The present invention relates to a conjugate for photodynamic diagnosis or treatment in which a peptide binds with a photosensitizer via an intracellularly degradable linkage, and to a composition for photodynamic diagnosis or treatment including the same.

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.

A method of preventing post-operative endophthalmitis involves injecting a colored antibiotic solution into the anterior segment of the eye during surgery, the antibiotic solution having moxifloxacin, cefuroxime, vancomycin, or some combination thereof, and the coloring agent being preferably a cobalamin (e.g., cyanocobalamin).

The object of the present invention is to potentiate the photodynamic effect in ALA-PDT and ALA-PDD. The present invention provides a pharmaceutical related to a combination of ALAs and a dynamin inhibitor.

Oxidase-based sensors and methods of using the sensors are provided.

The present disclosure relates to compositions and methods of killing cells. In particular examples, the method includes contacting a cell having a cell surface protein with a therapeutically effective amount of an antibody-IR700 molecule, wherein the antibody specifically binds to the cell surface protein, such as a tumor-specific antigen on the surface of a tumor cell. The cell is subsequently irradiated, such as at a wavelength of 660 to 740 nm at a dose of at least 1 J cm.sup.2. The cell is also contacted with one or more therapeutic agents (such as an anti-cancer agent), for example about 0 to 8 hours after irradiating the cell, thereby killing the cell. Also provided are methods of imaging cell killing in real time, using fluorescence lifetime imaging. Also provided are wearable devices that include an article of clothing, jewelry, or covering; and an NIR LED incorporated into the article, which can be used with the disclosed methods.

The present disclosure relates to compositions and methods of killing cells in vitro or in vivo. In particular examples, the method includes contacting a cell having a cell surface protein with a therapeutically effective amount of an antibody-IR700 molecule, wherein the antibody specifically binds to the cell surface protein. In particular examples the antibody recognizes a tumor-specific antigen on the surface of a tumor cell. The cell is subsequently irradiated, such as at a wavelength of 660 to 740 nm at a dose of at least 1 J cm.sup.2, thereby killing the cell. Also provided are wearable devices that include an article of clothing, jewelry, or covering; and an NIR LED incorporated into the article, which can be used with the disclosed methods.

The problem to be solved is to provide an anti-human MUC1 antibody Fab fragment that is expected to be useful in the diagnosis and/or treatment of a cancer, particularly, the diagnosis and/or treatment of breast cancer or bladder cancer, and a diagnosis approach and/or a treatment approach using a conjugate comprising the Fab fragment. The solution is an anti-human MUC1 antibody Fab fragment comprising a heavy chain fragment comprising a heavy chain variable region consisting of the amino acid sequence represented by SEQ ID NO: 8 or 10, and a light chain comprising a light chain variable region consisting of the amino acid sequence represented by SEQ ID NO: 12, and a conjugate comprising the Fab fragment.

A tumor treatment method for treating a tumor in a subject, the method includes: a step I of administering a therapeutically effective amount of one or a plurality of antibody-IR 700 molecules to the subject, in which the antibody specifically binds to a cell surface protein of the tumor; a step II of inserting an optical probe into the subject; a step III of applying light having a wavelength in a range from 660 nm to 740 nm from the optical probe, to supply energy of at least 1 J/cm.sup.2 to at least a part of the tumor; a step IV of waiting for a time until an immune response is elicited in the tumor; a step V of inserting an energy device into the subject; and a step VI of resecting tissues of the subject including the tumor using the energy device.

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.