High yield, shell-stabilized, narrow-sized C3F8 nanobubbles with different shell properties and precisely controllable response to acoustic excitations: experimental observations and numerical simulations

TL;DR

This study develops high-yield, shell-stabilized C3F8 nanobubbles with controllable shell properties, demonstrating how shell stiffness influences their acoustic response and pressure thresholds, with implications for ultrasound imaging and therapy.

Contribution

First production of high-yield, narrow-sized nanobubbles with tunable shell properties, linking shell mechanics to acoustic response through experiments and simulations.

Findings

Shell stiffness affects pressure threshold for acoustic amplification.

Membrane additives alter shell viscoelasticity and structure.

Numerical simulations confirm experimental dependence of acoustic response on shell properties.

Abstract

Understanding the pressure dependence of the nonlinear behavior of ultrasonically excited phospholipid (PL)-stabilized NBs is important for optimizing US exposure parameters for implementations of contrast enhanced ultrasound, critical to molecular imaging. The viscoelastic properties of the shell can be controlled by introduction of membrane additives, such as propylene glycol as a membrane softener or glycerol as a membrane stiffener. We report for the first time, the production of high yield NBs with narrow dispersity and different shell properties. Through precise control over size and shell structure, we show how these shell components interact with the phospholipid membrane, change its structure, affect their viscoelastic properties, and consequently change their acoustic response. A two-photon microscopy technique through a polarity-sensitive fluorescent dye, C-laurdan, was utilized to gain insights on the effect of membrane additives to the membrane structure. We report how the shell stiffness of NBs affects the pressure threshold (Pt) for the sudden amplification in the scattered acoustic signal from NBs. For narrow size NBs with 200 nm mean size, we find Pt to be between 123-245 kPa for the NBs with the most flexible membrane as assessed using C-Laurdan, 465-588 kPa for the NBs with intermediate stiffness and 588-710 kPa for the NBs with stiff membranes. Numerical simulations of the NB dynamics are in good agreement with the experimental observations confirming the dependence of acoustic response to shell properties, thereby substantiating further the development in engineering the shell of UCAs. The viscoelastic dependent threshold behavior can be utilized for significantly and selectively enhancing the diagnostic and therapeutic ultrasound applications of potent narrow size NBs.