化学
毒性
细胞毒性
生物利用度
药理学
PLGA公司
细胞凋亡
乳腺癌
化疗
阿霉素
癌症研究
癌细胞
癌症
体内
体外
治疗指标
铱
药代动力学
活性氧
纳米医学
生长抑制
细胞生长
心脏毒性
作用机理
生物活性
线粒体
细胞培养
作者
Shunfang Liu,Wenhao Wu,Linrong Fang,Zhiqi Rao,Jiyong Peng,Xiaodan Wang,Chuqin Yu,J.-K. Wang
标识
DOI:10.1021/acs.jmedchem.5c02025
摘要
Conventional chemotherapy faces systemic toxicity and suboptimal efficacy, necessitating innovative strategies. Herein, three iridium(III) complexes (PIQ, PPY, and BZQ) were synthesized, and PPY exhibited remarkable cytotoxicity against breast cancer cells (IC50 = 2.08 μM) by coinducing apoptosis/ferroptosis. Mechanistically, this dual effect is mediated via ROS overproduction, mitochondrial dysfunction, PI3K/AKT/mTOR signaling pathway inhibition, and GPX4 suppression, which collectively augment lipid peroxidation. Encapsulating PPY into biodegradable PLGA nanoparticles (PPY-NPs) enhanced tumor-specific delivery, achieving 78% tumor growth inhibition in mice with attenuated systemic toxicity. Pharmacokinetic studies revealed that PPY-NPs had reduced AUC, comparable to MRT, accelerated Cl, and increased Vd compared to free PPY, consistent with MPS-mediated clearance. Collectively, this approach harnesses the multitarget activity of iridium coupled with nanocarrier-enabled spatiotemporal control, overcoming bioavailability limitations and amplifying tumor-specific oxidative stress. By simultaneously activating apoptosis and ferroptosis, PPY-NPs overcome the limitations of conventional agents’ single-pathway therapeutic approaches, offering an expanded mechanistic therapeutic paradigm.
科研通智能强力驱动
Strongly Powered by AbleSci AI