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Erschienen in:
Graphene Based Physical and Chemical Sensors Kapitel lesen Erstes Kapitel lesen

2016 | OriginalPaper | Buchkapitel

Design and Realization of a Planar Interdigital Microsensor for Biological Medium Characterization

verfasst von : T.-T. Ngo, A. Bourjilat, J. Claudel, D. Kourtiche, M. Nadi

Erschienen in: Next Generation Sensors and Systems

Verlag: Springer International Publishing

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Abstract

In this work, we present the design of a planar interdigital microsensor for the characterization of biological mediums by impedance spectroscopy. We propose a theoretical optimization of the geometrical parameters of this sensor. The optimization allows to extend the measurement frequency range by reducing the polarization effect which is manifested by a double layer (DL). We present also a new method for a planar interdigital transducer to determine the parameters (relative permittivity, capacitance) of the double layer (DL) on the surface of the electrode loaded by a biological medium. The CoventorWare® software was used to simulate the model design of interdigital transducer in three dimensions (3D). The simulation results are coherent with the method proposed. Therefore, this method can be used to determine the parameters of double layers of a planar interdigital sensor in order to match its frequency band to the intented application.

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Vorheriges Kapitel Graphene Based Physical and Chemical Sensors
Nächstes Kapitel Molecularly Imprinted Impedimetric Sensing of Phthalates: A Real-Time Assay Technique
Literatur
1.
K.S. Cole, H.J. Curtis, Electric impedance of the squid giant axon during activity. J. Gen. Physiol. 22(5), 649–670 (1939)CrossRef
2.
H. Fricke, S. Morse, The electric capacity of tumors of the breast. J. Cancer Res. 10, 340–376 (1926)
3.
H. P. Schwan, Electrical properties of tissue and cell suspensions. Adv. Biol. Med. Phys. 5, 147–209 (1957)
4.
I. Giaever, C. Keese, Micromotion of mammalian cells measured electrically. Proc. Natl. Acad. Sci. USA 88(17), 7896–7900 (1991)CrossRef
5.
D.A. Borkholder, Cell Based Biosensors Using Microelectrodes.pdf (Stanford University, Stanford, 1998)
6.
M. Heuschkel, M. Fejtl, A three-dimensional multi-electrode array for multi-site stimulation and recording in acute brain slices. J. Neurosci. Methods 114(2), 135–148 (2002)CrossRef
7.
R. Popovtzer, T. Neufeld, Electrochemical detection of biological reactions using a novel nano-bio-chip array. Sens. Actuators B Chem. 119(2), 664–672 (2006)CrossRef
8.
J.S. Wei, Distributed capacitance of and acoustic surface. IEEE J. Quantum Electron. 13(4), 152–158 (1977)CrossRef
9.
G. Alley, Interdigital capacitors and their application to lumped-element microwave integrated circuits. Microw. Theory Tech. IEEE Trans. 18, 1028–1033 (1970)CrossRef
10.
P.R. Herczfeld, Special issue on applications of lightwave technology to microwave devices. IEEE-INST Electr. Electron. Eng. INC 38(5), 465–466 (1990)
11.
M. Ibrahim, J. Claudel, D. Kourtiche, M. Nadi, Geometric parameters optimization of planar interdigitated electrodes for bioimpedance spectroscopy. J. Electr. Bioimpedance 4(1), 13–22 (2013)
12.
T.-T. Ngo, H. Shirzadfar, D. Kourtiche, M. Nadi, A planar interdigital sensor for bio-impedance measurement: theoretical analysis, optimization and simulation. J. Nano- Electron. Phys. 6(1), 1–7 (2014)
13.
T. Ngo, H. Shirzadfar, A. Bourjilat, D. Kourtiche, M. Nadi, A method to determine the parameters of the double layer of a planar interdigital sensor. www-ist.massey.ac.nz (2014), pp. 2–4
14.
M. Ibrahim, J. Claudel, D. Kourtiche, Physical and electrical modeling of interdigitated electrode arrays for bioimpedance spectroscopy. in New Developments and Applications in Sensing Technology (2011), pp. 169–189
15.
W. Laureyn, D. Nelis, P. Van Gerwen, Nanoscaled interdigitated titanium electrodes for impedimetric biosensing. Sens. Actuators B 360–370 (2000)
16.
L. Yang, Y. Li, C.L. Griffis, M.G. Johnson, Interdigitated microelectrode (IME) impedance sensor for the detection of viable Salmonella typhimurium. Biosens. Bioelectron. 19(10), 1139–1147 (2004)CrossRef
17.
M. Varshney, Y. Li, Interdigitated array microelectrode based impedance biosensor coupled with magnetic nanoparticle-antibody conjugates for detection of Escherichia coli O157:H7 in food samples. Biosens. Bioelectron. 22(11), 2408–2414 (2007)CrossRef
18.
R. Wang, Y. Wang, K. Lassiter, Y. Li, B. Hargis, S. Tung, L. Berghman, W. Bottje, Interdigitated array microelectrode based impedance immunosensor for detection of avian influenza virus H5N1. Talanta 79, 159–164 (2009)CrossRef
19.
A.R. Mohd Syaifudin, S.C. Mukhopadhyay, P.-L. Yu, H.-S.M.J., C.-H. Chuang, V.J.D., Y.-W. Huang, Measurements and performance evaluation of novel interdigital sensors for different chemicals related to food poisoning. IEEE Sens. J. 11(11), 2957–2965 (2011)
20.
M. Da Silva, T. Sühnel, E. Schleicher, R. Vaibar, Planar array sensor for high-speed component distribution imaging in fluid flow applications. Sensors 7, 2445 (2007)CrossRef
21.
F. Alexander, D.T. Price, S. Bhansali, Optimization of interdigitated electrode (IDE) arrays for impedance based evaluation of Hs 578T cancer cells. J. Phys: Conf. Ser. 224, 012134 (2010)
22.
T. Huang, J. Chou, T. Sun, and S. Hsiung, A device for skin moisture and environment humidity detection. Sens. Actuators B 134, 206–212 (2008)
23.
V. Kasturi, S.C. Mukhopadhyay, Estimation of property of sheep skin to modify the tanning process using interdigital sensors. Lecture Notes in Electrical Engineering, vol. 21 LNEE, pp. 91–110 (2008)
24.
M. Mukhopadhyay, S.C. Yamada, S. Iwahara, Evaluation of near- surface material properties using planar mesh type coils with post-processing from neural network model. Int. J. Electromagn. Nondestuctive Eval. 23, 181–188 (2002)
25.
M.I.S.C. Mukhopadhyay, S. Yamada, Inspection of electroplated materials—performance comparison with planar meander and mesh type magnetic sensor. Int. J. Appl. Electromagn. Mech. 15, 323–329 (2002)
26.
A. Choi, J. Park, H. Jung, Solid-medium-integrated impedimetric biosensor for real-time monitoring of microorganisms. Sens. Actuators B Chem. 137, 357–362 (2009)CrossRef
27.
B. Pejcic, R. De Marco, Impedance spectroscopy: Over 35 years of electrochemical sensor optimization. Electrochim. Acta 51(28), 6217–6229 (2006)CrossRef
28.
R. Igreja, C.J. Dias, Analytical evaluation of the interdigital electrodes capacitance for a multi-layered structure. Sens. Actuators A Phys. 112(2–3), 291–301 (2004)CrossRef
29.
C.R. Bowen, L.J. Nelson, R. Stevens, M.G. Cain, M. Stewart, Optimisation of interdigitated electrodes for piezoelectric actuators and active fibre composites. J. Electroceramics 16(4), 263–269 (2006)CrossRef
30.
L. Wang, H. Wang, K. Mitchelson, Z. Yu, J. Cheng, Analysis of the sensitivity and frequency characteristics of coplanar electrical cell-substrate impedance sensors. Biosens. Bioelectron. 24(1), 14–21 (2008)CrossRef
31.
T. Pajkossy, D.M. Kolb, Double layer capacitance of Pt(111) single crystal electrodes. Electrochim. Acta 46(20–21), 3063–3071 (2001)CrossRef
32.
David A. Borkholder, Cell Based Biosensors Using (1998)
33.
A. Bard, L. Faulkner, Fundamentals and Applications (1980)
34.
R. Pradhan, A. Mitra, and S. Das, Extended Stern Model (2012), pp. 74–78
35.
W. Olthuis, W. Streekstra, P. Bergveld, Theoretical and experimental determination of cell constants of planar-interdigitated electrolyte conductivity sensors. Sens. Actuators B 25, 252–256 (1995)
36.
B. Timmer, W. Sparreboom, W. Olthuis, P. Bergveld, A. van den Berg, Optimization of an electrolyte conductivity detector for measuring low ion concentrations. Lab Chip 2(2), 121–124 (2002)CrossRef
37.
J.-F. Chateaux, Conception et réalisation d’une cellule de caractérisation des tissus biologiques par spectroscopie de bioimpédance dans la gamme fréquentielle [100 Hz–1 MHz]. Application aux tissus osseux—Prise en compte de l’anisotropie (Thèse de l’Université Henri Poincaré, Nancy I, 2000)
38.
L. Bernard, Caractérisation électrique des tissus biologiques et calcul des phénomènes induits dans le corps humain par des champs électromagnétiques de fréquence inférieure au GHz ., Thèse de l’Ecole Centrale de Lyon, 2007
39.
40.
O. Linderholm, Two-dimensional microimpedance imaging for cell culture monitoring, vol. 3604 (2006)
41.
C. Veyres, V.F. Hanna, Extension of the application of conformal mapping techniques to coplanar lines with finite dimensions. Int. J. Electron. 48(1), 47–56 (1980)
42.
V. 2010, Coventor Ware ® ANALYZER (2010)
Metadaten
Titel
Design and Realization of a Planar Interdigital Microsensor for Biological Medium Characterization
verfasst von
T.-T. Ngo
A. Bourjilat
J. Claudel
D. Kourtiche
M. Nadi
Copyright-Jahr
2016
Buch
Next Generation Sensors and Systems

Print ISBN: 978-3-319-21670-6

Electronic ISBN: 978-3-319-21671-3

Copyright-Jahr: 2016

DOI
https://doi.org/10.1007/978-3-319-21671-3_2

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