An In Vitro Microfluidic Alveolus Model to Study Lung Biomechanics.
The gas exchange units of the lung, the alveoli, are mechanically active and undergo cyclic deformation during breathing. The epithelial cells that line the alveoli contribute to lung function by reducing surface tension via surfactant secretion, which is highly influenced by the breathing-associated mechanical cues. These spatially heterogeneous mechanical cues have been linked to several physiological and pathophysiological states. Here, we describe the development of a microfluidically assisted lung cell culture model that incorporates heterogeneous cyclic stretching to mimic alveolar respiratory motions. Employing this device, we have examined the effects of respiratory biomechanics (associated with breathing-like movements) and strain heterogeneity on alveolar epithelial cell functions. Furthermore, we have assessed the potential application of this platform to model altered matrix compliance associated with lung pathogenesis and ventilator-induced lung injury. Lung microphysiological platforms incorporating human cells and dynamic biomechanics could serve as an important tool to delineate the role of alveolar micromechanics in physiological and pathological outcomes in the lung.
Duke Scholars
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- 4003 Biomedical engineering
- 3206 Medical biotechnology
- 3106 Industrial biotechnology
- 1004 Medical Biotechnology
- 0903 Biomedical Engineering
- 0699 Other Biological Sciences
Citation
Published In
DOI
ISSN
Publication Date
Volume
Start / End Page
Location
Related Subject Headings
- 4003 Biomedical engineering
- 3206 Medical biotechnology
- 3106 Industrial biotechnology
- 1004 Medical Biotechnology
- 0903 Biomedical Engineering
- 0699 Other Biological Sciences