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Ultrasonic imaging parameters ~Attenuation coefficient Advisor: Pai-Chi Li Student: Mei-Ru Yang Wei-Ning Lee
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Methods and Apparatus Apparatus –Two transducers(one transmitter and one receiver) Methods –Log Spectral Difference Technique –Dispersion correction –Diffraction correction
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Log Spectral Difference Technique
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Attenuation and dispersion Attenuation obeys Use amplitude and phase information of the pulse Ultrasound reflection at the water-specimen interface produce error A w (f) : amplitude spectrum with water path only A s (f) : amplitude spectrum with the specimen inserted L : specimen thickness
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Cont’d Attenuation (amplitude) Dispersion (phase) Szabo’s model Linear attenuation, n=1 Nonlinear attenuation, n>1
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Cont’d From the above two equations, they have similar forms. Minimize TSE, we get Then, define a total squared error function: and n=1
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Diffraction Correction Diffraction effect on attenuation estimate due to the two media with different ultrasound velocities Experimental Diffraction Correction technique –Using the spectrum of the reference media, i.e. water Ad(f, z) : diffraction magnitude transfer function
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Cont’d Fresnel parameter : S=Sa=zλ a /a 2 ensures that the water-specimen-water and water- only paths undergo equivalent diffraction effects Then, : wavelength in water : wavelength in specimen
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Material Phantoms –Graphite phantom 1:6:12 (7.6, 6.6, 6.8 cm) –Breast phantom Transducers –3.5, 5, 7.5 MHz Pulse receiver Oscilloscope A/D: GaGe fs=100 MHz LabView low middle high
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Experimental results
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Log Spectral Difference Technique ---- concentration & attenuation lowmiddlehigh Fc: 3.5 MHz Frequency (MHz)-attenuation (dB/cm)
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Cont’d lowmiddlehigh Fc: 5 MHz 7.5 MHz Frequency (MHz)-attenuation (dB/cm)
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Log Spectral Difference Technique --- frequency & attenuation Lowmiddlehigh Attenuation coefficient (dB/cm-MHz) Attenuation coefficient
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Dispersion correction Linear fitting, n=1
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Cont’d LowMedianHigh With correction0.0837±0.02340.1274±0.0170.2455 ±0.0748 Without correction0.0875±0.02450.1101±0.0040.2605±0.0754 Without correctionLowMedianHigh 3.5MHz0.1077±0.26650.1143±0.10120.3437±0.6453 5MHz0.0945±0.20470.1106±0.06170.2115±0.0511 7.5MHz0.0602±0.01210.1055±0.05340.2605±0.0754 With correctionLowMedianHigh 3.5MHz0.1033 ±0.01310.1310±0.00850.3544±0.0224 5MHz0.0548±0.00970.1417±0.01230.2034±0.022 7.5MHz0.0931±0.00380.1094±0.01040.1766±0.0147
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Diffraction correct Distance: 134mmDistance: 150 mmDistance: 205 mm 134+ 2.46 mm150+ 1.5 mm205+ 2.26 mm Attenuation coefficient (uncorrected) 0.8357-0.57940.3984 Attenuation coefficient (corrected) 0.8225-0.73930.7397
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Clinical application Heart samples Human dermis Bone
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Heart samples Transducer frequency –2.5-40 MHz Samples –Normal, infarcted, dilated cardiomyopathy Results –Attenuation of the normal sample was smaller than those of the infarcted and cardiomyopathy samples in all frequency –Exponent of power function
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Human dermis Transducer frequency –40 MHz Volar face of the forearm –150 healthy subjects aged 14-85 yr Results –the decrease with advancing age of the attenuation coefficient –Attenuation coefficient: 0.7-3.6 dB/cm-MHz
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Bone Cancellous bone & cortical bone –More porous and thinner with advancing age Osteoporotic bone –Low bone density and deterioration of bone tissue –Low attenuation and velocity X-ray & ultrasound –Bone density, microarchitecture, elasticity
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Cont’d Measuring techniques (250 kHz-1.25 MHz) –Transverse technique Both transducers are placed on each side of the skeletal site The wave passes through bone –Axial technique The set of transducers is placed on the skin along the bone Wave propagates along the long axis of bone Transmitter Receiver Cortical bone
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Cont’d Skeletal siteTypeTechnique couplingImageParameter Calcaneus (cancellous bone) Transverse transmission Immersion or contract PossibleSpeed Attenuation Finger phalanxes (Integral bone) Transverse transmission ContractNoSpeed Radius, Tibia Finger phalanxes (Cortical bone) Axial transmissionContractNoSpeed
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References [1] “Anisotropy of attenuation and backscatter in cancellous bone” IEEE Ultra. Sym., pp. 1325-1328, 1999. [2] Ping He, “Acoustic parameter estimation based on attenuation and dispersion measurements,” Proc. IEEE/EMBS, Oct. 29, Nov. 1, 1998 [3] Wei Xu, Jonathan J. Kaufman, “Diffraction correction methods for insertion ultrasound attenuation estimation,” IEEE Trans. On Biomedical Engineering, vol. 40, No. 6, June 1993 [4] N. Kudo, T. Kamataki, K. Yamamoto, H. Onozuka, T. Mikami, A. Kitabatake, Y. Ito and H. Kanda “Ultrasound attenuation measurement of tissue in frequency range 2.5-40 MHz using a multi-resonance transducer,” 1997 IEEE Ultrson. Symp., pp. 1181-1184. [5] C. Guittet, F. Ossant, L. Vaillant, M. Berson “In vivo high-frequency ultrasonic characterization of human dermis,” IEEE trans. Biomedical Engineering, vol. 46, no. 6, pp. 740-746, June,1999. [6] M. Lebertre, F. Ossant, L. Vaillant, S. Diridollou and F. Patat “Human dermis ultrasound characterization: backscattering parameters between 22-45M Hz,” in Proc. 2000 IEEE Ultrson. Symp., pp. 1371-1374.
![References [1] Anisotropy of attenuation and backscatter in cancellous bone IEEE Ultra.](http://images.slideplayer.com/24/7432226/slides/slide_23.jpg "Sym., pp , [2] Ping He, Acoustic parameter estimation based on attenuation and dispersion measurements, Proc. IEEE/EMBS, Oct. 29, Nov. 1, 1998 [3] Wei Xu, Jonathan J. Kaufman, Diffraction correction methods for insertion ultrasound attenuation estimation, IEEE Trans. On Biomedical Engineering, vol. 40, No. 6, June 1993 [4] N. Kudo, T. Kamataki, K. Yamamoto, H. Onozuka, T. Mikami, A. Kitabatake, Y. Ito and H. Kanda Ultrasound attenuation measurement of tissue in frequency range MHz using a multi-resonance transducer, 1997 IEEE Ultrson. Symp., pp [5] C. Guittet, F. Ossant, L. Vaillant, M. Berson In vivo high-frequency ultrasonic characterization of human dermis, IEEE trans. Biomedical Engineering, vol. 46, no. 6, pp , June,1999. [6] M. Lebertre, F. Ossant, L. Vaillant, S. Diridollou and F. Patat Human dermis ultrasound characterization: backscattering parameters between 22-45M Hz, in Proc IEEE Ultrson. Symp., pp")
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Cont’d [7] P. Laugier, E. Camus, S. Chaffai, F. Peyrin, M. Talmant and G. Berger “Quantitative Ultrasound for Bones status assessment,” in Proc. 2000 IEEE Ultrson. Symp., pp. 1341-1350. [8] Jorgensen, United states patent, P.N. 6086538, 2000. [9] Ping He, “Determination of ultrasonic parameters based on attenuation and dispersion measurements,” Ultrasonic imaging, 1998. [10] Ping He, “Direct measurement of ultrasonic dispersion using a broadband transmission technique,” Ultrasonics, 1998.
![Cont’d [7] P. Laugier, E. Camus, S. Chaffai, F.](http://images.slideplayer.com/24/7432226/slides/slide_24.jpg "Peyrin, M. Talmant and G. Berger Quantitative Ultrasound for Bones status assessment, in Proc IEEE Ultrson. Symp., pp [8] Jorgensen, United states patent, P.N , [9] Ping He, Determination of ultrasonic parameters based on attenuation and dispersion measurements, Ultrasonic imaging, [10] Ping He, Direct measurement of ultrasonic dispersion using a broadband transmission technique, Ultrasonics,")
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