Artificial magnetotactic motion control of Tetrahymena pyriformis using ferromagnetic nanoparticles: A tool for fabrication of microbiorobots

Dal Hyung Kim; U. Kei Cheang; László Khidai; Doyoung Byun; Min Jun Kim

doi:10.1063/1.3497275

Artificial magnetotactic motion control of Tetrahymena pyriformis using ferromagnetic nanoparticles: A tool for fabrication of microbiorobots

Dal Hyung Kim
, U. Kei Cheang
, László Khidai
, Doyoung Byun
, Min Jun Kim

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

69 Scopus citations

Abstract

We induce artificial magnetotaxis in Tetrahymena pyriformis, a eukaryotic ciliate, using ferro-magnetic nanoparticles and an external time-varying magnetic field. Magnetizing internalized iron oxide particles (magnetite), allows control of the swimming direction of an individual cell using two sets of electromagnets. Real-time feedback control was performed with a vision tracking system, which demonstrated controllability of a single cell. Since the endogenous motility of the cell is combined in one system with artificial magnetotaxis, the motion of artificially magnetotactic T. pyriformis is finely controllable. Thus, artificially magnetotactic T. pyriformis is a promising candidate microrobot for microassembly and transport in microfluidic environments.

Original language	English
Article number	173702
Journal	Applied Physics Letters
Volume	97
Issue number	17
DOIs	https://doi.org/10.1063/1.3497275
State	Published - 25 Oct 2010
Externally published	Yes

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title = "Artificial magnetotactic motion control of Tetrahymena pyriformis using ferromagnetic nanoparticles: A tool for fabrication of microbiorobots",

abstract = "We induce artificial magnetotaxis in Tetrahymena pyriformis, a eukaryotic ciliate, using ferro-magnetic nanoparticles and an external time-varying magnetic field. Magnetizing internalized iron oxide particles (magnetite), allows control of the swimming direction of an individual cell using two sets of electromagnets. Real-time feedback control was performed with a vision tracking system, which demonstrated controllability of a single cell. Since the endogenous motility of the cell is combined in one system with artificial magnetotaxis, the motion of artificially magnetotactic T. pyriformis is finely controllable. Thus, artificially magnetotactic T. pyriformis is a promising candidate microrobot for microassembly and transport in microfluidic environments.",

author = "Kim, \{Dal Hyung\} and Cheang, \{U. Kei\} and L{\'a}szl{\'o} Khidai and Doyoung Byun and Kim, \{Min Jun\}",

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T1 - Artificial magnetotactic motion control of Tetrahymena pyriformis using ferromagnetic nanoparticles

T2 - A tool for fabrication of microbiorobots

AU - Kim, Dal Hyung

AU - Cheang, U. Kei

AU - Khidai, László

AU - Byun, Doyoung

AU - Kim, Min Jun

PY - 2010/10/25

Y1 - 2010/10/25

N2 - We induce artificial magnetotaxis in Tetrahymena pyriformis, a eukaryotic ciliate, using ferro-magnetic nanoparticles and an external time-varying magnetic field. Magnetizing internalized iron oxide particles (magnetite), allows control of the swimming direction of an individual cell using two sets of electromagnets. Real-time feedback control was performed with a vision tracking system, which demonstrated controllability of a single cell. Since the endogenous motility of the cell is combined in one system with artificial magnetotaxis, the motion of artificially magnetotactic T. pyriformis is finely controllable. Thus, artificially magnetotactic T. pyriformis is a promising candidate microrobot for microassembly and transport in microfluidic environments.

AB - We induce artificial magnetotaxis in Tetrahymena pyriformis, a eukaryotic ciliate, using ferro-magnetic nanoparticles and an external time-varying magnetic field. Magnetizing internalized iron oxide particles (magnetite), allows control of the swimming direction of an individual cell using two sets of electromagnets. Real-time feedback control was performed with a vision tracking system, which demonstrated controllability of a single cell. Since the endogenous motility of the cell is combined in one system with artificial magnetotaxis, the motion of artificially magnetotactic T. pyriformis is finely controllable. Thus, artificially magnetotactic T. pyriformis is a promising candidate microrobot for microassembly and transport in microfluidic environments.

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DO - 10.1063/1.3497275

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VL - 97

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 17

M1 - 173702

ER -

Artificial magnetotactic motion control of Tetrahymena pyriformis using ferromagnetic nanoparticles: A tool for fabrication of microbiorobots

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