Dynamics modeling and real-time observation of galvanotaxis in Paramecium caudatum

Naoko Ogawa; Hiromasa Oku; Koichi Hashimoto; Masatoshi Ishikawa

Dynamics modeling and real-time observation of galvanotaxis in Paramecium caudatum

Naoko Ogawa, Hiromasa Oku, Koichi Hashimoto, Masatoshi Ishikawa

INF - System Information Sciences

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

1 Citation (Scopus)

Abstract

Paramecium caudatum, a kind of ciliates, exhibits very strong galvanotaxis; when a DC electric field is applied, cells are made to swim toward the cathode. In this article, we propose a novel physical scheme for Paramecium galvanotaxis to provide a quantitative explanation, using a bottom-up approach based on systems theory. We analytically derived the torque produced with respect to the cell angle and constructed equations of translational and rotational motion. Using the proposed model, we performed numerical simulations. We also performed a preliminary evaluation of the proposed model by using real data. Experimental data were obtained by using a real-time galvanotaxis observation system developed in our laboratory. We found that the simulated data was approximately in agreement with the experimental results. [Arranged from (Ogawa et al. 2005) and (Ogawa et al. 2006)].

Original language	English
Title of host publication	Bio-Mechanisms of Swimming and Flying
Subtitle of host publication	Fluid Dynamics, Biomimetic Robots, and Sports Science
Publisher	Springer-Verlag Tokyo
Pages	29-40
Number of pages	12
ISBN (Print)	9784431733799
Publication status	Published - 2008 Jan 1
Event	3rd International Symposium on Aero Aqua Bio-Mechanisms, ISABMEC 2006 - Okinawa, Japan Duration: 2006 Jul 3 → 2006 Jul 7

Publication series

Name	Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science

Other

Other	3rd International Symposium on Aero Aqua Bio-Mechanisms, ISABMEC 2006
Country/Territory	Japan
City	Okinawa
Period	06/7/3 → 06/7/7

Keywords

Dynamics model
Galvanotaxis
Microorganism
Paramecium
Tracking

ASJC Scopus subject areas

Biomedical Engineering

Cite this

Ogawa, N., Oku, H., Hashimoto, K., & Ishikawa, M. (2008). Dynamics modeling and real-time observation of galvanotaxis in Paramecium caudatum. In Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science (pp. 29-40). (Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science). Springer-Verlag Tokyo.

Dynamics modeling and real-time observation of galvanotaxis in Paramecium caudatum. / Ogawa, Naoko; Oku, Hiromasa; Hashimoto, Koichi et al.
Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science. Springer-Verlag Tokyo, 2008. p. 29-40 (Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Ogawa, N, Oku, H, Hashimoto, K & Ishikawa, M 2008, Dynamics modeling and real-time observation of galvanotaxis in Paramecium caudatum. in Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science. Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science, Springer-Verlag Tokyo, pp. 29-40, 3rd International Symposium on Aero Aqua Bio-Mechanisms, ISABMEC 2006, Okinawa, Japan, 06/7/3.

Ogawa, Naoko ; Oku, Hiromasa ; Hashimoto, Koichi et al. / Dynamics modeling and real-time observation of galvanotaxis in Paramecium caudatum. Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science. Springer-Verlag Tokyo, 2008. pp. 29-40 (Bio-Mechanisms of Swimming and Flying: Fluid Dynamics, Biomimetic Robots, and Sports Science).

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AB - Paramecium caudatum, a kind of ciliates, exhibits very strong galvanotaxis; when a DC electric field is applied, cells are made to swim toward the cathode. In this article, we propose a novel physical scheme for Paramecium galvanotaxis to provide a quantitative explanation, using a bottom-up approach based on systems theory. We analytically derived the torque produced with respect to the cell angle and constructed equations of translational and rotational motion. Using the proposed model, we performed numerical simulations. We also performed a preliminary evaluation of the proposed model by using real data. Experimental data were obtained by using a real-time galvanotaxis observation system developed in our laboratory. We found that the simulated data was approximately in agreement with the experimental results. [Arranged from (Ogawa et al. 2005) and (Ogawa et al. 2006)].

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Dynamics modeling and real-time observation of galvanotaxis in Paramecium caudatum

Abstract

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Keywords

ASJC Scopus subject areas

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