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.

Embodiments of near-infrared light-cleavable heptamethine cyanine-based conjugates, particularly targeting agent-drug conjugates, according to Formula I and conjugate precursors are disclosed. The disclosed targeting agent-drug conjugates are useful for targeted delivery and release of a drug. Methods of making and using the conjugates and precursors also are disclosed. ##STR00001##

Aspects of the disclosure include compositions, devices, systems and methods for optogenetic modulation of action potentials in target cells. The subject devices include light-generating devices, control devices, and delivery devices for delivering light-responsive polypeptides, or nucleic acids encoding same, to target cells. The subject compositions and systems include light-activated polypeptides, nucleic acids comprising nucleotide sequences encoding these polypeptides, as well as expression systems that facilitate expression of these polypeptides in target cells. Also provided are methods of using the subject devices and systems to optogenetically manipulate action potentials in target cells, e.g., to treat a neurological or psychiatric condition in a human or animal subject.

Methods for intravesical administration of a therapeutic agent including application of a photoactive nanogel to the mucosal surfaces of the bladder and/or intravesical application of cell-penetrating peptides. Photoactive nanogels may be aggregated by exposure to ultraviolet light, either in vitro or in vivo, to provide controlled or extended release of a therapeutic agent, such as an antibiotic.

The present invention provides a method of expressing an antigenic molecule or a part thereof on the surface of a cell using a photochemical internalization method in which a cytokine, preferably GM-CSF, is used to enhance the method. The method may be used to stimulate an immune response and for various therapeutic or prophylactic methods. Pharmaceutical compositions or kits comprising the components for use in the method, cells produced by the method and their use in therapy and prophylaxis also form aspects of the invention.

A method for intracellular delivery of single proteins or other cargo molecules by encapsulation within nanocapsules formed by interfacial polymerization of one or more types of monomers and selected protease cleavable cross-linkers is provided. The thin positively charged capsules are readily brought into the cytosol of target cells by endocytosis. The capsules are degraded by the action of endogenous proteases or co-delivered proteases on the cross-linkers releasing the functional cargo unaltered. The cross-linkers can be adapted to be cleavable by specific enzymes selected from available intracellular enzymes within the target cell or co-delivered or self-cleaving when the cargo itself is a protease. The nanocapsules produced by the methods have been shown to have long-term stability, high cell penetration capability, low toxicity and efficient protease-modulated specific degradability without affecting cargo protein function.

Methods, systems, and devices are disclosed for systemic delivery and selective and localized activation of nanoparticles containing an agent in an inactive form or a prodrug in a subject.

Disclosed herein are novel synthetic polypeptides and uses thereof in the preparation of liposomes. According to embodiments of the present disclosure, the synthetic polypeptide comprises a membrane lytic motif, a masking motif, and a linker configured to link the membrane lytic motif and the masking motif. The linker is cleavable by a stimulus, such as, light, protease, or phosphatase. Once being coupled to a liposome, the exposure to the stimulus cleaves the linker that results in the separation of the masking motif from the membrane lytic motif, which in turn exerts membrane lytic activity on the liposome that leads to the collapse of the intact structure of the liposome, and releases the agent encapsulated in the liposome to the target site. Also disclosed herein are methods of diagnosing or treating a disease in a subject by use of the present liposomes.

The syntheses of two phosphoramidite building blocks based on BNSF and BNSMB structures are disclosed. Furthermore, some common molecular intermediates have been designed and linked to the central biphenyl core of the two molecules, resulting in a versatile and cost-effective design. These compounds can be effectively introduced to DNA oligonucleotides via the well-established standard cyanoethylphosphoramidite chemistry on the nucleic acid synthesizer. Fragmentation of these BNSF- and BNSMB-functionalized DNA strands is achieved by both one-photon and two-photon photolysis of photoliable bonds of [2-(2-nitrophenyl)propoxy]carbonyl groups on BNSF and BNSMB molecules respectively, resulting in two short pieces of single-stranded DNAs. The versatile design and facile synthesis of these two-photon photocleavage phosphoramidite molecules are beneficial to synthetic chemists and photochemists for the development of new caged compounds which enables to introduce into oligonucleotides as light-triggered carriers via solid-phase synthesis for a wide range of applications in materials science, polymer, chemistry, biology and DNA nanoecthnology.

The present invention refers to a method for treating visual deficits comprising at least one step of injecting in the eye of a subject in need thereof a therapeutically effective amount of photoactive nanoparticles (NPs) or a composition comprising said photoactive nanoparticles (NPs).