Abstract: A pH-modulating poly(glycerol sebacate) composition includes poly(glycerol sebacate) and at least one pH-modulating agent associated with the poly(glycerol sebacate). A process of making a pH-modulating poly(glycerol sebacate) composition includes forming a poly(glycerol sebacate) by a water-mediated reaction from glycerol and sebacic acid and associating at least one pH-modulating agent with the poly(glycerol sebacate). A process of modulating a pH of a buffered aqueous solution includes placing a pH-modulating poly(glycerol sebacate) composition in a buffered aqueous solution. The pH-modulating agent is released into the buffered aqueous solution during degradation of the poly(glycerol sebacate) to reduce a decrease in pH of the buffered aqueous solution caused by degradation of the poly(glycerol sebacate).

Abstract: In some embodiments, a polymer film includes a base composition of poly(ethylene-vinyl acetate) and a surface composition comprising hydroxy groups. In some embodiments, a polymer film includes a base layer of a first composition of poly(ethylene-vinyl acetate), a surface layer at a surface of the base layer, and a coating layer of a second composition of a copolymer of glycerol and sebacic acid. The surface layer includes surface hydroxy groups converted from acetate groups of the poly(ethylene-vinyl acetate). The second composition is attached to the surface layer by ester bonds between carboxyl groups of the copolymer and the hydroxy groups. A single-use bioreactor bag includes a polymer film including a base composition of poly(ethylene-vinyl acetate) and a surface composition comprising hydroxy groups. A method of modifying a poly(ethylene-vinyl acetate) film includes converting acetate groups at a first surface of the poly(ethylene-vinyl acetate) film to hydroxy groups.

Abstract: A water-mediated process prepares a polymeric (meth)acrylation composition. In some embodiments, the process includes providing a stabilized aqueous solution including a (meth)acrylation component and a polyol monomer in a vessel under an inert atmosphere and adding a diacid monomer to the vessel under the inert atmosphere. In some embodiments, the process includes providing a stabilized aqueous solution including a (meth)acrylation component and a copolymer of a polyol monomer and a diacid monomer in a vessel under an inert atmosphere. The process further includes heating and removing water from the vessel under the inert atmosphere to produce the polymeric (meth)acrylation composition. The polymeric (meth)acrylation composition includes a (meth)acrylation polyester copolymer of the diacid monomer and the polyol monomer with the (meth)acrylation component conjugated to the (meth)acrylation polyester copolymer.

Abstract: In some embodiments, a polymer film includes a base composition of poly(ethylene-vinyl acetate) and a surface composition comprising hydroxy groups. In some embodiments, a polymer film includes a base layer of a first composition of poly(ethylene-vinyl acetate), a surface layer at a surface of the base layer, and a coating layer of a second composition of a copolymer of glycerol and sebacic acid. The surface layer includes surface hydroxy groups converted from acetate groups of the poly(ethylene-vinyl acetate). The second composition is attached to the surface layer by ester bonds between carboxyl groups of the copolymer and the hydroxy groups. A single-use bioreactor bag includes a polymer film including a base composition of poly(ethylene-vinyl acetate) and a surface composition comprising hydroxy groups. A method of modifying a poly(ethylene-vinyl acetate) film includes converting acetate groups at a first surface of the poly(ethylene-vinyl acetate) film to hydroxy groups.

Abstract: A water-mediated process prepares a polymeric (meth)acrylation composition. In some embodiments, the process includes providing a stabilized aqueous solution including a (meth)acrylation component and a polyol monomer in a vessel under an inert atmosphere and adding a diacid monomer to the vessel under the inert atmosphere. In some embodiments, the process includes providing a stabilized aqueous solution including a (meth)acrylation component and a copolymer of a polyol monomer and a diacid monomer in a vessel under an inert atmosphere. The process further includes heating and removing water from the vessel under the inert atmosphere to produce the polymeric (meth)acrylation composition. The polymeric (meth)acrylation composition includes a (meth)acrylation polyester copolymer of the diacid monomer and the polyol monomer with the (meth)acrylation component conjugated to the (meth)acrylation polyester copolymer.

Abstract: A polymeric delivery system delivers a biologic to cells. In some embodiments, the polymeric delivery system includes polyplexes. Each polyplex includes at least one charged polymer and at least one biologic. The at least one charged polymer includes a polyester copolymer of a polyol and a polycarboxylic acid modified with at least one charged moiety having an opposite charge from a net charge of the at least one biologic. In other embodiments, the polymeric delivery system includes self-assembled particles including a block copolymer and a biologic associated with the block copolymer. The block copolymer includes a first block of a polyester copolymer of a polyol and a polycarboxylic acid and a second block of a second monomer or a second polymer.

Abstract: A polymeric delivery system delivers a biologic to cells. In some embodiments, the polymeric delivery system includes polyplexes. Each polyplex includes at least one charged polymer and at least one biologic. The at least one charged polymer includes a polyester copolymer of a polyol and a polycarboxylic acid modified with at least one charged moiety having an opposite charge from a net charge of the at least one biologic. In other embodiments, the polymeric delivery system includes self-assembled particles including a block copolymer and a biologic associated with the block copolymer. The block copolymer includes a first block of a polyester copolymer of a polyol and a polycarboxylic acid and a second block of a second monomer or a second polymer.

Abstract: The present invention relates to the field of biomedical technology, and relates to a composite membrane comprising a decellularized amniotic membrane, a use of the composite membrane, and a method for preparing the composite membrane.

Abstract: A method of forming cured microparticles includes providing a poly(glycerol sebacate) resin in an uncured state. The method also includes forming the composition into a plurality of uncured microparticles and curing the uncured microparticles to form the plurality of cured microparticles. The uncured microparticles are free of a photo-induced crosslinker. A method of forming a scaffold includes providing microparticles including poly(glycerol sebacate) in a three-dimensional arrangement. The method also includes stimulating the microparticles in the three-dimensional arrangement to sinter the microparticles, thereby forming the scaffold having a plurality of pores. A scaffold is formed of a plurality of microparticles including a poly(glycerol sebacate) thermoset resin in a three-dimensional arrangement. The scaffold has a plurality of pores.

Abstract: A cryopreservation process includes combining a cryopreservation composition with a biological sample. The cryopreservation composition includes at least one glycerol ester component. The cryopreservation process also includes then cooling the cryopreservation composition with the biological sample to a cryopreservation temperature. The cryopreservation composition aids in cryopreserving the biological sample at the cryopreservation temperature. A cryopreservation composition includes at least one glycerol ester component. A cryopreserved system includes a biological sample in a cryopreservation composition at a cryopreservation temperature. The cryopreservation composition includes at least one glycerol ester component.

Abstract: A manufacturing process includes combining a liquid resin with a liquid reactive cross-linking composition to form a reactive core composition. The manufacturing also includes contacting the reactive core composition with a sheath composition including a carrier polymer in a solvent. The manufacturing process further includes wet spinning the reactive core composition with the sheath composition to form a sheath-core fiber including a core including at least one continuous fiber of a reaction product of the liquid resin and liquid cross-linking composition and a sheath surrounding the core. The cross-linking composition reacts with the resin during the wet spinning. The sheath includes the carrier polymer. A continuous poly(glycerol sebacate) urethane (PGSU) fiber comprising PGSU and a continuous PGSU fiber forming system are also disclosed.

Abstract: A cell selection and sorting process includes attaching cells of a target cell type to a first set of polymeric beads, washing the chamber through a first filter having a first pore size less than the first bead diameter to retain the first set of polymeric beads and greater than a cell diameter to remove unattached cells, releasing the cells of the target cell type from the first set of polymeric beads, and collecting the cells of the target cell type. A cell modification process includes modifying cells of the target cell type in the chamber. A cell modification system includes a cell modification chamber with entry ports and outlet ports, filters with predetermined pore sized selectably located on the outlet ports, and sets of polymeric beads with predetermined diameters being selected such that the sets of polymeric beads are separable by the filters.

Abstract: A pH-modulating poly(glycerol sebacate) composition includes poly(glycerol sebacate) and at least one pH-modulating agent associated with the poly(glycerol sebacate). A process of making a pH-modulating poly(glycerol sebacate) composition includes forming a poly(glycerol sebacate) by a water-mediated reaction from glycerol and sebacic acid and associating at least one pH-modulating agent with the poly(glycerol sebacate). A process of modulating a pH of a buffered aqueous solution includes placing a pH-modulating poly(glycerol sebacate) composition in a buffered aqueous solution. The pH-modulating agent is released into the buffered aqueous solution during degradation of the poly(glycerol sebacate) to reduce a decrease in pH of the buffered aqueous solution caused by degradation of the poly(glycerol sebacate).

Abstract: In some embodiments, a polymer film includes a base composition of poly(ethylene-vinyl acetate) and a surface composition comprising hydroxy groups. In some embodiments, a polymer film includes a base layer of a first composition of poly(ethylene-vinyl acetate), a surface layer at a surface of the base layer, and a coating layer of a second composition of a copolymer of glycerol and sebacic acid. The surface layer includes surface hydroxy groups converted from acetate groups of the poly(ethylene-vinyl acetate). The second composition is attached to the surface layer by ester bonds between carboxyl groups of the copolymer and the hydroxy groups. A single-use bioreactor bag includes a polymer film including a base composition of poly(ethylene-vinyl acetate) and a surface composition comprising hydroxy groups. A method of modifying a poly(ethylene-vinyl acetate) film includes converting acetate groups at a first surface of the poly(ethylene-vinyl acetate) film to hydroxy groups.

Abstract: A water-mediated process prepares a polymeric (meth)acrylation composition. In some embodiments, the process includes providing a stabilized aqueous solution including a (meth)acrylation component and a polyol monomer in a vessel under an inert atmosphere and adding a diacid monomer to the vessel under the inert atmosphere. In some embodiments, the process includes providing a stabilized aqueous solution including a (meth)acrylation component and a copolymer of a polyol monomer and a diacid monomer in a vessel under an inert atmosphere. The process further includes heating and removing water from the vessel under the inert atmosphere to produce the polymeric (meth)acrylation composition. The polymeric (meth)acrylation composition includes a (meth)acrylation polyester copolymer of the diacid monomer and the polyol monomer with the (meth)acrylation component conjugated to the (meth)acrylation polyester copolymer.

Abstract: A pH-modulating poly(glycerol sebacate) composition includes poly(glycerol sebacate) and at least one pH-modulating agent associated with the poly(glycerol sebacate). A process of making a pH-modulating poly(glycerol sebacate) composition includes forming a poly(glycerol sebacate) by a water-mediated reaction from glycerol and sebacic acid and associating at least one pH-modulating agent with the poly(glycerol sebacate). A process of modulating a pH of a buffered aqueous solution includes placing a pH-modulating poly(glycerol sebacate) composition in a buffered aqueous solution. The pH-modulating agent is released into the buffered aqueous solution during degradation of the poly(glycerol sebacate) to reduce a decrease in pH of the buffered aqueous solution caused by degradation of the poly(glycerol sebacate).

Abstract: A modular flow-through cartridge bioreactor system includes a plurality of modular flow-through cartridges. Each modular flow-through cartridge includes a cartridge housing with ports for through flow of a biological media and predetermined contents preloaded in the cartridge housing permitting the cartridge to perform at least one predetermined function of the bioreactor process upon through-flow of the biological media. The modular flow-through cartridge bioreactor system also includes at least one interlock connector fluidly connecting the plurality of modular flow-through cartridges by the ports. A modular flow through cartridge includes rows of porous textiles preloaded in the cartridge housing. A process includes selecting a plurality of modular flow-through cartridges to perform, in combination, a bioreactor process. The process also includes fluidly connecting the modular flow-through cartridges in a fluid sequence to form the modular flow-through cartridge bioreactor system.

Abstract: A bone filling composition includes a bone filler. The bone filler includes microparticles of at least one elastomeric material. The at least one elastomeric material includes a poly(glycerol sebacate)-based thermoset. The poly(glycerol sebacate)-based thermoset may be porous thermoset poly(glycerol sebacate) flour, thermoset poly(glycerol sebacate) microspheres, or a combination thereof. In some embodiments, the bone filling composition is a bone filling composite that further includes a carrier material including a poly(glycerol sebacate) resin. A method of forming a bone filling composite includes selecting a bone filler and mixing the bone filler with a carrier material to form the bone filling composite. A method of treating a bony defect includes molding a bone filling composite and placing the bone filling composite in the bony defect. The bone filling composite includes a bone filler mixed with a carrier material.

Abstract: A bone filling composition includes a bone filler. The bone filler includes microparticles of at least one elastomeric material. The at least one elastomeric material includes a poly(glycerol sebacate)-based thermoset. The poly(glycerol sebacate)-based thermoset may be porous thermoset poly(glycerol sebacate) flour, thermoset poly(glycerol sebacate) microspheres, or a combination thereof. In some embodiments, the bone filling composition is a bone filling composite that further includes a carrier material including a poly(glycerol sebacate) resin. A method of forming a bone filling composite includes selecting a bone filler and mixing the bone filler with a carrier material to form the bone filling composite. A method of treating a bony defect includes molding a bone filling composite and placing the bone filling composite in the bony defect. The bone filling composite includes a bone filler mixed with a carrier material.

Abstract: A process of forming a coated textile includes culturing human cells on a fiber of a textile such that the human cells produce and deposit human extracellular matrix (hECM) on the textile. The process also includes removing the human cells from the hECM to provide the coated textile of the textile and a coating comprising a residual of the hECM produced and deposited by the human cells on the textile during the culturing. A coated textile includes a textile and a coating on the textile. The coating includes hECM in a cell-deposited state in the coating. A solid-state bioreactor composition includes a poly(glycerol sebacate) (PGS) adduct. The PGS adduct includes PGS and a promoting factor or a promoting factor precursor. Another method includes implanting a coated textile in a human. The coated textile is an autograft. The coating includes hECM deposited by human cells from the human.