Structured substrate including (a) a plurality of nanoparticles distributed on a solid support, (b) a gel material forming a layer in association with the plurality of nanoparticles, and (c) a library of target nucleic acids in the gel material.

Structured substrate including (a) a plurality of nanoparticles distributed on a solid support, (b) a gel material forming a layer in association with the plurality of nanoparticles, and (c) a library of target nucleic acids in the gel material.

The invention generally relates to assemblies for displacing droplets from a vessel that facilitate the collection and transfer of the droplets while minimizing sample loss. In certain aspects, the assembly includes at least one droplet formation module, in which the module is configured to form droplets surrounded by an immiscible fluid. The assembly also includes at least one chamber including an outlet, in which the chamber is configured to receive droplets and an immiscible fluid, and in which the outlet is configured to receive substantially only droplets. The assembly further includes a channel, configured such that the droplet formation module and the chamber are in fluid communication with each other via the channel. In other aspects, the assembly includes a plurality of hollow members, in which the hollow members are channels and in which the members are configured to interact with a vessel. The plurality of hollow members includes a first member configured to expel a fluid immiscible with droplets in the vessel and a second member configured to substantially only droplets from the vessel. The assembly also includes a main channel, in which the second member is in fluid communication with the main channel. The assembly also includes at least one analysis module connected to the main channel.

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.

Techniques for detecting a presence of an analyte and determining a concentration of analytes are provided. An analyte may be provided on an LSPR-active surface. The LSPR-active surface may comprise sensitivity enhancing labels. The analyte may induce a local change near the LSPR-active surface. The LSPR-active surface may be imaged with an imaging device for images before, during, or after a reaction takes place. Local regions of interest within the images may be analyzed to detect the local changes.

Techniques for detecting a presence of an analyte and determining a concentration of analytes are provided. An analyte may be provided on an LSPR-active surface. The LSPR-active surface may comprise sensitivity enhancing labels. The analyte may induce a local change near the LSPR-active surface. The LSPR-active surface may be imaged with an imaging device for images before, during, or after a reaction takes place. Local regions of interest within the images may be analyzed to detect the local changes.

An apparatus for label-free analysis of molecules, including interactions and reactions of the molecules, is disclosed. The apparatus is based on detecting molecule movement under the influence of an external electric field. The apparatus is able to achieve sensitive detection of molecular binding to proteins or other molecules, and conformational changes of proteins or other molecules and biochemical reactions of the proteins or other molecules. Applications of the apparatus include screening of drug molecules, kinetic analysis of posttranslational modification of proteins, and small molecule-protein interactions.

An apparatus for label-free analysis of molecules, including interactions and reactions of the molecules, is disclosed. The apparatus is based on detecting molecule movement under the influence of an external electric field. The apparatus is able to achieve sensitive detection of molecular binding to proteins or other molecules, and conformational changes of proteins or other molecules and biochemical reactions of the proteins or other molecules. Applications of the apparatus include screening of drug molecules, kinetic analysis of posttranslational modification of proteins, and small molecule-protein interactions.

The present invention relates to a method of detecting a target nucleic acid on the basis of rolling circle amplification (RCA), and more specifically, to a method of detecting a target nucleic acid, the method in which a target nucleic acid (a nucleic acid having a target nucleic acid sequence), when present, forms a circular template with a template for performing an amplification reaction, wherein during the amplification reaction, a restriction enzyme is added to further induce a new RCA reaction, thus increasing the reaction rate and sensitivity, and to an RCA composition for implementing the method. The method of detecting a target nucleic acid according to the present invention, by detecting a barcode sequence predefined according to the type of the target nucleic acid, enables multiple detections of the presence of the target nucleic acid without sequencing, is inexpensive for not using costly enzymes, such as CRISPR, can detect barcode sequences, and can utilize various existing nucleic acid detection systems, and thus, can be useful in the detection of gene mutations.