Clinical Trial Details
— Status: Not yet recruiting
Administrative data
| NCT number |
NCT04983485 |
| Other study ID # |
AIBU-FTR-CT-02 |
| Secondary ID |
|
| Status |
Not yet recruiting |
| Phase |
|
| First received |
|
| Last updated |
|
| Start date |
June 25, 2023 |
| Est. completion date |
August 25, 2023 |
Study information
| Verified date |
October 2022 |
| Source |
Abant Izzet Baysal University |
| Contact |
Eylem TÜTÜN YÜMIN, Assoc Prof. |
| Phone |
05056763191 |
| Email |
eylemtutun78[@]hotmail.com |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Observational
|
Clinical Trial Summary
In the literature, it has been observed that there is an increase in respiratory muscle
activity in individuals with COPD due to the increase in respiratory workload and in response
to the loads given by respiratory muscle training devices. However, no study has been found
in the literature comparing the activation of respiratory muscles during constant threshold
load endurance test and increasing threshold load endurance test performed with respiratory
muscle training devices, which are important for respiratory muscle function evaluation. With
this planned study, it is aimed to contribute to the literature by examining the changes in
muscle activation during the constant threshold load and increasing threshold load endurance
tests where different workloads are given and by comparing these changes.
Description:
Chronic obstructive pulmonary disease (COPD) is a common, preventable and treatable disease
characterized by persistent respiratory symptoms and airway limitation due to airway and/or
alveolar abnormality that is affected by many factors that cause abnormal lung development
resulting from exposure to harmful gases or particles. COPD is known as the fourth most
common cause of death in the world and is expected to rise to third place by the end of 2020.
Physiopathological changes such as airflow limitation, bronchial fibrosis, increased airway
resistance, ciliary dysfunction, gas exchange abnormalities and air trapping occur in COPD.
While smoking is the most common risk factor in COPD; Occupational dust and chemicals, air
pollution, lung growth and development, genetic predisposition such as age and gender, and
exposure to environmental effects. Symptoms such as shortness of breath (dyspnea), cough, and
sputum are common in COPD. In addition to pulmonary changes such as an increase in
respiratory workload in individuals with COPD, there are also extrapulmonary changes such as
respiratory muscle dysfunction.
respiratory muscle dysfunction; It is a decrease in respiratory muscle strength, endurance,
or both, resulting from factors such as elongated diaphragm fibers, increased respiratory
workload, changes in muscle mass and abdominal weight. Strength is defined as the muscle's
capacity to produce power, while endurance is defined as the muscle's ability to sustain a
given force over time (the capacity to resist fatigue). Loss of strength and/or endurance
contributes to diaphragm weakness and impaired performance. Today, respiratory muscle
strength parameters (MIP, MEP) are widely used in the evaluation of respiratory muscle
function. However, evaluation of respiratory muscle endurance is more effective than
respiratory muscle strength in the evaluation of submaximal respiratory muscle contraction,
which is valid for daily activities, and in the clinical, functional and prognostic
evaluation of respiratory muscles. Respiratory muscle endurance can be measured with constant
threshold load and increased threshold load endurance tests. The imbalance between the
function of the respiratory muscles and the respiratory workload they face chronically plays
an important role in the formation of dyspnea and hypercapnia. Neural respiratory impulse
(NRD), which is indirectly measured by electromyogram (EMG) of respiratory muscles, has
attracted attention as a potential physiological marker indicating clinical deterioration due
to imbalance between workload and capacity of respiratory muscles. The neural respiratory
drive (NRD) is the output of the brainstem respiratory centers. NRD is not affected by the
patient's will, is associated with symptoms such as dyspnea, and is usually increased in
COPD.
Mechanical abnormalities such as airflow obstruction, static and dynamic hyperinflation, and
intrinsic positive end-expiratory pressure increase the load on respiratory muscles in
individuals with COPD. Inspiratory muscle contraction is impaired as a result of pressure
changes, muscle shortening, increased contraction rate, change in geometry, and decreased
compliance of the respiratory system. As a result, an increase in muscle activation and NRD
is observed. Those with severe COPD require significantly higher muscle activations, both
electrical and mechanical, to breathe and overcome the respiratory workload than those with
mild to moderate COPD. In individuals with COPD, NRD increases when the load on the
respiratory muscles increases as a result of an increase in respiratory workload, a decrease
in capacity, or a combination of both. Studies have shown that, in addition to respiratory
workload, workloads given with respiratory muscle training devices lead to an increase in the
activation of respiratory muscles.
In the literature, it has been observed that there is an increase in respiratory muscle
activity in individuals with COPD due to the increase in respiratory workload and in response
to the loads given by respiratory muscle training devices. However, no study has been found
in the literature comparing the activation of respiratory muscles during constant threshold
load endurance test and increasing threshold load endurance test performed with respiratory
muscle training devices, which are important for respiratory muscle function evaluation. With
this planned study, it is aimed to contribute to the literature by examining the changes in
muscle activation during the constant threshold load and increasing threshold load endurance
tests where different workloads are given and by comparing these changes.
