| Literature DB >> 31179467 |
Louis Jun Ye Ong1, Terry Ching, Lor Huai Chong, Seep Arora, Huan Li, Michinao Hashimoto, Ramanuj DasGupta, Po Ki Yuen, Yi-Chin Toh.
Abstract
Multi-organ perfusion systems offer the unique opportunity to mimic different physiological systemic interactions. However, existing multi-organ culture platforms have limited flexibility in specifying the culture conditions, device architectures, and fluidic connectivity simultaneously. Here, we report a modular microfluidic platform that addresses this limitation by enabling easy conversion of existing microfluidic devices into tissue and fluid control modules with self-aligning magnetic interconnects. This enables a 'stick-n-play' approach to assemble planar perfusion circuits that are amenable to both bioimaging-based and analytical measurements. A myriad of tissue culture and flow control TILE modules were successfully constructed with backward compatibility. Finally, we demonstrate applications in constructing recirculating multi-organ systems to emulate liver-mediated bioactivation of nutraceuticals and prodrugs to modulate their therapeutic efficacies in the context of atherosclerosis and cancer. This platform greatly facilitates the integration of existing organs-on-chip models to provide an intuitive and flexible way for users to configure different multi-organ perfusion systems.Entities:
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Year: 2019 PMID: 31179467 DOI: 10.1039/c9lc00160c
Source DB: PubMed Journal: Lab Chip ISSN: 1473-0189 Impact factor: 6.799