IEEE Trans Med Imaging. 2018 Aug;37(8):1887-1898. doi: 10.1109/TMI.2018.2820157. Epub 2018 Mar 28.
Characterizing the viscoelastic properties of thin-layer tissues with micro-level thickness has long remained challenging. Recently, several micro-elastography techniques have been developed to improve the spatial resolution. However, most of these techniques have not considered the medium boundary conditions when evaluating the viscoelastic properties of thin-layer tissues such as arteries and corneas; this might lead to estimation bias or errors. This paper aims to integrate the Lamb wave model with our previously developed ultrasonic micro-elastography imaging system for obtaining accurate viscoelastic properties in thin-layer tissues. A 4.5-MHz ring transducer was used to generate an acoustic radiation force for inducing tissue displacements to produce guided wave, and the wave propagation was detected using a confocally aligned 40-MHz needle transducer. The phase velocity and attenuation were obtained from k-space by both the impulse and the harmonic methods. The measured phase velocity was fit using the Lamb wave model with the Kelvin-Voigt model. Phantom experiments were conducted using 7% and 12% gelatin and 1.5% agar phantoms with different thicknesses (2, 3, and 4 mm). Biological experiments were performed on porcine cornea and rabbit carotid artery ex vivo. Thin-layer phantoms with different thicknesses were confirmed to have the same elasticity; this was consistent with the estimates of bulk phantoms from mechanical tests and the shear wave rheological model. The trend of the measured attenuations was also confirmed with the viscosity results obtained using the Lamb wave model. Through the impulse and harmonic methods, the shear viscoelasticity values were estimated to be 8.2 kPa for $0.9\text {Pa}{\cdot} \text {s}$ and 9.6 kPa for $0.8\text {Pa}{\cdot} \text {s}$ in the cornea and 27.9 kPa for $0.1\text {Pa}\cdot \text {s}$ and 26.5 kPa for $0.1\text {Pa}\cdot \text {s}$ in the artery.
characterization 表征
viscoelastic properties 粘弹性
thin-layer tissues 薄层组织
micro-level thickness 微观厚度
long 一直
remain 保持
challenging 具有挑战性的
recently 最近
several 几个
micro-elastography techniques 微弹性成像技术
develop 开发
improve 提高
spatial resolution 空间分辨率
most of 大多数
evaluate 评估
viscoelastic properties 粘弹性
thin-layer tissues 薄层组织
arteries 动脉
corneas 角膜
medium boundary conditions 介质边界条件
might 可能
lead to 导致
estimation bias 估计偏差
errors 误差
aim to 旨在
integrate 集成
Lamb wave model Lamb 波模型
previously developed ultrasonic micro-elastography imaging system 先前开发的超声微弹性成像系统
obtain 获得
accurate 准确的
viscoelastic properties 粘弹性
thin-layer tissues 薄层组织
4.5-MHz ring transducer 4.5MHz 环形换能器
generate 产生
acoustic radiation force 声辐射力
induce 引起
tissue displacements 组织位移
produce 产生
guided wave 导波
detect 检测
confocally aligned 共焦对准的
40-MHz needle transducer 40MHz 针状换能器
k-space k 空间
obtain 获得
phase velocity 相速度
attenuation 衰减
impulse method 脉冲法
harmonic method 谐波法
fit 拟合
Lamb wave model Lamb 波模型
Kelvin-Voigt model Kelvin-Voigt 模型
phantom experiments 体模实验
gelatin 明胶
agar 琼脂
different thicknesses 不同厚度
7% 7%
12% 12%
1.5% 1.5%
2mm 2mm
3mm 3mm
4mm 4mm
confirm 确认
have the same elasticity 具有相同的弹性
bulk phantoms 体模
mechanical tests 力学测试
shear wave rheological model 剪切波流变模型
estimate 估计
trend 趋势
viscosity 粘度
Lamb wave model Lamb 波模型
impulse method 脉冲法
harmonic method 谐波法
shear viscoelasticity 剪切粘弹性
cornea 角膜
rabbit 兔子
carotid artery 颈动脉
ex vivo 在体
0.9~Pa·s 0.9 帕秒
0.8~Pa·s 0.8 帕秒
0.1~Pa·s 0.1 帕秒
