An adhesive composition comprising silicone adhesives and one or more absorbent fillers such as hydrocolloids is disclosed. The adhesive composition is particularly well suited for use in negative pressure wound therapies.

An adhesive composition comprising silicone adhesives and one or more absorbent fillers such as hydrocolloids is disclosed. The adhesive composition is particularly well suited for use in negative pressure wound therapies.

The subject matter of the invention is an autopolymerisable 2-component prosthetic base material, a kit containing the material as well as a method for its production comprising at least one liquid monomer component (A), and at least one powdered component (B), wherein the prosthetic material in component (A) besides methylmethacrylate contains at least one N-alkyl-substituted acryloyloxy carbamate having a molecular mass of less than or equal to 250 g/mol, optionally at least one at least di-functional urethane (meth)acrylate, a di-, tri-, tetra- or multi-functional monomer not being urethane (meth)acrylate, and optionally polymeric particles having a primary particle size of less than 800 nm, and the powdered component (B) comprises polymeric particles having at least three different particle size fractions, and both (A) and (B) contains at least one initiator or at least one component of an initiator system for autopolymerisation.

A system for performing a minimally invasive percutaneous procedure comprises a medical device comprising a hydrogel delivery needle (4) with a tip and a hydrogel outlet (6), an injectable, shear-thinning, self-healing viscoelastic hydrogel that exhibits a storage modulus (G′) of at least 600 Pa, and a tan δ (G"/G′) from 0.1 to 0.6 in dynamic viscoelasticity measured by a rheometer at 1 Hz and 1% strain rate at 25° C. The system may also comprise a coaxial cannula (2) having a lumen configured for receipt of the hydrogel delivery needle (4), wherein the hydrogel delivery needle comprises an adjustable positioning mechanism (8) configured to limit the advancement depth of the hydrogel delivery needle through the coaxial cannula to a predetermined depth distal to a distal-most end of the coaxial cannula.

A system for performing a minimally invasive percutaneous procedure comprises a medical device comprising a hydrogel delivery needle (4) with a tip and a hydrogel outlet (6), an injectable, shear-thinning, self-healing viscoelastic hydrogel that exhibits a storage modulus (G′) of at least 600 Pa, and a tan δ (G"/G′) from 0.1 to 0.6 in dynamic viscoelasticity measured by a rheometer at 1 Hz and 1% strain rate at 25° C. The system may also comprise a coaxial cannula (2) having a lumen configured for receipt of the hydrogel delivery needle (4), wherein the hydrogel delivery needle comprises an adjustable positioning mechanism (8) configured to limit the advancement depth of the hydrogel delivery needle through the coaxial cannula to a predetermined depth distal to a distal-most end of the coaxial cannula.

The present invention provides a hemostatic porous composite sponge comprising i) a matrix of a biomaterial; and ii) one hydrophilic polymeric component comprising reactive groups wherein i) and ii) are associated with each other so that the reactivity of the polymeric component is retained, wherein associated means that said polymeric component is coated onto a surface of said matrix of a biomaterial, or said matrix is impregnated with said polymeric material, or both.

A hydrogel-based biological delivery vehicle used to effectively deliver drug and biological material to tissue or organ sites. More specifically, a hydrogel binding matrix having a biopolymer backbone containing carboxyl groups. Tyramine may be substituted for at least a portion of the carboxyl groups, so that, when hydrogen peroxide is added, it causes creation of covalent bonds between tyramine molecules and cross-links the hydrogel binding matrix, thereby enabling the hydrogel binding matrix to transition from liquid to gel state. The hydrogel binding matrix, in its liquid form, is capable of encapsulating drug reservoirs to create a homogenous liquid with evenly distributed particles containing drugs or target molecules. As the hydrogel binding matrix solidifies into a gel state, the newly created cross-links do not disrupt or react with the drugs or target molecules contained within the drug reservoirs. This hydrogel-based biological delivery vehicle can be used in several medical applications.

A hydrogel-based biological delivery vehicle used to effectively deliver drug and biological material to tissue or organ sites. More specifically, a hydrogel binding matrix having a biopolymer backbone containing carboxyl groups. Tyramine may be substituted for at least a portion of the carboxyl groups, so that, when hydrogen peroxide is added, it causes creation of covalent bonds between tyramine molecules and cross-links the hydrogel binding matrix, thereby enabling the hydrogel binding matrix to transition from liquid to gel state. The hydrogel binding matrix, in its liquid form, is capable of encapsulating drug reservoirs to create a homogenous liquid with evenly distributed particles containing drugs or target molecules. As the hydrogel binding matrix solidifies into a gel state, the newly created cross-links do not disrupt or react with the drugs or target molecules contained within the drug reservoirs. This hydrogel-based biological delivery vehicle can be used in several medical applications.

The present invention provides a hemostatic porous composite sponge comprising: i) a matrix of a biomaterial; and ii) one hydrophilic polymeric component comprising reactive groups wherein i) and ii) are associated with each other so that the reactivity of the polymeric component is retained, wherein associated means that said polymeric component is coated onto a surface of said matrix of a biomaterial, or said matrix is impregnated with said polymeric material, or both.

A hydrogel-based biological delivery vehicle used to effectively deliver drug and biological material to tissue or organ sites. More specifically, a hydrogel binding matrix having a biopolymer backbone containing carboxyl groups. Tyramine may be substituted for at least a portion of the carboxyl groups, so that, when hydrogen peroxide is added, it causes creation of covalent bonds between tyramine molecules and cross-links the hydrogel binding matrix, thereby enabling the hydrogel binding matrix to transition from liquid to gel state. The hydrogel binding matrix, in its liquid form, is capable of encapsulating drug reservoirs to create a homogenous liquid with evenly distributed particles containing drugs or target molecules. As the hydrogel binding matrix solidifies into a gel state, the newly created cross-links do not disrupt or react with the drugs or target molecules contained within the drug reservoirs. This hydrogel-based biological delivery vehicle can be used in several medical applications.