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Ann Geriatr Med Res > Volume 25(1); 2021 > Article
Ozsoy, Kahraman, Ozsoy, Ilcin, Tekin, and Savci: Effects of an Integrated Exercise Program Including “Functional” Inspiratory Muscle Training in Geriatric Individuals with and without Chronic Obstructive Pulmonary Disease

Abstract

Background

Inspiratory muscle training (IMT) is a commonly used exercise method for both patients with chronic obstructive pulmonary disease (COPD) and the older adult population. In addition to their primary function, respiratory muscles play an active role in core stabilization. However, no IMT program includes both of these functions (i.e., core stabilization and postural control functions as well as respiration). This study investigated the effects of a newly integrated exercise program, termed “functional IMT,” in geriatric individuals with and without COPD.

Methods

This prospective and experimental study included 45 geriatric individuals with COPD (n=22) and without COPD (n=23). The training program consisted of 4 weeks of conventional IMT followed by 4 weeks of functional IMT. Respiratory muscle strength, symptoms, exercise capacity, balance, postural control, physical activity, and quality of life were evaluated.

Results

After training, respiratory muscle strength, symptoms, exercise capacity, balance, postural control, and quality of life improved in both groups (p<0.05). In addition, physical activity was increased in the COPD group (p<0.05). We observed no statistically significant difference in outcomes between the two groups before and after treatment (p>0.05).

Conclusion

The gains were similar in both groups. Functional IMT, which is an integrated approach that includes all respiratory muscle functions, is a safe, effective, and innovative method for use in geriatric individuals with and without COPD.

INTRODUCTION

The incidence of chronic obstructive pulmonary disease (COPD), one of the most important causes of worldwide mortality and morbidity, increases with age; moreover, the disease worsens with aging.1) Airflow obstruction in COPD causes problems with lung hyperinflation and blood gas exchange, a condition that increases respiratory workload. When respiratory muscles cannot meet the demand, dyspnea causes exercise intolerance and eventually leads to physical inactivity.2) Aging increases physical impairment that results in functional disability.3)
Respiratory muscles are skeletal muscles that must maintain continuous activity to ensure life.4) Similar to other skeletal muscles, respiratory muscles can also be trained based on the principles of exercise.5) Inspiratory muscle training (IMT) is an exercise method used for both patients with COPD and the older adult population, with positive effects in both populations.6-8) However, in these studies, the IMT (also known as “foundation or conventional IMT”) focused only on the respiratory task of respiratory muscles. In addition to their basic task of respiration, respiratory muscles are involved in core stabilization and postural control.9) The motor activities of all trunk muscles, including the diaphragm, during both postural and respiratory tasks are coordinated by the central nervous system. The regulation of abdominal pressure occurs through coordinated activities of the abdominal, diaphragm, and pelvic floor muscles, and such modulation is important for postural control and spinal stability.9) Moreover, balance and postural control are impaired in patients with COPD. 10,11)
The idea of a newly integrated exercise program that includes functional IMT, which includes all inspiratory muscle functions, was first proposed by McConnell.5) This program aims to increase the gains by applying exercises addressing all muscle functions,5) whereas foundation IMT mainly targets respiration. However, the contributions of the respiratory muscles to postural control and core stabilization have not been directly addressed in a rehabilitation context. To our knowledge, no previous study has directly assessed the effects of respiratory muscle training together with non-respiratory functions (core stabilization and postural control) in COPD and geriatric rehabilitation programs. Thus, this study aimed to create and investigate the effects of an integrated IMT program for geriatric individuals with and without COPD.

MATERIALS AND METHODS

Study Design and Participants

This prospective experimental study included 45 geriatric individuals (age ≥65 years) with COPD (n=22) and without COPD (n=23) (ClinicalTrials.gov Identifier: NCT04460261). The training program was identical for both groups and consisted of 4 weeks of foundation IMT followed by 4 weeks of functional IMT. Normal spirometry values were set as the inclusion criteria for healthy older adults. The study was announced to healthy older adults via social media and brochures. The Global Initiative for Chronic Obstructive Pulmonary Disease (GOLD) guidelines were used to diagnose COPD. The inclusion criterion for patients with COPD was the diagnosis of COPD—forced expiratory volume in 1 second (FEV1)/forced vital capacity (FVC) ratio <0.7 after bronchodilator administration. At the time of the study, all patients with COPD were in a stable clinical condition (same medication routine for the past 3 weeks without taking any antibiotics). Patients with neurological, orthopedic, or cognitive problems were excluded from the study.
All procedures performed in studies involving human participants or human tissue were conducted according to the ethical standards of the Institutional Ethical Review Board of Dokuz Eylul University (No. 2017/21-50) and the 1975 Declaration of Helsinki and its later amendments or comparable ethical standards. Informed consent was obtained from all participants included in the study.

Outcome Measures

The evaluations were conducted over 2 days. In particular, balance and postural control and exercise capacity tests were conducted on separate days. All performance tests were performed twice to eliminate the learning effect and ensure measurement accuracy.
A computer-based spirometer (Minispir; Medical International Research, Rome, Italy) was used to assess pulmonary function.12)

Primary outcome measures

Inspiratory and expiratory muscle strength: Inspiratory muscle strength (maximal inspiratory pressure [MIP]) and expiratory muscle strength (maximal expiratory pressure [MEP]) were measured using a handheld mouth pressure device (Micro RMP; Micro Medical, Rochester, UK). Three to five acceptable and reproducible maximal maneuvers (i.e., differences between values <10%) were performed, and the highest value was recorded.13)

Secondary outcome measures

Symptoms: The modified Medical Research Council (mMRC) Dyspnea Scale was used to evaluate dyspnea. Commonly used in the assessment of dyspnea in COPD patients, the mMRC has a five-level scoring system ranging from 0 to 4, in which a high score indicates an increased sense of dyspnea.14)
The COPD Assessment Test (CAT) was used to assess symptoms in patients with COPD. The CAT has eight items, with scores ranging from 0 to 40. Higher scores indicate increased symptoms.15)
Functional exercise capacity: The 6-minute walking test (6MWT) and the 6-minute pegboard and ring test (6PBRT) were performed to assess functional exercise capacity. The 6MWT was performed according to American Thoracic Society guidelines16) as follows. The 6MWT was performed on a 32-m continuous track. The 6PBRT was performed as described by Zhan et al.17) to assess unsupported upper-extremity exercise capacity.
Balance and postural control: Balance was assessed using the Berg Balance Scale (BBS). This scale consists of 14 items, each of which is scored between 0 and 4, with higher scores indicating a better balance.18) A portable balance device (Biodex Biosway Portable Balance System, New York, NY, USA) was used to measure static postural stability. A total of three measurements, each for 20 seconds, with a rest period of 10 seconds between measurements, were performed, with higher scores indicating impaired postural control.19)
Physical activity: Physical activity was assessed using the Physical Activity Scale for the Elderly (PASE), a validated 12-item self-administered scale, in which higher scores indicated increased physical activity.20)
Quality of life: Quality of life was assessed using the World Health Organization Quality of Life Instrument-Older Adults Module (WHOQOL-OLD). This questionnaire consists of 24 items in six different domains, with higher scores indicating a better quality of life.21)

Treatment Programs

We divided participants into two groups based on the presence or absence of COPD. Both groups underwent a total of 8 weeks of IMT using a threshold pressure loading device (POWERbreathe Classic Light Resistance; IMT Technologies Ltd., Birmingham, UK). The participants were asked to perform IMT twice daily in the morning and evening. Both groups were trained 3 days a week under physiotherapist supervision and without supervision on the other days of the week. The exercise duration and frequency were recorded in a diary. This study required that participants attend at least 80 prescribed exercise sessions. The treatment program consisted of 4 weeks of foundation IMT followed by 4 weeks of functional IMT.

IMT Intensity

The intensity of the exercise was adjusted to 40%–50% of the MIP. After 10 consecutive breathing cycles, the participants were asked to perform 3–4 breath controls. As tolerance increased, the number of consecutive respiratory cycles increased. The IMT intensity was adjusted using weekly MIP measurements (Table 1).

Foundation IMT

Foundation IMT is commonly used to train respiratory muscles. The present study applied foundation IMT during the first 4 weeks of training. We asked participants to sit in a comfortable upright position. We then placed a nose clip and instructed the patients to tighten their lips around the mouthpiece and breathe against the resistance. During this 4-week-long training, all IMT was performed solely in a sitting position, without any loading in other positions.

Functional IMT

After the foundation IMT, all participants underwent 4 weeks of functional IMT. Initially, all participants were taught diaphragmatic breathing and activation of the abdominal wall musculature. Each training session started with warm-up exercises and ended with cool-down exercises. During the loading phase, core stability, dynamic trunk activation, and postural control exercises were applied together with the IMT. The contents of the exercise program are shown in Table 2 and Fig. 1.

Sample Size

To our knowledge, no other study has investigated the effects of functional IMT in geriatric individuals with and without COPD. However, a previous study showed that IMT increased MIP in older individuals (baseline MIP, 82±27 cmH2O; post-intervention MIP, 103±23 cmH2O).22) Based on these results, we calculated a minimum required sample size of 18 patients per group for an effect size of 0.83. A probability level of 0.05, and a statistical power level of 90% using G*Power Software (ver. 3.1.9.2; Düsseldorf, Germany). Allowing for a 20% dropout rate, this study included 45 participants.

Data Analysis

We analyzed the data using IBM SPSS Statistics for Windows version 20.0. (IBM Corp., Armonk, NY, USA). Shapiro-Wilk tests and histograms were used to check for normality of the data distributions. Values are expressed as mean±standard deviation and median (25th–75th quartiles) for continuous variables and as frequencies for categorical variables. Independent samples t-test (when samples met parametric conditions) and Mann–Whitney U test (when samples did not meet parametric conditions) were used to compare continuous variables between the two groups. Chi-square tests were used to compare categorical variables between the two groups. Paired-sample t-test (when samples met parametric conditions) and Wilcoxon signed-rank test (when samples did not meet parametric conditions) were used to determine the mean differences between before and after treatment.

RESULTS

This study included a total of 45 geriatric individuals (COPD group, n=22; non-COPD group, n=23). Three participants in the COPD group and two in the non-COPD group dropped out. Hence, the study was completed with 19 and 21 participants in the COPD and non-COPD groups, respectively (Fig. 2).
The demographic characteristics (age, sex, weight, height, and body mass index) and cognitive status (Mini-Mental State Examination score) were similar between the groups (p>0.05) (Table 3).
Pulmonary function, respiratory muscle strength (except MIP%), exercise capacity, balance, postural control (except anterior/posterior [score]), physical activity, and quality of life were significantly higher in the non-COPD group than in the COPD group, while symptom scores were significantly higher in the COPD group than in the non-COPD group (all p<0.05) (Table 3).
After training, respiratory muscle strength, symptom perception, exercise capacity, balance, postural control, and quality of life were significantly improved in both groups (p<0.05) (Table 4). Additionally, physical activity was increased in the COPD group (p<0.05) (Table 4).
We observed no statistically significant differences in respiratory muscle strength, symptom perception, exercise capacity, balance, postural control, physical activity, and quality of life between the groups before and after treatment (p>0.05) (Table 4).

DISCUSSION

This is the first study to investigate the effects of a new integrated exercise program, called functional IMT, in geriatric individuals with and without COPD. After the intervention, the gains were similar between groups. In the literature, IMT for COPD patients and geriatric people has focused solely on the respiratory tasks of the inspiratory muscles. However, the inspiratory muscles are also involved in core stabilization and postural control. Muscle training should include all muscle functions for optimal gain. Thus, the training program in the present study included all inspiratory muscle functions, i.e., both respiration and core stabilization.
In our study, 4 weeks of foundation IMT was followed by 4 weeks of functional IMT. The most important indication for IMT is the disturbance of supply/demand balance owing to increased respiratory workload. Increased demand for respiration leads to increased loading of respiratory muscles to meet these needs. In such situations, the respiratory muscles are mainly involved in their primary task of breathing, with their postural stabilization/control functions secondary to the primary task. Enhancing the optimal gain from a muscle training program requires functional training. Functional loading of the respiratory muscles while they lack the strength to perform their primary task of breathing will lead to failure of the muscles to perform optimally. Therefore, we initially applied foundation IMT to strengthen the muscles for respiration. Functional IMT was administered only when the adaptive process was completed.5)
Respiratory muscle training is an exercise method frequently employed for individuals with COPD.23,24) A review investigating the effects of IMT in individuals with COPD reported that the treatment increased inspiratory muscle strength.23) Furthermore, both inspiratory and expiratory muscle strengths improve with IMT.25) Souza et al.8) reported increased diaphragm mobility and thickness and improved inspiratory and expiratory muscle strength in geriatric women following IMT. Another study conducted in a geriatric population showed the development of inspiratory muscle strength with IMT.22) Consistent with the literature showing the positive effects of IMT, functional IMT in our study increased both inspiratory and expiratory muscle strength in geriatric individuals with and without COPD. However, the gains were similar in both groups.
Respiratory muscle weakness plays a predominant role in the development of dyspnea.2) Therefore, studies of COPD often evaluate dyspnea as an outcome measure. Two large systematic reviews examining the effects of IMT on individuals with COPD showed that IMT reduced dyspnea.23,24) In our study, we observed decreased mMRC scores after 8 weeks of IMT, consistent with previous findings. We also observed a decrease in CAT scores after treatment, indicating that functional IMT can reduce dyspnea and general symptom perception in patients with COPD. The effects of IMT in geriatric individuals are mostly assessed relative to respiratory muscle strength and exercise capacity; however, a study investigating the effects on dyspnea reported decreased dyspnea after 6 weeks of training.26) Consistent with the literature, we observed decreased dyspnea following functional IMT in geriatric individuals. However, the difference between the two groups was not statistically significant. These results suggest that functional IMT is an effective method for reducing dyspnea in geriatric individuals with and without COPD.
Functional exercise capacity is one of the most important outcome measures in IMT studies of individuals with COPD.23) There are inconsistent results regarding the effects of IMT on 6MWT distance in geriatric individuals. One study reported significant improvements in 6MWT and 12MWT results in the IMT group compared to those in the control group.23) In contrast, Mills et al. reported no change in 6MWT distance after an 8-week-long IMT in 65- to 75-year-old individuals.22) However, Huang et al.26) reported that functional exercise capacity improved after 6 weeks of IMT in geriatric individuals without COPD. In our study, the 6MWT distance improved after the training program in both groups, indicating that functional IMT is an effective method to increase functional exercise capacity in geriatric individuals with and without COPD.
Studies on exercise capacity in COPD have generally focused on the lower extremities. However, the upper extremities play a key role in performing daily living activities.27) Zhan et al.17) reported that the 6PBRT was a valid and reliable test for individuals with COPD. However, no study has investigated the effect of IMT on 6PBRT in geriatric individuals with and without COPD. We found functional IMT to be an effective method for increasing the unsupported upper-extremity exercise capacity in geriatric individuals with and without COPD. One reason for this finding may be the increased efficiency of respiratory muscles in performing non-respiratory tasks owing to improved strength, which leads to higher exercise capacity in the arms. Decreased dyspnea may also contribute to improved exercise capacity of the upper extremities.
To our knowledge, no other studies have investigated the effects of IMT on balance and postural control in COPD and geriatric individuals, which makes comparisons difficult. In our study, functional IMT yielded similar gains in balance and postural control in geriatric individuals with and without COPD. Further studies on this subject are required.
Physical activity levels were significantly lower in individuals with COPD than in healthy controls.28) Eight weeks of IMT reportedly decreased dynamic hyperinflation and consequently improved physical performance in patients with GOLD stage II–III COPD.29) In our study, the PASE scores of the COPD group increased after the training program. This result shows that functional IMT can improve physical activity in geriatric patients with COPD.
A study including geriatric individuals that evaluated physical activity using an accelerometer reported increased physical activity as a result of an 8-week-long IMT program.30) In contrast with the literature, in our study, the physical activity scores of participants in the non-COPD group were similar before and after the training, which might be due to the differences in the method of evaluating physical activity.
Quality of life in older individuals is a multidimensional concept that is mainly based on perceived health and happiness. Quality of life is affected in patients with COPD; moreover, as the disease severity increases, there is a marked deterioration in the patient quality of life.31) In the literature, quality of life is considered a main outcome of IMT. Two comprehensive reviews stated that IMT improved the quality of life of patients with COPD.23,24) In our study, quality of life improved significantly in the COPD group, indicating that functional IMT can improve the quality of life in these patients.
Contradicting results have been reported regarding the effects of IMT on the quality of life of geriatric individuals. Mills et al.22) concluded that 8 weeks of IMT did not affect the quality of life of geriatric individuals. The results of a study investigating the effects of IMT on the quality of life of physically active geriatric individuals observed no improvement in the quality of life score.32) However, Huang et al.26) studied the effects of 6 weeks of IMT in geriatric individuals and reported improved quality of life. In our study, participants in the non-COPD group showed a significant increase in quality of life scores, thus demonstrating that functional IMT can be effective in increasing the quality of life of geriatric individuals with or without COPD.
This study had some limitations. First, the study did not include a control group, which might have provided clearer information regarding treatment effectiveness. However, there were difficulties in designing treatment applications for the control group. The numerous options include control groups with sham IMT, foundation IMT, postural control, core stabilization, and no intervention. Regardless of the control group, we could not completely demonstrate the effectiveness of functional IMT. Further studies are required on this subject. Second, only acute effects of the training were investigated without any long-term follow-up.
In conclusion, this is the first study to investigate the effects of a newly integrated exercise program, functional IMT, in geriatric individuals with and without COPD. After the intervention, the gains were similar between the groups. Our results of the study suggest that functional IMT is safe and effective in geriatric individuals with and without COPD.

ACKNOWLEDGMENTS

CONFLICT OF INTEREST

The researchers claim no conflicts of interest.

FUNDING

None.

AUTHOR CONTRIBUTION

Conceptualization: IO, BOK, GO, NI, NT, SS; Data curation: IO, BOK, GO; Funding acquisition: IO, BOK, GO, NI, NT, SS; Investigation: IO, BOK; Methodology: IO, BOK, GO, NI, NT, SS; Project administration: IO, SS; Supervision: IO, BOK, GO, SS; Writing-original draft: IO, BOK, GO; Writing-review and editing: IO, NI, NT, SS.

Fig. 1.
The contents of the exercise program. Core stability exercises: (A) plank on the wall, (B) side bridge on the wall, and (C) bridge on the wall. Dynamic trunk activation exercises with upper-extremity movements: (D) shoulder flexion, (E) shoulder abduction, and (F) trunk rotation. Postural control exercises: (G) sit-stand, (H) standing leg lift, and (I) walking.
agmr-21-0014f1.jpg
Fig. 2.
Study flow diagram. COPD, Chronic obstructive pulmonary disease.
agmr-21-0014f2.jpg
Table 1.
IMT programs
Description
Duration Foundation IMT: 4 weeks
Functional IMT: 4 weeks
Intensity Foundation IMT: Weeks 1–2, MIP 40%; weeks 3–4, MIP 50%
Functional IMT: Weeks 5–6, MIP 40%; weeks 7–8, MIP 50%
Frequency Two times daily in the morning and evening
Time A total of 30 minutes per day
Number of repetitions 10 consecutive breathing cycles (3–4 breath control)
A gradually increasing number of cycles depending on tolerance
Exercise load The IMT intensity was adjusted according to weekly MIP measurements

IMT, inspiratory muscle training; MIP, maximal inspiratory pressure (inspiratory muscle strength).

Table 2.
Content of the functional IMT program
Description Exercise time Remark
Warm-up Diaphragmatic breathing exercises 5–10 minutes At the same time IMT
Flexibility exercises
Core stability exercises Plank on the wall 60 seconds, 3 sets
Side bridge on the wall 60 seconds, 3 sets
Bridge on the wall 60 seconds, 3 sets
Dynamic trunk activation exercises with upper-extremity movements Shoulder flexion 8–12 reps, 2 sets
Shoulder abduction 8–12 reps, 2 sets
Trunk rotation 8–12 reps, 2 sets
Postural control exercises Sit-stand 6 reps, 2 sets
Standing leg lift 30 seconds, 2 sets
Walking 30 seconds, 3 sets
Cool-down Flexibility exercises 5 minutes

IMT, inspiratory muscle training; MIP, maximal inspiratory pressure (inspiratory muscle strength).

Table 3.
Demographic and clinical characteristics
COPD group Non-COPD group p-value
Age (y) 78.0 (72.0–85.0) 75.0 (70.0–79.0) 0.270a)
Sex 0.962c)
 Male 58 57
 Female 42 43
Weigh (kg) 72.7±10.7 74.0±12.2 0.740b)
Height (cm) 164.7±9.5 164.6±8.9 0.955b)
BMI (kg/m2) 24.9 (24.1–29.4) 27.1 (24.3–28.8) 0.361a)
GOLD stage
 II 13 -
 III 6 -
MMSE score 27.0 (27.0–28.0) 28.0 (27.0–28.0) 0.525a)
Pulmonary function
 FEV1 (% predicted) 57.2±12.2 101.3±26.5 <0.001*,b)
 FVC (% predicted) 72.7±13.5 93.5±23.0 0.001*,b)
 FEV1/FVC 64.9 (53.7–66.2) 82.4 (80.8–89.1) <0.001*,a)
 PEF (% predicted) 52.0 (40.0–76.0) 93.0 (68.5–130.5) <0.001*,a)
 FEF25–75% (% predicted) 38.0 (25.0–61.0) 95.0 (83.0–156.0) <0.001*,a)
Respiratory muscle strength
 MIP (cmH2O) 43.0 (35.0–79.0) 58.0 (47.0–79.0) 0.031*,a)
 MIP (%) 72.5 (55.0–98.0) 88.1 (72.9–112.9) 0.068a)
 MEP (cmH2O) 72.0 (50.0–105.0) 100.0 (75.0–138.0) 0.036*,a)
 MEP (%) 56.8±19.4 75.1±28.7 0.025*,b)
Symptoms
 mMRC (score) 2.0 (2.0–3.0) 1.0 (0.0–1.0) <0.001*,a)
 CAT (score) 14.8±5.3 -
Exercise capacity
 6MWT distance (m) 350.0 (280.0–393.8) 455.0 (358.8–490.0) 0.012*,a)
 6MWT distance (%) 61.9±13.6 74.3±12.3 0.004*,b)
 6PBRT (score) 111.9±27.7 140.3±27.9 0.003*,b)
Balance and postural control
 Balance
  BBS (0–56) 47.6±3.3 50.3±3.6 0.022*,b)
 Static postural stability
  A/P stability index (score) 0.5 (0.4–0.6) 0.4 (0.3–0.6) 0.111a)
  M/L stability index (score) 0.3 (0.2–0.5) 0.2 (0.1–0.3) 0.018*,a)
  Overall stability index (score) 0.6 (0.5–0.9) 0.4 (0.3–0.8) 0.033*,a)
Physical activity and quality of life
 PASE (score) 68.3±30.4 100.0±35.1 0.004*,b)
 WHOQOL-OLD (score) 54.2 (47.9–58.3) 66.7 (63.5–72.4) <0.001*,a)

Values are expressed as mean±standard deviation or median (25–75 quartiles) for continuous variables and frequencies were reported for categorical variables.

COPD, Chronic obstructive pulmonary disease; BMI, body mass index; GOLD, Global Initiative for Chronic Obstructive Pulmonary Disease; MMSE, Mini-Mental State Examination; FVC, forced vital capacity; FEV1, forced expiratory volume in 1 second; PEF, peak expiratory flow rate; FEF25–75%, forced expiratory flow between 25% and 75% of FVC; MIP, maximal inspiratory pressure; MEP, maximal expiratory pressure; mMRC, modified Medical Research Council; CAT, COPD Assessment Test; 6MWT, 6-minute walk test; 6PBRT, 6-minute pegboard and ring test; BBS, Berg Balance Scale; A/P, anterior/posterior; M/L, medial/lateral; PASE, Physical Activity Scale for the Elderly; WHOQOL-OLD, World Health Organization Quality of Life Instrument-Older Adults Module.

* p<0.05.

a) Mann-Whitney U test,

b) Student t-test,

c) chi-square test.

Table 4.
Comparisons of outcome measures
COPD group
Non-COPD group
p-value
Baseline After p-value Δ Baseline After p-value Δ
Respiratory muscle strength
 MIP (cmH2O) 43.0 (35.0–79.0) 77.0 (49.0–90.0) <0.001*,a) 12.0 (10.0–33.0) 58.0 (47.0–79.0) 81.0 (68.0–98.0) <0.001*,a) 21.0 (12.5–28.5) 0.323c)
 MIP (%) 72.5 (55.0–98.0) 112.7 (90.9–122.3) <0.001*,a) 19.0 (15.9–48.2) 88.1 (72.9–112.9) 115.6 (101.3–156.2) <0.001*,a) 32.4 (16.6–43.0) 0.579c)
 MEP (cmH2O) 72.0 (50.0–105.0) 92.0 (85.0–108.0) <0.001*,a) 19.0 (7.0–29.0) 100.0 (75.0–138.0) 107.0 (89.5–158.0) <0.001*,a) 23.0 (5.5–30.5) 0.776c)
 MEP (%) 57.3 (43.2–65.2) 66.0 (61.1–79.1) <0.001*,a) 12.4 (4.9–21.6) 77.2 (52.0–87.5) 88.2 (69.2–100.9) <0.001*,a) 14.0 (4.2–18.8) 0.989c)
Symptoms
 mMRC (score) 2.0 (2.0–3.0) 2.0 (1.0–2.0) 0.001*,a) –1.0 (–1.0–0) 1.0 (0–1.0) 0 (0–1.0) 0.014*,a) 0 (–1.0–0) 0.064c)
 CAT (score) 14.8±5.3 12.3±4.6 <0.001*,b) - - - - - -
Exercise capacity
 6MWT distance (m) 341.3±91.1 402.0±92.8 <0.001*,b) 60.8±39.4 455.0 (358.8–490.0) 490.0 (402.5–516.3) <0.001*,a) 47.5±35.6 0.269d)
 6MWT distance (%) 61.9±13.6 73.4±15.0 <0.001*,b) 11.5±7.9 77.1 (67.2–81.7) 82.3 (72.8–93.6) <0.001*,a) 8.5±6.3 0.196a)
 6PBRT (score) 111.9±27.7 131.4±26.5 <0.001*,b) 19.5±7.7 140.3±27.9 154.6±29.7 <0.001*,b) 14.2±10.5 0.082d)
Balance and postural control
 Balance
  BBS (0–56) 47.6±3.3 50.3±2.7 <0.001*,b) 2.7±1.8 50.3±3.6 52.4±3.0 <0.001*,b) 2.1±1.4 0.291d)
 Static postural stability
  A/P stability index (score) 0.5 (0.4–0.6) 0.3 (0.3–0.5) 0.001*,a) –0.1 (–0.2–0) 0.4 (0.3–0.6) 0.3 (0.2–0.5) 0.002*,a) –0.1 (–0.1–0) 0.248c)
  M/L stability index (score) 0.3 (0.2–0.5) 0.2 (0.2–0.4) 0.007*,a) 0 (–1.0–0) 0.2 (0.1–0.3) 0.2 (0.1–0.3) 0.046*,a) 0.0 (–1.0–0) 0.296c)
  Overall stability index (score) 0.6 (0.5–0.9) 0.5 (0.4–0.7) 0.001*,a) –0.1 (–0.1–0) 0.4 (0.30–0.8) 0.4 (0.30–0.6) 0.001*,a) –0.1 (–0.1–0) 0.667c)
Physical activity
 PASE (score) 68.3±30.4 80.5±37.9 0.005*,b) 9.5 (–3.7–23.8) 100.0±35.1 101.6±33.2 0.671b) 0.6 (–6.6–16.0) 0.116c)
Quality of life
 WHOQOL-OLD ( score) 54.2 (47.9–58.3) 65.6 (62.5–74.0) <0.001*,a) 10.4 (9.4–12.5) 66.7 (63.5–72.4) 76.0 (72.9–80.2) <0.001*,a) 9.4 (6.3–10.9) 0.095c)

Values are presented as median (25th–75th quartiles) or mean±standard deviation.

COPD, Chronic obstructive pulmonary disease; MIP, maximal inspiratory pressure; MEP, maximal expiratory pressure; mMRC, modified Medical Research Council; CAT, COPD Assessment Test; 6MWT, 6-minute walk test; 6PBRT, 6-minute pegboard and ring test; BBS, Berg Balance Scale; A/P, anterior/posterior; M/L, medial/lateral; PASE, Physical Activity Scale for the Elderly; WHOQOL-OLD, World Health Organization Quality of Life Instrument-Older Adults Module.

* p<0.05.

a) Wilcoxon signed-rank test,

b) paired-samples t-test,

c) Mann-Whitney U test,

d) Student t-test.

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