The present invention can provide a method of determining the presence, location, quantity, or a combination thereof, of a biological substance, comprising: (a) exposing a sample to a plurality of targeted nanoparticles, where each targeted nanoparticle comprises a paramagnetic nanoparticle conjugated with one or more targeting agents that preferentially bind with the biological substance, under conditions that facilitate binding of the targeting agent to at least one of the one or more biological substances; (b) subjecting the sample to a magnetic field of sufficient strength to induce magnetization of the nanoparticles; (c) measuring a magnetic field of the sample after decreasing the magnetic field applied in step b below a threshold; (d) determining the presence, location, quantity, or a combination thereof, of the one or more biologic substances from the magnetic field measured in step (c).

A human lung cancer marker N3G4, and use of the same as human lung cancer marker is disclosed. Hybridoma cells which produce anti-N3G4 monoclonal antibodies, and the secreted monoclonal antibody LC128, and use of LC128 for the preparation of a diagnostic agent for lung cancer are also disclosed. Kits for in vitro diagnosis comprising the monoclonal antibody LC128 and methods for detecting tumor markers in lung tissue by using the monoclonal antibody LC128 are also disclosed.

Provided herein are theranostic compositions comprising a Janus nanoparticle-coated microbubble that are useful for imaging (e.g., MRI, or ultrasound) and for delivering a therapeutic or bioactive agent (e.g., nucleic acid(s), drugs, etc), among other uses.

Disclosed herein are nanoconstructs comprising a nanoparticle, coated with additional agents such as cationic polymers, stabilizers, targeting molecules, labels, oligonucleotides and small molecules. These constructs may be used to deliver compounds to treat solid tumors and to diagnose cancer and other diseases. Further disclosed are methods of making such compounds and use of such compounds to treat or diagnose human disease.

This invention relates to conjugate antibody, drug and nanoparticle compositions and methods of generating the same. This invention further relates to methods of using same for imaging, diagnosing or treating a disease.

A biocompatible magnetic material containing an iron oxide nanoparticle and one or more biocompatible polymers, each having formula (I) below, covalently bonded to the iron oxide nanoparticle: ##STR00001##
in which each of variables R, L, x, and y is defined herein, the biocompatible magnetic material contains 4-15% Fe(II) ions relative to the total iron ions. Also disclosed in a method of preparing the biocompatible magnetic material.

The present disclosure describes formulations, methods, and devices tor biomarker sampling and therapeutic delivery using magnetic formulations. When combined with the application of external magnetic fields, magnetic formulations move within the nasal cavity. Magnetic formulations provide benefits including the ability to: target or steer placement of the formulations via a magnetic field, enhance mixing of the formulation via a magnetic field, enhance biological material collection via antibody-coated magnetic beads, or enhance sample retrieval via a magnetic-tipped inserter. Example biological materials for collection include proteins, enzymes, neural stem cells, and other biomarkers.