Manu Jain1, J Iasha Sznajder. 1. Division of Pulmonary and Critical Care, Feinberg School of Medicine, Northwestern University, Chicago, Illinois 60611, USA. m-jan@northwestern.edu
Abstract
PURPOSE OF REVIEW: Peripheral airways are less than 2 mm in diameter and comprise a relatively large cross-sectional area, which allows for slower, laminar airflow. They include both membranous bronchioles and gas exchange ducts, and have been referred to in the past as the 'quiet zone', partly because these structures were felt to contribute little to lung mechanics, and partly because they are difficult to study directly. RECENT FINDINGS: Recent studies suggest that peripheral airway dysfunction plays a significant role in acute respiratory distress syndrome, which may be exacerbated by injurious mechanical ventilation strategies. The presence of elevated airways resistance, intrinsic positive end-expiratory pressure or a lower inflection point on a pressure-volume curve of the respiratory system may indicate presence of impaired peripheral airway function. In-vitro animal and human studies have begun to elucidate the signaling mechanisms responsible for stretch and shear mediated cellular injury. SUMMARY: Understanding the pathophysiology of peripheral airway dysfunction in acute respiratory distress syndrome and mechanical ventilation continues to evolve. Greater insight into the signaling mechanisms involved in cellular injury and repair will lead to further alterations in mechanical ventilation strategies, and may lead to specific treatment options.
PURPOSE OF REVIEW: Peripheral airways are less than 2 mm in diameter and comprise a relatively large cross-sectional area, which allows for slower, laminar airflow. They include both membranous bronchioles and gas exchange ducts, and have been referred to in the past as the 'quiet zone', partly because these structures were felt to contribute little to lung mechanics, and partly because they are difficult to study directly. RECENT FINDINGS: Recent studies suggest that peripheral airway dysfunction plays a significant role in acute respiratory distress syndrome, which may be exacerbated by injurious mechanical ventilation strategies. The presence of elevated airways resistance, intrinsic positive end-expiratory pressure or a lower inflection point on a pressure-volume curve of the respiratory system may indicate presence of impaired peripheral airway function. In-vitro animal and human studies have begun to elucidate the signaling mechanisms responsible for stretch and shear mediated cellular injury. SUMMARY: Understanding the pathophysiology of peripheral airway dysfunction in acute respiratory distress syndrome and mechanical ventilation continues to evolve. Greater insight into the signaling mechanisms involved in cellular injury and repair will lead to further alterations in mechanical ventilation strategies, and may lead to specific treatment options.
Authors: Maina M B Morales; Ruy C Pires-Neto; Nicole Inforsato; Tatiana Lanças; Luiz F F da Silva; Paulo H N Saldiva; Thais Mauad; Carlos R R Carvalho; Marcelo B P Amato; Marisa Dolhnikoff Journal: Crit Care Date: 2011-01-06 Impact factor: 9.097
Authors: Savino Spadaro; Iryna Kozhevnikova; Paolo Casolari; Paolo Ruggeri; Tiziana Bellini; Riccardo Ragazzi; Federica Barbieri; Elisabetta Marangoni; Gaetano Caramori; Carlo Alberto Volta Journal: BMJ Open Respir Res Date: 2017-09-04