Self-assembled dipeptide grafted nanohybrid material strips for reliable spectroscopic and electrochemical recognition of tryptamine

Abstract

According to the World Health Organization (WHO), foods high in tryptamine may cause foodborne diseases and abnormal activity in the central nervous system (CNS). The real-time monitoring of tryptamine levels is an emphasized topic among scientific community. In the present work, we report a cost-effective fluorescent paper strips-based methodology impregnated with self-assembled dipeptide-modified (DM1) zinc oxide (ZnO) i.e.DM1@ZnO for the real-time monitoring of tryptamine levels. It is based on an organic-inorganic nanohybrid material of self-assembled N-functionalised dipeptide molecule coated over the surface of ZnO thus tailoring its properties for the detection of tryptamine employing spectroscopic and electrochemical methods. The designed material exhibited a noteworthy response towards tryptamine irrespective of the presence of other biogenic amines (BAs). It selectively displayed blue fluorescence under the 365 nm UV light. On top of that, the detection of tryptamine was also corroborated by its transition to 2-oxytryptamine, as deduced from its electrochemical route. Thus, the proposed paper strip-based methodology unbolts a realistic platform for the efficient recognition of varying levels of tryptamine thus tackling the prima facie reasons for foodborne diseases.