Characterization of deciliation-regeneration process of Tetrahymena Pyriformis for cellular robot fabrication

Artificial magnetotactic Tetrahymena pyriformis GL (T. pyriformis) cells were created by the internalization of iron oxide nano particles and became controllable with a time-varying external magnetic field. Thus, T. pyriformis can be utilized as a cellular robot to conduct micro-scale tasks such as transportation and manipulation. To complete these tasks, loading inorganic or organic materials onto the cell body is essential, but functionalization of the cell membrane is obstructed by their motile organelles, cilia. Dibucaine HCl, a local anesthetic, removes the cilia from the cell body, and the functional group would be absorbed more efficiently during cilia regeneration. In this paper, we characterize the recovery of artificial magnetotactic T. pyriformis after the deciliation process to optimize a cellular robot fabrication process. After sufficient time to recover, the motility rate and the average velocity of the deciliated cells were six and ten percent lower than that of non-deciliated cells, respectively. We showed that the motile cells after recovery can still be controlled using magnetotaxis, making T. pyriformis a good candidate to be used as a cellular robot.

[1]  J. Rosenbaum,et al.  CILIA REGENERATION IN TETRAHYMENA AND ITS INHIBITION BY COLCHICINE , 1969, The Journal of cell biology.

[2]  George J. Pappas,et al.  Electrokinetic and optical control of bacterial microrobots , 2011 .

[3]  Jake J. Abbott,et al.  Micromanipulation using artificial bacterial flagella , 2009, 2009 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[4]  M. Gorovsky,et al.  Cilia regeneration in Tetrahymena. A simple reproducible method for producing large numbers of regenerating cells. , 1982, Experimental cell research.

[5]  G. Csaba,et al.  Effects of the mammalian vasoconstrictor peptide, endothelin-1, on Tetrahymena pyriformis GL, and the immunocytological detection of endogenous endothelin-like activity. , 1995, Comparative biochemistry and physiology. Part C, Pharmacology, toxicology & endocrinology.

[6]  R. Frankel,et al.  Biomineralization of magnetic iron minerals in bacteria , 1998 .

[7]  P. Fischer,et al.  Controlled propulsion of artificial magnetic nanostructured propellers. , 2009, Nano letters.

[8]  Metin Sitti,et al.  Effect of quantity and configuration of attached bacteria on bacterial propulsion of microbeads , 2008 .

[9]  M. J. Kim,et al.  Artificial magnetotactic motion control of Tetrahymena pyriformis using ferromagnetic nanoparticles: A tool for fabrication of microbiorobots , 2010 .

[10]  S. Martel,et al.  Controlled manipulation and actuation of micro-objects with magnetotactic bacteria , 2006 .

[11]  N. C. Meirelles,et al.  Erythrocruorin of Glossoscolex paulistus (Righi) (Oligochaeta, Glossoscolecidae): effects of divalent ions, acid—Alkaline transition and alkali and urea denaturation , 1995 .

[12]  John Rannestad THE REGENERATION OF CILIA IN PARTIALLY DECILIATED TETRAHYMENA , 1974, The Journal of cell biology.

[13]  G. Csaba,et al.  Chemotaxis and chemotactic selection induced with cytokines (IL-8, RANTES and TNF-alpha) in the unicellular Tetrahymena pyriformis. , 1998, Cytokine.

[14]  Christopher E. Brennen,et al.  Fluid Mechanics of Propulsion by Cilia and Flagella , 1977 .

[15]  W. Sale,et al.  Membrane renewal after dibucaine deciliation of Tetrahymena. Freeze-fracture technique, cilia, membrane structure. , 1976, Experimental cell research.

[16]  G. A. Thompson,et al.  NONLETHAL DECILIATION OF TETRAHYMENA BY A LOCAL ANESTHETIC AND ITS UTILITY AS A TOOL FOR STUDYING CILIA REGENERATION , 1974, The Journal of cell biology.

[17]  J. Westerweel,et al.  Magnetically-actuated artificial cilia for microfluidic propulsion , 2009, 0901.3687.

[18]  Min Jun Kim,et al.  Galvanotactic and phototactic control of Tetrahymena pyriformis as a microfluidic workhorse , 2009 .

[19]  Sylvain Martel,et al.  Flagellated Magnetotactic Bacteria as Controlled MRI-trackable Propulsion and Steering Systems for Medical Nanorobots Operating in the Human Microvasculature , 2009, Int. J. Robotics Res..

[20]  Lixin Dong,et al.  Artificial bacterial flagella: Fabrication and magnetic control , 2009 .

[21]  E. Diamandis,et al.  The biotin-(strept)avidin system: principles and applications in biotechnology. , 1991, Clinical chemistry.

[22]  Sylvain Martel,et al.  Towards swarms of communication-enabled and intelligent sensotaxis-based bacterial microrobots capable of collective tasks in an aqueous medium , 2009, 2009 IEEE International Conference on Robotics and Automation.

[23]  Thomas Powers,et al.  Life at low Reynolds' number revisited , 2012 .