Establishment of a fabrication method for a long-term actuated hybrid cell robot

Jinseok Kim; Jungyul Park; Sungwook Yang; Jeongeun Baek; Byungkyu Kim; Sang Ho Lee; Eui Sung Yoon; Kukjin Chun; Sukho Park

doi:10.1039/b705367c

Establishment of a fabrication method for a long-term actuated hybrid cell robot

Jinseok Kim
, Jungyul Park
, Sungwook Yang
, Jeongeun Baek
, Byungkyu Kim
, Sang Ho Lee
, Eui Sung Yoon
, Kukjin Chun
, Sukho Park^*

^*Corresponding author for this work

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

138 Citations (Scopus)

Abstract

We developed a novel method to fabricate a crab-like microrobot that can actuate for a long period in a physiological condition. The microrobot backbone was built with a biocompatible and elastic material - polydimethylsiloxane (PDMS) - by using a specially designed 3D molding aligner, and consisted of three strips of PDMS "legs" connected across a "body." Cardiomyocytes were then plated on the grooved top surface of the backbone, resulting in a high concentration of pulsating cells. These key techniques enabled the microrobot to walk continuously for over ten days. The performance of our crab-like microrobot was measured at an average velocity of 100 μm s^-1, and the estimated total distance it travelled was 50 m over a one-week period. Thus, we have demonstrated for the first time a walking robot that exhibited reliable and long-term actuation performances.

Original language	English
Pages (from-to)	1504-1508
Number of pages	5
Journal	Lab on a Chip
Volume	7
Issue number	11
DOIs	https://doi.org/10.1039/b705367c
Publication status	Published - 2007

ASJC Scopus subject areas

Bioengineering
Biochemistry
General Chemistry
Biomedical Engineering

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10.1039/b705367c

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abstract = "We developed a novel method to fabricate a crab-like microrobot that can actuate for a long period in a physiological condition. The microrobot backbone was built with a biocompatible and elastic material - polydimethylsiloxane (PDMS) - by using a specially designed 3D molding aligner, and consisted of three strips of PDMS {"}legs{"} connected across a {"}body.{"} Cardiomyocytes were then plated on the grooved top surface of the backbone, resulting in a high concentration of pulsating cells. These key techniques enabled the microrobot to walk continuously for over ten days. The performance of our crab-like microrobot was measured at an average velocity of 100 μm s-1, and the estimated total distance it travelled was 50 m over a one-week period. Thus, we have demonstrated for the first time a walking robot that exhibited reliable and long-term actuation performances.",

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AU - Kim, Jinseok

AU - Park, Jungyul

AU - Yang, Sungwook

AU - Baek, Jeongeun

AU - Kim, Byungkyu

AU - Lee, Sang Ho

AU - Yoon, Eui Sung

AU - Chun, Kukjin

AU - Park, Sukho

PY - 2007

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AB - We developed a novel method to fabricate a crab-like microrobot that can actuate for a long period in a physiological condition. The microrobot backbone was built with a biocompatible and elastic material - polydimethylsiloxane (PDMS) - by using a specially designed 3D molding aligner, and consisted of three strips of PDMS "legs" connected across a "body." Cardiomyocytes were then plated on the grooved top surface of the backbone, resulting in a high concentration of pulsating cells. These key techniques enabled the microrobot to walk continuously for over ten days. The performance of our crab-like microrobot was measured at an average velocity of 100 μm s-1, and the estimated total distance it travelled was 50 m over a one-week period. Thus, we have demonstrated for the first time a walking robot that exhibited reliable and long-term actuation performances.

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Establishment of a fabrication method for a long-term actuated hybrid cell robot

Abstract

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