A new “turn-on” molecular switch for idiosyncratic detection of Al 3+ ion along with its application in live cell imaging
New Journal of Chemistry, 2022•pubs.rsc.org
A highly sensitive, reversible, reusable and fluorogenic “turn-on” probe (HBTC) is fabricated
for the sole detection of Al3+. On incremental addition of Al3+ in a solution of HBTC in ACN:
H2O (4: 1), a sharp “turn-on” emission enhancement is observed at 480 nm. The reversibility
of the probe (HBTC) was displayed on the addition of F− solution. The detection limit is
found to be of the order of 10− 9 M which suggests that HBTC can detect Al3+ at a very
minute level. The mechanism for Al3+ detection in ACN: H2O (4: 1) is attributed to forbidding …
for the sole detection of Al3+. On incremental addition of Al3+ in a solution of HBTC in ACN:
H2O (4: 1), a sharp “turn-on” emission enhancement is observed at 480 nm. The reversibility
of the probe (HBTC) was displayed on the addition of F− solution. The detection limit is
found to be of the order of 10− 9 M which suggests that HBTC can detect Al3+ at a very
minute level. The mechanism for Al3+ detection in ACN: H2O (4: 1) is attributed to forbidding …
A highly sensitive, reversible, reusable and fluorogenic “turn-on” probe (HBTC) is fabricated for the sole detection of Al3+. On incremental addition of Al3+ in a solution of HBTC in ACN : H2O (4 : 1), a sharp “turn-on” emission enhancement is observed at 480 nm. The reversibility of the probe (HBTC) was displayed on the addition of F− solution. The detection limit is found to be of the order of 10−9 M which suggests that HBTC can detect Al3+ at a very minute level. The mechanism for Al3+ detection in ACN : H2O (4 : 1) is attributed to forbidding CN isomerization and ESIPT process simultaneously turning on the chelation-enhanced fluorescence process. The reusability and real-time application of the probe are also studied. Bioimaging study reveals that HBTC can detect Al3+ in human breast cancer cells (MDA-MB-231). Electronic structure of the probe is explained by density functional theory.
The Royal Society of Chemistry