Ultrasound-mediated drug delivery is typically performed using transducers with center frequencies 1 MHz to promote acoustic cavitation. Such frequencies are not commonly used for diagnostic ultrasound due to limited spatial resolution. Therefore, delivery and monitoring of therapeutic ultrasound typically requires two transducers to enable both treatment and imaging. This study investigates the feasibility of using a single commercial ultrasound imaging transducer operating at 5 MHz for both drug delivery and real-time imaging. We compared a single-transducer system (STS) at 5 MHz with a conventional dual-transducer system (DTS) using a 1.1 MHz therapeutic transducer and an imaging probe. in vitro experiments demonstrated that the STS could achieve comparable extravasation depth and area as the DTS, with higher drug deposition observed at 5 MHz. Additionally, extravasation patterns were influenced by peak negative pressure (PNP) and duty cycle, with the narrower beam width at 5 MHz offering potential advantages for targeted drug delivery. in vivo experiments in a murine bladder cancer model confirmed the efficacy of the STS for real-time imaging and drug delivery, with cavitation dose correlating with drug deposition. The results suggest that a single-transducer approach may enhance the precision and efficiency of ultrasound-mediated drug delivery, potentially reducing system complexity and cost.
Keywords: cavitation; image-guided therapy; microbubbles; theranostic; ultrasound-mediated drug delivery.