Disclosed herein is a bi-specific antibody that specifically directs a therapeutic agent to a cancer cell by targeting a tumor antigen of the cancer cell, and thereby suppressing the growth of the cancer or blocking the invasion or metastasis of the cancer. The bi-specific antibody of the present disclosure includes a first antigen binding site that binds to polyethylene glycol (PEG); and a second antigen binding site that binds to a target ligand, such as a tumor antigen.

Surface conjugated diamagnetic Chemical Exchange Saturation Transfer (diaCEST) agent carriers and methods of making and using are described herein. The particles are safe alternatives to conventional paramagnetic or superparamagnetic metal-based MRI contrast agents that are often toxic and therefore not biocompatible. The carriers described herein can provide simultaneous monitoring of multiple particle types labeled with multicolor diaCEST contrast agents. In some embodiments, the carriers are micro- and/or nanoparticles. In other embodiments, the carriers are liposomes. In some embodiments, the particles and/or liposomes are mucus penetrating. In other embodiments, the particles and/or liposomes are not mucus penetrating.

A multi-chromophore virus particle is constructed by covalent binding of chromophores and provides super-radiant behavior. A virus-enabled targeted vector is provided for imaging with qualitatively different optical emission properties from state-of-the-art agents. Bright emission is obtained through quantum coherence, which in turn is facilitated by the symmetry of the virus shell. In an exemplary embodiment the targeted vector is used in laser-guided surgery, specifically for the treatment of in brain cancer.

A microsphere and method for forming the same are disclosed. The microsphere includes modified cellulose and at least one of a visualization agent, a magnetic material, or a radioactive material.

The present invention describes an X-ray contrast composition for local administration, wherein the X-ray contrast composition exhibits contrast properties and wherein at least 60% of an administrated amount of said X-ray contrast composition remains more than 24 hours within 10 cm from an injection point when the X-ray contrast composition is administrated to a human or animal body.

Multifunctional cancer targeting nanoparticles include a magnetic central core including gold coated iron oxide, an outer layer including trimethyl chitosan microspheres and folic acid and a linker between the central core and the outer layer, the linker including cysteamine. An anti-cancer drug can be supported by the outer layer. The multifunctional cancer targeting nanoparticle can provide simultaneous cancer cell diagnosis and therapy. An amount of heat and an amount of the anti-cancer drug released by the nanoparticle can be controlled by application of a magnetic field.

Systems, methods and related devices used to produce and collect polarized noble gas to inhibit, suppress, detect or filter alkali metal nanoclusters to preserve or increase a polarization level thereof. The systems can include a pre-sat chamber that has an Area Ratio between 20 and 500.

Systems, methods and related devices used to produce and collect polarized noble gas to inhibit, suppress, detect or filter alkali metal nanoclusters to preserve or increase a polarization level thereof. The systems can include a pre-sat chamber that has an Area Ratio between 20 and 500.

The present invention provides amphiphilic telodendrimers that aggregate to form nanocarriers characterized by a hydrophobic core and a hydrophilic exterior. The nanocarrier core may include amphiphilic functionality such as cholic acid or cholic acid derivatives, and the exterior may include branched or linear poly(ethylene glycol) segments. Nanocarrier cargo such as hydrophobic drugs and other materials may be sequester in the core via non-covalent means or may be covalently bound to the telodendrimer building blocks. Telodendrimer structure may be tailored to alter loading properties, interactions with materials such as biological membranes, and other characteristics.

Mucus-penetrating liposomal nanoparticles and methods of making and using thereof are described herein. The nanoparticles contain one or more lipids, one or more PEG-conjugated lipids, and optionally one or more additional materials that physically and/or chemically stabilize the particles. The nanoparticle have an average diameter of about 100 nm to about 300 nm, preferably from about 100 nm to about 250 nm, more preferably from about 100 nm to about 200 nm. The particles are mobile in mucus. The liposomes can further contain one or more therapeutic, prophylactic, and/or diagnostic agent to be delivered to a mucosal surface, such as the CV tract, the colon, the nose, the lungs, and/or the eyes. The liposomes can further contain one or more CEST agents to allow real time imaging of the particles in a live animal. The particles may also further contain an imaging agent, such as a fluorescent label.