Medium throughput breathing human primary cell alveolus-on-chip model

Janick D Stucki,Nicole Schneider-Daum,Claus-Michael Lehr,Andreas O Stucki,Nina Hobi,Manuela Funke-Chambour,Hanno Huwer,Artur Galimov,Olivier T Guenat,Manfred Frick,Thomas Geiser

doi:10.1038/s41598-018-32523-x

Abstract

Organs-on-chips have the potential to improve drug development efficiency and decrease the need for animal testing. For the successful integration of these devices in research and industry, they must reproduce in vivo contexts as closely as possible and be easy to use. Here, we describe a ‘breathing’ lung-on-chip array equipped with a passive medium exchange mechanism that provide an in vivo-like environment to primary human lung alveolar cells (hAEpCs) and primary lung endothelial cells. This configuration allows the preservation of the phenotype and the function of hAEpCs for several days, the conservation of the epithelial barrier functionality, while enabling simple sampling of the supernatant from the basal chamber. In addition, the chip design increases experimental throughput and enables trans-epithelial electrical resistance measurements using standard equipment. Biological validation revealed that human primary alveolar type I (ATI) and type II-like (ATII) epithelial cells could be successfully cultured on the chip over multiple days. Moreover, the effect of the physiological cyclic strain showed that the epithelial barrier permeability was significantly affected. Long-term co-culture of primary human lung epithelial and endothelial cells demonstrated the potential of the lung-on-chip array for reproducible cell culture under physiological conditions. Thus, this breathing lung-on-chip array, in combination with patients’ primary ATI, ATII, and lung endothelial cells, has the potential to become a valuable tool for lung research, drug discovery and precision medicine.

Highlights

Organs-on-chips are advanced in vitro models mimicking the cellular microenvironment found in vivo[1]
The air–blood interface is an ultrathin barrier of only a few micrometers[19], consisting of tight, semi-selective epithelial- and endothelial cell layers enveloped by the extracellular matrix (ECM)[20,21], rhythmically expanding and contracting
We describe a breathing lung alveolar barrier consisting of primary human alveolar epithelial and lung endothelial cells cultured in an in vivo–like environment

Summary

Introduction

Organs-on-chips are advanced in vitro models mimicking the cellular microenvironment found in vivo[1]. In contrast to our earlier work, the new lung-on-chip is equipped with passive medium exchange that enables the reproduction of the cyclic mechanical stress, and long-term cell culture at the air–liquid interface, and reproduces the unique aspects of the lung microenvironment even more closely. The presence of type I- (ATI) and type II-like (ATII) alveolar epithelial phenotypes is demonstrated for the first time in a lung-on-chip Using this system, we assessed the effect of physiological stretching on cell morphology and barrier permeability of primary ATI- and ATII-like cells. We assessed the effect of physiological stretching on cell morphology and barrier permeability of primary ATI- and ATII-like cells This new system is compatible with a number of standard readout techniques, including ELISA, trans-epithelial electrical resistance (TEER), permeability assays, qPCR, immunostaining and electron microscopy. This device opens up new possibilities for basic research of the alveoli and preclinical testing of drug candidates, and will enable testing of cells from individual patients in precision medicine approaches

Methods

Results

Conclusion