Multiplex ultrasound imaging of perfluorocarbon nanodroplets enabled by decomposition of post-vaporization dynamics

TL;DR

This paper introduces a novel multiplex ultrasound imaging method using perfluorocarbon nanodroplets with different boiling points, enabling simultaneous visualization of multiple molecular targets through their unique dynamic responses.

Contribution

The study demonstrates a new multiplex ultrasound imaging technique utilizing phase-transition nanodroplets with distinct boiling points to differentiate multiple contrast agents.

Findings

Accurately measured relative concentrations of two nanodroplet populations within 1.1% error

Characterized dynamic responses of nanodroplets with boiling points of 28 and 56°C

Showed potential for simultaneous imaging of multiple molecular targets

Abstract

Among the various molecular imaging modalities, ultrasound imaging benefits from its real-time, nonionizing, and cost-effective nature. Despite its benefits, there is a dearth of methods to visualize two or more populations of contrast agents simultaneously, a technique known as multiplex imaging. In this paper, we present a new approach to multiplex ultrasound imaging using perfluorocarbon (PFC) nanodroplets. The nanodroplets, which undergo a liquid-to-gas phase transition in response to an acoustic trigger, act as activatable contrast agents. By using two populations of PFC nanodroplets, each with a different core boiling point, their unique temporal responses to an acoustic trigger were leveraged to differentiate their unique contributions to the overall ultrasound signal. This work characterized the dynamic responses of two PFC nanodroplets with boiling points of 28 and 56 {\deg}C. These characteristic responses were then used to demonstrate that the relative concentrations of the two populations of PFC nanodroplets could be accurately measured in the same imaging volume within an average error of 1.1%. Overall, the findings indicate the potential of this approach for multiplex ultrasound imaging, allowing for the visualization of multiple molecular targets simultaneously.