Synthesis and Study in Solution of a New Dansyl-Modified Azacryptand

Greta Bergamaschi,Ana Miljkovic,Antonio Poggi,Stefania Marcheggiani

doi:10.1155/2016/3415690

Greta Bergamaschi, Ana Miljkovic + Show 2 more

Open Access

https://doi.org/10.1155/2016/3415690

Copy DOI

Abstract

We report the synthesis of a new asymmetric azacryptand (L1), characterized by three p-xylyl spacers, one of which carries a dansyl side arm. The fluorescent sensor has been studied by potentiometric, UV-Vis, and emission studies in MeOH : water 3 : 2 mixture (0.07 M NaNO3), determining, in particular, the protonation constants of the free ligand and metal ion complexation equilibria. Interestingly, the obtained results revealed that the new receptor is fluorescent at neutral pH with a typical emission band of the dansyl group. Metal addition induced a partial quenching of the dansyl emission band; this behavior is more pronounced with Cu(II) that reduces the receptor’s emission by 60%. With all the studied cations, quenching follows the formation of a dimetallic complex. Similar studies on the model compound L2 confirmed that fluorescence quenching is mainly driven by a static mechanism, attributable to the formation of the inclusion dicopper complex [L1Cu2]4+. In order to test the stability of copper complexes under physiological conditions, spectrofluorimetric titrations with Cu(II) were performed in water buffered at pH = 8 (HEPES 0.07 M) and the values of binding constants, K11 and K12, were determined.

Highlights

The detection of transition metal ions is a significant research field due to cations’ relevance in life science, medicine, biology, and chemistry [1,2,3,4,5,6]
The obtained results revealed that the new receptor is fluorescent at neutral pH with a typical emission band of the dansyl group
We report the synthesis of the new asymmetric fluorescent azacryptand L1, characterized by a dansylated fragment anchored to one of the p-xylyl spacers

Summary

Introduction

The detection of transition metal ions is a significant research field due to cations’ relevance in life science, medicine, biology, and chemistry [1,2,3,4,5,6]. For these reasons, many cation sensors have been described and synthesized; fluorescent chemosensors, in particular, are very intriguing thanks to the low detection limits of the fluorescence technique [7,8,9,10,11]. Dimetallic bistren cryptands were synthesized for the first time by Lehn [23,24,25]

Methods

Results

Conclusion