Research Center for Applied Sciences Academia Sinica Taipei

RCAS. Tung. Lab • Established in June, 2009. • Currently with 4 Research Assistants

Publication • From July, 2009 to June, 2010: 4 Journal Papers, and 4 in

Self-Controlled Microfluidics (I) • Elastomeric components for autonomously controlled microfluidic devices:

Self-Controlled Microfluidics (II) • Check valve and automated fluid circuits for cascading operations:

Self-Controlled Microfluidics (III) • Interactive elastomeric components for oscillatory switching:

Microfluidic Blood-Brain Barrier (BBB) (I) • Fabricated BBB microfluidic device with embedded Ag/Ag. Cl

Microfluidic Blood-Brain Barrier (BBB) (II) • Impedance measurement results:

High-Speed Laser Wavelength Tuning (I) • Nanoimprinted grating optical tunable filter MEMS device:

High-Speed Laser Wavelength Tuning (II) • High-speed laser wavelength tuning results and its biomedical

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Research Center for Applied Sciences Academia Sinica, Taipei, Taiwan Integrated Biomedical Microdevices for Cell Biology Studies Yi-Chung Tung, Ph. D. Assistant Research Fellow Research Center for Applied Sciences Academia Sinica, Taipei, Taiwan

RCAS. Tung. Lab • Established in June, 2009. • Currently with 4 Research Assistants (Master Degree), and 2 Interns.

Publication • From July, 2009 to June, 2010: 4 Journal Papers, and 4 in Preparation: • • B. Mosadegh, C. -H. Kuo, Y. -C. Tung, Y. Torisawa, T. Bersano-Begey, H. Tavana, and S. Takayama*, “Integrated Elastomeric Components for Autonomous Regulation of Sequential and Oscillatory Flow Switching in Microfluidic Devices, ” Nat. Phys. , Vol. 6, pp. 433 -437, June 2010. W. Cha, Y. -C. Tung, M. E. Meyerhoff*, and S. Takayama*, “Patterned Electrode. Based Amperometric Gas Sensor for Direct Nitric Oxide Detection within Microfluidic Devices, ” Anal. Chem. , Vol. 82, Issue 8, pp. 3300 -3305, April 2010. N. J. Douville, Y. -C. Tung, R. Li, J. D. Wang, M. E. H. El-Sayed, and S. Takayama*, “Fabrication of Two-Layered Channel System with Embedded Electrodes to Measure Resistance across Epithelial and Endothelial Barriers, ” Anal. Chem. , Vol. 82, Issue 6, pp. 2505 -2511, March 2010. N. -T. Huang, S. C. Truxal, Y. -C. Tung, A. Hsiao, S. Takayama, and K. Kurabayashi*, “High-Speed Tuning of Visible Laser Wavelength Using a Nanoimprinted Grating Optical Tunable Filter, ” Appl. Phys. Lett. , Vol. 95, Issue 21, pp. 21106 (3 pages), November 2009.

Self-Controlled Microfluidics (I) • Elastomeric components for autonomously controlled microfluidic devices:

Self-Controlled Microfluidics (II) • Check valve and automated fluid circuits for cascading operations:

Self-Controlled Microfluidics (III) • Interactive elastomeric components for oscillatory switching:

Microfluidic Blood-Brain Barrier (BBB) (I) • Fabricated BBB microfluidic device with embedded Ag/Ag. Cl electrodes:

Microfluidic Blood-Brain Barrier (BBB) (II) • Impedance measurement results:

High-Speed Laser Wavelength Tuning (I) • Nanoimprinted grating optical tunable filter MEMS device:

High-Speed Laser Wavelength Tuning (II) • High-speed laser wavelength tuning results and its biomedical application: