材料科学
星团(航天器)
荧光
纳米颗粒
Atom(片上系统)
显微镜
原子探针
散射
穿透深度
兴奋剂
光子
纳米技术
直接成像
分子物理学
荧光显微镜
原子力显微镜
光学
光电子学
光子能量
可视化
激光器
荧光寿命成像显微镜
作者
Zhenhua Li,Zili Zhang,Siyu Ao,Guo Li,Shasha Li,Di Ma,Jiayan Zang,Haoyue Yan,Fangzhen Tian,Zhenda Chen,Kefeng Jia,Qi Xin,Pengfei Liu,Hao Wang,Changlong Liu,Huizhen Ma,Xiao‐Dong Zhang
标识
DOI:10.1002/adhm.202504082
摘要
ABSTRACT Conventional fluorescence imaging in the visible and first near‐infrared (NIR‐I, 700–900 nm) windows is limited by tissue scattering and autofluorescence. The second near‐infrared (NIR‐II, 1000–3000 nm) window offers deeper penetration depth and higher signal‐to‐noise ratio due to reduced photon scattering. Among the high‐performance probes, atomically precise gold clusters emerge as a promising class of materials, as their defined structure can be engineered for enhanced NIR‐II emission. Here, we report controllable Au 18 clusters for NIR‐II bioimaging, which exhibit superior brightness, stability, and biocompatibility. We successfully dope a single Zn atom into the Au 18 cluster structure, thereby optimizing optical properties and improving photostability. Zn atom doping shifts the energy levels downward by approximately 1.2 eV and induces local charge redistribution, resulting in enhanced photoluminescence. The Au 17 Zn 1 clusters exhibit a 4.1‐fold NIR‐II fluorescence enhancement and high temporal stability with excellent biological safety. Furthermore, Au 17 Zn 1 shows potential for visualizing liver tissue in mice with hepatic ischemia‐reperfusion injury (HIRI). In addition, three‐dimensional (3D) imaging of HIRI mice using light‐sheet microscopy (LSM) reveals vascular dilation from approximately 120 to 300 µm, clearly delineating the different stages of HIRI. Therefore, Au 17 Zn 1 shows potential as a tool for HIRI assessment.
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