Issue 22, 2020

Aggregation-driven fluorescence quenching of imidazole-functionalized perylene diimide for urea sensing

Abstract

Stimuli-responsive self-assembly of functional amphiphilic molecules by specific chemical stimulants is a promising strategy for sensor application. Herein, we demonstrate a fast optical detection of urea in human urine by exploiting bolaform perylene diimide functionalized with imidazoles (PDI-Hm), whose aggregation is induced by urea hydrolysis. The hydroxides produced from the enzymatic urea hydrolysis deprotonate the imidazoles to reduce electrostatic repulsion between PDI-Hm molecules in a HCl–methanol mixture, thereby leading to aggregation and consequent fluorescence quenching. The molecular interaction of PDI-Hm was further scrutinized to understand the aggregation behavior driven by the screening of electrical repulsion. As an optical sensing probe, PDI-Hm displays a prompt response (<1 min) to hydroxide and detection limit of 0.4 mM for urea. PDI-Hm incorporating urease offers considerable selectivity toward urea among various components in human urine. The urea sensing accuracy of this PDI-Hm fluorescence chemosensor is comparable to that of a clinical method, showing 93.4% consistency. Furthermore, the PDI-Hm was fabricated into a gel film allowed for the fast screening of excessive urea in urine.

Graphical abstract: Aggregation-driven fluorescence quenching of imidazole-functionalized perylene diimide for urea sensing

Supplementary files

Article information

Article type
Paper
Submitted
23 Jun 2020
Accepted
17 Aug 2020
First published
17 Aug 2020

Analyst, 2020,145, 7312-7319

Aggregation-driven fluorescence quenching of imidazole-functionalized perylene diimide for urea sensing

J. Cho, C. Keum, S. Lee and S. Lee, Analyst, 2020, 145, 7312 DOI: 10.1039/D0AN01252A

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