Pulsed ultrasound enhances nanoparticle penetration into breast cancer spheroids.

Effective treatment of solid tumors requires homogeneous distribution of anticancer drugs within the entire tumor volume to deliver lethal concentrations to resistant cancer cells and tumor-initiating cancer stem cells. However, penetration of small molecular weight chemotherapeutic agents and drug-loaded polymeric and lipid particles into the hypoxic and necrotic regions of solid tumors remains a significant challenge. This article reports the results of pulsed ultrasound enhanced penetration of nanosized fluorescent particles into MCF-7 breast cancer spheroids (300-350 μm diameter) as a function of particle size and charge. With pulsed ultrasound application in the presence of microbubbles, small (20 nm) particles achieve 6-20-fold higher penetration and concentration in the spheroid's core compared to those not exposed to ultrasound. Increase in particle size to 40 and 100 nm results in their effective penetration into the spheroid's core to 9- and 3-fold, respectively. In addition, anionic carboxylate particles achieved higher penetration (2.3-, 3.7-, and 4.7-fold) into the core of MCF-7 breast cancer spheroids compared to neutral (2.2-, 1.9-, and 2.4-fold) and cationic particles (1.5-, 1.4-, and 1.9-fold) upon US exposure for 30, 60, and 90 s under the same experimental conditions. These results demonstrate the feasibility of utilizing pulsed ultrasound to increase the penetration of nanosized particles into MCF-7 spheroids mimicking tumor tissue. The effects of particle properties on the penetration enhancement were also illustrated.