A BODIPY-based ICT probe for ratiometric and chromo-fluorogenic detection of hazardous oxalyl chloride

“…Based on the reports in the relevant literature, it was further speculated that a possible binding model between the probe and CN − was shown in Figure 8. Due to the strong nucleophilicity of CN − , after binding with sensor 1, a nucleophilic addition reaction occurred between CN − and C = N, producing the ICT effect that suppressed fluorescence release and led to significant fluorescence quenching of sensor 1, achieving the recognition of CN − [48,49]. Therefore, we affirm that sensor 1 belongs to chemical reaction-based addition CN − sensor.…”

A New Phenothiazine-Based Fluorescent Sensor for Detection of Cyanide

“…Based on the reports in the relevant literature, it was further speculated that a possible binding model between the probe and CN − was shown in Figure 8. Due to the strong nucleophilicity of CN − , after binding with sensor 1, a nucleophilic addition reaction occurred between CN − and C = N, producing the ICT effect that suppressed fluorescence release and led to significant fluorescence quenching of sensor 1, achieving the recognition of CN − [48,49]. Therefore, we affirm that sensor 1 belongs to chemical reaction-based addition CN − sensor.…”

A New Phenothiazine-Based Fluorescent Sensor for Detection of Cyanide

Synthesis and optical properties of tyramine-functionalized boron dipyrromethene dyes for cell bioimaging

Naturally Occurring Flavonol, Quercetagetin 5,6,7,3′,4′-Pentamethyl Ether (Marionol), as a Nontoxic Plant-Based Fluorescent Probe for Rapid, Sensitive, and Selective Detection of Cu²⁺ in Water