Here, we report a fluorescent electrospun nanofiber membrane for integration into
microfluidic devices towards lung-on-a-chip applications complemented with the results of …

A modular and 3D compartmentalized microfluidic system with electrospun porous
membranes (PMs) for epithelialized organ-on-a-chip systems is presented. Our novel …

Organ-on-a-chip technology can simulate the physiological and pathological
microenvironment of tissues and organs in vitro, thus offering the potential of dispensing with …

Lung-on-a-chip devices could provide new strategies for a biomimetic lung cell
microenvironment and construction of lung disease models in vitro, and are expected to …

In vitro environments that realize biomimetic scaffolds, cellular composition, physiological
shear, and strain are integral to developing tissue models of organ-specific functions. In this …

Thin porous membranes are important components in a microfluidic device, serving as
separators, filters, and scaffolds for cell culture. However, the fabrication and the integration …

An alveolar basement membrane plays a crucial role in the organogenesis and functioning
of the lungs at the alveoli level. To emulate the function of the basement membrane in …

Organs-on-a-chip has emerged as a powerful tool for pharmacological and physiological
studies. A key part in the construction of such a model is the ability to pattern or culture cells …

Lung‐on‐chips have showed great promise as a tool to recapitulate the respiratory system
for investigation of lung diseases in the past decade. However, the commonly applied …

Mimicking the physiological or pathophysiological barrier function of endothelial and
epithelial cells is an essential consideration in organ-on-a-chip models of numerous tissues …