Giga-Hertz ultrasonic microscopy: Getting over the obscurity- A short review on the biomedical applications

Q3 Medicine

Physics in Medicine Pub Date : 2020-06-01 DOI:10.1016/j.phmed.2020.100025

Esam T. Ahmed Mohamed, Nico F. Declercq

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引用次数: 4

Abstract

Scanning acoustic microscopy in the gigahertz regime (GHz-SAM) has long been a versatile and complementary micro and nanoscopic imaging and analysis tool. Nevertheless, it remained obscured to some extent, compared to its counterparts, such as atomic force microscopy (AFM), despite its unique capability of subsurface analysis. Some current research in our lab at Georgia Tech Lorraine is devoted to the use of the subsurface imaging of GHz-SAM in biological tissues, which has been restricted, mostly, to very stiff materials, in terms of acousto-mechanical impedance, such as metals.

The feasibility, degrees of complexity, the different techniques, and future fates of (GHz-SAM) are discussed with particular focus on those most used in the biological applications, such as the combined phase and magnitude contrasts acoustic microscopy.

This paper gives a general overview of SAM, the peculiarities of GHz-SAM with emphasis on the restrictions that led to the semi-obscurity of GHz-SAM so far, and reveals some recent research developments in this field in our laboratory.

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千兆赫超声显微镜:克服模糊-生物医学应用的简短回顾

千兆赫波段扫描声学显微镜(GHz-SAM)长期以来一直是一种多功能和互补的微纳米成像和分析工具。然而，尽管它具有独特的地下分析能力，但与原子力显微镜(AFM)等同类技术相比，它在某种程度上仍然模糊不清。我们在乔治亚理工学院洛林分校的实验室目前的一些研究致力于在生物组织中使用GHz-SAM的地下成像，这主要局限于非常坚硬的材料，就声机械阻抗而言，比如金属。讨论了(GHz-SAM)的可行性、复杂程度、不同的技术和未来的命运，并特别关注了那些在生物应用中最常用的技术，如相和幅度对比声学显微镜。本文对地对空信号进行了概述，重点介绍了ghz地对空信号的特点，并着重介绍了导致ghz地对空信号半模糊的限制因素，揭示了本实验室在该领域的一些最新研究进展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Physics in Medicine Physics and Astronomy-Instrumentation

CiteScore

2.60

自引率

0.00%

发文量

审稿时长

12 weeks

期刊介绍： The scope of Physics in Medicine consists of the application of theoretical and practical physics to medicine, physiology and biology. Topics covered are: Physics of Imaging Ultrasonic imaging, Optical imaging, X-ray imaging, Fluorescence Physics of Electromagnetics Neural Engineering, Signal analysis in Medicine, Electromagnetics and the nerve system, Quantum Electronics Physics of Therapy Ultrasonic therapy, Vibrational medicine, Laser Physics Physics of Materials and Mechanics Physics of impact and injuries, Physics of proteins, Metamaterials, Nanoscience and Nanotechnology, Biomedical Materials, Physics of vascular and cerebrovascular diseases, Micromechanics and Micro engineering, Microfluidics in medicine, Mechanics of the human body, Rotary molecular motors, Biological physics, Physics of bio fabrication and regenerative medicine Physics of Instrumentation Engineering of instruments, Physical effects of the application of instruments, Measurement Science and Technology, Physics of micro-labs and bioanalytical sensor devices, Optical instrumentation, Ultrasound instruments Physics of Hearing and Seeing Acoustics and hearing, Physics of hearing aids, Optics and vision, Physics of vision aids Physics of Space Medicine Space physiology, Space medicine related Physics.