The present disclosure provides method of making a nanoparticle complex wherein the nanoparticle complex comprises a ligand and a metal cation. The disclosure also provides nanoparticle complexes, methods of treating a disease in a patient utilizing the nanoparticle complexes, methods of identifying a disease in a patient utilizing the nanoparticle complexes, and kits involving the nanoparticle complexes.

The present disclosure is directed to a method of making a composition by combining a vehicle, e.g., a single phase vehicle, and an insoluble component comprising a beneficial agent, and sterilizing the composition using ionizing radiation prior to use, wherein the beneficial agent is stable following exposure to a sterilizing dose of ionizing radiation. Related compositions and methods are provided.

The present disclosure is directed to a method of making a composition by combining a vehicle, e.g., a single phase vehicle, and an insoluble component comprising a beneficial agent, and sterilizing the composition using ionizing radiation prior to use, wherein the beneficial agent is stable following exposure to a sterilizing dose of ionizing radiation. Related compositions and methods are provided.

Compositions and methods for treating cancer in a subject in need thereof are described that includes administering a therapeutically effective amount of an oligonucleotide that specifically hybridizes to MALAT1.

Compositions and methods for treating cancer in a subject in need thereof are described that includes administering a therapeutically effective amount of an oligonucleotide that specifically hybridizes to MALAT1.

This disclosure relates to a drug delivery system comprising a neurotrophic agent, an apoptosis signaling fragment inhibitor (FAS) or FAS-ligand (FASL) inhibitor, a tumor necrosis factor-α (TNF-α) or TNF receptor (TNFR) inhibitor, a mitochondrial peptide, an oligonucleotide, a chemokine inhibitor, or a cysteine-aspartic protease (caspase) inhibitor, including any combination of these compounds and, optionally, a sustained delivery component. This type of drug delivery system can be used to treat a medical condition such as an inherited or age-related choroid, retina, optic nerve disorder, or optic nerve degeneration; an otic disorder; a neurologic or CNS disorder; or a related condition; or a condition related to occlusion or obstruction of a blood vessel or blood circulation such as a stroke, myocardial or renal infarction. Medicaments, methods of manufacturing medicaments, kits, and other related products or methods are also described.

This disclosure relates to a drug delivery system comprising a neurotrophic agent, an apoptosis signaling fragment inhibitor (FAS) or FAS-ligand (FASL) inhibitor, a tumor necrosis factor-α (TNF-α) or TNF receptor (TNFR) inhibitor, a mitochondrial peptide, an oligonucleotide, a chemokine inhibitor, or a cysteine-aspartic protease (caspase) inhibitor, including any combination of these compounds and, optionally, a sustained delivery component. This type of drug delivery system can be used to treat a medical condition such as an inherited or age-related choroid, retina, optic nerve disorder, or optic nerve degeneration; an otic disorder; a neurologic or CNS disorder; or a related condition; or a condition related to occlusion or obstruction of a blood vessel or blood circulation such as a stroke, myocardial or renal infarction. Medicaments, methods of manufacturing medicaments, kits, and other related products or methods are also described.

A bone repair material, a preparation method of the bone repair material, and a biological composite scaffold are provided. The bone repair material includes: a base material, and a carbon nanomaterial and a polypeptide both mixed with the base material; and the carbon nanomaterial and the polypeptide are bonded by chemical bonds. The preparation method includes: bonding a carbon nanomaterial with a polypeptide by chemical bonds; and mixing the carbon nanomaterial and the polypeptide bonded by the chemical bonds with a base material, and performing a molding treatment.

A bone repair material, a preparation method of the bone repair material, and a biological composite scaffold are provided. The bone repair material includes: a base material, and a carbon nanomaterial and a polypeptide both mixed with the base material; and the carbon nanomaterial and the polypeptide are bonded by chemical bonds. The preparation method includes: bonding a carbon nanomaterial with a polypeptide by chemical bonds; and mixing the carbon nanomaterial and the polypeptide bonded by the chemical bonds with a base material, and performing a molding treatment.

Combinations of boron compounds and adjuvants and compositions thereof are suitable for use in a method to induce myotube formation and suppress cell mortality in a mammal in need thereof and for the treatment of epithelial cancers. Compositions comprise boron compounds, adjuvants and support platforms, which enhance the effect of synergistic activation of the boron cell membrane transporter (NaBC1) and adhesion receptors in cells. The combinations and compositions are for the treatment of pathophysiological condition, which affects skeletal muscle, such as dystrophy and epithelial cancer. The combinations and compositions can be included in the field of medical chemistry or pharmacology.