| P50 | author | Bradley A. Edwards | Q42177776 |
| | Danny J Eckert | Q43063110 |
| | Scott A Sands | Q43063117 |
| | Andrew Wellman | Q113272734 |
| P2093 | author name string | Atul Malhotra | |
| | James P Butler | |
| | David P White | |
| | Robert L Owens | |
| P2860 | cites work | Influence of head extension, flexion, and rotation on collapsibility of the passive upper airway. | Q30490443 |
| | Induction of upper airway occlusion in sleeping individuals with subatmospheric nasal pressure | Q33471794 |
| | Predictors of response to a nasal expiratory resistor device and its potential mechanisms of action for treatment of obstructive sleep apnea | Q34585400 |
| | Response of genioglossus muscle to increasing chemical drive in sleeping obstructive apnea patients | Q35110556 |
| | Acute upper airway responses to hypoglossal nerve stimulation during sleep in obstructive sleep apnea. | Q35813639 |
| | Upper airway collapsibility and patterns of flow limitation at constant end-expiratory lung volume | Q36320852 |
| | Contribution of male sex, age, and obesity to mechanical instability of the upper airway during sleep | Q36776107 |
| | The influence of end-expiratory lung volume on measurements of pharyngeal collapsibility. | Q37174703 |
| | Adult obstructive sleep apnoea. | Q37540226 |
| | Biomechanical properties of the human upper airway and their effect on its behavior during breathing and in obstructive sleep apnea | Q38119057 |
| | Is the pharynx a muscular hydrostat? | Q38699238 |
| | Onset of airflow limitation in a collapsible tube model: impact of surrounding pressure, longitudinal strain, and wall folding geometry. | Q39949915 |
| | The pharyngeal critical pressure. The whys and hows of using nasal continuous positive airway pressure diagnostically | Q41169490 |
| | Motor control of the pharyngeal musculature and implications for the pathogenesis of obstructive sleep apnea | Q41403317 |
| | Pharyngeal wall fold influences on the collapsibility of the pharynx | Q42655049 |
| | The effect of diaphragm contraction on upper airway collapsibility. | Q43852618 |
| | CrossTalk opposing view: the human upper airway during sleep does not behave like a Starling resistor | Q43858756 |
| | Effect of uvulopalatopharyngoplasty on upper airway collapsibility in obstructive sleep apnea | Q44020532 |
| | A threshold lung volume for optimal mechanical effects on upper airway airflow dynamics: studies in an anesthetized rabbit model | Q46543706 |
| | Effect of weight loss on upper airway collapsibility in obstructive sleep apnea | Q47425576 |
| | Tonic and phasic respiratory drives to human genioglossus motoneurons during breathing | Q47685444 |
| | A simplified method for measuring critical pressures during sleep in the clinical setting | Q47996593 |
| | Changes in lung volume and upper airway using MRI during application of nasal expiratory positive airway pressure in patients with sleep-disordered breathing | Q48291045 |
| | Tracheal traction effects on upper airway patency in rabbits: the role of tissue pressure. | Q48475872 |
| | Analysis of inspiratory flow shapes in patients with partial upper-airway obstruction during sleep | Q48705918 |
| | Upper airway collapsibility in snorers and in patients with obstructive hypopnea and apnea | Q48904625 |
| | Upper airway pressure-flow relationships in obstructive sleep apnea | Q48960423 |
| | Effect of tracheal and tongue displacement on upper airway airflow dynamics. | Q53723479 |
| | Pathogenesis of upper airway occlusion during sleep | Q67355497 |
| P433 | issue | 8 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 1105-1112 | |
| P577 | publication date | 2014-01-23 | |
| P1433 | published in | Journal of Applied Physiology | Q1091719 |
| P1476 | title | The classical Starling resistor model often does not predict inspiratory airflow patterns in the human upper airway | |
| P478 | volume | 116 | |