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.

Disclosed herein are conjugates including a fatty acid, a self-assembly domain, and a polypeptide having phase transition behavior. Further disclosed are methods of using the conjugates to treat disease, methods of delivering an agent, and methods of preparing the conjugates.

[Problem] To provide: an actually effective therapeutic method which is for dementia of Alzheimer's disease, and which is a causal treatment rather than a symptomatic treatment; and a therapeutic substance for dementia of Alzheimer's disease. [Solution] This substance alleviates symptoms such as dementia of Alzheimer's disease by overexpressing a microtubule-associated protein 1B gene in intracerebral neurons. In addition, as methods to solve the problem above, there are mainly two methods: a method for intracerebral administration of a gene therapy vector bound to a microtubule-associated protein 1B gene; and a method for binding a microtubule-associated protein 1B gene to a blood-brain barrier (BBB) permeable nanomachine and administering intravascularly.

The present technology relates generally to oligolactic acid conjugates of paclitaxel, rapamycin, selumetinib, and other anticancer agents, micelle compositions containing such conjugates and methods of preparing and using such compositions to treat various cancers. Specifically, there are provided oligolactic acid conjugates wherein the oligolactic acid comprises 2 to 24 lactic acid subunits and is attached through an ester linkage to the oxygen of the 7-hydroxyl of the paclitaxel or paclitaxel derivative, the 40-hydroxyl of the rapamycin or rapamycin derivative, and the 2′-hydroxyl of the selumetinib or selumetinib derivative. Compositions comprising water and a micelle comprising a polylactic acid-containing polymer and the oligolactic acid conjugate may be readily prepared. Methods of inhibiting or killing cancer cells and treating paclitaxel, rapamycin, and/or selumetinib cancers are also provided.

The present invention discloses a multifunctional DNA-templated micelle system that has a payload carrier of at least a DNA bridge and a functionalized polyethylene glycol (PEG) segment. The micelle can be used to deliver molecules, such as drugs and polynucleotides, to targeted cells for pharmaceutical uses. The PEG segment provides a functional group, such as amine, for ligand conjugation. The DNA-templated micelle of the present invention is highly controllable in size, loading efficiency and tissue targeting, and can carry multiple payloads for targeted combination strategies in cancer therapy, such as gene delivery, gene therapy, and immunotherapy.

There is provided a nanocomplex having a core-shell structure. The shell of the nanocomplex comprises a functionalized hyaluronic acid while the core of the nanocomplex comprises a flavonoid encapsulating a metal-containing compound. Preferably, the flavonoid is epigallocatechin gallate (EGCG) and the hyaluronic acid is thiol-functionalized and subsequently conjugated to the flavonoid. There is also provided a method of forming the nanocomplex, a pharmaceutical composition comprising the nanocomplex, medical uses of the nanocomplex and a method of treating a patient, preferably with cancer using the nanocomplex.

A process for producing a peptide antigen conjugate suitable for administration to a mammal is disclosed. The peptide antigen conjugate comprises a peptide antigen linked to a hydrophobic block. The process comprises reacting a hydrophobic block fragment with a peptide antigen fragment comprising the peptide antigen in a pharmaceutically acceptable organic solvent in a hydrophobic block fragment to peptide antigen fragment molar ratio of 1:1 or greater under conditions to directly or indirectly link the peptide antigen to the hydrophobic block and obtaining a product solution comprising the peptide antigen conjugate, unreacted hydrophobic block fragment and pharmaceutically acceptable organic solvent.

The present technology relates generally to oligolactic acid conjugates and stereocomplexes of conjugates of gemcitabine and gemcitabine derivatives, micelle compositions containing such conjugates or stereocomplexes of conjugates, and methods of preparing and using such compositions to treat various cancers. The oligolactic acid conjugates and stereocomplexes of conjugates may include oligolactic acid comprising 2 to 20 lactic acid subunits and may be attached through an amide linkage to the nitrogen of the 4(N) of the gemcitabine or gemcitabine derivative. Compositions comprising water and a micelle comprising a polylactic acid-containing polymer and the oligolactic acid conjugate or stereocomplex of conjugates may be readily prepared. Methods of inhibiting or killing cancer cells and treating gemcitabine sensitive cancers are also provided.

Provide is a method of using a topoisomerase I inhibitor in treatment of cancer to reduce bone marrow suppression. The method includes administering to a subject in need thereof an effective amount of a pharmaceutical composition. The composition has at least one hydrophobic topoisomerase I inhibitor or a pharmaceutically acceptable salt thereof, and at least one polyethylene glycol (PEG) conjugated phospholipid, wherein the molar ratio of said PEG conjugated phospholipid to said hydrophobic topoisomerase I inhibitor or said pharmaceutically acceptable salt of said hydrophobic topoisomerase I inhibitor is about 0.45:1 to about 1.05:1.

The present invention encompasses prodrug compositions, nanoparticles comprising one or more prodrugs, and methods of use thereof.