材料科学
荧光
脚手架
小分子
合理设计
纳米技术
荧光寿命成像显微镜
平面度测试
光热治疗
分子内力
分子工程
共轭体系
四苯乙烯
量子产额
摩尔吸收率
纳米纤维
分子
分子成像
树枝状大分子
生命科学中的荧光
单分子实验
产量(工程)
生物成像
芯(光纤)
光热效应
作者
Pengfei Chen,Qingxin Zeng,Bokai Liu,Kai Chen,Zikun Yu,Yansu Lan,Changjiang Li,Pengfei Sun,Zhiyao Li,Chongzhi Wu,Bowen Li,Quli Fan
标识
DOI:10.1002/adfm.202529470
摘要
ABSTRACT Small‐molecule fluorophore‐based phototheranostics hold great promise, particularly those emitting in the second near‐infrared window IIb (NIR‐IIb, 1500–1700 nm). However, the rational design of such molecules remains a formidable challenge. Here, we propose a molecular spatial scaffolding strategy to precisely modulate donor‐acceptor‐donor (D–A–D)‐type fluorophores, resulting in the development of an optimized phototheranostic agent, termed TPCTP NPs. The introduction of rationally designed spatial scaffolding units preserves the planarity of the conjugated molecular core while suppressing undesired π‐π stacking. This structural optimization conferred a high molar extinction coefficient (1.2 × 10 4 M − 1 cm − 1 ), an enhanced fluorescence quantum yield (0.18%), and good NIR‐IIb fluorescence imaging (FLI) performance. Moreover, the aromatic scaffold unit promote intramolecular motion, thereby improving the photothermal conversion efficiency (PCE = 45.6%) and enabling effective tumor ablation. Collectively, these attributes render TPCTP NPs a promising platform for NIR‐IIb FLI/photothermal imaging (PTI)‐guided photothermal therapy.
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