Microfluidic Manipulation for Biomedical and Biohealth Applications
Authors: Reza Hadjiaghaie Vafaie, Sevda Givtaj
Abstract:
Automation and control of biological samples and solutions at the microscale is a major advantage for biochemistry analysis and biological diagnostics. Despite the known potential of miniaturization in biochemistry and biomedical applications, comparatively little is known about fluid automation and control at the microscale. Here, we study the electric field effect inside a fluidic channel and proper electrode structures with different patterns proposed to form forward, reversal, and rotational flows inside the channel. The simulation results confirmed that the ac electro-thermal flow is efficient for the control and automation of high-conductive solutions. In this research, the fluid pumping and mixing effects were numerically studied by solving physic-coupled electric, temperature, hydrodynamic, and concentration fields inside a microchannel. From an experimental point of view, the electrode structures are deposited on a silicon substrate and bonded to a PDMS microchannel to form a microfluidic chip. The motions of fluorescent particles in pumping and mixing modes were captured by using a CCD camera. By measuring the frequency response of the fluid and exciting the electrodes with the proper voltage, the fluid motions (including pumping and mixing effects) are observed inside the channel through the CCD camera. Based on the results, there is good agreement between the experimental and simulation studies.
Keywords: Microfluidic, nano/micro actuator, AC electrothermal, Reynolds number, micropump, micromixer, microfabrication, mass transfer, biomedical applications.
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 86References:
[1] Ebensberger, Y. C., Lausen, T. and Thewes, R., 2018, September. Design of a High Accuracy Spatially Distributed Temperature Sensor Array for CMOS Lab-on-Chip Applications. In ANALOG 2018; 16th GMM/ITG-Symposium(pp. 1-5). VDE.
[2] Alam, M., Golozar, M. and Darabi, J., 2018. Modelling and simulation of particle-particle interaction in a magnetophoretic bio-separation chip. Physics of Fluids, 30(4), p.042001 .
[3] Chen, X. and Zhang, L., 2018. Review in manufacturing methods of nanochannels of bio-nanofluidic chips. Sensors and Actuators B: Chemical, 254, pp.648-659.
[4] Cui, X., Liu, Y., Hu, D., Qian, W., Tin, C., Sun, D., Chen, W. and Lam, R.H., 2018. A fluorescent microbead-based microfluidic immunoassay chip for immune cell cytokine secretion quantification. Lab on a Chip, 18(3), pp.522-531.
[5] Mozaffari, M. H., Ebnali-Heidari, M., Abaeiani, G. and Moravvej-Farshi, M.K., 2018. Designing a miniaturized photonic crystal based optofluidic biolaser for lab-on-a-chip biosensing applications. Organic Electronics, 54, pp.184-191.
[6] Shwetha, M., Reddy, N. K., Pattnaik, P. K. and Narayan, K., 2018, June. Design and analysis of silicon ring resonator for bio-sensing application. In Optical Design and Engineering VII (Vol. 10690, p. 106902R). International Society for Optics and Photonics.
[7] Whitesides, G., 2018. Microfluidics in Late Adolescence. arXiv preprint arXiv:1802.05595.
[8] Yu, F., Kumar, N. D. S., Choudhury, D., Foo, L. C. and Ng, S. H., 2018. Microfluidic platforms for modeling biological barriers in the circulatory system. Drug discovery today.
[9] Liu, G., Ma, X., Wang, C., Sun, X. and Tang, C., 2018. Piezoelectric driven self-circulation micromixer with high frequency vibration. Journal of Micromechanics and Microengineering, 28(8), p.085010.
[10] Hadjiaghaie Vafaie, R., 2018. A high-efficiency micromixing effect by pulsed AC electrothermal flow. COMPEL-The international journal for computation and mathematics in electrical and electronic engineering, 37(1), pp.418-431.
[11] Gambhire, S., Patel, N., Gambhire, G. and Kale, S., 2016. A Review on Different Micromixers and its Micromixing within Microchannel. International Journal of Current Engineering and Technology, 4, pp.409-413.
[12] Prabhakaran, R. A., Zhou, Y., Zhao, C., Hu, G., Song, Y., Wang, J., Yang, C. and Xuan, X., 2017. Induced charge effects on electrokinetic entry flow. Physics of Fluids, 29(6), p.062001.
[13] Wu, Y., Ren, Y., Tao, Y. and Jiang, H., 2017. Fluid pumping and cells separation by DC-biased traveling wave electroosmosis and dielectrophoresis. Microfluidics and Nanofluidics, 21(3), p.38.
[14] Rashidi, S., Bafekr, H., Valipour, M. S. and Esfahani, J. A., 2018. A review on the application, simulation, and experiment of the electrokinetic mixers. Chemical Engineering and Processing-Process Intensification, 126, pp.108-122.
[15] Yu, H., Ye, W., Zhang, W., Yue, Z. and Liu, G., 2015. Design, fabrication, and characterization of a valveless magnetic travelling-wave micropump. Journal of Micromechanics and Microengineering, 25(6), p.065019.
[16] Gao, Y., Tran, P., Petkovic-Duran, K., Swallow, T. and Zhu, Y., 2015. Acoustic micromixing increases antibody-antigen binding in immunoassays. Biomedical microdevices, 17(4), p.79.
[17] Ramos, A., García-Sánchez, P. and Morgan, H., 2016. AC electrokinetics of conducting microparticles: A review. Current Opinion in Colloid & Interface Science, 24, pp.79-90.
[18] Yang, F., Kuang, C., Zhao, W. and Wang, G., 2017. AC electrokinetic fast mixing in non-parallel microchannels. Chemical Engineering Communications, 204(2), pp.190-197.
[19] Ramos, A., Morgan, H., Green, N.G. and Castellanos, A., 1998. Ac electrokinetics: a review of forces in microelectrode structures. Journal of Physics D: Applied Physics, 31(18), p.2338.
[20] Vafaie, R. H., Mehdipoor, M., Pourmand, A., Poorreza, E. and Ghavifekr, H.B., 2013. An electroosmotically-driven micromixer modified for high miniaturized microchannels using surface micromachining. Biotechnology and bioprocess engineering, 18(3), pp.594-605.
[21] Ng, W. Y., Goh, S., Lam, Y. C., Yang, C. and Rodríguez, I., 2009. DC-biased AC-electroosmotic and AC-electrothermal flow mixing in microchannels. Lab on a Chip, 9(6), pp.802-809.
[22] Feldman, H. C., Sigurdson, M. and Meinhart, C. D., 2007. AC electrothermal enhancement of heterogeneous assays in microfluidics. Lab on a Chip, 7(11), pp.1553-1559.
[23] Vafaie, R. H., Ghavifekr, H. B., Van Lintel, H., Brugger, J. and Renaud, P., 2016. Bi‐directional ACET micropump for on‐chip biological applications. Electrophoresis, 37(5-6), pp.719-726.