化学
前药
免疫疗法
连接器
合理设计
电泳剂
激进的
癌症研究
兴奋剂
药理学
小分子
药品
TLR7型
药物发现
计算生物学
密度泛函理论
药物设计
生物活性
组合化学
作者
Wenhao Tan,Linrong Chen,Tianyu Zhang,Qianqian Mu,Muhetaerjiang Mamuti,Haoqi Wu,Siqi Li,Jing Ma,XiQun JIANG,Xu Zhen
摘要
Precise spatiotemporal control over drug activation is essential to mitigate the systemic toxicity of potent immunotherapeutics. While ultrasound offers a safe modality with intrinsic deep tissue penetration, the scarcity of high-sensitivity chemical triggers has severely hindered the development of direct ultrasound-activated prodrugs. Herein, we report the rational design of a library of ultrasound-activated prodrugs based on benzyloxycarbonyl scaffolds. By systematically modulating the electronic properties of the aromatic ring, we established a structure-activity relationship governing the responsiveness to sonolytically generated hydroxyl radicals (·OH). Among the screened candidates, the 3,5-bis(methylamino)-substituted linker (BMBC) was identified as an optimal trigger, enabling efficient and instantaneous drug activation. Density functional theory (DFT) calculations reveal that BMBC's superior performance stems from a unique synergy: a high-lying HOMO energy level indicative of enhanced electron-donating character and high susceptibility toward electrophilic radical attack, and a minimized activation barrier for the rate-determining self-immolation step. This platform demonstrates broad universality, efficiently caging amines, hydroxyls, and carboxyls. As a proof of concept, a BMBC-caged TLR7 agonist elicited robust antitumor immunity and durable immunological memory in a murine model. Notably, the prodrug exhibited a significantly widened therapeutic window, remaining safe even at a 10-fold therapeutic dose. This work provides a versatile chemical toolkit for safe and spatiotemporally controlled drug activation.
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