posted on 2021-04-13, 18:03authored byKimberly
M. Trevino, Brandon K. Tautges, Rohan Kapre, Francisco C. Franco Jr, Victor W. Or, Edward I. Balmond, Jared T. Shaw, Joel Garcia, Angelique Y. Louie
The metal-binding
capabilities of the spiropyran family of molecular
switches have been explored for several purposes from sensing to optical
circuits. Metal-selective sensing has been of great interest for applications
ranging from environmental assays to industrial quality control, but
sensitive metal detection for field-based assays has been elusive.
In this work, we demonstrate colorimetric copper sensing at low micromolar
levels. Dimethylamine-functionalized spiropyran (SP1)
was synthesized and its metal-sensing properties were investigated
using UV–vis spectrophotometry. The formation of a metal complex
between SP1 and Cu2+ was associated with a
color change that can be observed by the naked eye as low as ≈6
μM and the limit of detection was found to be 0.11 μM
via UV–vis spectrometry. Colorimetric data showed linearity
of response in a physiologically relevant range (0–20 μM
Cu2+) with high selectivity for Cu2+ ions over
biologically and environmentally relevant metals such as Na+, K+, Mn2+, Ca2+, Zn2+, Co2+, Mg2+, Ni2+, Fe3+, Cd2+, and Pb2+. Since the color change accompanying SP1–Cu2+ complex formation could be detected
at low micromolar concentrations, SP1 could be viable
for field testing of trace Cu2+ ions.