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Molecular Crystal Engineering of Organic Chromophores for NIR-II Fluorescence Quantification of Cerebrovascular Function

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posted on 2022-02-14, 15:07 authored by Yuanyuan Li, Xiaoxiao Fan, Yirun Li, Shunjie Liu, Clarence Chuah, Youhong Tang, Ryan T. K. Kwok, Jacky W. Y. Lam, Xuefeng Lu, Jun Qian, Ben Zhong Tang
Although molecular design strategies for highly bright near-infrared II (NIR-II) fluorophores were proposed, the lack of solid structural identification (single crystal) hinders the further development of this field. This thorny issue is addressed by performing the structure–function relationship of NIR-II dyes, as confirmed by molecular single crystal engineering. Single crystal structure analysis confirms that twisted architectures (large dihedral angles ∼70°) and loose packing patterns (intermolecular distance of ∼3.4–4.5 Å) are key elements to enhance the absolute quantum yield (QY) in the solid state. Through regulating donor–acceptor distance and donor–acceptor interactions, the resultant well-defined TBP-b-DFA fluorophore displays an absolute QY of 0.4% with an emission extending to 1400 nm, which is favorable for NIR-II bioimaging. The cerebrovascular function, including cerebral blood flow and cerebrovascular reactivity of different conditions, is accurately quantified by a NIR-II fluorescence wide-field microscope. Our study provides a sight for designing NIR-II fluorophores, which is useful for studying cerebrovascular function.

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