An Introduction to Small Molecule Fluorescent Sensors

“…There are a number of photochemical processes that can also be manipulated to rationally design an analyte-responsive fluorescent probe . These processes include charge, energy, or proton transfer . Photoinduced electron transfer (PET) is a fluorescence quenching mechanism that is a form of charge transfer, involving the movement of an excited state electron from donor to acceptor, preventing subsequent fluorescence emission. , Another charge transfer technique, termed intramolecular charge transfer (ICT), is crucial for fluorescence in donor–acceptor type fluorophores such as coumarins, 1,8-naphthalimides and cyanines, and disruption or enhancement of ICT can therefore be harnessed for the development of metal sensors .…”

“…Probes 10a, 12, and 14 were subsequently used to study organelle-specific changes in Fe(II) during ferroptosis, revealing that the labile iron pools in the lysosomes and endoplasmic reticulum increased in concentration, while there was no change in the mitochondria. 94 A similar N-oxide-TPP sensor P Fe(II) (15) was developed by Bhuniya and coworkers. 78 The probe 15 employed a coumarin dye as the fluorophore, but the putative subcellular mitochondrial targeting was not confirmed.…”

“…527 Binding of two Co(II) ions to the sensor gives rise to fluorescence quenching. While turn-off intensity-based sensors are not ideal for biological applications, 530 the authors were able to use the sensor to observe changes in emission of the probe at the cell walls of celery, amaranth, and chive roots treated with Co(II).…”

“…A subset of these stains are fluorescent sensors (a term used interchangeably with fluorescent probes), which are responsive to an aspect of their local chemical environment, whether a specific analyte or a chemical condition such as pH or viscosity. 15 In this context, many different classes of fluorescent sensors have been reported to date, broadly defined as genetically encoded or exogenously applied. Genetically encoded sensors encompass fluorescent proteins, chemigenetic probes, DNAzymes and RNA-based sensors, and all of these types of reporters have been applied to the development of metal sensors.…”

“…A more recent extension of this work has been the development of responsive fluorescent stains, which can be coupled to fluorescence microscopy techniques to enable cellular imaging of living cells with high spatiotemporal resolution. A subset of these stains are fluorescent sensors (a term used interchangeably with fluorescent probes), which are responsive to an aspect of their local chemical environment, whether a specific analyte or a chemical condition such as pH or viscosity . In this context, many different classes of fluorescent sensors have been reported to date, broadly defined as genetically encoded or exogenously applied.…”

Small-Molecule Fluorescent Probes for Binding- and Activity-Based Sensing of Redox-Active Biological Metals

“…There are a number of photochemical processes that can also be manipulated to rationally design an analyte-responsive fluorescent probe . These processes include charge, energy, or proton transfer . Photoinduced electron transfer (PET) is a fluorescence quenching mechanism that is a form of charge transfer, involving the movement of an excited state electron from donor to acceptor, preventing subsequent fluorescence emission. , Another charge transfer technique, termed intramolecular charge transfer (ICT), is crucial for fluorescence in donor–acceptor type fluorophores such as coumarins, 1,8-naphthalimides and cyanines, and disruption or enhancement of ICT can therefore be harnessed for the development of metal sensors .…”

“…Probes 10a, 12, and 14 were subsequently used to study organelle-specific changes in Fe(II) during ferroptosis, revealing that the labile iron pools in the lysosomes and endoplasmic reticulum increased in concentration, while there was no change in the mitochondria. 94 A similar N-oxide-TPP sensor P Fe(II) (15) was developed by Bhuniya and coworkers. 78 The probe 15 employed a coumarin dye as the fluorophore, but the putative subcellular mitochondrial targeting was not confirmed.…”

“…527 Binding of two Co(II) ions to the sensor gives rise to fluorescence quenching. While turn-off intensity-based sensors are not ideal for biological applications, 530 the authors were able to use the sensor to observe changes in emission of the probe at the cell walls of celery, amaranth, and chive roots treated with Co(II).…”

“…A subset of these stains are fluorescent sensors (a term used interchangeably with fluorescent probes), which are responsive to an aspect of their local chemical environment, whether a specific analyte or a chemical condition such as pH or viscosity. 15 In this context, many different classes of fluorescent sensors have been reported to date, broadly defined as genetically encoded or exogenously applied. Genetically encoded sensors encompass fluorescent proteins, chemigenetic probes, DNAzymes and RNA-based sensors, and all of these types of reporters have been applied to the development of metal sensors.…”

“…A more recent extension of this work has been the development of responsive fluorescent stains, which can be coupled to fluorescence microscopy techniques to enable cellular imaging of living cells with high spatiotemporal resolution. A subset of these stains are fluorescent sensors (a term used interchangeably with fluorescent probes), which are responsive to an aspect of their local chemical environment, whether a specific analyte or a chemical condition such as pH or viscosity . In this context, many different classes of fluorescent sensors have been reported to date, broadly defined as genetically encoded or exogenously applied.…”

Small-Molecule Fluorescent Probes for Binding- and Activity-Based Sensing of Redox-Active Biological Metals

Near-Infrared Ratiometric Fluorescent Probe for Detecting Endogenous Cu²⁺ in the Brain

Comparison of Synthetic Pathways for Obtaining Fluorescent Nanomaterials Based on Halloysite and Carbon Dots for Potential Biological Sensing