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.

Methods for evaluating micrometastases in a tissue region of a subject are described. The methods include administering to the subject a detectably effective amount of a tumor-targeted photoactivatable immunoconjugate; allowing a sufficient amount of time for the tumor-targeted photoactivatable immunoconjugate to enter micrometastases in the tissue region; illuminating the tumor-targeted photoactivatable immunoconjugate; obtaining an image of the tissue region of the subject using a fluorescent imaging device, and evaluating the micrometastases in the tissue region by conducting algorithmic analysis of the image. Methods of treating micrometastases in a tissue region of a subject are also described.

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

The present invention provides a compound of formula (I): A-B-C (I), wherein A is a hydrophobic moiety; B is a peptide, wherein the peptide forms a beta-sheet; and C is a hydrophilic targeting ligand, wherein the hydrophilic targeting ligand is a LLP2A prodrug, LLP2A, LXY30, LXW64, DUPA, folate, a LHRH peptide, a HER2 ligand, an EGFR ligand, or a toll-like receptor agonist CpG oligonucleotides. The present invention also provides nanocarriers comprising compounds of the present invention, nanofibril formation from the nanocarriers, and methods of using the nanocarriers for treating diseases and imaging.

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.

Described herein are polymeric compounds including an acceptor dye and donor luminophore, a polymer, and optionally a bioconjugate group. A polymeric compound of the present invention may have a structure represented by: A-B-C or C-A-B, wherein A is an acceptor dye; B is a polymer comprising one or more hydrophobic unit(s) and one or more hydrophilic unit(s); and optionally C, wherein C, when present, comprises a bioconjugate group, wherein one or more donor luminophore(s) are each separately attached to a portion of the polymer and/or to a portion of the acceptor dye. Also described herein are compositions comprising the polymeric compounds and methods of preparing and using the same.

The present disclosure provides a non-peripheral quaternary ammonium-modified zinc phthalocyanine and a preparation method and use thereof, belonging to the field of preparation of photodynamic drugs or photosensitizers. The non-peripheral quaternary ammonium-modified zinc phthalocyanine can be used as a photosensitizer for a photodynamic therapy (PDT) and photodynamic diagnosis, and can also be used for a photodynamic-immune synergistic therapy. Due to a unique structure, the non-peripheral quaternary ammonium-modified zinc phthalocyanine can be combined with an immune checkpoint blocker to achieve an excellent synergistic anti-tumor effect, which has a significant prospect for use in treating a metastatic tumor.

It is disclosed an improved transdermal sunscreen composition including porphyrin, porphyrin analogues and/or porphyrin precursors (particularly 5-aminolevulinic acid, ALA) in a sub-therapeutic dose in combination with vitamin D3 or its analogues/derivatives in a transdermal carrier or carrier system to generate biomedical effects on reducing photodamaged skin conditions, inducing skin rejuvenation and compensating vitamin D3 for sunscreen-mediated vitamin D3 reduction/deficiency while simultaneously blocking harmful UV radiation from reaching and harming DNA in the cells of the skin.

A self-assembled nanostructure including an amphiphilic chitosan and a contrast agent compound is provided. The contrast agent compound is grafted to the amphiphilic chitosan. The chemical bonding between the amphiphilic chitosan and the contrast agent compound has a synergistic effect to further improve the contrasting ability of the contrast agent compound.

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.