The Effects of Positive Expiratory Pressure Breathing on The Rate of Post-exercise Recovery in Patients With COPD

Chronic obstructive pulmonary disease (COPD) was the 4th leading cause of morbidity and mortality worldwide in 2012 and represents an important public health challenge that is both preventable and treatable. COPD is characterized by persistent airflow limitation that is usually progressive and associated with an enhanced chronic inflammatory response in the airways and the lung to noxious particles or gases.

The pathophysiological hallmark of COPD is an expiratory air flow limitation. During exercise, increasing ventilatory demands can induce premature airway closure by forced expiration leading to air trapping and further leading to lung hyperinflation. Dynamic hyperinflation (DH) during exercise contributes to increased end expiratory lung volume (EELV), reduces inspiratory capacity (IC), and increases the mechanical load on inspiratory muscles leading to dyspnea, exercise intolerance, limited physical activity, and thus to a poor quality of life in COPD patients. In addition, abnormal lung mechanical function during dynamic hyperinflation leads to increased sensation of dyspnea, which is the disparity between respiratory drive and the respiratory mechanical response. Abnormal controls of blood chemicals and of vasculature factors also aggravate the sensation of dyspnea.

The autonomic dysfunction (AD) that occurs in the patients with COPD is evident as an inability of heart rate to reach an appropriate level during exercise (chronotropic incompetence; CI). There is also a prolonged heart rate recovery (HRR) at the end of exercise which may contribute to increase dyspnea sensations and increased mortality rate in COPD.

Expiratory flow retardation when breathing with a positive expiratory pressure (PEP) device is the one of various techniques to manage dyspnea in COPD. Most studies using a PEP device have focused on investigating the effects of PEP to reduce lung hyperinflation, reduce dyspnea, and increase exercise capacity. Only one study of Martin and Devenport, has examined the effects of PEP breathing during the recovery periods after exercise and found that following 6 minutes sub-maximal treadmill walking, 6 breath exhalation against a 10 cmH2O threshold PEP reduced dyspnea and increased HRR. Oxygen pulse saturation (SpO2) was also increased within 2 minutes although there was no statistical significant between groups.