The techniques and systems described herein relate to manufacturing, characterizing, and/or identifying one or more types of magnetic nanowires (MNWs). One or more types of MNWs may be associated with different objects, and a system may identify the objects based on the magnetic nanowires associated with the objects. For example, such techniques may involve characterizing the types of MNWs based on magnetic field transmission characteristics and ferromagnetic resonance characteristics of each type of MNW. In some examples, the techniques described herein may enable the identification of each of a plurality of types of MNWs present in a sample or object based on a combined transmission value of the sample. Such techniques may enable the development and use of barcode-like systems of different types of MNWs for labeling and identifying objects of interest.

Nanoparticles for use in assay methods for detecting analytes in samples, which comprise a signal inducing agent, e.g. a transition-metal catalyst or a chemiluminophore, a chemiluminophore precursor, a soluble absorber, or a soluble absorber precursor. After binding to an analyte, the nanoparticle is dissociated by a chemical or physical trigger, e.g. an organic solvent or ultrasound, to release the signal inducing agent, which releases a detectable signal via a physical or chemical reaction. The nanoparticles comprising a chemiluminophore, a chemiluminophore precursor, a soluble absorber, or a soluble absorber precursor can also effect chemical reactions that serve as signal amplifiers.

A gold nanoparticle-based assay for the detection of a target molecule, such as Hepatitis C Virus (HCV) RNA in serum samples, that uses positively charged gold nanoparticles (AuNPs) in solution based format. The assay has been tested on 74 serum clinical samples suspected of containing HCV RNA, with 48 and 38 positive and negative samples respectively. The developed assay has a specificity and sensitivity of 96.5% and 92.6% respectively. The results obtained were confirmed by Real-Time PCR, and a concordance of 100% for the negative samples and 89% for the positive samples has been obtained between the Real-Time PCR and the developed AuNPs based assay. Also, a purification method for the HCV RNA has been developed using HCV RNA specific probe conjugated to homemade silica nanoparticles. These silica nanoparticles have been synthesized by modified Stober method. This purification method enhanced the specificity of the developed AuNPs assay. The method can detect a target molecule, such as HCV RNA in serum, by employing modified silica nanoparticles to capture the target from a biological sample followed by detection of the captured target molecule using positively charged AuNPs. The assay is simple, cheap, sensitive and specific. Another aspect of the invention is anisotropic silver nanoparticles and methods of their use.

Provided herein are methods and systems for the production of a nanolipoprotein particle (NLP) that includes a scaffold protein a membrane forming lipid and optionally a target protein. At least one of the scaffold protein and target protein can be provided through an IVT system. The membrane forming lipid, scaffold protein and optionally the target protein can be assembled for a time and under conditions that allow obtaining high yield NLPs, NPLs with an increased solubility, an NLP of a controlled size, and/or an NLP having a size predetermined to include a pre-selected target protein.

Methods of producing light in liquid media are provided using nanoparticles capable of generating electroluminescence when stimulated by an electrical signal. The nanoparticles are provided as a label on a target species or on a specific binding partner of the target species to be detected in a test method. The nanoparticle-labeled species are drawn into operable proximity to electrodes which, when energized by a power source, excite the nanoparticles to produce electroluminescence. Methods of performing binding assays are described using the disclosed methods.

The present disclosure relates to luminescent including photon up-conversion nanoparticles. These nanoparticles dude a polymeric organic matrix, at least one light emitter distributed within this matrix, a stabilizing agent, and at least one metal particle enclosed within the matrix, wherein the metal particles are plasmonic nanoparticles. The present disclosure further relates to methods of manufacture and to uses of such nanoparticles.

The present invention relates to a nucleic acid nanostructure comprising one or more, preferably at least two, targeting agent(s) and a plurality of dye molecules, preferably at least to dye molecules. The present invention further relates to a composition, preferably pharmaceutical composition, comprising a nucleic acid nanostructure. The present invention also relates to a nanostructure or composition for use in medicine, preferably for use in medical imaging, and for use in a method of preventing, treating, and/or diagnosing a disease. Furthermore, the present invention relates to a method of labelling a target in a sample, to the use of a nanostructure as a stain, and to a kit. Moreover, the present invention further relates to a method of preparing a nanostructure. The present invention further relates to a method of identifying a targeting agent combination having a desired property, a desired effect, and/or a desired spatial organization, and to a method of producing a bi- or multispecific targeting agent-comprising molecule. Furthermore, the present invention relates to a method of screening a sample for a target having at least two target molecules.

Disclosed are various embodiments of a device comprising a synthetic polymeric substrate having a high quality finish upper surface, the upper surface having at least a bilayer coating comprising a first, reflective layer and a second, transparent layer. Also disclosed are kits containing embodiments of the disclosed device and detectable particles. Also disclosed are various embodiments of a method of using the disclosed device and various embodiments of a method of using the disclosed kit.

The present disclosure relates to a novel method for lateral flow immunoassay (LFIA) by utilizing plasmonic enhancement strategy. More specifically, the present disclosure provides a plasmonic enhanced lateral flow sensor (pLFS) concept by introducing a liposome-based amplification of the colorimetric signals on the lateral flow platform for ultrasensitive detection of pathogens.

Polymers, monomers, chromophoric polymer dots and related methods are provided. Highly fluorescent chromophoric polymer dots with narrow-band emissions are provided. Methods for synthesizing the chromophoric polymers, preparation methods for forming the chromophoric polymer dots, and biological applications using the unique properties of narrow-band emissions are also provided.