The invention described herein relates to sterically stabilized colloidal constructs comprising preformed colloidal particles encapsulated within a polymeric shell. The constructs, which are controllably sized, are nanoparticles comprising hydrophobic elements, electrostatically charged particles with hydrophobic surfaces, hydrophobic inorganic nanostructures, and amphiphilic copolymers with hydrophobic domains and hydrophilic domains. The constructs are made by a process that allows for the simultaneous encapsulation of a preformed colloidal agent as well as a dissolved hydrophobic active within the core of the polymeric nanoparticle. Among the actives incorporated in various embodiments are organic fluorescent dyes, metal nanostructures and superparamagnetic materials for use in combined fluorescence, optical and magnetic resonance imaging applications, and hydrophobic drugs for therapeutic applications.

The present invention concerns a luminescent particle comprising a nanoparticle of formula
A.sub.1-xLn.sub.xVO.sub.4(1-y)(PO.sub.4).sub.y  (I)
in which A is selected from yttrium (Y), gadolinium (Gd), lanthanum (La), and mixtures thereof; Ln is selected from europium (Eu), dysprosium (Dy), samarium (Sm), neodymium (Nd), erbium (Er), ytterbium (Yb), and mixtures thereof; 0<x<1; and 0≤y<1; characterized in that the nanoparticle on its surface has tetraalkylammonium cations in an amount such that said nanoparticle has a zeta potential, ζ, of less than or equal to −28 mV in an aqueous medium with a pH≥5, more particularly with a pH≥5.5, and with an ionic conductivity >100 μS.Math.cm.sup.−1. It also concerns a method for preparing such luminescent particles, a colloidal suspension of these particles, and the use thereof as a diagnostic agent, and also a diagnostic kit comprising such luminescent particles.

A method for early stage pathology detection, location, imaging, evaluation, and treatment of cells and/or extracellular vesicles in the circulation.

The invention provides novel nanoparticles with tunable and multi-color afterglow emission for extended time after excitation, and compositions thereof as well as methods for their preparation and use in various applications.

The present invention discloses a diagnostic device or kit for visual detection of bilirubin. Said diagnostic device or kit comprises chitosan stabilized gold nanoclusters based luminescence source, Cu.sup.2+ ions source for quenching luminescence intensity of said gold nanoclusters and recovery of quenched luminescence intensity in the presence of bilirubin. The said device enables non-invasive detection of hyper-bilirubinemia by thumb impression visually or from blood serum.

A nanoagent for detections and treatments of multiple targets of interest includes multiple types of nanocomposites, each type of nanocomposites comprising at least one nanostructure, each nanostructure having a core and a shell surrounding the core; a respective reporter assembled on the shell of each nanostructure; and a layer of a respective treating agent and a respective targeting agent conjugated to the respective reporter. In use, each type of nanocomposite targets to a respective target of interest according to the respective targeting agent and releases the respective treating agent and the nanostructure therein for therapeutic treatment of the respective target of interest, and the respective target of interest transmits at least one signature responsive to the respective reporter for detection of the respective target of interest.

Metal-organic frameworks (MOFs) comprising amines on the organic linker can be used for cell targeting. In particular, primary amine groups represent one of the most versatile chemical moieties for conjugation to biologically relevant molecules, including antibodies and enzymes. Different chemical conjugation schemes can be used to conjugate biological molecules to the amino functionality on the organic linker. For example, carbodiimide chemistry can be used to link a primary amine to available carboxyl groups on the protein. For example, sulfhydryl crosslinking chemistry can be used via Traut's reagent scheme. As a demonstration of the invention, the ability of EpCAM antibody-targeted MOFs to bind to a human epithelial cell line (A549), a common target for imaging studies, was confirmed with confocal microscopy.

Nanodiamond particles and related devices and methods, such as nanodiamond particles for the detection and/or quantification of analytes, are generally described. In some embodiments, the device comprises a plurality of nanodiamond particles and a species bound to the nanodiamond particles. In certain embodiments, the plurality of nanodiamond particles may be exposed to a sample suspected of containing an analyte. In some cases, the analyte may bind to the species such that the presence of the analyte in the sample may be detected. In some embodiments, the devices, systems, and methods described herein are useful for the detection of an analyte in a sample obtained from a subject for, for example, diagnostic purposes. In some cases, the systems, devices, and methods described herein may be useful for diagnosing, prevent, treating, and/or managing a disease or bodily condition. In an exemplary embodiment, such systems, devices, and methods described herein may be useful for detecting and/or quantifying the presence of a virus (e.g., ebola) in a subject and/or a sample obtained from the subject.

A light emitter is formed from nanoparticles including a compound semiconductor containing an Ag component, In component, and Se component. The peak wavelength of the emission intensity falls within the range of 700 to 1400 nm, and the half-value width ΔH for the peak wavelength is 100 nm or less. The light emitted is configured to emit strong light in the near-infrared region, and which is capable of detecting biological information, and is preferred for bioimaging.

The present invention relates to a nanocarrier for targeted therapy and/or diagnosis of a prostate cancer cell, the nanocarrier including a micelle including a phosphate surfactant represented by a specific Chemical Formula. The micelle including the phosphate surfactant constituting the nanocarrier for targeted therapy and/or diagnosis of the prostate cancer cell according to the present invention is cleaved by the overexpressed enzyme in the vicinity of the prostate cancer cell, so that therapeutic agent or diagnostic agent particles loaded on the micelle are capable of being selectively released to the prostate cancer cell. Therefore, it is possible to maximize the therapeutic and/or diagnostic effects while remarkably reducing the side effects of the drug in the living body compared to a conventional technology.