用于黑色素瘤低毒性和协同化学光动力疗法的混合同源原药纳米组件

IF 8.1 Q1 ENGINEERING, BIOMEDICAL Biomaterials research Pub Date : 2024-11-01 eCollection Date: 2024-01-01 DOI:10.34133/bmr.0101
Peirong Xu, Fanchao Meng, Jianqin Wan, Hengyan Zhu, Shijiang Fang, Hangxiang Wang
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引用次数: 0

摘要

具有协同活性的纳米粒子在促进多模式癌症治疗方面大有可为。然而,目前仍缺乏可行的制造和优化配方的策略。在此,我们利用小分子的超分子纳米组装技术,开发了具有肿瘤限制性药物激活和化学光动力药理作用的混合同二聚体原药纳米疗法。通过活性氧(ROS)激活的连接体将细胞毒性类固醇化疗药物共价二聚化,产生了一种同二聚体原药,并进一步与产生 ROS 的二聚体光敏剂共同组装。纳米组合体很容易在两亲性聚乙二醇化基质中精制,用于颗粒表面隐形和体内静脉注射。经过优化的纳米组合物具有良好的稳定性和组合协同作用,能够杀死癌细胞。在近红外激光照射下,邻近的二聚体光敏剂产生 ROS,随后引发键裂解,促进药物活化,进而产生抗癌的化学光动力协同效应。在黑色素瘤的临床前模型中,静脉注射 PEG 化纳米组合物,然后进行近红外肿瘤照射,可显著消退肿瘤。此外,使用这种高效、可光激活的纳米疗法治疗的动物即使在高剂量下也表现出较低的全身毒性。本研究介绍了一种简单而经济有效的方法,通过自组装小分子原药来设计组合治疗纳米系统,从而整合多模式疗法。我们认为,这一新范例具有推动临床转化的巨大潜力。
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Hybrid Homodimeric Prodrug Nanoassemblies for Low-Toxicity and Synergistic Chemophotodynamic Therapy of Melanoma.

Synergistically active nanoparticles hold great promise for facilitating multimodal cancer therapy. However, strategies for their feasible manufacture and optimizing their formulations remain lacking. Herein, we developed hybrid homodimeric prodrug nanotherapeutics with tumor-restricted drug activation and chemophotodynamic pharmacology by leveraging the supramolecular nanoassembly of small molecules. The covalent dimerization of cytotoxic taxane chemotherapy via reactive oxygen species (ROS)-activated linker yielded a homodimeric prodrug, which was further coassembled with a ROS-generating dimeric photosensitizer. The nanoassemblies were readily refined in an amphiphilic PEGylation matrix for particle surface cloaking and in vivo intravenous injection. The nanoassemblies were optimized with favorable stability and combinatorial synergism to kill cancer cells. Upon near-infrared laser irradiation, the neighboring dimer photosensitizer generated ROS, subsequently triggering bond cleavage to facilitate drug activation, which in turn produced synergistic chemophotodynamic effects against cancer. In a preclinical model of melanoma, the intravenous administration of PEGylated nanoassemblies followed by near-infrared tumor irradiation led to significant tumor regression. Furthermore, animals treated with this efficient, photo-activatable nanotherapy exhibited low systemic toxicity even at high doses. This study describes a simple and cost-effective approach to integrate multimodal therapies by creating self-assembling small-molecule prodrugs for designing a combinatorial therapeutic nanosystem. We consider that this new paradigm holds substantial potential for advancing clinical translation.

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