A tissue-mimicking phantom with flexible optical properties for studying photoacoustic response of nanoparticles

Abstract

Photoacoustic imaging (PAI) is a rapidly growing imaging modality, which combines high contrast of optical absorption with deep penetration depth of ultrasound. When combined with endogenous contrast agents based on light-absorbing nanoparticles (NPs), PAI can visualize various biological processes and tissues. Here, we describe a simple experimental setup based on a tissue-mimicking phantom with flexible optical properties for studying photoacoustic (PA) response of NPs. Our approach is based on a polyacrylamide gel phantom with independently variable optical absorption and scattering. The phantom allows one to model and study PA response of contrast agents with diverse spatial distributions and concentrations. To demonstrate high potential of the developed experimental setup, we prepared a phantom with optical properties matching human prostate tissue and performed a PAI of laser-synthesized titanium nitride (TiN) NPs, distributed in a disk-shaped area, located 10 mm under the phantom surface. We believe that our approach will contribute the successful development of clinical PAI with NPs-based contrast agents.