A biomimetic kidney tubule model

TL;DR

This paper introduces a novel in vitro kidney tubule model using 3D printing and hydrogel matrices, enabling manipulation of mechanical factors for disease study and drug testing.

Contribution

The study presents a new biomimetic kidney tubule device with live imaging capability and functional features like lumen flow and remodeling, advancing in vitro renal modeling.

Findings

Kidney epithelial cells form polarized monolayers in the device.

The tubule diameter can be adjusted via myosin-II activity.

Cells can remodel the hydrogel, leading to budding from the main tubule.

Abstract

A critical barrier in the nephrology field is the lack of appropriate in vitro renal tubule models that allow manipulation of various mechanical factors, facilitating studies of disease pathophysiology and drug discovery. Here we report development of a novel in vitro assay system comprised of a renal tubule within an elasto-plastic extracellular matrix microenvironment. This in vitro tubule mimetic device consists of a container with two, pipette-accessible ports, filament-deposition (3D-) printed into 35 mm cell culture dishes. The container is filled with a hydrogel, such as a collagen I or fibrin gel, while a narrow masking tube is threaded through the ports. Following gelation, the masking material is pulled out leaving a tunnel within the gel. Seeding of the tunnels with M1 or MDCK renal epithelial cells through the side ports results in a monolayer with apical-basal polarity, such that laminin and fibronectin are present on the basal surface, while primary cilia project from the apical side of cells into the tubular lumen. The device is optically accessible, and can be live-imaged by phase contrast or epifluorescence microscopy. The lumen of the epithelial-lined tube can be connected through the side ports to a circulatory flow. We demonstrate that kidney epithelial cells are able to adjust the diameter of the model tubule by myosin-II dependent contractility. Furthermore, cells of the tubule are also able to remodel the surrounding hydrogel leading to budding from the main tubule. We propose that this versatile in vitro model system can be developed into a future pre-clinical tool to study pathophysiology of kidney diseases and identify therapeutic compounds.