Alcohol intoxication causes serious diseases, whereas current treatments are mostly supportive and unable to remove alcohol efficiently. Upon alcohol consumption, alcohol is sequentially oxidized to acetaldehyde and acetate by the endogenous alcohol dehydrogenase and aldehyde dehydrogenase, respectively. We disclose a hepatocyte-mimicking antidote for alcohol intoxication through the co-delivery of the nanocapsules of alcohol oxidase (AOx), catalase (CAT), and aldehyde dehydrogenase (ALDH) to the liver, where AOx and CAT catalyze the oxidation of alcohol to acetaldehyde, while ALDH catalyzes the oxidation of acetaldehyde to acetate. Administered to alcohol-intoxicated mice, the antidote rapidly accumulates in the liver and enables a significant reduction of the blood alcohol concentration. Moreover, blood acetaldehyde concentration is maintained at an extremely low level, significantly contributing to liver protection. Such an antidote, which can eliminate alcohol and acetaldehyde simultaneously, holds great promise for the treatment of alcohol intoxication and poisoning.

The present inventions in various aspects provide elastic biodegradable polymers. In various embodiments, the polymers are formed by the reaction of a multifunctional alcohol or ether and a difunctional or higher order acid to form a pre-polymer, which is cross-linked to form the elastic biodegradable polymer. In preferred embodiments, the cross-linking is performed by functionalization of one or more OR groups on the pre-polymer backbone with vinyl, followed by photopolymerization to form the elastic biodegradable polymer composition or material. Preferably, acrylate is used to add one or more vinyls to the backbone of the pre-polymer to form an acrylated pre-polymer. In various embodiments, acrylated pre-polymers are co-polymerized with one or more acrylated co-polymers.

Materials and methods for generating protein-polymer conjugates on solid supports are provided herein. The methods can include, for example, reversibly immobilizing a protein on a solid support, modifying the protein by adding polymer subunits, and releasing the protein-polymer conjugate from the solid support.

Materials and methods for generating protein-polymer conjugates on solid supports are provided herein. The methods can include, for example, reversibly immobilizing a protein on a solid support, modifying the protein by adding polymer subunits, and releasing the protein-polymer conjugate from the solid support.

The purpose of the present invention is to solve conventional problems involving immunoisolation devices using a porous membrane as an immunoisolation membrane, such problems including fibrotic formation on the device surface, shortage of oxygen supplied to cells, and non-uniform distribution of cells. An immunoisolation device for transplantation is characterized by comprising: an immunoisolation membrane; and an oxygen supply mechanism and a three-dimensional cell support which are tightly enclosed inside the immunoisolation membrane by physical sealing, a biocompatible adhesive, or a combination thereof, wherein the immunoisolation membrane is a porous membrane provided with a hydrophilic layer on the outer surface, and the oxygen supply mechanism can supply oxygen to cells supported by the three-dimensional cell support through an oxygen permeable membrane.

The present invention provides a biomolecule conjugate having one or more functionalized biomolecules wherein the biomolecule is functionalized with one or more reactive sites, and at least one polymer capable of undergoing a polymer growth reaction, wherein the polymer is attached to at least one of the reactive sites of the functionalized biomolecule and wherein the polymer envelopes the functionalized biomolecule to form a reversible nanoparticle structure which protects the biomolecule by dynamically collapsing to preserve the biomolecule when an adverse environmental stimulus is present. A method of protecting a biomolecule from environmental conditions is also provided.

The invention relates to an immobilized protein material comprising a protein that is immobilized on a glass material or organic polymer through affinity tag binding. The glass material may be a porous glass material such as (hybrid) controlled porosity glass. The invention also relates to the use of an immobilized enzyme material as a heterogeneous biocatalyst in chemical synthesis. The invention further relates to a method for the immobilization of affinity tagged proteins on a glass material or organic polymer, and to a method for the purification and isolation of affinity tagged proteins by the immobilization of such proteins on a glass material or organic polymer.

The microorganism-containing biocatalysts disclosed have a large population of the microorganisms irreversibly retained in the interior of the biocatalysts. The biocatalysts possess a surprisingly stable population of microorganisms and have an essential absence of debris generation from metabolic activity of the microorganisms. The biocatalysts are composed of highly hydrophilic polymer and have an internal, open, porous structure that promotes community phenotypic changes.

Hydrogel compositions including a polymer uniformly embedded with a loading agent are provided. Also provided are methods for extrusion printing hydrogel compositions to provide extruded hydrogel compositions, which can be crosslinked to provide crosslinked hydrogel structures. Also provided are methods for using crosslinked hydrogel structures in chemical processes.

The invention provides a ligand-bonded fiber in which a ligand having affinity for a cell membrane receptor is immobilized on a fiber precursor, and a cell culture substrate capable of repeating ex vivo amplification of a cell expressing a cell membrane receptor by using the ligand-bonded fiber.