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Electrical Impedance Spectroscopic Studies on Broiler Chicken Tissue Suitable for the Development of Practical Phantoms in Multifrequency EIT

Tushar Kanti Bera
Tushar Kanti Bera
 oraz 
J. Nagaraju
J. Nagaraju
   | 16 cze 2011
Journal of Electrical Bioimpedance's Cover Image
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Article Category: Articles
Data publikacji: 16 cze 2011
Zakres stron: 48 - 63
Otrzymano: 16 kwi 2011
DOI: https://doi.org/10.5617/jeb.174
Słowa kluczowe
© 2011 Tushar Kanti Bera, J. Nagaraju, published by Sciendo
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 3.0 License.

Figure-1

(a) A schematic of electrical impedance measurement, (b) four electrode measurement of electrical transfer impedance.
(a) A schematic of electrical impedance measurement, (b) four electrode measurement of electrical transfer impedance.

Figure-2

Nyquist plots for different circuit combinations: (a) R and L in parallel, (b) R and C in parallel, (c) r in series with (R and C in parallel), (d) r in series with (R and C in parallel) and (R and C in parallel), (e) R and CPE in parallel, (f) R1 in series with the parallel combinations of (R2 in series with W) and C.
Nyquist plots for different circuit combinations: (a) R and L in parallel, (b) R and C in parallel, (c) r in series with (R and C in parallel), (d) r in series with (R and C in parallel) and (R and C in parallel), (e) R and CPE in parallel, (f) R1 in series with the parallel combinations of (R2 in series with W) and C.

Figure-3

(a) animal cell membrane structure, (b) chicken muscle tissue paste in rectangular glass tank, (c) EIS study of chicken muscle tissue paste using QuadTech7600, (d) chicken muscle tissue block under EIS study using Agilent 4294A, (e) EIS study of chicken muscle tissue paste using Agilent 4294A.
(a) animal cell membrane structure, (b) chicken muscle tissue paste in rectangular glass tank, (c) EIS study of chicken muscle tissue paste using QuadTech7600, (d) chicken muscle tissue block under EIS study using Agilent 4294A, (e) EIS study of chicken muscle tissue paste using Agilent 4294A.

Figure-4

Conductivity profile of KCl solution (a) variation (over frequency) at different concentration, (b) variation (over concentration) at different frequencies.
Conductivity profile of KCl solution (a) variation (over frequency) at different concentration, (b) variation (over concentration) at different frequencies.

Figure-5

Variation of impedance parameters of chicken tissue paste over frequency: (a) ZMuscle Paste, (b) θMuscle Paste, (c) RMuscle Paste, (d) XMuscle Paste
Variation of impedance parameters of chicken tissue paste over frequency: (a) ZMuscle Paste, (b) θMuscle Paste, (c) RMuscle Paste, (d) XMuscle Paste

Figure-6

Variation of impedance parameters of chicken tissue over frequency: (a) ZFat, (b) θFat, (c) RFat, (d) XFat
Variation of impedance parameters of chicken tissue over frequency: (a) ZFat, (b) θFat, (c) RFat, (d) XFat

Figure-7

Variation of impedance parameters of chicken tissue over frequency: (a) ρMuscle Paste, (b) σMuscle Paste, (c) ρFat, (d) σFat.
Variation of impedance parameters of chicken tissue over frequency: (a) ρMuscle Paste, (b) σMuscle Paste, (c) ρFat, (d) σFat.

Figure-8

Nyquist plots tissue samples (a) muscle Paste, (b) fat.
Nyquist plots tissue samples (a) muscle Paste, (b) fat.

Figure-9

Algebraic mean of the Z, θ, R and X of chicken muscle tissue paste and fat tissue: (a) Z, (b) θ, (c) R, (d) X
Algebraic mean of the Z, θ, R and X of chicken muscle tissue paste and fat tissue: (a) Z, (b) θ, (c) R, (d) X

Figure-10

Algebraic mean of the ρ a nd σ of chicken muscle tissue paste and fat tissue: (a) ρMean, (b) σMean
Algebraic mean of the ρ a nd σ of chicken muscle tissue paste and fat tissue: (a) ρMean, (b) σMean

Figure-11

Mean Nyquist plots: (a) RMuscle Paste vs -XMuscle Paste, (b) RFat vs -XFat.
Mean Nyquist plots: (a) RMuscle Paste vs -XMuscle Paste, (b) RFat vs -XFat.

Figure-12

STDV of the impedance parameters of chicken muscle tissue paste and fat tissue: (a) Z, (b) θ, (c) R, (d) X
STDV of the impedance parameters of chicken muscle tissue paste and fat tissue: (a) Z, (b) θ, (c) R, (d) X

Figure-13

MDR of Z, θ, R and X of chicken muscle tissue paste and fat tissue: (a) Z, (b) θ, (c) R, (d) X.
MDR of Z, θ, R and X of chicken muscle tissue paste and fat tissue: (a) Z, (b) θ, (c) R, (d) X.

Figure-14

STDV of ρ and σ of chicken muscle tissue paste and fat tissue: (a) ρ, (b) σ
STDV of ρ and σ of chicken muscle tissue paste and fat tissue: (a) ρ, (b) σ

Figure-15

MDR of ρ and σ of chicken muscle tissue paste and fat tissue: (a) ρ, (b) σ
MDR of ρ and σ of chicken muscle tissue paste and fat tissue: (a) ρ, (b) σ

Figure-16

Variations of impedance parameters of chicken muscle tissue block over frequency: (a) ZMuscle Block, (b) θMuscle Block, (c) RMuscle Block, (d) XMuscle Block.
Variations of impedance parameters of chicken muscle tissue block over frequency: (a) ZMuscle Block, (b) θMuscle Block, (c) RMuscle Block, (d) XMuscle Block.

Figure-17

Variations of impedance parameters of chicken muscle tissue paste over frequency: (a) ZMuscle Paste, (b) θMuscle Paste, (c) RMuscle Paste, (d) XMuscle Paste.
Variations of impedance parameters of chicken muscle tissue paste over frequency: (a) ZMuscle Paste, (b) θMuscle Paste, (c) RMuscle Paste, (d) XMuscle Paste.

Figure-18

Variations of impedance parameters of chicken muscle tissue block over frequency: (a) ρMuscle Block, (b) σMuscle Block, (c) CMuscle Block, (d) εrMuscle Block.
Variations of impedance parameters of chicken muscle tissue block over frequency: (a) ρMuscle Block, (b) σMuscle Block, (c) CMuscle Block, (d) εrMuscle Block.

Figure-19

Variations of impedance parameters of chicken muscle tissue paste over frequency: (a) ρMuscle Paste, (b) σMuscle Paste.
Variations of impedance parameters of chicken muscle tissue paste over frequency: (a) ρMuscle Paste, (b) σMuscle Paste.

Figure-20

Nyquist plots tissue samples muscle tissue block
Nyquist plots tissue samples muscle tissue block

Variation of impedance parameters of muscle tissue paste and fat tissue samples (ZMuscle Paste, θMuscle Paste, RMuscle Paste, XMuscle Paste, ρMuscle Paste, σMuscle Paste, ZFat, θFat, RFat, XFat, ρFat and σFat.) for 10 Hz to 2 MHz.

ParametersMinMaxMeanChange
ZMuscle10 Hz445.01465.54455.284.51 %
2 MHz207.75209.33208.540.76 %
ZFat10 Hz1065.091168.151116.629.23 %
2 MHz730.08783.66756.877.08 %
θMuscle10 Hz-40.34-39.38-39.862.40 %
2 MHz0.660.700.684.71 %
θFat10 Hz-18.82-18.41-18.622.21 %
2 MHz-5.67-5.08-5.3811.04 %
RMuscle10 Hz343.76354.96349.363.20 %
2 MHz207.73209.32208.520.76 %
RFat10 Hz1008.191108.411058.309.47 %
2 MHz727.22779.82753.526.98 %
XMuscle10 Hz282.60301.22291.916.38 %
2 MHz-2.52-2.42-2.473.95 %
XFat10 Hz343.47368.77356.127.10 %
2 MHz64.6277.4471.0318.05 %
ρMuscle10 Hz2.752.842.793.20 %
2 MHz1.661.671.670.76 %
ρFat10 Hz60.4966.5063.509.47 %
2 MHz43.6346.7945.216.98 %
σMuscle10 Hz0.35220.36360.35793.19 %
2 MHz0.59720.60170.59950.75 %
σFat10 Hz0.01500.01650.01589.44 %
2 MHz0.02140.02290.02216.99 %
eISSN:
1891-5469
Język:
Angielski
Częstotliwość wydawania:
Volume Open
Dziedziny czasopisma:
Engineering, Bioengineering and Biomedical Engineering, Biomedical Electronics, Life Sciences, Biophysics, Medicine, Biomedical Engineering, Physics, Spectroscopy and Metrology
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