267 results about "Hydrogel film" patented technology

The invention discloses a method for preparing an Ag-carrying bacterial cellulose hydrogel antimicrobial dressing and a product thereof. The method comprises the following steps of: soaking a bacterial cellulose hydrogel film in solution of silver metal precursor; then heating the film to be between 121 and 135 DEG C in a high-pressure sterilizing pot, and pressurizing between 0.205 and 0.313MPa; standing bacterial cellulose for 5 to 30min; and then taking the treated bacterial cellulose out for washing, partial dehydration, packaging and sterilization to obtain an Ag-carrying bacterial cellulose hydrogel antimicrobial dressing which is formed by compounding silver metal nano-particles and bacterial cellulose and is attached with 0.01 to 10 weight percent of the silver metal nano-particles in a bacterial cellulose three-dimensional porous network structure. The preparation process of the invention has the advantages of simplicity, easiness, convenient operation, controllable preparation technology, no pollution and low cost; and the prepared nano-particles have the advantages of high purity, small particle size, uniform size and good dispersity. The obtained Ag-carrying bacterial cellulose hydrogel antimicrobial dressing has the characteristics of good antimicrobial property, high water content, good water-retaining property, strong toughness, good air permeability and the like, and can meet the requirements of treating various wounds by a wet method.

The invention provides a composition comprising a matrix of chitosan and a tannin wherein the chitosan is electrostatically bonded to the tannin to form a chitosan-tannin composite material. The chitosan can be partially or fully deacetylated, and the tannin can be a monomeric or an oligomeric proanthocyanidin or a hydrolysable tannin. The chitosan-tannin composite material can be a nanoparticle, a hydrogel film, a bio-foam, or a biogel, or the chitosan-tannin composite material can coat a liposome. The composite materials can be used for drug delivery, for antibacterial and / or antifungal applications, for tissue engineering applications, for wound healing applications, or they can be used as adjuvants for vaccination, including oral vaccinations. The invention also provides methods of preparing the composite materials and their various forms.

There is provided new mono-(meth)acrylate functionalized silicone monomers containing carbosiloxane linkage for improved hydrolysis resistance, useful in making water absorbing silicone-hydrogel films for contact lens applications. This invention also provides homo-polymers and copolymers made from the mono-(meth)acrylate functionalized hydrophilic silicone monomers described herein. Also provided is a process for producing the monomers and polymers described herein and contact lenses produced from the same.

The invention discloses a rapid response optical glucose sensor based on glucose sensitive hydrogel film. The hydrogel film used for sensing has two properties that on one hand, a swellbility of the hydrogel film in aqueous solution is changed with a glucose concentration in the solution; on the other hand, an absorption spectrum or a reflection spectrum has Fabry-Perot interference fringes. The change of glucose concentration leads to change of hydrogel film swellbility, so as to cause moving of the Fabry-Perot interference fringes; therefore the moving of the Fabry-Perot interference fringes indicates the change of glucose concentration in the solution. The invention utilizes a layer by layer assembly method to prepare the glucose sensitive hydrogel film with a thickness from hundreds nanometers to micrometers, so as to conduct rapid response.

There is provided a mono-(meth)acrylate functionalized hydrophilic silicone monomers containing a polyether with branched linking group, useful in making water absorbing silicone-hydrogel films for contact lens applications. This invention also provides homo-polymers and copolymers made from the mono-(meth)acrylate functionalized hydrophilic silicone monomers described herein. Also provided is a process for producing the monomers and polymers described herein and contact lenses produced from the same.

The application of a highly controlled, micron-sized, branched, porous architecture to enhance the handling properties and degradation rate of hydrogels is described in the instant invention. A previously described pattern created through one-step nucleated crystallization in a hydrogel film creates tunable mechanical properties and / or chemical stability for use in tissue engineering applications. The bulk mechanical properties and the degradation rate of the material can be tuned easily by the addition or subtraction of crystalline structure or by the addition and subtraction of backfill material, making this useful for a variety of applications. Relevant mechanical properties that can be tuned through the application of this unique porosity are moduli, elasticity, tensile strength, and compression strength. The method of the present invention can be applied to biopolymers and natural materials as well as synthetic materials.

The invention provides a preparation method of a fibroin aquagel film. Natural silk is added into a sodium carbonate solution; stirring reaction is performed for 30 to 50 min at the temperature of 100to 110 DEG C; the operation is repeated for 3 to 5 times to obtain pure fibroin fiber; lithium bromide, butyl oxide and water are mixed and are subjected to ultrasonic treatment for 5 to 10 min to obtain a uniform mixed solution A; the pure fibroin fiber is added into the mixed solution A; dissolution reaction is performed for 30 to 50 min at the temperature of 80 to 120 DEG C; then, dialysis andfiltering are performed to obtain a fibroin water solution; a polyvinyl alcohol solution is prepared; nanometer titanium dioxide, elastin, the fibroin water solution and the polyvinyl alcohol solution are mixed; the reaction treatment is performed for 3 to 8h at the temperature being 60 to 80 DEG C and the pH being 7.3 to 8.1; obtained products are subjected to spreading flowing to realize the flat spreading in a shaping mode; freeze drying is performed at the temperature of -30 to -10 DEG C to obtain the fibroin aquagel film.