Kazuhiro Sunagawa1,2, Hiroshi Kanai3. 1. Department of Electronic Engineering, Graduate School of Engineering, Tohoku University, Aramaki-aza-Aoba 05, Aoba-ku, Sendai, 980-8579, Japan. 2. Panasonic Mobile Communications Sendai R&D Laboratory, Sendai, Japan. 3. Department of Electronic Engineering, Graduate School of Engineering, Tohoku University, Aramaki-aza-Aoba 05, Aoba-ku, Sendai, 980-8579, Japan. hkanai@ecei.tohoku.ac.jp.
Abstract
PURPOSE: The aim of this study was to find an array of frequency components, ranging from 0 Hz (direct current) to several tens of hertz that comprise the small vibrations on the arterial wall using noninvasive in vivo experiments. These vibrations are caused mainly by blood flow. The viscoelasticity of the arterial wall was estimated from the frequency characteristics of these vibrations propagating from the intima to the adventitia. METHODS: Propagation of these frequencies in human tissue displays certain frequency characteristics. Based on the Voigt model, shear viscoelasticity can be estimated from the frequency characteristics of the propagating vibrations. Moreover, we estimated shear viscoelasticity from the measured frequency characteristics of shear wave attenuation. RESULTS: Shear wave propagation from the intima to the adventitia resulting from blood flow was explained theoretically based on the obtained measurements. Shear viscoelasticity was also estimated from the measured frequency characteristics of shear wave attenuation. CONCLUSIONS: Based on the proposed method, shear viscoelasticity can be estimated from ultrasonographic measurements. These results have a novel potential for characterizing tissue noninvasively.
PURPOSE: The aim of this study was to find an array of frequency components, ranging from 0 Hz (direct current) to several tens of hertz that comprise the small vibrations on the arterial wall using noninvasive in vivo experiments. These vibrations are caused mainly by blood flow. The viscoelasticity of the arterial wall was estimated from the frequency characteristics of these vibrations propagating from the intima to the adventitia. METHODS: Propagation of these frequencies in human tissue displays certain frequency characteristics. Based on the Voigt model, shear viscoelasticity can be estimated from the frequency characteristics of the propagating vibrations. Moreover, we estimated shear viscoelasticity from the measured frequency characteristics of shear wave attenuation. RESULTS: Shear wave propagation from the intima to the adventitia resulting from blood flow was explained theoretically based on the obtained measurements. Shear viscoelasticity was also estimated from the measured frequency characteristics of shear wave attenuation. CONCLUSIONS: Based on the proposed method, shear viscoelasticity can be estimated from ultrasonographic measurements. These results have a novel potential for characterizing tissue noninvasively.