Abstract: The invention provides luminescent lanthanide nanoparticles having simultaneously an improved brightness and an increased lifetime of the excited-state. These nanoparticles comprise terbium ions and ions of a second lanthanide, preferentially europium, and are coated with molecules of chromophore ligand bonded to the surface of the nanoparticle. The ligand is an organic molecule comprising at least one chromophore radical of formula (I) or of formula (II): wherein R is selected from H, CN group or COOH group. The phosphorescence excited-state lifetime is improved by energy transfer from surface terbium ions to core ions of the second lanthanide The nanoparticle may further comprise a carrier molecule of analytical interest covalently attached to at least one ligand molecule.

Abstract: Disclosed is a new kit for detecting or quantifying one or multiple nucleic acid targets in a biological sample by FRET measurement, and a detection or quantification method using this kit.

Abstract: A new kit is provided for detecting or quantifying the amount of one or multiple nucleic acid targets in a biological sample, and a detection or quantification method using this kit. The present kit is constituted by a universal energy donor probe, a universal energy acceptor probe and a couple of adaptors.

Abstract: Described herein is a time-gated, two-step FRET relay effective to provide temporal transference of a prompt FRET pathway, or provide spectro-temporal encoding analytical signals and other information. A FRET relay assembly includes a long lifetime FRET donor (for example, a lanthanide complex), a semiconductor quantum dot (QD) configured as an intermediate acceptor/donor in FRET, and a fluorescent dye configured as a terminal FRET acceptor, wherein the long lifetime FRET donor has an excited state lifetime of at least one microsecond and the QD and fluorescent dye each have excited state lifetimes of less than 100 nanoseconds.

Abstract: A new kit is provided for detecting or quantifying the amount of one or multiple nucleic acid targets in a biological sample, and a detection or quantification method using this kit. said the present kit is constituted by a universal energy donor probe, a universal energy acceptor probe and a couple of adaptors.

Abstract: Described herein is a time-gated, two-step FRET relay effective to provide temporal transference of a prompt FRET pathway, or provide spectro-temporal encoding analytical signals and other information. A FRET relay assembly includes a long lifetime FRET donor (for example, a lanthanide complex), a semiconductor quantum dot (QD) configured as an intermediate acceptor/donor in FRET, and a fluorescent dye configured as a terminal FRET acceptor, wherein the long lifetime FRET donor has an excited state lifetime of at least one microsecond and the QD and fluorescent dye each have excited state lifetimes of less than 100 nanoseconds.

Abstract: Described herein is a time-gated, two-step FRET relay effective to provide temporal transference of a prompt FRET pathway, or provide spectro-temporal encoding analytical signals and other information. A FRET relay assembly includes a long lifetime FRET donor (for example, a lanthanide complex), a semiconductor quantum dot (QD) configured as an intermediate acceptor/donor in FRET, and a fluorescent dye configured as a terminal FRET acceptor, wherein the long lifetime FRET donor has an excited state lifetime of at least one microsecond and the QD and fluorescent dye each have excited state lifetimes of less than 100 nanoseconds.

Abstract: The invention concerns a method for detecting an analyte in a sample by multiplexing FRET (Förster Resonance Energy Transfer) analysis, the method comprising the following steps: providing a sample containing an energy transfer donor, several spectrally different quantum dot species, and an analyte, wherein the analyte is configured to mediate an energy transfer within a first energy transfer donor-acceptor pair provided by the energy transfer donor and a first quantum dot specie, the energy transfer donor is configured to act as energy transfer donor in the first energy transfer donor-acceptor pair, and the first quantum dot specie is configured to act as energy transfer acceptor in the first energy transfer donor-acceptor pair, irradiating excitation light from an excitation light source to the sample, in the first energy transfer donor-acceptor pair, transferring excitation energy from the energy transfer donor excited by the excitation light to the first quantum dot specie, the energy transfer being media