荧光
材料科学
荧光寿命成像显微镜
生物医学中的光声成像
分子
光化学
纳米技术
化学
光学
有机化学
物理
作者
Yaxi Li,Hongli Zhou,Renzhe Bi,Xiuting Li,Menglei Zha,Yanqing Yang,Jen‐Shyang Ni,Weng Heng Liew,Malini Olivo,Kui Yao,Jie Liu,Hao Chen,Kai Li
摘要
]benzotriazole (TBZ) core to replace BBTD as the electron acceptor. Thanks to the weaker electron deficiency of the TBZ core than BBTD, the newly yielded NIR-II molecule (BTB) based nanoparticles have a higher mass extinction coefficient and quantum yield in water. In contrast, the nanoparticle suspension of its counterpart with BBTD as the core is nearly nonemissive. The NIR-II BTB nanoparticles allow video-rate fluorescence imaging for vasculature imaging in ears, hindlimbs, and the brain of the mouse. Additionally, its large absorptivity in the NIR-I region also promotes bioimaging using photoacoustic microscopy (PAM) and tomography (PAT). Upon surface conjugation with the Arg-Gly-Asp (RGD) peptide, the functionalized nanoparticles ensured targeted detection of integrin-overexpressed tumors through both imaging modalities in two- and three-dimensional views. Thus, our approach to engineering acceptors of organic fluorophores offers a promising molecular design strategy to afford new NIR-II fluorophores for versatile biomedical imaging applications.
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