A gel-coated air-liquid-interface culture system with tunable substrate stiffness matching healthy and diseased lung tissues

Abstract

AbstractSince its invention in the late 1980s, the air-liquid-interface (ALI) culture system has been the standardin vitromodel for studying human airway biology and pulmonary diseases. However, in a conventional ALI system, cells are cultured on a porous plastic membrane that is much stiffer than human airway tissues. Here, we develop a gel-ALI culture system by simply coating the plastic membrane with a thin layer of hydrogel with tunable stiffness matching that of healthy and fibrotic airway tissues. We determine the optimum gel thickness that does not impair the transport of nutrients and biomolecules essential to cell growth. We show that the gel-ALI system allows human bronchial epithelial cells (HBECs) to proliferate and differentiate into a pseudostratified epithelium. Further, we discover that HBECs migrate significantly faster on hydrogel substrates with stiffness matching that of fibrotic lung tissues, highlighting the importance of mechanical cues to human airway remodeling. The developed gel-ALI system provides a facile approach to studying the effects of mechanical cues on human airway biology and in modeling pulmonary diseases.New and NoteworthyIn a conventional air-liquid-interface (ALI) system, cells are cultured on a plastic membrane that is much stiffer than human airway tissues. We develop a gel-ALI system by coating the plastic membrane with a thin layer of hydrogel with tunable stiffness matching that of healthy and fibrotic airway tissues. We discover that human bronchial epithelial cells migrate significantly faster on hydrogel substrates with pathological stiffness, highlighting the importance of mechanical cues to human airway remodeling.