The present invention relates to a novel compound for preventing or treating neurodegenerative diseases and use thereof. Provided is a novel compound of Formula (I). The compound can effectively promotes the proliferation of neural progenitor cells in both in vitro and in vivo experiments, and can serves as a treatment approach to promote nerve regeneration to fight against cognition impairment associated with aging and neurodegenerative diseases.

The present invention relates to a novel compound for preventing or treating neurodegenerative diseases and use thereof. Provided is a novel compound of Formula (I). The compound can effectively promotes the proliferation of neural progenitor cells in both in vitro and in vivo experiments, and can serves as a treatment approach to promote nerve regeneration to fight against cognition impairment associated with aging and neurodegenerative diseases.

The present invention relates to a vitamin E-based amphipathic compound, a method for producing same, and a method for extracting, solubilizing, stabilizing, or crystallizing a membrane protein using same. By using a compound according to the present invention, not only is an excellent membrane protein extraction and solubilization effect achieved, but the membrane protein can be stably stored for a long period of time in an aqueous solution, and thus the compound can be utilized in analyzing the function and structure of the membrane protein. Moreover, the vitamin E-based amphipathic compounds exhibited superb properties in the visualization of protein compounds through an electron microscope. Membrane protein structure and function analysis is one of the fields of greatest interest in biology and chemistry today, and since at least half of new drugs currently being developed target membrane proteins, the vitamin E-based amphipathic compounds may be applied to the membrane protein structure research, which is closely related to the development of new drugs.

The invention provides lipid A mimics in which one or both of the sugar residues of a natural lipid A disaccharide backbone has been replaced with an aromatic group. These lipid A mimics may further differ from a natural lipid A molecule with respect to other structural characteristics, such as, a different number of phosphate groups present, changes in the number, structure and location of lipid chains and/or changes in the spacing and linkage of the sugar residues (or their aromatic replacements). The lipid A mimics may be lipid A agonists and as such may be useful as immunostimulatory agents in inducing or patenting an antibody and/or cell-mediated immune response, or may be lipid A antagonists and as such may be useful in treating or preventing a lipopolysaccharide (LPS)/lipid A-mediated disease or disorder. Also provided are methods for preparing the lipid A mimics.

Disclosed is synthesis of an O-Antigen oligosaccharide compound of Helicobacter pylori serotype O2, belonging to the field of organic synthesis. The disclosure obtains O-antigen disaccharide to tetracosasaccharide of Helicobacter pylori serotype O.sub.2 by chemical synthesis. A chemical synthesis method which is quite conducive to production of a glucose-α-lglucosidic bond is developed in the disclosure by a protectant strategy, temperature effect, solvent effect, and additive effect. The method is applied in synthesis of an O-antigen oligosaccharide compound of Helicobacter pylori serotype O2 assembled with an amino linking arm. A saccharide conjugate can be prepared from the synthesized O-antigen oligosaccharide compound of Helicobacter pylori serotype O2 assembled with an amino linking arm together with a carrier protein for immunology researches, playing an important role in preventing and treating Helicobacter pylori.

Disclosed is synthesis of an O-Antigen oligosaccharide compound of Helicobacter pylori serotype O2, belonging to the field of organic synthesis. The disclosure obtains O-antigen disaccharide to tetracosasaccharide of Helicobacter pylori serotype O.sub.2 by chemical synthesis. A chemical synthesis method which is quite conducive to production of a glucose-α-lglucosidic bond is developed in the disclosure by a protectant strategy, temperature effect, solvent effect, and additive effect. The method is applied in synthesis of an O-antigen oligosaccharide compound of Helicobacter pylori serotype O2 assembled with an amino linking arm. A saccharide conjugate can be prepared from the synthesized O-antigen oligosaccharide compound of Helicobacter pylori serotype O2 assembled with an amino linking arm together with a carrier protein for immunology researches, playing an important role in preventing and treating Helicobacter pylori.

The present invention relates to methods of treating immune disorders and/or inflammation using certain modulator compounds. In one embodiment, the present invention provides a method of treating an immune and inflammatory disorders disorder by administering a composition comprising a therapeutically effective dosage of an ascaroside compound, or a mixture of ascaroside compounds, or a mixture containing at least one ascaroside.

The present invention relates to methods of treating immune disorders and/or inflammation using certain modulator compounds. In one embodiment, the present invention provides a method of treating an immune and inflammatory disorders disorder by administering a composition comprising a therapeutically effective dosage of an ascaroside compound, or a mixture of ascaroside compounds, or a mixture containing at least one ascaroside.

The present disclosure provides linker compounds of Formula (I) or (II): pharmaceutically acceptable salts thereof, and related scaffolds and conjugates. The present disclosure also relates to uses of the linker compounds, scaffolds, and conjugates, e.g., in delivering nucleic acid and/or treating or preventing diseases.

The present inventions provides drug-drug conjugates, drug-porphyrin conjugates, nanoparticles of the conjugates, as well as modified nanoparticles having PEGylated exteriors or encapsulated by red blood cell vesicles. The conjugates, nanoparticles and nanocarriers are useful for treating cancers and other diseases, as well as for imaging diseased tissue or organs.