Design, Simulation, and Fabrication of a Hexagonal Microfluidic Platform for Culturing Neurons

Abstract

Developing an organoid computing platform from neurons in vitro demands stable, precisely controlled microenvironments. To address this requirement, we designed, simulated, and fabricated a microfluidic device featuring hexagonal wells (34.64\,μ m side length) in a honeycomb array connected by 20\,μ m channels. Computational fluid dynamics (CFD) modeling, validated by high mesh quality (0.934 orthogonal quality) and robust convergence, confirmed the architecture supports flow regimes ideal for ensuring cell viability. At target flow rates of 0.1 - 1\,μ L/min, simulations revealed the extrapolated pressure differential across the full 50,000\,μ m device remains within stable operating limits at 177\,kPa (average) and 329\,kPa (maximum). Photolithography successfully produced this architecture, with only minor corner rounding observed at feature interfaces. This work therefore establishes a computationally validated and fabricated platform, paving the way for experimental flow characterization and subsequent neural integration.