Organic Materials with Ultrabright Phosphorescence at Room Temperature under Physiological Conditions for Bioimaging

In contrast to the high efficiency of room temperature phosphorescence in crystal states, the generally utilized nanoparticles of organic materials in bioimaging demonstrated sharply decreased performance by orders of magnitude under physiological conditions, badly limiting the realization of their unique advantages. This case, especially for organic red/near‐infrared (NIR) phosphorescence materials, is not only the challenge present in reality but more importantly, for the theoretical problem of deeply understanding and avoiding the quenching effect by oxygen and water toward excited triplet states. Herein, thanks to the intelligent molecular design by the introduction of abundant hydrophobic chains and highly‐branched structures, bright and persistent red/NIR phosphorescence under physiological conditions has been realized, which demonstrated the shielding effect towards oxygen, and the strengthened intermolecular interactions to suppress the non‐radiative transitions. Accordingly, the record phosphorescence intensity of nanoparticles in bioimage, up to 8.21±0.36×108 p s−1 cm−2 sr−1, was achieved, to realize the clear phosphorescence imaging of liver and tumors in living mice, even lymph nodes in rabbit models with high SBRs. This work afforded an efficient way to achieve the bright red/NIR phosphorescence nanoparticles, guiding their further applications in biology and medicine. The record NIR/red phosphorescence intensity of nanoparticles under physiological conditions has been achieved by four‐branched luminogens with shielding effect toward oxygen and water. It can penetrate tissue with depth as high as 35 mm, resulting in the clear in vivo phosphorescence imaging of the liver, tumor, and stomach in living mice, and lymph nodes in living rabbits with high signal‐to‐background ratios.