The present invention relates to a protein which binds to the domain encoded by exon 9 of human CD44 (CD44ex9), to fusion proteins and conjugates of said protein and especially to nanoparticles conjugated to said protein. The invention further relates to a method of production for the protein and the respective conjugated nanoparticles and the use of the protein of the invention for treatment and diagnosis of cancer diseases.

Compositions are provided comprising water-stable semi-conductor nanoplatelets encapsulated in a hydrophilic coating further comprising lipids and lipoproteins. Uses include biomolecular imaging and sensing, and methods of making comprise: colloidal synthesis of CdSe core NPLs; layer-by-layer growth of a CdS shell; and encapsulation of CdSe/CdScore/shell NPLs in lipid and lipoprotein components through an evaporation-encapsulation using zwitterionic phospholipids, detergents, and amphipathic membrane scaffold proteins.

Described herein is a multiplex platform that uses ultrasmall nanoparticles (e.g., C dots and C dots) to graphically differentiate specific nerves (e.g., sensory nerves vs. motor nerves) for nerve transplants and other surgeries. Also described herein is a multiplex platform that uses ultrasmall nanoparticles (e.g., C dots and C dots) to graphically differentiate between different types of lymph nodes and/or lymphatic pathways, e.g., to safely and effectively perform vascularized lymph node transplantation in the treatment of lymphedema. Also described herein is a multiplex platform that uses ultrasmall nanoparticles (e.g., C dots and C dots) to graphically differentiate parathyroid tissue.

The present invention is directed to sulfonic esters of metal oxides including those of formulas I and II: ##STR00001##

A 5-aminolevulinic acid conjugated quantum dot nanoparticle is useful for treating cancer by administering the 5-aminolevulinic acid conjugated quantum dot nanoparticle in photodynamic therapy as a precursor of both a fluorescence label and a photosensitizer.

Certain disclosed embodiments of the present invention concern the synthesis, derivatization, conjugation to immunoglobulins and signal amplification based on discrete, relatively short polymers having plural reactive functional groups that react with plural molecules of interest. Reactive functional groups, such as hydrazides, may be derivatized with a variety of detectable labels, particularly haptens. The remaining reactive functional groups may be conjugated directly to a specific binding molecule, such as to the oxidized carbohydrate of the Fc region of the antibody. Disclosed conjugates display large signal amplification as compared to those based on molecules derivatized with single haptens, and are useful for assay methods, particularly multiplexed assays.

Nanoclusters comprising inorganic nanocrystals and a biodegradable polymer are disclosed. The inorganic nanocrystals have a mean particle size of 1 to 500 nm. The inorganic nanocrystals are contained within a core of the nanoclusters, on the surface of the nanoclusters, contained within a core of the nanoclusters, dispersed throughout the nanoclusters, or a combination thereof. The biodegradable polymer allows the inorganic nanocrystals to be excreted renally over a period of time. The nanoclusters can be used for medical imaging or other biomedical applications.

A near-infrared fluorescent quantum dot for achieving rapid renal clearance, and a preparation method and application thereof are provided. The preparation method includes the following steps: carrying out a solvothermal reaction on a first uniformly mixed reaction system including a first probe of a near-infrared fluorescent quantum dot and a weakly polar solvent to prepare a second probe of the near-infrared fluorescent quantum dot with a particle size of less than 5 nm; and then mixing the second probe of near-infrared fluorescent quantum dot with a hydrophilic ligand to form a second uniformly mixed reaction system for a ligand exchange reaction, thus obtaining a near-infrared fluorescent quantum dot for achieving rapid renal clearance, which has a fluorescence emission wavelength ranging from 700 nm to 1700 nm. The near-infrared fluorescent quantum dot for achieving renal clearance is obtained through a simple solvothermal reaction and a subsequent ligand exchange method.

The present disclosure relates to methods of administering fluorescent particles to animal and for measuring the location of the fluorescent particles within an animal over time.