A graphite composite includes a graphite sheet having a void inside and a resin member. The void is partially filled by at least a part of the resin member in its entirety. The proportion of the resin member to the sum of the graphite sheet and the resin member is equal to or greater than 5% by mass. The graphite composite has a porosity equal to or greater than 50% by volume and equal to or less than 95% by volume.

The present disclosure relates generally to wound dressing compositions and methods of manufacturing the wound dressing compositions of the present technology. The wound dressing composition includes a mixture of a collagen and/or chitosan and oxidized regenerated cellulose (ORC) with a layer of citric acid disposed therein. Also disclosed herein are methods of manufacturing such wound dressing compositions as well as kits including such wound dressing compositions.

The present disclosure relates generally to wound dressing compositions and methods of manufacturing the wound dressing compositions of the present technology. The wound dressing composition includes a mixture of a collagen and/or chitosan and oxidized regenerated cellulose (ORC) with a layer of citric acid disposed therein. Also disclosed herein are methods of manufacturing such wound dressing compositions as well as kits including such wound dressing compositions.

The present disclosure provides wound dressing compositions that disrupt biofilm formation in a wound upon application. The wound dressing composition includes a first layer comprising a homogeneous mixture of a collagen, an oxidized regenerated cellulose (ORC), and at least one bacteria reducing active ingredient and a second layer comprising a homogeneous mixture of a collagen, an oxidized regenerated cellulose (ORC), a silver compound, and at least one bacteria reducing active ingredient, and the uses thereof. Also disclosed herein are kits comprising the wound dressing compositions of the present technology, and instructions for use.

The present disclosure provides wound dressing compositions that disrupt biofilm formation in a wound upon application. The wound dressing composition includes a first layer comprising a homogeneous mixture of a collagen, an oxidized regenerated cellulose (ORC), and at least one bacteria reducing active ingredient and a second layer comprising a homogeneous mixture of a collagen, an oxidized regenerated cellulose (ORC), a silver compound, and at least one bacteria reducing active ingredient, and the uses thereof. Also disclosed herein are kits comprising the wound dressing compositions of the present technology, and instructions for use.

Interpenetrating network hydrogels with independently tunable stiffness enhance tissue regeneration and wound healing.

Interpenetrating network hydrogels with independently tunable stiffness enhance tissue regeneration and wound healing.

The invention concerns a composition to be electrospun comprising a first compound to be electrospun, an electrospinning promoter and at least one active ingredient, as well as a method to prepare it. This composition allows to obtain electrospun nanometric fibers with good structural and absorption properties.

The invention concerns a composition to be electrospun comprising a first compound to be electrospun, an electrospinning promoter and at least one active ingredient, as well as a method to prepare it. This composition allows to obtain electrospun nanometric fibers with good structural and absorption properties.

The present invention relates to a porous scaffold having excellent tissue engineering properties, and a method for manufacturing same. The scaffold of the present invention can be manufactured by a simple process, and exhibits high tensile strength and biocompatibility, as well as an excellent cell engraftment rate, and thus can be useful as a support composition for various of human transplantation, for example, as a support for artificial ligaments or abdominal wall reinforcement.