Micro pumping with cardiomyocyte-polymer hybrid

Jungyul Park; Il Chaek Kim; Jeongeun Baek; Misun Cha; Jinseok Kim; Sukho Park; Junghoon Lee; Byungkyu Kim

doi:10.1039/b703900j

Micro pumping with cardiomyocyte-polymer hybrid

Jungyul Park, Il Chaek Kim, Jeongeun Baek, Misun Cha, Jinseok Kim, Sukho Park, Junghoon Lee, Byungkyu Kim

Department of Robotics and Mechatronics Engineering

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

85 Scopus citations

Abstract

This paper presents a hybrid micropump actuated by the up-down motion of a dome shaped cell-polymer membrane composite. The contractile force induced from self-beating cardiomyocytes cultured on the membrane causes shrinkage and relaxation of a microchamber, leading to a flow in a microchannel. Flow direction is controlled by the geometry of diffuser/nozzle in the microchannel. The fabrication process is noninvasive to cells, thus, cardiomyocytes can robustly maintain their activity for a long time. The fluid motion in the microchannel was monitored by tracking 2 μm polystyrene beads. A net flow rate of 0.226 nl min^-1 was obtained in our microscale device. Our device demonstrates a unique performance of a cell-microdevice hybrid lab-on-a-chip that does not require any external power source, preventing electrical or heat shock to analytes.

Original language	English
Pages (from-to)	1367-1370
Number of pages	4
Journal	Lab on a Chip
Volume	7
Issue number	10
DOIs	https://doi.org/10.1039/b703900j
State	Published - 2007

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10.1039/b703900j

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title = "Micro pumping with cardiomyocyte-polymer hybrid",

abstract = "This paper presents a hybrid micropump actuated by the up-down motion of a dome shaped cell-polymer membrane composite. The contractile force induced from self-beating cardiomyocytes cultured on the membrane causes shrinkage and relaxation of a microchamber, leading to a flow in a microchannel. Flow direction is controlled by the geometry of diffuser/nozzle in the microchannel. The fabrication process is noninvasive to cells, thus, cardiomyocytes can robustly maintain their activity for a long time. The fluid motion in the microchannel was monitored by tracking 2 μm polystyrene beads. A net flow rate of 0.226 nl min-1 was obtained in our microscale device. Our device demonstrates a unique performance of a cell-microdevice hybrid lab-on-a-chip that does not require any external power source, preventing electrical or heat shock to analytes.",

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AU - Park, Jungyul

AU - Kim, Il Chaek

AU - Baek, Jeongeun

AU - Cha, Misun

AU - Kim, Jinseok

AU - Park, Sukho

AU - Lee, Junghoon

AU - Kim, Byungkyu

PY - 2007

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AB - This paper presents a hybrid micropump actuated by the up-down motion of a dome shaped cell-polymer membrane composite. The contractile force induced from self-beating cardiomyocytes cultured on the membrane causes shrinkage and relaxation of a microchamber, leading to a flow in a microchannel. Flow direction is controlled by the geometry of diffuser/nozzle in the microchannel. The fabrication process is noninvasive to cells, thus, cardiomyocytes can robustly maintain their activity for a long time. The fluid motion in the microchannel was monitored by tracking 2 μm polystyrene beads. A net flow rate of 0.226 nl min-1 was obtained in our microscale device. Our device demonstrates a unique performance of a cell-microdevice hybrid lab-on-a-chip that does not require any external power source, preventing electrical or heat shock to analytes.

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JO - Lab on a Chip

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Micro pumping with cardiomyocyte-polymer hybrid

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