complementary drugs or non-pharmacological methods (including breathing exercises, pulmonary rehabilitation, yoga and inspiratory muscle training) are applied in the treatment of asthma. Exercise training; it has been reported to improve asthma symptoms, quality of life, exercise capacity, bronchial hyperresponsiveness, exercise-induced bronchoconstriction and cardiopulmonary fitness and reduce airway inflammation and nighttime symptoms in asthmatic patients. In addition, asthma control can be increased with appropriate timing and intensity of exercise-based PR. The physiological effect of inspiratory muscle training is to weaken the metaboreflex mechanism, possibly reducing the activity of chemosensitive afferents and sympathetic nerve stimulation. Inspiratory muscle training stimulates structural and biochemical adaptations within the inspiratory muscles. It is stated in the literature that physiotherapy approaches such as breathing exercises and respiratory muscle training provide clinical benefits by increasing inspiratory muscle strength and reducing symptoms and the need for bronchodilators. In recent years, the role of lncRNAs has also been emphasized in studies conducted on asthma patients. LncRNAs are long non-coding RNAs and there are studies indicating that they play an important role in the regulation of asthma. However, there is no study in the literature examining the effect of exercise training on lncRNA MALAT1 in asthmatic patients. The research is a preliminary study for further studies in this field.Asthma is the most common chronic respiratory disease worldwide, characterized by inflammation in the respiratory tract accompanied by bronchoconstriction, edema, and increased mucosa. Oxidative stress causes smooth muscle contraction, proliferation, and hypersensitivity of the airways, while hypoxia and systemic inflammation weaken the respiratory muscles. Lung hyperinflation in asthmatic patients causes an increase in the work of breathing. The increased workload on the respiratory muscles increases the respiratory frequency and causes dyspnea. Pharmacological agents, allergen avoidance, lifestyle modification, anti-IgE antibodies and selectively alternative/complementary drugs or non-pharmacological methods (including breathing exercises, pulmonary rehabilitation, yoga and inspiratory muscle training) are applied in the treatment of asthma. Exercise training; it has been reported to improve asthma symptoms, quality of life, exercise capacity, bronchial hyperresponsiveness, exercise-induced bronchoconstriction and cardiopulmonary fitness and reduce airway inflammation and nighttime symptoms in asthmatic patients. In addition, asthma control can be increased with appropriate timing and intensity of exercise-based PR. The physiological effect of inspiratory muscle training is to weaken the metaboreflex mechanism, possibly reducing the activity of chemosensitive afferents and sympathetic nerve stimulation. Inspiratory muscle training stimulates structural and biochemical adaptations within the inspiratory muscles. It is stated in the literature that physiotherapy approaches such as breathing exercises and respiratory muscle training provide clinical benefits by increasing inspiratory muscle strength and reducing symptoms and the need for bronchodilators. In recent years, the role of lncRNAs has also been emphasized in studies conducted on asthma patients. LncRNAs are long non-coding RNAs and there are studies indicating that they play an important role in the regulation of asthma. However, there is no study in the literature examining the effect of exercise training on lncRNA MALAT1 in asthmatic patients. The research is a preliminary study for further studies in this field.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
84
In the other arm of the study, respiratory muscle training is performed in addition to the "standard pulmonary rehabilitation program." Respiratory muscle strengthening training is performed with a resistive thereshold inspiratory muscle strengthening device. The exercise is performed at an intensity of 30% of the maximum inspiratory pressure determined by mouth pressure measurement. The exercise is performed in 7 sets, with 2 minutes of work and 1 minute break for a total of 21 minutes.
Patients are asked to perform thoracic, diaphragmatic breathing, and lower basal breathing exercises with 10 repetitions. Then, strengthening exercises are performed on the major muscle groups of the upper and lower extremities. In accordance with the resistance training program in the ATS/ERS guidelines for pulmonary rehabilitation, two to four sets of 6-12 repetitions are performed with intensities ranging from 50% to 85% of one maximum repetition, two to three times a week. During the exercises, the patient is questioned about their fatigue and dyspnea levels using the Borg scale, and breaks are given when necessary. The aerobic exercise program is performed as a 12-week, 3-day-a-week self-walking exercise. The walking program is performed in the form of walking on flat ground at 60% workload, based on the data obtained from the 6-minute walking test result (land-based walking).
Peripheral blood samples will be taken once from the participants in the control group and no other intervention will be performed.
University of Health Sciences
Istanbul, Turkey (Türkiye)
lncRNA MALAT1 expression levels
Real-time PCR will be performed twice for each sample for each gene, and after all the steps, ΔCT, ΔΔCT, 2\^(ΔΔCT) fold change in expression between the experiment and control.
Time frame: Baseline and 12 weeks
Respiratory Muscle Strength Measurement
The patient is seated in a straight-backed chair. The patient is asked to grasp the silicone mouthpiece with his/her mouth and inhale and exhale as quickly and deeply as possible. The measurements are repeated until 3 measurement values are obtained with a maximum of 10% deviation between the measured peak value. The maximum value is taken among the measured values.
Time frame: Baseline and 12 weeks
Forced Expiratory Volume in 1 s (FEV1 )
FEV1 will perform by using the Pony Fx spirometry device, and according to the American Thoracic Society (ATS) guidelines.
Time frame: Baseline and 12 weeks
Exercise capacity
A 6-minute walk test is performed for exercise capacity. After resting in a chair for a sufficient period (\>30 minutes), patients walk as fast as possible, without running, for 6 minutes on a straight 30-meter corridor. Before and after the test, the patient's fatigue and dyspnea are questioned using the Modified Borg Scale. Oxygen saturation and heart rate are monitored and recorded using a finger pulse oximeter before, during, and after the test.
Time frame: Baseline and 12 weeks
Forced Vital Capacity (FVC)
FVC will perform by using the Pony Fx spirometry device, and according to the American Thoracic Society (ATS) guidelines.
Time frame: Baseline and 12 weeks
FEV1/FEVC
FEV1/FEVC will perform by using the Pony Fx spirometry device, and according to the American Thoracic Society (ATS) guidelines.
Time frame: Baseline and 12 weeks
Asthma Control Test (ACT-ACQ)
ACQ is a scale that evaluates the patient's perspective on their current asthma control level, which can be used to evaluate the general status of their asthma control. The test consists of five questions, the highest score is 25 and the lowest score is zero. A score of 25 indicates full control, while a score between 24-20 indicates partial control. A score below 19 on the scale indicates that asthma is uncontrolled.
Time frame: Baseline and 12 weeks
Asthma Quality of Life Scale (AQLQ)
It is a 32-question asthma-specific quality of life scale. It evaluates the responses with a 7-point scale (1: Severe effect, 7: No effect). It consists of 12 different questions about asthma symptoms, 11 about activity limitation, 5 about emotional function and 4 about environmental factors. Total score average and average scores for sub-dimensions are calculated.
Time frame: Baseline and 12 weeks
Modified Medical Research Council (mMRC) Dyspnea Scale
mMRC is a 0-4 point category scale where patients select the value that best describes their level of dyspnea. Increases in mMRC levels, especially values of 2 and above, are considered to indicate an increased risk of mortality.
Time frame: Baseline and 12 weeks
International Physical Activity Questionnaire-Short form (IPAQ-SF)
It is an internationally valid questionnaire for the assessment of physical activity. The short form of the questionnaire consists of seven questions and provides information about the time spent in sitting, walking, moderate and intense activities. A score is obtained as "MET-minutes/week" by multiplying minutes, days and MET values. The numerical values obtained are classified as inactive, minimally active or very active.
Time frame: Baseline and 12 weeks
Digital muscle strength measurement
Muscle strength is assessed using an electronic hand dynamometer. The patient is asked to maintain muscle strength against the dynamometer for at least 5 seconds in each attempt, with the force measurement repeated 3 times. The best value from the 3 test results is recorded.
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Time frame: Baseline and 12 weeks
Hospital Anxiety and Depression Scale (HADS)
It is a scale that questions whether patients have clinical symptoms of anxiety and depression. HADS-A is the anxiety subscale and consists of 7 questions, while HADS-D is the depression subscale and consists of 7 questions. Scoring is between 0-21 for both tests. An increase in the score on the scale means that the severity of anxiety and depression increases. The cut-off points were 10 for the anxiety subscale and 7 for the depression subscale.
Time frame: Baseline and 12 weeks