Michiko Sato1, Hideaki Ishida2, Kei Konno1, Tomoya Komatsuda3, Kayoko Furukawa3, Mamiko Yamada3, Hitoshi Yagisawa3, Yasuo Yoshida1, Sumio Watanabe1. 1. First Department of Internal Medicine, Akita University School of Medicine, Akita, Japan. 2. Center of Diagnostic Ultrasound, Akita Red Cross Hospital, 222-1 Saruta Kamikitade, Akita, 010-1495, Japan. ishida@archosp-1998.com. 3. Center of Diagnostic Ultrasound, Akita Red Cross Hospital, 222-1 Saruta Kamikitade, Akita, 010-1495, Japan.
Abstract
PURPOSE: To evaluate the role of vertical images reconstructed using 3-D data in the analysis of posterior echoes. METHODS: Reconstructed vertical images of US phantoms with the following artifacts were retrieved and analyzed: acoustic shadowing (clean and dirty); posterior echo enhancement (with/without lateral shadowing); and reverberation artifacts (clean and dirty). RESULTS: For acoustic shadowing, a stone and posterior clean acoustic shadowing were imaged as an echogenic mass or an echogenic ring containing a central echo-free area. However, the stone and dirty acoustic shadowing were imaged as an echogenic mass or an echogenic mass consisting of many fine echo spots disseminated throughout the whole mass. For posterior echo enhancement, when lateral shadowing is present, the cyst and posterior echo enhancement are imaged as a round anechoic mass or a triple circle consisting of a thin anechoic outer rim, an echogenic ring, and an anechoic center. However, when lateral shadowing is absent, they are imaged as a round anechoic mass or a double circle consisting of an echogenic outer rim and an anechoic center. For clean reverberation artifacts and dirty reverberation artifacts, vertical images of clean reverberation artifacts consist of either a homogeneous echogenic area or an absent signal. However, vertical images of dirty reverberation artifacts consist of a homogeneous echogenic area and an area consisting of fine echo spots. CONCLUSION: Our study suggests that reconstructed, previously unattainable, vertical plane images help us better understand the mode of posterior echoes.
PURPOSE: To evaluate the role of vertical images reconstructed using 3-D data in the analysis of posterior echoes. METHODS: Reconstructed vertical images of US phantoms with the following artifacts were retrieved and analyzed: acoustic shadowing (clean and dirty); posterior echo enhancement (with/without lateral shadowing); and reverberation artifacts (clean and dirty). RESULTS: For acoustic shadowing, a stone and posterior clean acoustic shadowing were imaged as an echogenic mass or an echogenic ring containing a central echo-free area. However, the stone and dirty acoustic shadowing were imaged as an echogenic mass or an echogenic mass consisting of many fine echo spots disseminated throughout the whole mass. For posterior echo enhancement, when lateral shadowing is present, the cyst and posterior echo enhancement are imaged as a round anechoic mass or a triple circle consisting of a thin anechoic outer rim, an echogenic ring, and an anechoic center. However, when lateral shadowing is absent, they are imaged as a round anechoic mass or a double circle consisting of an echogenic outer rim and an anechoic center. For clean reverberation artifacts and dirty reverberation artifacts, vertical images of clean reverberation artifacts consist of either a homogeneous echogenic area or an absent signal. However, vertical images of dirty reverberation artifacts consist of a homogeneous echogenic area and an area consisting of fine echo spots. CONCLUSION: Our study suggests that reconstructed, previously unattainable, vertical plane images help us better understand the mode of posterior echoes.