Optical Verification of Microbubble Response to Acoustic Radiation Force in Large Vessels With In Vivo Results

Overview

Journal Invest Radiol

Specialty Radiology

Date 2015 Jul 3

PMID 26135018

Citations 16

Authors

Shiying Wang

Claudia Y Wang

Sunil Unnikrishnan

Alexander L Klibanov

John A Hossack

F William Mauldin Jr

Affiliations

Soon will be listed here.

Abstract

Objective: The objective of this study was to optically verify the dynamic behaviors of adherent microbubbles in large blood vessel environments in response to a new ultrasound technique using modulated acoustic radiation force.

Materials And Methods: Polydimethylsiloxane (PDMS) flow channels coated with streptavidin were used in targeted groups to mimic large blood vessels. The custom-modulated acoustic radiation force beam sequence was programmed on a Verasonics research scanner. In vitro experiments were performed by injecting a biotinylated lipid-perfluorobutane microbubble dispersion through flow channels. The dynamic response of adherent microbubbles was detected acoustically and simultaneously visualized using a video camera connected to a microscope. In vivo verification was performed in a large abdominal blood vessel of a murine model for inflammation with injection of biotinylated microbubbles conjugated with P-selectin antibody.

Results: Aggregates of adherent microbubbles were observed optically under the influence of acoustic radiation force. Large microbubble aggregates were observed solely in control groups without targeted adhesion. Additionally, the dispersion of microbubble aggregates were demonstrated to lead to a transient acoustic signal enhancement in control groups (a new phenomenon we refer to as "control peak"). In agreement with in vitro results, the control peak phenomenon was observed in vivo in a murine model.

Conclusions: This study provides the first optical observation of microbubble-binding dynamics in large blood vessel environments with application of a modulated acoustic radiation force beam sequence. With targeted adhesion, secondary radiation forces were unable to produce large aggregates of adherent microbubbles. Additionally, the new phenomenon called control peak was observed both in vitro and in vivo in a murine model for the first time. The findings in this study provide us with a better understanding of microbubble behaviors in large blood vessel environments with application of acoustic radiation force and could potentially guide future beam sequence designs or signal processing routines for enhanced ultrasound molecular imaging.

Citing Articles

In Vivo Validation of Modulated Acoustic Radiation Force-Based Imaging in Murine Model of Abdominal Aortic Aneurysm Using VEGFR-2-Targeted Microbubbles.

Huang Y, Herbst E, Xie Y, Yin L, Islam Z, Kent E Invest Radiol. 2023; 58(12):865-873.

PMID: 37433074 PMC: 10784413. DOI: 10.1097/RLI.0000000000001000.

Targeted Microbubbles for Drug, Gene, and Cell Delivery in Therapy and Immunotherapy.

Navarro-Becerra J, Borden M Pharmaceutics. 2023; 15(6).

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Exosomes and ultrasound: The future of theranostic applications.

Sridharan B, Lim H Mater Today Bio. 2023; 19:100556.

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Cavitation Characterization of Size-Isolated Microbubbles in a Vessel Phantom Using Focused Ultrasound.

Martinez P, Bottenus N, Borden M Pharmaceutics. 2022; 14(9).

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Molecular Ultrasound Imaging.

Kose G, Darguzyte M, Kiessling F Nanomaterials (Basel). 2020; 10(10).

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