Novel microfluidic device integrated with a fluidic-capacitor to mimic heart beating for generation of functional liver organoids

Jiaxu Wu; Yoshikazu Hirai; Ken Ichiro Kamei; Toshiyuki Tsuchiya; Osamu Tabata

doi:10.1002/ecj.12210

Novel microfluidic device integrated with a fluidic-capacitor to mimic heart beating for generation of functional liver organoids

Jiaxu Wu, Yoshikazu Hirai, Ken Ichiro Kamei, Toshiyuki Tsuchiya, Osamu Tabata

Biology

Research output: Contribution to journal › Article › peer-review

Abstract

Liver organoids hold a great potential to understand liver development and contribute for drug screening and toxicological testing. However, conventional methods to generate organoids provide insufficient liver functions and less reproducibility, due to lack of controllability of cellular microenvironmental cues. To tackle these issues, we focus on one of the environmental cues, pressure stimuli by heart beating, and develop a microfluidic-based cell culture platform integrating a fluidic capacitor to produce pressure stimuli with hydrostatic pressure. Furthermore, we demonstrate a numerical simulation based on equivalent circuit model for designing the device parameters with sufficient accuracy. This device concept will provide insights into physical micro-environmental regulation on organoid development.

Original language	English (US)
Pages (from-to)	41-49
Number of pages	9
Journal	Electronics and Communications in Japan
Volume	102
Issue number	10
DOIs	https://doi.org/10.1002/ecj.12210
State	Published - Oct 1 2019

Keywords

equivalent circuit model
fluidic capacitor
organoid
polydimethylsiloxane
pressure stimulus

ASJC Scopus subject areas

Signal Processing
General Physics and Astronomy
Computer Networks and Communications
Electrical and Electronic Engineering
Applied Mathematics

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10.1002/ecj.12210

Cite this

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abstract = "Liver organoids hold a great potential to understand liver development and contribute for drug screening and toxicological testing. However, conventional methods to generate organoids provide insufficient liver functions and less reproducibility, due to lack of controllability of cellular microenvironmental cues. To tackle these issues, we focus on one of the environmental cues, pressure stimuli by heart beating, and develop a microfluidic-based cell culture platform integrating a fluidic capacitor to produce pressure stimuli with hydrostatic pressure. Furthermore, we demonstrate a numerical simulation based on equivalent circuit model for designing the device parameters with sufficient accuracy. This device concept will provide insights into physical micro-environmental regulation on organoid development.",

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AU - Wu, Jiaxu

AU - Hirai, Yoshikazu

AU - Kamei, Ken Ichiro

AU - Tsuchiya, Toshiyuki

AU - Tabata, Osamu

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N2 - Liver organoids hold a great potential to understand liver development and contribute for drug screening and toxicological testing. However, conventional methods to generate organoids provide insufficient liver functions and less reproducibility, due to lack of controllability of cellular microenvironmental cues. To tackle these issues, we focus on one of the environmental cues, pressure stimuli by heart beating, and develop a microfluidic-based cell culture platform integrating a fluidic capacitor to produce pressure stimuli with hydrostatic pressure. Furthermore, we demonstrate a numerical simulation based on equivalent circuit model for designing the device parameters with sufficient accuracy. This device concept will provide insights into physical micro-environmental regulation on organoid development.

AB - Liver organoids hold a great potential to understand liver development and contribute for drug screening and toxicological testing. However, conventional methods to generate organoids provide insufficient liver functions and less reproducibility, due to lack of controllability of cellular microenvironmental cues. To tackle these issues, we focus on one of the environmental cues, pressure stimuli by heart beating, and develop a microfluidic-based cell culture platform integrating a fluidic capacitor to produce pressure stimuli with hydrostatic pressure. Furthermore, we demonstrate a numerical simulation based on equivalent circuit model for designing the device parameters with sufficient accuracy. This device concept will provide insights into physical micro-environmental regulation on organoid development.

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Novel microfluidic device integrated with a fluidic-capacitor to mimic heart beating for generation of functional liver organoids

Abstract

Keywords

ASJC Scopus subject areas

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