Ultrasound-responsive liposomes: A mechanistic framework to decode the effects of acoustic parameters

计算机科学 传感器 声学 治疗性超声 占空比 翻译(生物学) 声压 声共振 脉搏(音乐) 超声波 声辐射 空化 材料科学 聚焦超声 声传感器 生物系统 系统动力学 缩小 共振(粒子物理) 超声波传感器 物理 振动 动力学(音乐) 声波
作者
Ignasi Simon,Rebecca F. A. van den Elshout,Gandhika K. Wardhana,Masoumeh Aqamolaei,Isabella S. T. de Jonge,Remco Hartkamp,Riccardo Alessandri,Tiago L. Costa,Alina Y. Rwei
出处
期刊:Proceedings of the National Academy of Sciences of the United States of America [National Academy of Sciences]
卷期号:123 (13): e2535429123-e2535429123
标识
DOI:10.1073/pnas.2535429123
摘要

Ultrasound offers a noninvasive, clinically relevant means to achieve precise spatiotemporal control of cargo release from ultrasound-responsive drug delivery systems within deep tissues. This approach enables targeted delivery of therapeutic agents, enhancing efficacy while minimizing systemic toxicity. While previous studies show that release from ultrasound-responsive liposomes depends on acoustic parameters, the underlying mechanisms remain unclear. A deeper mechanistic understanding is essential to achieve precision over release and maximize therapeutic outcomes. To address this, we propose a sonoporation-based framework to describe release dynamics across varying frequencies, pressures, duty cycles, and pulse repetition frequencies for ultrasound-responsive poly(ethylene glycol)-functionalized liposomes. Using computational simulations validated by empirical results, our framework identifies a critical pressure threshold for release onset and demonstrates how the time spent above this threshold, modulated by acoustic parameters, governs release efficiency. To elucidate these effects, custom-built ultrasound transducers with different resonance frequencies were fabricated and characterized to ensure precise sample alignment, minimize acoustic distortion, and maintain a controlled focal-volume-to-sample-volume ratio across different frequencies. COMSOL simulations indicated that oscillatory acoustic pressure plays a more dominant role than acoustic radiation force, while coarse-grained molecular dynamics simulations captured pressure-dependent pore formation dynamics within the lipid bilayer. Together, our experiments and simulations highlight mechanical effects-particularly oscillatory acoustic pressure-as the primary driver of sonoporation-facilitated release. Finally, we discuss how optimizing acoustic parameters through this mechanistic framework could facilitate safe and effective clinical translation by considering tissue safety and ultrasound transducer design.
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