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Single particle trapping and characterization

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1 Single particle trapping and characterization
using dielectrophoretic particle trap Tae Joon Kwak, Hwangjae Lee, Jörg C. Woehl, Woo-Jin Chang Department of Mechanical Engineering, Chemistry and Biochemistry, and School of Freshwater Sciences, University of Wisconsin-Milwaukee

2 INTRODUCTION • Recent progress in micro- and nano-technology enables the development of various methods and devices to manipulate molecules such as electrophoresis, dielectrophoresis (DEP), etc. • Separation and characterization of specific particle and cell is important for a wide range of applications in pharmaceutical companies or cancer cell research. • We have applied AC-based DEP to capture and separate vast number of particles and cells in single particle level. • The electrical properties of the particles can be determined by combining single particle manipulation and further analytical techniques. • All traps in the array supply the identical electric field distribution to provide the same operating condition on any particles in the sample solution.

3 MATERIALS AND METHODS Dielectrophoresis (DEP)
• A dielectric particle placed in an electric field becomes electrically polarized as a result of partial charge separation • The charge separation leads to an induced dipole moment. In a non-uniform electric field, the particle experience dielectrophoretic force. r – radius of particle E – electric field – permittivity of medium Re[K] – Clasius-Mossotti Factor where σ = conductivity of electric field ω = angular frequency of electric field

4 r – radius of particle , E – electric field, – permittivity of medium
Dielectrophoresis (DEP) r – radius of particle , E – electric field, – permittivity of medium Re[K] – Clasius-Mossotti Factor where • The direction of the force is determined by the K, as known as the Clausius-Mossoti factor. • If a suspended particle has higher polarizability than the medium, the DEP force will push the particle toward regions of higher electric field (positive DEP). • On the other hand, if the medium has a higher polarizability than the suspended particle, the particle is driven toward regions of low field strength (negative DEP).

5 Numerical Simulation • The trap geometry is designed using numerical simulation to trap single particles. Circular shaped traps are designed for the generation of omni-directional negative dielectrophoretic forces. • Numerical analysis is also used to calculate the dielectrophoretic force acting on each particle by the voltage applied to the electrode. z y

6 Lab-on-a-chip Microfluidic System.
• The Lab-on-a-chip microfluidic device was fabricated through micro photolithography process.

7 Lab-on-a-chip Microfluidic System.

8 RESULT AND DISSCUSSION
• The polystyrene particles in the solution flowing in the microchannel moved freely along the flow. Individual particle was trapped in each trap by the trapping force of the DEP force with the aid of the electric field formed around the trap. • In a trap array, the electric field distribution around each dielectrophoretic trap capturing a particle does not vary from trap to trap. Particles with the same physical and electrical properties are captured in all traps under certain, well-defined conditions.

9 CONCLUSION • This study will advance the rapid isolation and identification of the molecules and micro- and nano-particles, such as cells, bacteria and DNA in single molecule level, by simultaneous manipulation of large number of the particles under identical condition.

10 Thank You


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