Collapse pressure measurement of single hollow glass microsphere using single-beam acoustic tweezer

• Published in: Ultrasonics sonochemistry Vol. 82; p. 105844
• Main Authors: Yoo, Jinhee, Kim, Hyunhee, Kim, Yeonggeun, Lim, Hae Gyun, Kim, Hyung Ham
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 01.01.2022; Elsevier
• Subjects: Acoustic pressure measurement; Collapse pressure; High-frequency ultrasound; Short Communication; Single hollow glass microsphere; Single-beam acoustic tweezer; Single hollow glass microsphere; Single-beam acoustic tweezer; Acoustic pressure measurement; High-frequency ultrasound; Collapse pressure
• ISSN: 1350-4177; 1873-2828; 1873-2828
• DOI: 10.1016/j.ultsonch.2021.105844

[Display omitted] •Single-microsphere collapse pressure was obtained using focused ultrasound.•Use of single-beam acoustic tweezer eliminates the influence of additional factors.•The relationship between collapse pressure and microsphere size was determined.•A method for estimating high-frequency acoustic pressure was developed. Microbubbles are widely used in medical ultrasound imaging and drug delivery. Many studies have attempted to quantify the collapse pressure of microbubbles using methods that vary depending on the type and population of bubbles and the frequency band of the ultrasound. However, accurate measurement of collapse pressure is difficult as a result of non-acoustic pressure factors generated by physical and chemical reactions such as dissolution, cavitation, and interaction between bubbles. In this study, we developed a method for accurately measuring collapse pressure using only ultrasound pulse acoustic pressure. Under the proposed method, the collapse pressure of a single hollow glass microsphere (HGM) is measured using a high-frequency (20–40 MHz) single-beam acoustic tweezer (SBAT), thereby eliminating the influence of additional factors. Based on these measurements, the collapse pressure is derived as a function of the HGM size using the microspheres’ true density. We also developed a method for estimating high-frequency acoustic pressure, whose measurement using current hydrophone equipment is complicated by limitations in the size of the active aperture. By recording the transmit voltage at the moment of collapse and referencing it against the corresponding pressure, it is possible to estimate the acoustic pressure at the given transmit condition. These results of this study suggest a method for quantifying high-frequency acoustic pressure, provide a potential reference for the characterization of bubble collapse pressure, and demonstrate the potential use of acoustic tweezers as a tool for measuring the elastic properties of particles/cells.