Physical Activity and Respiratory Conditions
Original Editor - Mariam Hashem
- 1 Introduction
- 2 Why Exercise?
- 3 Key Evidence:
- 4 Barriers/Limitations to Physical Activities
- 5 Exercise prescription
- 6 Precautions
- 7 Resources
- 8 References
Chronic respiratory diseases are a group of chronic diseases affecting the airways and the other structures of the lungs. Common chronic respiratory diseases are Asthma, Bronchiectasis, chronic obstructive pulmonary disease COPD, Chronic rhinosinusitis, Hypersensitivity pneumonitis,Lung cancer, cystic fibrosis, Adult Respiratory Distress syndrome
Physical activity (PA) is defined as any bodily movement produced by skeletal muscles which results in energy expenditure. Physical activity in daily life can be categorised into occupational, sports, conditioning, household, or other activities. Exercise is a subset of physical activity that is planned, structured, and repetitive and has as a final or an intermediate objective the improvement or maintenance of physical fitness.
Increased PA is associated with enhanced psychological functioning and quality of life, improved cardiorespiratory ﬁtness, and decreased morbidity.
Increasing physical ﬁtness may be beneficial for children with asthma by increasing exercise tolerance and capacity and, as a consequence, the threshold for inducing a condition called exercise-induced bronchoconstriction. A low level of regular physical activity, in turn, leads to chronic deconditioning. It is not surprising, therefore, that some studies have found that patients with asthma tend to have lower cardiorespiratory fitness than their healthy counterparts. 
Physical training programs in asthma have been designed to enhance aerobic power, neuromuscular coordination, and self-confidence.Reduced activity levels observed in asthmatics may also increase the incidence of obesity, with negative consequences on self-esteem .
Physical activity levels play a key role in the onset of muscle dysfunction and de-conditioning and have been associated with quality of life, hospital admission, co-morbidities, lung function decline and mortality. Skeletal muscle dysfunction is now recognised as a major problem for COPD patients , and, as such, the use of strength training as a modality to reverse the deleterious effects of the disease is now recommended . A recent systematic review demonstrated strength training could improve skeletal muscle strength in COPD patients, and these improvements were associated with increased activities of daily living 
Gardiner et al. showed that a strength training program can decrease the atrophy and strength loss associated with steroid use. They also demonstrated that the extent of fast-twitch muscle atrophy resulting from chronic glucocorticoid treatment can be lessened by mild weight-lifting exercise. 
PA causes a reduction in mortality for patients with COPD
PA has been shown to be the strongest predictor of all-cause mortality in COPD patients, with PA showed the best discriminative properties for 4-year survival. The authors of a large study concluded: "We found that objectively measured physical activity is the strongest predictor of all-cause mortality in patients with COPD".
PA and Lung Function
Despite all the positive effects of PA for people with respiratory conditions, there is no evidence of change in lung function.
- A pilot 6 week excises intervention study measured exercise intensity, attendance rate, recorded respiratory fitness and health related quality of life (HRQoL) pre and post intervention.
- Asthmatic children, even with moderate to severe disease, had their aerobic capacity significantly improved after a 16-wk physical training program.
- Home-based pulmonary rehabilitation improves clinical features and systemic inflammation in chronic obstructive pulmonary disease patients
Barriers/Limitations to Physical Activities
There are many barriers that could limit the participation of a chronic respiratory condition patient in exercises.
Children and adolescents with asthma may experience frustration, embarrassment and low self conﬁdence because of their disease-related limitations. They may also withdraw from PA because of their parents’ fear and protectiveness.
The fear of breathlessness (Dyspnoea) due to cardiovascular disease, peripheral vascular disease, lung cancer, diabetes, dyslipidemia, hypertension, osteoporosis, and psychological disorders inhibits many patients from taking part in PA. Corticosteroid use, overuse of bronchodilators, and interactions with other medications can further complicate management of PA programs in these patients. Other concerns during both rest and exercise include pulmonary hypertension, gas-trapping, dynamic hyperinflation, poor gas exchange, and increased respiratory pressure associated with destruction of lung parenchyma and increased airway resistance.
To facilitate engagement in exercise programs many approaches should be addressed, such as managing acute dyspnoea, Psychosocial and behavioural interventions through educational sessions focusing on specific problems such as stress management, instructions in relaxation exercises, panic control, and smoking cessation. Nutritional interventions should be considered, as well as social support, the option to participate in group activities, and the availability of professional support are frequently reported as enablers of physical activity.
Individualised exercise training prescriptions should be based on patient characteristics, such as baseline pulmonary function, exercise capacity, habitual physical activity levels, inflammation and infection status to establish favourable exercise-training induced effects.
Burr, Davidson, Shephard and Eves Developed two clinical decision trees for assessing the risk of adverse events during PA in patients with COPD ad Asthma. These decision trees can be used to categorise a patient as higher or lower risk, informing the requirements of PA prescription and the monitoring of exercise programs. The info-graphs below illustrate the clinical decision trees:
In patients with advanced COPD, interval exercise consisting of repeated bouts (30–60 s) of high- or even maximal-intensity work (80–100% peak) separated by periods (30–60 s) of lower intensity work intervals, has been shown to be associated with a small increase in arterial lactate concentration, lower ventilation and degrees of dynamic hyperinflation and lower symptoms of dyspnoea and leg discomfort, thus allowing the total amount of work performed to be significantly greater than that of constant-load exercise.
Implementation of high-intensity interval training in patients with COPD has proven to be effective in terms of improvements in muscle fibre oxidative capacity, thus enhancing the utilisation of oxygen by the exercising muscles. 
Moderate aerobic exercises is defined as exercise, which noticeably accelerates heart rate and requires 3.0 to 6.0 metabolic equivalents (METs) (e.g. slow cycling, brisk walking or swimming), whereas vigorous aerobic exercise requires more than 6.0 METs and causes rapid breathing and a substantial increase in heart rate (e.g. running fast, swimming laps, singles tennis)
A large body of evidence demonstrates important health benefits from aerobic exercise, including decreases in dynamic hyperinflation and exertional dyspnea; improved exercise tolerance; and enhanced quality of life, with fewer disease exacerbations and reported sick days.
To optimise the benefits gleaned from a strength training program, the exercise prescription variables of intensity, volume and frequency should be tailored to the needs of each patient.
strength training exercises be performed at an intensity of approximately 60% of the muscle’s maximum force generating capacity to increase strength. To determine the amount of weight of the appropriate stimulus, the common approach is based on a 1 repetition maximum, (1-RM) or the ability to lift or perform a movement only once before fatigue prevents a subsequent contraction. If the weight employed is below 60% of the 1-RM, there may be only modest improvements of 5% to 10% in strength.
The volume of the strength training exercise is a function of the number of repetitions and sets of an exercise completed. For frail patients, the ACSM recommends that at least one set of each exercise be performed. As patients increase the intensity of their exercise prescription, the number of sets of an exercise may also increase. Once the patient can complete the pre-determined number of repetitions for all the prescribed sets, the resistance should be increased. Specific exercises should target strength improvements for the major muscle groups which include the chest, shoulders, arms, upper and lower back, abdomen, hips and legs. One or more exercises can be prescribed for each of these muscle groups depending upon the patient’s specific needs.
The final component of the exercise prescription that needs to be considered is frequency or the number of times the exercise should be performed per week. Outpatient recommendations stipulate that individuals exercise 2 to 3 times per week and to allow 48 hours of recovery between exercise bouts.
Exercises should be discouraged during periods of active infection in patients with Cystic Fibrosis.
patients with substantial hypoxaemia (SpO2 < 90%) at rest or during exertion, uncontrolled asthma, or the presence of pulmonary hypertension should be optimally medically managed before starting exercise
Persons with COPD who wish to become more physically active should be evaluated using a graded exercise test including ECG monitoring and pulse oximetry. Remarkable test results and evidence of serious cardiovascular conditions (ie, angina, ischaemia, complex ectopy, high-degree AV block, uncontrolled blood pressure) should be seen by the appropriate specialist before commencing PA
Supervising exercise professionals should have specific training with and monitor for potential pulmonary related complications as well as complications related to the common sequelae and co-morbidities of COPD
To reduce the risk of exercise-related adverse events, those with asthma should make sure that their disease is properly controlled before becoming more physically active. Those with poor or partial control of their asthma should see their physicians before becoming more active
For individuals who develop EIB or asthma like symptoms with exercise, a rapid-acting β2-agonist should be taken before exercise. Individuals with asthma should also incorporate a progressive warm-up and should try to avoid exercising in the excessive cold or environments with known asthma triggers
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