Litcius/Paper detail

Extending the Stokes Shifts of Donor–Acceptor Fluorophores by Regulating the Donor Configuration for <i>In Vivo</i> Three-Photon Fluorescence Imaging

Sifan Li, Mubin He, Xin Jin, Weihang Geng, Chenglin Li, Xinsheng Li, Zhiyun Zhang, Jun Qian, Jianli Hua

2022Chemistry of Materials39 citationsDOI

Abstract

Simple donor–acceptor (D–A) molecules with large Stokes-shifted and bright near-infrared (NIR) emissions are extremely attractive for the high-resolution three-photon fluorescence (3PF) imaging of deep tissues. Herein, we present a new strategy for significantly extending the Stokes shifts of D–A fluorophores, relying on increasing the excited-state structural/electronic relaxation of the donor moiety. The prototype of the D–A structure DPCN, containing the planar donor N,N′-diphenyl-dihydrophenazine (DHP) and the acceptor malononitrile, exhibits normal Stokes-shifted (∼60 nm) NIR emission. By introducing two methyl groups at the ortho sites of the fused DHP ring of DPCN, DMPCN (methyl-decorated DPCN) is developed with an obviously bent donor unit. Compared to DPCN, DMPCN exhibits significantly blue-shifted absorption and keeps NIR luminescence with a large Stokes shift of ∼200 nm, mainly due to the remarkable bent-to-planar transformation of the donor upon photoexcitation. Additionally, the DMPCN NPs offer enhanced luminescence quantum yields (11%) and three-photon excitation cross sections. More importantly, DMPCN NPs exhibit excellent performances for in vivo 3PF imaging of the cerebrovascular tissue and lipid droplets (LDs) in a fatty liver with a depth of 1200 and 50 μm, respectively. This research provides a distinct strategy for extending the Stokes shifts of D–A fluorophores, inspiring the utilization of dynamic NIR fluorophores for in vivo 3PF imaging.

Topics & Concepts

Stokes shiftFluorescenceLuminescenceFluorophorePhotochemistryAcceptorFluorescence-lifetime imaging microscopyChemistryExcited stateMaterials scienceQuantum yieldPreclinical imagingIn vivoOptoelectronicsOpticsAtomic physicsPhysicsBiologyCondensed matter physicsBiotechnologyLuminescence and Fluorescent MaterialsNanoplatforms for cancer theranosticsPorphyrin and Phthalocyanine Chemistry