Abstract
The resistive work of breathing against an external load during inspiration (WRI) was measured at the mouth, during sub-maximal exercise in healthy participants. This measure (which excludes the elastic work component) allows the relationship between resistive work and power, ventilation and exercise modality to be explored. A total of 45 adult participants with healthy lung function took part in a series of exercise protocols, in which the relationship between WRI, power of breathing, PRI and minute ventilation, were assessed during rest, while treadmill walking or ergometer cycling, over a range of exercise intensities (up to 150 Watts) and ventilation rates (up to 48 L min−1) with applied constant resistive loads of 0.75 and 1.5 kPa.L.sec−1. Resting WRI was 0.12 JL−1 and PRI was 0.9 W. At each resistive load, independent of the breathing pattern or exercise mode, the WRI increased in a linear fashion at 20 mJ per litre of , while PRI increased exponentially. With increasing resistive load the work and power at any given increased exponentially. Calculation of the power to work ratio during loaded breathing suggests that loads above 1.5 kPa.L.sec−1 make the work of resistive breathing become inhibitive at even a moderate (>30 L sec−1). The relationship between work done and power generated while breathing against resistive loads is independent of the exercise mode (cycling or walking) and that ventilation is limited by the work required to breathe, rather than an inability to maintain or generate power.
Highlights
Resistive loads are used to train respiratory muscles in athletes and in rehabilitation of people with pulmonary disease or spinal injuries [1,2,3]
This study aims to use a new non-invasive method to measure the resistive work of breathing and the subsequent power generated (WRI and PRI respectively) while breathing against added resistive loads and explore this relationship with ventilation during sub-maximal exercise, sitting, walking or cycling
The study describes a method for assessing resistive work and power during inspiration during sub-maximal exercise while either walking or cycling and shows that while WRI increases linearly with ventilation rate, the associated power output increases exponentially (Fig. 1)
Summary
Resistive loads are used to train respiratory muscles in athletes and in rehabilitation of people with pulmonary disease or spinal injuries [1,2,3]. Resistive work is dependent on ventilation, and different exercise modes, for example walking and cycling place different metabolic demands on the body. A measure of the work performed during breathing can be derived from the product of the volume and pressure change generated during the respiratory cycle. The mechanical work of breathing which includes the elastic and resistive components, defined per litre of ventilation in resting healthy subjects is around 0.3560.1 JL21 while the power generated is around 2.460.7 W [5]. The power generated is influenced by respiratory rate and volume of air moved. Measuring these parameters often involve using invasive techniques and require an estimate of chest wall compliance [6]
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