Numerical analysis of ultrasound propagation and reflection intensity for biological acoustic impedance microscope

Numerical analysis of ultrasound propagation and reflection intensity for biological acoustic impedance microscope

•Acoustic impedance microscope for biological tissue was proposed.•Calibration curve was obtained from acoustic field analysis.•The calibration curve was verified experimentally by using saline solution.•The result did not change even if the reference material changed significantly.•Cerebellar tissu...

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Bibliographic Details
Published in:Ultrasonics Vol. 61; pp. 79 - 87
Main Authors: Gunawan, Agus Indra, Hozumi, Naohiro, Yoshida, Sachiko, Saijo, Yoshifumi, Kobayashi, Kazuto, Yamamoto, Seiji
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 01-08-2015
Subjects:
Acoustic impedance
Acoustic Impedance Tests
Animals
Calibration
Cerebellum - diagnostic imaging
Equipment Design
k-space
Microscopy, Acoustic
Plane wave
Rats
Tissue
Ultrasound
Plane wave
Tissue
k-space
Ultrasound
Acoustic impedance
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Summary:•Acoustic impedance microscope for biological tissue was proposed.•Calibration curve was obtained from acoustic field analysis.•The calibration curve was verified experimentally by using saline solution.•The result did not change even if the reference material changed significantly.•Cerebellar tissue of a rat was successfully observed into acoustic impedance profile. This paper proposes a new method for microscopic acoustic imaging that utilizes the cross sectional acoustic impedance of biological soft tissues. In the system, a focused acoustic beam with a wide band frequency of 30–100MHz is transmitted across a plastic substrate on the rear side of which a soft tissue object is placed. By scanning the focal point along the surface, a 2-D reflection intensity profile is obtained. In the paper, interpretation of the signal intensity into a characteristic acoustic impedance is discussed. Because the acoustic beam is strongly focused, interpretation assuming vertical incidence may lead to significant error. To determine an accurate calibration curve, a numerical sound field analysis was performed. In these calculations, the reflection intensity from a target with an assumed acoustic impedance was compared with that from water, which was used as a reference material. The calibration curve was determined by changing the assumed acoustic impedance of the target material. The calibration curve was verified experimentally using saline solution, of which the acoustic impedance was known, as the target material. Finally, the cerebellar tissue of a rat was observed to create an acoustic impedance micro profile. In the paper, details of the numerical analysis and verification of the observation results will be described.
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content type line 23
ISSN:0041-624X
1874-9968
DOI:10.1016/j.ultras.2015.03.010