Boronic acid-based sensors for small-molecule reactive species: A review

Small-molecule reactive species, such as reactive oxygen species, catecholamines, ions, sialic acid and gas signal molecules, are involved in many important biological events. For example, abnormal reactive oxygen species levels can lead to a range of cell dysfunctions and eventually cancer and neurodegenerative diseases. Therefore, the development of sensors for detecting small-molecule reactive species is of great significance for disease prevention, diagnosis and treatment. Boronic acid has been widely used for the selective recognition of sugars due to their obvious fluorescence change after combining with sugar, easily structure modification and good light stability. In recent years, a large number of boronic acid-based sensors that can selectively recognize small-molecule reactive species have been reported, however, there are few systematic reviews in this field, and lack of in-depth understanding of the identification mechanism and structure-activity relationship. In this review, boronic acid-based sensors detecting small-molecule reactive species (such as reactive oxygen species (H2O2, ONOO-, CLO-), catecholamines (dopamine, norepinephrine), sialic acid and sialic acid derivatives (sialic acid, sialic Lewis X, sialic Lewis Y) and ions (F-, Fe3+, Cu2+)) over the recent years (2015-2020) will be discussed, focusing on the fluorescence characteristics of the sensors and their potential in disease detection, and we are aiming to provide researchers with better inspiration.

Automated summary

This review discusses the development of boronic acid-based sensors for detecting small-molecule reactive species over the recent years (2015-2020), focusing on the fluorescence characteristics of the sensors and their potential in disease detection. The aim is to provide researchers with better inspiration in this field.