The ability to manipulate or separate a biological small particle, such as a living cell and embryo, is fundamental needed to many biological and medical applications. The insulator-based dielectrophoresis (iDEP) trapping is composed of conductless tetragon structures in micro-chip. In this study, a lower conductive material of photoresist was adopted as a structure in open-top microchannel instead of a metallic wire to squeeze the electric field in a conducting solution, therefore, creating a high field gradient with a local maximum. The microchip with the open-top microchannels was designed and fabricated herein. The insulator-based DEP trapping microchip with the open-top microchannels was designed and fabricated in this work. The cells trapped by DEP force could be further treated or cultured in the open-top microchannel ; however, those trapped in the microchip with enclosed microchannels could not be proceeded easily

Chen, Teng-Wen

Huang, Yao-Hung

Jen, Chun-Ping

I-Revues

9-11 April 2008 
©EDA Publishing/DTIP 2008  ISBN: 978-2-35500-006-5 
Cell Trapping Utilizing Insulator-based 
Dielectrophoresis in The Open-Top Microchannels 
 
Chun-Ping Jen*, Yao-Hung Huang and Teng-Wen Chen 
Department of Mechanical Engineering, National Chung Cheng University,  
No. 168, University Rd., Min-Hsiung, Chia Yi, 62102, Taiwan, R.O.C. 
 
Abstract- The ability to manipulate or separate a biological 
small particle, such as a living cell and embryo, is 
fundamental needed to many biological and medical 
applications.  The insulator-based dielectrophoresis (iDEP) 
trapping is composed of conductless tetragon structures in 
micro-chip. In this study, a lower conductive material of 
photoresist was adopted as a structure in open-top 
microchannel instead of a metallic wire to squeeze the electric 
field in a conducting solution, therefore, creating a high field 
gradient with a local maximum.  The microchip with the 
open-top microchannels was designed and fabricated herein.  
The insulator-based DEP trapping microchip with the 
open-top microchannels was designed and fabricated in this 
work.  The cells trapped by DEP force could be further treated 
or cultured in the open-top microchannel; however, those 
trapped in the microchip with enclosed microchannels could 
not be proceeded easily. 
  
I. INTRODUCTION 
The ability to manipulate particles, especially living cells, 
is essential to many biological and medical applications, 
including isolation and detection of rare cancer cells, 
concentration of cells from dilute suspensions, separation of 
cells according to specific properties, and trapping and 
positioning of individual cells for characterization.  Several 
kinds of physical forces can be employed for particle 
manipulation. Those are optical [1], mechanical [2], magnetic 
[3,4], electrical [5,6], and other manipulations [7,8].   
Dielectrophoresis (DEP) has been widely used for the 
manipulation, separation and characterization of cells, DNA, 
virus, and colloid particles (in both micro- and nano-scales) in 
various microfluidic platforms.  DEP force is generated by 
electrode structures of appropriately designed such as the 
pin-plate [9] isomotive [10], polynomial [11], or castellated 
interdigitated forms [12].  Early studies of DEP used electrode 
structures made from thin metal wires, needles, or plates, 
while modern DEP employs microfabrication technology to 
produce microelectrode arrays capable of producing 
sufficiently large DEP forces to induce particle motion with 
small applied voltages.  DEP on micro-fabricated electrodes 
has been proved especially suitable for its relative ease of 
micro-scale generation and structuring of an electric field on 
microchips.  Moreover, integrated DEP biochips provide the 
advantages of speed, flexibility, controllability and ease of 
application to automation because DEP traps consist of 
scalable electrode arrays be designed to pattern thousands of 
cells on a single glass slide.  DEP have been using as cell 
trapping [13], levitation [14], separation [15], and sorting [16] 
on an electrode array by varying electrode shape and 
arrangement. DEP on micro-fabricated electrodes has been 
proved especially suitable for its relative ease of micro-scale 
generation and structuring of an electric field on microchips.   
DEP force field could also be generated by using dielectric 
constrictions or insulating obstacles, therefore, these methods 
further extend the scope of DEP applications.  These 
approaches have been termed electrodeless dielectrophoresis 
(EDEP) [17] or insulator-based dielectrophoresis (iDEP) [18], 
respectively, in distinguishing from the method 
conventionally employed by metal electrodes-based DEP for 
force generation.   
In this study, a lower conductive material of photoresist 
(JSR, THB 151N) was adopted as a structure in open-top 
microchannel instead of a metallic wire to squeeze the electric 
field in a conducting solution, therefore, creating a high field 
gradient with a local maximum.  The microchip with the 
open-top microchannels was designed and fabricated herein.  
The schematic illustration of the trapping device is shown in 
Fig 1.  This trapping microchip is suitable for trapping cells or 
biological samples and easily proceeding further treatment for 
cells, such as culturing or contact detection.  Biological 
sample and buffer loading before analysis and cleaning after 
analysis in the proposed microchip with the open-top 
microchannels could become easier and faster, hence, it is 
beneficial in high-speed sequential multiple measurements.  
Furthermore, the Joule heat generated by applying high 
voltage in the open-top microchannel could dissipate more 
effectively than that in the enclosed microchannel, because 
that it is open to the air.  When the fluorescent detection is 
used, the intensity of the emitted light will not be interfered by 
the cover, which is absent in the microchip with open-top 
microchannels.   
II. DIELECTROPHORETIC(DEP) FORCE THEORY 
The phenomenon of DEP is first defined by Pohl (1978) as 
the motion of neutral particles caused by dielectric 
polarization effects in non-uniform electric fields that 
alternating fields of a wide range of frequencies were used.  
The DEP force FDEP acting on a spherical particle of radius r 
suspended in a fluid of permittivity 
mε  is given： 
)()](Re[2 20
3 EKrF mDEP ∇= ∗ ωεεπ                                  (1) 
9-11 April 2008 
©EDA Publishing/DTIP 2008  ISBN: 978-2-35500-006-5 
and 
∗∗
∗∗
∗
+
−=
mp
mpK εε
εεω
2
)(
 
where  and  are complex permittivity of the dielectric 
particle and the medium, and the magnitude of the electric 
field, E, may be replaced by Erms, which is  root-mean-square 
of the external field, in an alternating field.  , the 
real (in-phase) part of the Clausius Mossotti factor, , is 
a parameter of the effective polarizability of the particle 
which varies as a function of the frequency of the applied field 
(ω), and the dielectric properties of the particle and the 
surrounding medium. 
*
pε *mε
)](Re[ ω∗K
)(ω∗K
III. FABRICATION OF THE MICROCHIP 
The microchip of with the open-top microchannels was 
fabricated by microfabrication techniques, which were 
depicted in Fig. 2.  The electrodes were made by depositing 
chrome and aurum sequentially on the slides by an electron 
beam evaporator.  Chrome was the first deposited for the 
purpose of enhancement.  The finally deposition thickness of 
Chrome and Aurum are 50 nm and 100 nm.  The JSR 
photoresist (60 μm in thickness) was spun on the glass slide to 
pattern micro-channels of constriction for insulator-based 
DEP.  The PDMS prepolymer mixture was cured and cut to 
form a well of 3 cm by 1.5 cm.  The glass slide and the PDMS 
well were bonded after the treatment of oxygen plasma to 
avoid the leakage of the sample. 
IV RESULTS AND DISCUSSIONS 
The contours of the square of electric field at different 
heights in the open-top microchip were simulated and 
depicted in Fig. 3.  The applied electric field is 3×104 V/m; the 
space and the angle of the tip are 60 μm and 30 degree, 
respectively.  The insulator (JSR photoresist) is 60 μm in 
height.  On the surface and 30 μm above of the glass slide 
(where is the middle plane of the insulator), the local 
maximum of the electric fields occurred at the tips which 
form the constriction of the electric field.  When the height 
increases, the electric field became uniform due to the 
absence of the insulator-based constriction.  The distributions 
of the gradient of E2 along the centerline between the tips at 
different heights (for the gap between tips 60 μm and the 
angle of the tip 30 degree) were plotted in Fig. 4a.  The 
magnitude of gradient of E2 is proportional to the DEP force.  
Comparing to the DEP force at the surface of the glass slid, 
the magnitude of the DEP was reduced approximately 14% 
and 53%, when the height was increased to 30 and 60 μm, 
respectively.  The results in Fig 4a revealed that the DEP 
force decrease with the height, however, the force is still 
strong enough within the insulator, where the height is less 
than 60 μm.  The shorter the distance is, the larger gradient of 
E2 is, which implied stronger DEP force.  The scanning 
electron microscopy (SEM) image of microfabricated 
trapping chip with the open-top microchannels was shown in 
Fig. 5.  The experimental results were also performed in the 
present work.  The experimental set up was established as 
shown in Fig. 6 (the tips are 100 μm apart).  According to the 
preliminary results obtained experimentally, the 3T3 (Mouse 
embryonic fibroblast cell line) cells suspended in the sucrose 
solution (8.62 % weight percent; and its conductivity is 17.6 
μS/cm) could be successfully trapped at the tip when applying 
the electric field of 3×104 V/m, and the AC frequency of 1 
MHz (Fig. 7).  The insulator-based DEP trapping microchip 
with the open-top microchannels was designed and fabricated 
in this work.  The cells trapped by DEP force could be further 
treated or cultured in the open-top microchannel; however, 
those trapped in the microchip with enclosed microchannels 
could not be proceeded easily. 
ACKNOWLEDGMENT 
The authors would like to thank the National Science 
Council of the Republic of China for financial support of this 
research under contract No. NSC-96-2221-E-194-053. 
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9-11 April 2008 
©EDA Publishing/DTIP 2008  ISBN: 978-2-35500-006-5 
x (μm)
∂(E
2 )
/∂x
(V
2
/m
3 )
-100 -50 0 50 100
-2.5x10+13
-2.0x10+13
-1.5x10+13
-1.0x10+13
-5.0x10+12
0.0x10+00
5.0x10+12
1.0x10+13
1.5x10+13
2.0x10+13
2.5x10+13
60 μm
80 μm
100 μm
1
2
3
1
2
3
x
y
Z = height = 30 μm
Distance between tips
x (μm)
∂(E
2 )
/∂x
(V
2 /
m
3 )
-100 -50 0 50 100
-2.5x10+13
-2.0x10+13
-1.5x10+13
-1.0x10+13
-5.0x10+12
0.0x10+00
5.0x10+12
1.0x10+13
1.5x10+13
2.0x10+13
2.5x10+13
60 μm
80 μm
100 μm
1
2
3
1
2
3
x
y
Z = height = 60 μm
Distance between tips
 
(c)                                       (d) 
Figure 4: The numerical results of the gradient of the square of 
electric field along the centerline between the tips: (a) at 
different heights (the gap between tips 60 μm and the angle of 
the tip 30 degree); (b-d) for different distance between tips at 
heights of 0, 30 and 60 μm, respectively.  The applied electric 
field is 3×104 V/m.   
Figure 1: Schematic diagram of cell trapping chips with 
open-top microchannels.   
 
  Figure 2: The fabrication processes of the cell trapping 
microchips: fabrication of (a) electrode on glass slide; (b) 
microchannel; and (c) bonding.   
Figure 5: The scanning electron microscopy (SEM) image of the 
microfabricated trapping device. 
 
  
(a)                                           (b) 
  
Function generator 
PC and image 
acquisition system
Amplifier 
Optical microscope
(c)                                           (d) 
Figure 3: The numerical simulation of the electric field in the 
microchannel at (a) the surface of the glass slide; (b) 30 μm 
above the glass slide; (c) 60 μm above the glass slide (the 
thickness of the JSR photo resist is 60 μm); and (d) 160 μm 
above the glass slide.  The applied electric field is 3×104 V/m 
and the space and the angle of the tip are 60 μm and 30 degree, 
respectively.  
 
Figure 6: The schematic illustration of the experimental set up.   
 
   
x (μm)
∂(E
2
)/
∂x
(V
2 /
m
3 )
-100 -50 0 50 100
-2.5x10+13
-2.0x10+13
-1.5x10+13
-1.0x10+13
-5.0x10+12
0.0x10+00
5.0x10+12
1.0x10+13
1.5x10+13
2.0x10+13
2.5x10+13
Z=0μm
Z=30μm
Z=60μm
Z=160μm
0
1
2
3
1
2
3
0
x
y
Z = height
Distance between tips = 60 μm
x (μm)
∂(E
2 )
/∂x
(V
2 /
m
3 )
-100 -50 0 50 100
-2.5x10+13
-2.0x10+13
-1.5x10+13
-1.0x10+13
-5.0x10+12
0.0x10+00
5.0x10+12
1.0x10+13
1.5x10+13
2.0x10+13
2.5x10+13
60 μm
80 μm
100 μm
1
2
3
1
2
3
x
y
Z = height = 0 μm
Distance between tips
 
Figure 7: The experimental results of cell trapping using 
insulator-based DEP: (a) AC field is off; (b) AC field is on, the 
applied electric field is 3×104 V/m, the frequency of the AC field 
is 1 MHz. (a)                                       (b) 
 


Cell Trapping Utilizing Insulator-based Dielectrophoresis in The Open-Top Microchannels

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Cell Trapping Utilizing Insulator-based Dielectrophoresis in The Open-Top Microchannels

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