Radiative Decay Engineering: Biophysical and Biomedical Applications

Abstract: Fluorescence spectroscopy is a widely used research tool in biochemistry and molecular biology. Fluorescence has also become the dominant method enabling the revolution in medical diagnostics, DNA sequencing, and genomics. To date all the fluorescence observables, including spectral shifts, anisotropies, quantum yields, and lifetimes, have all been utilized in basic and applied uses of fluorescence. In this forward-looking article we describe a new opportunity in fluorescence, radiative decay engineering (RDE)… Show more

“…In addition, significant increases in probe photostability were observed for probes coated on the silver fractal like structures. These results further serve to compliment our recent work on the effects of nobel metal particles with fluorophores, a relatively new phenomenon in fluorescence we have termed both "metal-enhanced fluorescence" [1] and "radiative decay engineering" [2,3]. These results are explained by the metallic surfaces modifying the radiative decay rate (Γ) of the fluorescent labels.…”

“…We have recently reported the favorable effects obtained for fluorophores in close proximity to metallic particles and islands [1][2][3][4][5][6][7][8][9]. These effects include increased quantum yields, decreased lifetimes, increased photostability, and increased energy transfer.…”

“…These effects include increased quantum yields, decreased lifetimes, increased photostability, and increased energy transfer. These effects are due to the interactions of excited-state fluorophores with the surface plasmon resonance (the oscillations of free electrons) on a metals surface [1,2,6,7]. These interactions result in increased rates of excitation, quenching, increased intensities, or quantum yield (Fig.…”

“…For the most favorable effect of enhanced fluorescence, we are mostly concerned with the important prospect of increasing the radiative decay rate (Γ) for fluorophores, which typically occurs when a fluorophore is positioned some ≈50-100 Å from an appropriately sized and shaped metallic particle. We have recently reviewed these criteria [1,2] and refer to the use of fluorophore-metal interactions as radiative decay engineering (RDE) [2,3] or metal-enhanced fluorescence (MEF) [1]. Interestingly, from Fig.…”

“…1 and Eqs. (1)(2)(3)(4), when the radiative decay rate (the spontaneous rate at which a fluorophore emits photons) is increased, the quantum yield increases while the lifetime decreases Eqs. (3,4).…”

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“…In addition, significant increases in probe photostability were observed for probes coated on the silver fractal like structures. These results further serve to compliment our recent work on the effects of nobel metal particles with fluorophores, a relatively new phenomenon in fluorescence we have termed both "metal-enhanced fluorescence" [1] and "radiative decay engineering" [2,3]. These results are explained by the metallic surfaces modifying the radiative decay rate (Γ) of the fluorescent labels.…”

“…We have recently reported the favorable effects obtained for fluorophores in close proximity to metallic particles and islands [1][2][3][4][5][6][7][8][9]. These effects include increased quantum yields, decreased lifetimes, increased photostability, and increased energy transfer.…”

“…These effects include increased quantum yields, decreased lifetimes, increased photostability, and increased energy transfer. These effects are due to the interactions of excited-state fluorophores with the surface plasmon resonance (the oscillations of free electrons) on a metals surface [1,2,6,7]. These interactions result in increased rates of excitation, quenching, increased intensities, or quantum yield (Fig.…”

“…For the most favorable effect of enhanced fluorescence, we are mostly concerned with the important prospect of increasing the radiative decay rate (Γ) for fluorophores, which typically occurs when a fluorophore is positioned some ≈50-100 Å from an appropriately sized and shaped metallic particle. We have recently reviewed these criteria [1,2] and refer to the use of fluorophore-metal interactions as radiative decay engineering (RDE) [2,3] or metal-enhanced fluorescence (MEF) [1]. Interestingly, from Fig.…”

“…1 and Eqs. (1)(2)(3)(4), when the radiative decay rate (the spontaneous rate at which a fluorophore emits photons) is increased, the quantum yield increases while the lifetime decreases Eqs. (3,4).…”

Untitled

Plasmonics

Metal‐Enhanced Fluorescence: Application to High‐Throughput Screening and Drug Discovery