<p>Electrochemiluminescent (ECL) luminophore with high quantum efficiency is one of the most essential components in ECL biosensor system. However, high excitation potential caused oxygen emission in electrolyte damages the modified electrode and biological activity, which limits the efficiency of luminophores. Herein, perylene-3,4,9,10-tetracarboxylic acid (PTC) was employed as an organic ligand to synthesize a perylene derivative nanosheet (PDIP) which was characterized by a significantly lower excitation potential of -0.28&#xa0;V and a narrow potential sweep range (-0.3&#xa0;V–0.3&#xa0;V). Silver nanoparticle-functionalized PDIP (Ag@PDIP) was further synthesized and applied to construct an ECL biosensor system (Ag@PDIP/GCE/K<sub>2</sub>S<sub>2</sub>O<sub>8</sub>). Ag@PDIP possessed a more positive excitation potential (-0.21&#xa0;V) and a 1.8-fold enhancement in quantum efficiency compared to PDIP. The sensitivity and specificity of Ag@PDIP/GCE/K<sub>2</sub>S<sub>2</sub>O<sub>8</sub> were testified in detecting programmed death ligand 1 (PD-L1), achieving a five-order linear dynamic range (100&#xa0;fg/mL–100 ng/mL), along with a remarkably low detection threshold of 10&#xa0;fg/mL, and high selectivity towards PD-L1. The newly synthesized PDIP showed significant enhancement in quantum efficiency of ECL luminophore, and its successful application in detecting PD-L1 provided a prospective and efficient approach for ECL-based clinical detection of biomarkers.</p> Graphical abstract <p></p>

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Ultrasensitive biosensor based on AgNPs-functionalized perylene derivative nanosheets with enhanced electrochemiluminescence at narrow potential sweep range

  • Yujian Li,
  • Pan Ju,
  • Lu Liu,
  • Ziwei Li,
  • Xiaoming Li,
  • Hua Wang,
  • Bo Shen,
  • Wei Gong,
  • Shijia Ding,
  • Xinmin Li,
  • Rong Luo,
  • Xinyu Li

摘要

Electrochemiluminescent (ECL) luminophore with high quantum efficiency is one of the most essential components in ECL biosensor system. However, high excitation potential caused oxygen emission in electrolyte damages the modified electrode and biological activity, which limits the efficiency of luminophores. Herein, perylene-3,4,9,10-tetracarboxylic acid (PTC) was employed as an organic ligand to synthesize a perylene derivative nanosheet (PDIP) which was characterized by a significantly lower excitation potential of -0.28 V and a narrow potential sweep range (-0.3 V–0.3 V). Silver nanoparticle-functionalized PDIP (Ag@PDIP) was further synthesized and applied to construct an ECL biosensor system (Ag@PDIP/GCE/K2S2O8). Ag@PDIP possessed a more positive excitation potential (-0.21 V) and a 1.8-fold enhancement in quantum efficiency compared to PDIP. The sensitivity and specificity of Ag@PDIP/GCE/K2S2O8 were testified in detecting programmed death ligand 1 (PD-L1), achieving a five-order linear dynamic range (100 fg/mL–100 ng/mL), along with a remarkably low detection threshold of 10 fg/mL, and high selectivity towards PD-L1. The newly synthesized PDIP showed significant enhancement in quantum efficiency of ECL luminophore, and its successful application in detecting PD-L1 provided a prospective and efficient approach for ECL-based clinical detection of biomarkers.

Graphical abstract