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Journal of Medical Ultrasonics
Published in: Journal of Medical Ultrasonics 1/2020

01-01-2020 | Ultrasound | Original Article–Physics & Engineering

Frequency dependence of attenuation and backscatter coefficient of ex vivo human lymphedema dermis

Authors: Masaaki Omura, Kenji Yoshida, Shinsuke Akita, Tadashi Yamaguchi

Published in: Journal of Medical Ultrasonics | Issue 1/2020

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Abstract

Purpose

Radio-frequency (RF) signals from the most dominant scatterer in a dermis, i.e., collagen fibers, are collected as backscattered signals. We aim to confirm the frequency dependence of the spatial distribution of features in ultrasound images, as well as the attenuation coefficient (AC) and backscatter coefficient (BSC) of skin tissue without [LE (−)] and with lymphedema [LE (+)].

Methods

Measurement samples (n = 13) were excised from human skin tissue with LE (−) and middle severity LE (+). A laboratory-made scanner and single-element concave transducers (range 9–47 MHz) were used to measure RF data. A localized AC was computed from the normalized power spectrum using the linear least squares technique. The reflector method and compensation technique of the attenuation of tissue were applied to calculate the BSC. In addition, effective scatterer diameter (ESD), effective acoustic concentration (EAC), and integrated BSC (IBS) were calculated from the BSC as the benchmark to differentiate LE (−) and LE (+) tissues.

Results

High-frequency ultrasound displayed different echogenicity and texture compared between LE (−) and LE (+) in all transducers. The AC for LE (−) (0.22 dB/mm/MHz) and LE (+) (0.29 dB/mm/MHz) was comparable. BSC in LE (−) and LE (+) increased linearly with each transducer. The difference of intercept of the BSC between LE (−) and LE (+) indicated that both EAC and IBS of LE (+) were higher than that of LE (−). In contrast, ESD correlated with the slope of the BSC demonstrated the same tendency for both LE (−) and LE (+). These tendencies appeared for each transducer independent of the frequency bandwidth.

Conclusion

Frequency independence of AC and BSC in LE (−) and LE (+) was confirmed. Several 9- to 19-MHz ultrasound beams are sufficient for BSC analysis to discriminate LE (−) and LE (+) in terms of the penetration depth of the ultrasound.
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Metadata
Title
Frequency dependence of attenuation and backscatter coefficient of ex vivo human lymphedema dermis
Authors
Masaaki Omura
Kenji Yoshida
Shinsuke Akita
Tadashi Yamaguchi
Publication date
01-01-2020
Publisher
Springer Singapore
Published in
Journal of Medical Ultrasonics / Issue 1/2020
Print ISSN: 1346-4523
Electronic ISSN: 1613-2254
DOI
https://doi.org/10.1007/s10396-019-00973-z

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