Abstract
In spite of intensive investigations, the role of spontaneous breathing (SB) activity in ARDS has not been well defined yet and little has been known about the different contribution of inspiratory or expiratory muscles activities during mechanical ventilation in patients with ARDS. In present study, oleic acid-induced beagle dogs’ ARDS models were employed and ventilated with the same level of mean airway pressure. Respiratory mechanics, lung volume, gas exchange and inflammatory cytokines were measured during mechanical ventilation, and lung injury was determined histologically. As a result, for the comparable ventilator setting, preserved inspiratory muscles activity groups resulted in higher end-expiratory lung volume (EELV) and oxygenation index. In addition, less lung damage scores and lower levels of system inflammatory cytokines were revealed after 8 h of ventilation. In comparison, preserved expiratory muscles activity groups resulted in lower EELV and oxygenation index. Moreover, higher lung injury scores and inflammatory cytokines levels were observed after 8 h of ventilation. Our findings suggest that the activity of inspiratory muscles has beneficial effects, whereas that of expiratory muscles exerts adverse effects during mechanical ventilation in ARDS animal model. Therefore, for mechanically ventilated patients with ARDS, the demands for deep sedation or paralysis might be replaced by the strategy of expiratory muscles paralysis through epidural anesthesia.
Highlights
The expiratory muscle of animal model was paralyzed through epidural anesthesia, and inspiratory muscle through phrenic nerve paralysis, to establish a model maintaining diaphragm activity and one preserving abdominal muscles respectively
The aim was to explore the impacts and mechanism of inspiratory and expiratory muscles activities during mechanical ventilation in acute respiratory distress syndrome (ARDS) animal model and test the hypothesis that the demands for deep sedation or paralysis might be replaced by the strategy of expiratory muscles paralysis through epidural anesthesia
On the basis of the ARDS animal model, the research findings indicate that the activation of inspiratory muscles increased end-expiratory “baby lung” volume (EELV), improved oxygenation and decreased lung injury scores
Summary
A recent study has demonstrated that the shear force produced by the alveolar opening and closing of lung increases the mortality in ARDS patients[22,23]. In view of the advantages and disadvantages of SB during mechanical ventilation in patients with ARDS, it was hypothesized that the activity of inspiratory muscles had beneficial effects, while that of expiratory muscles had adverse effects. The expiratory muscle of animal model was paralyzed through epidural anesthesia, and inspiratory muscle through phrenic nerve paralysis, to establish a model maintaining diaphragm (inspiratory muscle) activity and one preserving abdominal muscles (expiratory muscle) respectively. The aim was to explore the impacts and mechanism of inspiratory and expiratory muscles activities during mechanical ventilation in ARDS animal model and test the hypothesis that the demands for deep sedation or paralysis might be replaced by the strategy of expiratory muscles paralysis through epidural anesthesia
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