Spatiotemporal Theranostic Nanoprobes Dynamically Monitor Targeted Tumor Therapy

Abstract

AbstractCurrently, spatiotemporal theranostic nanoprobes are in great demand, owing to their enhanced target therapy and precise dynamic tracing of in vivo drug fate. Herein, this study highlights the successful development of dynamic theranostic nanoprobes, which are facilely established via self‐assembly between glutathione (GSH)‐responsive dasatinib (DAS) dimers and indocyanine green (ICG). The DAS dimers endow the nanoprobes with aggregation‐induced emission (AIE) characteristic, whose emission wavelength successfully redshifts from 420 to 810 nm compared to DAS‐based nanoprobes, the same as that of ICG, thus improving the total fluorescence intensity. Moreover, the nanoprobes exhibit a dynamic fluorescence intensity conversion that first decreases and then increases at the tumor site via intracellular GSH‐triggered AIE quenching and fluorescence re‐enhancement of ICG, therefore achieving precise tumor diagnosis, prognosis evaluation, and spatiotemporal tracing of drug fate compared to other imaging strategies. Furthermore, the nanoprobes show long‐term circulation stability via suitable particle sizes and zeta potentials, improved tumor accumulation via extracellular protonation and active cellular uptake, efficient drug release via response to the intracellular milieu, and enhanced apoptosis via targeting to intracellular kinase, therefore achieving the significant tumor inhibition. Thus, the spatiotemporal theranostic nanoprobes can dynamically monitor the targeted tumor therapy, greatly advancing their application in clinics.