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Abstract

In this study, we propose an innovative driving method for a microrobot. By using acoustic levitation, the microrobot can be levitated from the glass substrate. We are able to achieve positioning accuracy of less than 1 μm, and the response speed and output force are also significantly improved. Silicon-based microrobots can be made into diverse shapes using deep reactive-ion etching (DRIE). Using custom-designed microrobots allows for the 3-D rotational control of a single bovine oocyte. Orientation with an accuracy of 1° and an average rotation velocity of 3 rad/s are achieved. This study contributes to the biotechnology. In the study of oocytes/embryos, manipulation is used for the enucleation, microinjection, and investigation of the characteristics of oocytes, such as the meiotic spindle and zona pellucida using PolScope. These studies and their clinical applications involve the three-dimensional (3-D) rotation of mammalian oocytes. The overall out-of-plane and in-plane rotations of the oocyte are demonstrated by using an acoustically levitated microrobot. In addition, by using this approach, it becomes much easier to manipulate the cell to investigate the characteristics of the single cell and analyze its mechanical properties.

Keywords

Microrobotics acoustic levitation cell manipulation 3-D cell rotation

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References

Abbott

J. J.

Peyer

K. E.

Lagomarsino

M. C.

Zhang

Dong

Kaliakatsos

I. K.

Nelson

B. J.

(2009). How Should Microrobots Swim? The International Journal of Robotics Research, 28(11-12), 1434–1447.

Akagi

Takahashi

Adachi

Hasegawa

Sugawara

Tozuka

Yamamoto

Shimizu

Izaike

(2003). In vitro and in vivo developmental potential of nuclear transfer embryos using bovine cumulus cells prepared in four different conditions. Cloning & Stem Cells, 5(2), 101-108.

Bayoudh

Nieminen

T. A.

Heckenberg

N. R.

Rubinsztein-dunlop

(2003). Orientation of biological cells using plane-polarized gaussian beam optical tweezers. Journal of Modern Optics, 50(10), 1581–1590.

Borges

A. Tarciso

Tecnico

Colegio

Gilbert

John K.

(1998). “Models of Magnetism.” International Journal of Science Education, 20(3): 361–78.

Chu

B.-T.

(1982). Acoustic radiation pressure produced by a beam of sound. The Journal of the Acoustical Society of America, 72(6), 1673.

Diller

Giltinan

Sitti

(2013). Independent control of multiple magnetic microrobots in three dimensions. The International Journal of Robotics Research, 32(5), 614–631.

Donald

B. R.

Levey

C. G.

Paprotny

Rus

(2013). Planning and Control for Microassembly of Structures Composed of Stress-Engineered MEMS Microrobots. The International Journal of Robotics Research, 32(2), 218–246.

Feng

Hagiwara

Ichikawa

Arai

(2013). On-Chip Enucleation of Bovine Oocytes using Microrobot-Assisted Flow-Speed Control. Micromachines, 4(2), 272–285.

Feng

Sun

Ohsumi

Arai

(2013). Accurate dispensing system for single oocytes using air ejection. Biomicrofluidics, 7(5), 054113.

10.

Gray

D. S.

Tan

J. L.

Voldman

Chen

C. S.

(2004). Dielectrophoretic registration of living cells to a microelectrode array. Biosensors and Bioelectronics, 19(12), 1765–1774.

11.

Hagiwara

Kawahara

Iijima

Arai

(2013). High-Speed Magnetic Microrobot Actuation in a Microfluidic Chip by a Fine V-Groove Surface. IEEE Transactions on Robotics, 29(2), 363–372.

12.

Hagiwara

Kawahara

Yamanishi

Arai

(2010). Driving method of microtool by horizontally arranged permanent magnets for single cell manipulation. Applied Physics Letters, 97(1), 013701.

13.

Hagiwara

Kawahara

Yamanishi

Masuda

Feng

Arai

(2011). On-chip magnetically actuated robot with ultrasonic vibration for single cell manipulations. Lab on a Chip, 11(12), 2049–54.

14.

Hashimoto

Koike

Ueha

(1996). Near-field acoustic levitation of planar specimens using flexural vibration. The Journal of the Acoustical Society of America, 100(4), 2057.

15.

Hua

Zhang

J. M.

Zhang

Quan

F. S.

Liu

Wang

Y. S.

Zhang

(2011). Effects of the removal of cytoplasm on the development of early cloned bovine embryos. Animal Reproduction Science, 126(1-2), 37–44.

16.

Huang

T. Y.

Qiu

Tung

H. W.

Chen

X. B.

Nelson

B. J.

Sakar

M. S.

(2014). Generating mobile fluidic traps for selective three-dimensional transport of microobjects. Applied Physics Letters, 105(11), 114102.

17.

Ichikawa

Sakuma

Sugita

Shoda

Tamakoshi

Akagi

Arai

(2014). On-chip enucleation of an oocyte by untethered microrobots. Journal of Micromechanics and Microengineering, 24(9), 095004.

18.

Ichikawa

Kubo

Yoshikawa

Kimura

(2008). Tilt control in optical tweezers. Journal of Biomedical Optics, 13(1), 010503.

19.

Johnson

(1986). Manipulating the mouse embryo: A laboratory manual. Trends in Genetics.

20.

Kawahara

Sugita

Hagiwara

Arai

Kawano

Shihira-Ishikawa

Miyawaki

(2013). On-chip microrobot for investigating the response of aquatic microorganisms to mechanical stimulation. Lab on a Chip, 13(6), 1070–8.

21.

Kunikata

Takahashi

Koide

Itayama

Yasukawa

Shiku

Matsue

(2009). Three dimensional microelectrode array device integrating multi-channel microfluidics to realize manipulation and characterization of enzyme-immobilized polystyrene beads. Sensors and Actuators B: Chemical, 141(1), 256–262.

22.

Leung

Zhang

Sun

(2012). Three-Dimensional Rotation of Mouse Embryos.…, IEEE Transactions on, 59(4), 1049–1056.

23.

Liang

Y.-L.

Huang

Y.-P.

Y.-S.

Hou

M. T.

Yeh

J. A.

(2010). Cell rotation using optoelectronic tweezers. Biomicrofluidics, 4(4), 43003.

24.

Liu

(2009). Investigation of inclined dual-fiber optical tweezers for 3D manipulation and force sensing. Optics Express, 17(16), 13624–13638.

25.

Nishioka

Katsura

Hirano

Mizuno

(1997). Evaluation of cell characteristics by step-wise orientational rotation using optoelectrostatic micromanipulation. IEEE Transactions on Industry Applications, 33(5).

26.

Nomura

Kamakura

Matsuda

(2002). Theoretical and experimental examination of near-field acoustic levitation. The Journal of the Acoustical Society of America, 111(4), 1578-1583.

27.

Onda

Arai

(2012, February 13). Multi-beam bilateral teleoperation of holographic optical tweezers. Optics Express.

28.

Park

J. P. J.

Jung

S.-H. J. S.-H.

Kim

Y.-H. K. Y.-H.

Kim

B. K. B.

Lee

S.-K. L. S.-K.

B. J. B.

Lee

K.-I. L. K.-I

. (2004). An integrated bio cell processor for single embryo cell manipulation. 2004 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS) (IEEE Cat. No.04CH37566), 1.

29.

Pawashe

Floyd

Diller

Sitti

(2012). Two-dimensional autonomous microparticle manipulation strategies for magnetic microrobots in fluidic environments. Robotics, IEEE Transactions on, 28(2), 467-477.

30.

Peura

Lewis

Trounson

(1998). The effect of recipient oocyte volume on nuclear transfer in cattle. Molecular Reproduction and Development, 191(December 1997), 185–191.

31.

Salbu

E. O. J.

(1964). Compressible Squeeze Films and Squeeze Bearings. Journal of Basic Engineering, 86(2), 355.

32.

Sato

Ishigure

Inaba

(1991). Optical trapping and rotational manipulation of microscopic particles and biological cells using higher-order mode Nd:YAG laser beams. Electronics Letters.

33.

Steager

E. B.

Selman Sakar

Magee

Kennedy

Cowley

Kumar

(2013). Automated biomanipulation of single cells using magnetic microrobots. The International Journal of Robotics Research, 32(3), 346–359.

34.

Sun

Nelson

B. J.

(2002). Biological Cell Injection Using an Autonomous MicroRobotic System. The International Journal of Robotics Research, 21(10-11), 861–868.

35.

Yamanishi

Feng

Arai

(2010). On-demand Production of Emulsion Droplets Over a Wide Range of Sizes. Advanced Robotics, 24(14), 2005-2018.

36.

Yesin

K. B.

(2006). Modeling and Control of Untethered Biomicrorobots in a Fluidic Environment Using Electromagnetic Fields. The International Journal of Robotics Research, 25(5-6), 527–536.

37.

Zakhartchenko

Stojkovic

Brem

Wolf

(1997). Karyoplast-cytoplast volume ratio in bovine nuclear transfer embryos: Effect on developmental potential. Molecular Reproduction and Development, 48(3), 332–338.

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High-precision motion of magnetic microrobot with ultrasonic levitation for 3-D rotation of single oocyte

Abstract

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