An implantable device for providing a therapeutic agent includes a container configured to contain multiple cells capable of producing the therapeutic agent within an interior region of the container and a substance capable of reacting to generate oxygen for the multiple cells within the interior region of the container. The container defines first pores defined by an interior wall portion of the container and second pores defined by an exterior wall portion of the container. The first pores have a first average size that (i) allows passage of the therapeutic agent through the first pores and (ii) prevents passage of immune cells through the first pores. The second pores have a second average size that is larger than the first average size, and the second pores are sized to promote vascularization along the exterior wall portion.

The present invention relates to a water-absorbing polymer and to a process for preparation, including finishing the water-absorbing polymer, with 0.0001 to 3% by weight, of a peroxo compound, based on the acrylic acid, after the polymerization is treated, and to a process for producing a hydrogel polymer, to the product of the process and to use.

There is provided a composition comprising covalently linked segments of for example, polycaprolactone and polyethylene glycol that are linked by a cross-linker. Such a composition foams in the presence of a catalyst and a solution containing an oxygen forming chemical like hydrogen peroxide. The foamed composition retains oxygen for delivery to, for example, a wound, where it aids in healing.

Peroxides and chlorine dioxide (compounds) can be stabilized for long periods of time (years) by combining the compounds with water that has been infused with dioxytetrahydride gas. Such stabilized materials can be used to infuse soft, solid substrates that can be used as sterile wipes, wound dressings, or the like.

Disclosed are compositions, materials, garments, devices, and methods for controlling or neutralizing offensive odors associated with mammalian urine. For example, disclosed are personal care products (e.g., diapers), deodorizing colloidal compositions, urine-based fertilizers, portable urination systems, and methods of their use. Such deodorizing colloidal compositions, urine-based fertilizers, portable urination systems are characterized in that they contain an acrylate polymer comprising at least one acrylic acid monomer or salt thereof, which imparts an odor-neutralizing effect. Also provided are methods of recovering water from the systems disclosed herein.

The present disclosure is directed towards an absorbent binder composition that includes a hydrophilic polymer which has the capability of post-application, moisture-induced cross-linking. The absorbent binder composition can include 1) a superabsorbent polymer material which can include at least 15 mass percent monoethylenically unsaturated polymer, such as carboxylic acid, sulphonic acid, or phosphoric acid, or salts thereof, and an acrylate or methacrylate ester that contains an alkoxysilane functionality and 2) a polyvalent metal cation having a valence of at least two. Upon loss of water by evaporation, the alkoxysilane functionality forms a silanol functional group which condenses to form a crosslinked polymer. Upon exposure of the absorbent binder composition to a biological material, such as urine, blood, or feces, the biological material can interact with the polyvalent metal cation and can serve as a catalyst to accelerate the polymer cross-linking and gelation of the polymer.

The present invention provides compositions and methods for reducing microbial and nematodal contamination or infection in plants, animals, fabrics, and products therefrom. The present invention also provides compositions and methods for reducing human infections and the emergence of antimicrobial resistance. In particular, the invention provides magnetic nanoparticles comprising biocidal or biostatic enzymes in one component, substrates for the enzymes in a second component, and a biocidal chemical agent that works in combination or synergistically with the enzymes. The compositions are dormant and become active upon exposure to hydration, oxygen, or mixing.

This invention relates to regenerable antimicrobial coatings with long-lasting efficacy for use in medical applications including implants, medical instruments or devices, and hospital equipment. The same coatings would also have broad utility in the consumer, industrial, and institutional markets. The coating technology would be based on sequestration of hydrogen peroxide (HP) by zinc oxide binders incorporated into the coatings.

The present disclosure is directed to a closed cell foam matrix for delivering oxygen containing a superabsorbent material oxygen entrapped within the superabsorbent material. The superabsorbent material has at least 15 percent by mass monoethylenically unsaturated carboxylic, sulphonic or phosphoric acid or salts thereof, an acrylate or methacrylate ester that contains an alkoxysilane functionality, and a copolymerizable hydrophilic glycol containing ester monomer. To produce the closed cell foam matrix for delivering oxygen, an alkali hydroxide catalyst is added to the superabsorbent material to form a hydrogel layer. Then, an oxygen precursor is added to the hydrogel layer. The hydrogel layer is heated to produce oxygen by reacting the alkali hydroxide catalyst and the oxygen precursor thereby entrapping the oxygen in the formed closed cell foam matrix.

The present disclosure is directed to an absorbent article including a closed cell foam matrix for delivering oxygen. The absorbent article includes a liquid permeable inner surface for facing the wearer, an outer surface for facing away from the wearer, an absorbent assembly disposed therebetween, and a closed-cell foam matrix material applied to a portion of the absorbent article. The closed cell foam matrix contains a superabsorbent material and oxygen entrapped within the superabsorbent material. To produce the closed cell foam matrix for delivering oxygen, an alkali hydroxide catalyst and oxygen precursor are both added to an aqueous superabsorbent material. The aqueous solution is applied to a nonwoven material. The nonwoven material is then heated to produce oxygen by reacting the alkali hydroxide catalyst and the oxygen precursor thereby entrapping the oxygen in the formed closed cell foam matrix.