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.

The present invention describes compositions containing cholesterol-linker-glutathione conjugates for targeting the brain by overcoming barrier entry to the CNS through the blood brain barrier (BBB), including micelle and liposome forms of such compositions. In addition, methods for treating subjects by administering such compositions are also disclosed.

Provided are aromatic compounds, phospholipid-polymer-aromatic conjugates comprising the aromatic compounds, and liposome compositions including the phospholipid-polymer-aromatic conjugates. The liposomal compositions may be useful for imaging of Alzheimer's Disease, for example, imaging of the amyloid- plaque deposits characteristic of Alzheimer's Disease.

The disclosed compositions and methods relate to an immunogenic composition that, in certain aspects, comprise cationic liposomes; a mixture of toll like receptor 3 (TLR3) and toll like receptor 9 (TLR9) ligands; and a cellular adhesion agent, and methods of using such compositions. In certain aspects, disclosed compositions are administered to a mammal to induce a non-specific innate immune response at mucosal surfaces. In further aspects, disclosed compositions are administered to a mammal in conjunction with an antigen to enhance the immune response of the mammal to the antigen.

Disclosed is a conjugated polymer-based nanoprobe, including a fluorescent conjugated polymer, a surface ligand, a target molecule, a near-infrared fluorescent dye and optionally a gadolinium-containing magnetic resonance contrast agent. This application also discloses a method for preparing the conjugated polymer-based nanoprobe, including: adding raw materials to an organic solvent followed by ultrasonication to obtain a mixture; and adding the mixture to ultrapure water and continuously ultrasonicating the reaction mixture. The conjugated polymer-based nanoprobe can be applied in a combined molecular imaging technique of near infrared fluorescence imaging, photoacoustic imaging and magnetic resonance imaging to effectively recognize metastatic lymph nodes and normal lymph nodes, and it can be retained in the metastatic lymph nodes for a long time, meeting the requirements for long-term observation. Moreover, the near-infrared fluorescent conjugated polymer-based nanoprobe can generate reactive oxygen under irradiation, which is suitable for the photodynamic treatment of tumors.

The invention discloses a recombinant protein (P-selectin glycoprotein ligand-1 and Neural Retina-specific Leucine Zipper) PSGL-1-NRL chimeric protein comprising a Selectin Binding domain and a non-covalent dimerization domain, which is a leucine zipper and is more preferably the leucine zipper domain of the human or mouse Neural Retina-specific Leucine Zipper. The chimeric protein further comprises a covalent dimerization domain with at least one cysteine suitable to form a disulfide bridge with another chimeric protein to form a homodimer. In the chimeric protein, the PSGL-1 domain corresponds to the extracellular region of Human PSGL-1 and is more preferably the selectin binding region of the mature protein. The chimeric protein is correctly post-translationally modified and is efficiently expressed in a mammalian system. It is sulfated, O-linked glycosylated and sialylated and binds P, E and L selectin, allowing in vivo and in vitro targeting for diagnostic or therapeutic purposes.

A system for reducing toxicity from intravascular triggered drug delivery includes a chamber comprising an inflow port, an outflow port, and a filter positioned upstream of the outflow port. A trigger module is configured to trigger the release of a drug from an intravascular triggered drug delivery system present in blood in the chamber. A method for reducing toxicity from intravascular triggered drug delivery includes the steps of removing blood comprising an intravascular triggered drug delivery system from a patient's vascular system and delivering the blood to a chamber, applying a trigger to the blood to release a drug from the intravascular triggered drug delivery system, filtering the drug from the blood, and returning the filtered blood to the patient.

The application relates to liposomal nanovesicles comprising porphyrin-lipid conjugates within the liposomal lipid bilayer. Said porphyrin-lipid conjugate comprise porphyrins that are modified with a CH(R.sup.1)OR.sup.2 group and that chelate a metal ion. Such modifications of the porphyrin allow for ordered assembly in the lipid bilayer of the nanovesicles while resulting in a bathochromic shift in the wavelength of light absorbed by the porphyrin chromophore. These nanovesicles can be used for photothermal therapy, photodynamic therapy, photoacoustic imaging and fluorescence imaging. The application also teaches methods for preparing the porphyrin-lipid conjugates and the nanovesicles.

A multi-component nanochain for use in diagnostic and therapeutic applications includes at least three nanoparticles linked together to form the nanochain. At least one nanoparticle of the nanochain has an asymmetric surface chemistry defined by asymmetrically disposed first linkers and second linkers. The nanoparticles are linked to form the nanochain by linking first linkers and/or second linkers disposed on separate nanoparticles.

Described herein are compounds, compositions and methods for modification of the surface of a living cell with a therapeutically relevant targeting moiety. Also described herein are methods for treating disease states, such as acute myocardial ischemia or infarction, with said compositions, in a subject.