A microstructured chip (3; 33; 43; 53; 63) for surface plasmon resonance (SPR) analysis, taking the form of a solid formed by: a base (5; 77); an upper surface (4; 44), at least part of which is covered with a metal layer (2; 22; 42; 52; 62); and at least one side surface (55; 66). The chip is characterized in that the aforementioned upper surface is provided with micrometric zones intended to receive species to be analyzed and selected from among n protrusions and m cavities, and in that when n+m≧2 the zones are separated from one another by planar surfaces, with n varying between 1 and j, m varying between 0 and i, and j and i being integers.

Disclosed probes comprise metal nanoparticle cores associated with magnetic particles that allow probes associated with targets to be concentrated by an applied magnetic field to increase detection sensitivity and provide sufficient spacing between concentrated probes to avoid signal quenching. The probe may comprise at least one recognition receptor, and may further comprise at least one reporter molecule, such as a fluorescent tag, a Raman reporter, or combinations thereof. Concentrating probe-target composites substantially enhances a sensing signal, such as from 5 to 10 times, compared to detection without concentrating the probes. The method may be used to detect, for example, interleukins at concentrations at least as low as 25 pg/ml in sputum or blood from a subject for early and precise profiling of viral infections, such as SARS-CoV-2 infections.

Disclosed probes comprise metal nanoparticle cores associated with magnetic particles that allow probes associated with targets to be concentrated by an applied magnetic field to increase detection sensitivity and provide sufficient spacing between concentrated probes to avoid signal quenching. The probe may comprise at least one recognition receptor, and may further comprise at least one reporter molecule, such as a fluorescent tag, a Raman reporter, or combinations thereof. Concentrating probe-target composites substantially enhances a sensing signal, such as from 5 to 10 times, compared to detection without concentrating the probes. The method may be used to detect, for example, interleukins at concentrations at least as low as 25 pg/ml in sputum or blood from a subject for early and precise profiling of viral infections, such as SARS-CoV-2 infections.

Systems and methods for plasmonic heating by combined use of thin plasmonic film-based 2D and 3D structures and a light-emitting diode (LED) for nucleic acids amplification through fast thermal cycling of polymerase chain reaction (PCR) are described.

Systems and methods for plasmonic heating by combined use of thin plasmonic film-based 2D and 3D structures and a light-emitting diode (LED) for nucleic acids amplification through fast thermal cycling of polymerase chain reaction (PCR) are described.

Provided are methods and systems for reducing the time needed for sequencing nucleic acids. The approach relies on detecting formation of nucleotide-specific ternary complexes comprising a polymerase (e.g., a DNA polymerizing enzyme), a primed template nucleic acid molecule, and a nucleotide complementary to the templated base of the primed template nucleic acid. The methods and systems facilitate determination of the next correct nucleotide, as well as the subsequent next correct nucleotide from a cycle of examining four different nucleotides without requiring chemical incorporation of any nucleotide into the primer.

Provided are methods and systems for reducing the time needed for sequencing nucleic acids. The approach relies on detecting formation of nucleotide-specific ternary complexes comprising a polymerase (e.g., a DNA polymerizing enzyme), a primed template nucleic acid molecule, and a nucleotide complementary to the templated base of the primed template nucleic acid. The methods and systems facilitate determination of the next correct nucleotide, as well as the subsequent next correct nucleotide from a cycle of examining four different nucleotides without requiring chemical incorporation of any nucleotide into the primer.

The present invention concerns a method of sequencing immobilized polynucleotides in which beads which are tethered to the solid support are used as labels to identify bases within the polynucleotides. The beads carry sets of probes or bases which can bind to the polynucleotide allowing identification of the target base(s). Identification of the base(s) is achieved through sequential application of different cleavage means specific to different probes/bases carried on the beads. Also provided is an apparatus for performing the method and a kit comprising the apparatus and other components necessary for performing the method.

The present invention concerns a method of sequencing immobilized polynucleotides in which beads which are tethered to the solid support are used as labels to identify bases within the polynucleotides. The beads carry sets of probes or bases which can bind to the polynucleotide allowing identification of the target base(s). Identification of the base(s) is achieved through sequential application of different cleavage means specific to different probes/bases carried on the beads. Also provided is an apparatus for performing the method and a kit comprising the apparatus and other components necessary for performing the method.

The present invention pertains to the field of pre-functionalised nanoparticles (NPs). It relates more particularly to NPs pre functionalized using a self-assembled monolayer (SAM) and also to NPs functionalized using biomolecules such that the NPs are stable in solution. These NPs may be used in numerous applications, especially as a diagnostic tool, tool for depleting a molecule of interest in a solution, and therapeutic tool.