The present disclosure relates to a biocompatible patch and methods of use thereof. A biocompatible patch and uses thereof for treating a damaged cardiac tissue.

Provided are an adhesion preventing agent and an adhesion preventing method using the same. Specifically, provided are an adhesion preventing agent, including at least one anionized nanomaterial selected from the group consisting of anionized nanocellulose and anionized nanochitin, and an adhesion preventing method using the adhesion preventing agent.

A medical device includes a body defining an exterior surface, and a coating including a therapeutic agent-containing nanoparticle disposed on the exterior surface of the medical device. The nanoparticle may include a brush-arm star polymer. The therapeutic agent may be paclitaxel.

A nanofibrous mat comprising: electrospun nanofibres forming said mat; and ceramic particles dispersed throughout said nanofibres and comprising a ceramic matrix and a dopant releasably encapsulated within said ceramic matrix, wherein the ceramic particles are dispersed throughout the nanofibres during electrospinning of the nanofibres, whereby said dopant is protected by said ceramic matrix during said electrospinning.

Disclosed are methods of promoting wound healing in a patient in need thereof comprising administering to the patient a composition comprising a neonatal fibrin scaffold. Further disclosed are in vitro methods for evaluating a target composition on human wound healing comprising a neonatal porcine plasma scaffold with the target composition and evaluating scaffold properties of the plasma sample.

According to an example aspect of the present invention, there is provided an auxetic structure, comprising or consisting of cellulosic material, preferably comprising nanostructured or microstructured cellulose on at least one of its surfaces or consisting of nanostructured or microstructured cellulose and optionally other cellulosic material.

Cellulose-reinforced hydrogels may include a cellulose nanofiber network and an interstitial hydrogel portion within interstitial regions of the cellulose nanofiber network, the interstitial hydrogel portion comprising polyvinyl alcohol (PVA), wherein the hydrogel component has a crystallinity of 20% or greater.

One of the significant challenges to translation of intravenously administered nanomaterials has been complement-mediated infusion reactions which can be lethal. Slow infusions can reduce infusion reactions, but slow infusions are not always possible in applications like controlling bleeding following trauma. Nanocapsules based on polyurethane are introduced as candidates that do not substantially activate complement protein C5a and the PEGylation and functionalization of the nanocapsules with the GRGDS peptide to create a new class of hemostatic nanomaterials is disclosed. Advantageously, the nanocapsules substantially avoid complement-mediated infusion reactions, promote faster clotting than controls, maintain maximum clot firmness, and do not activate pro-inflammatory cytokines.

Polymers suitable for forming carbon nanotube-functionalized reverse thermal gel compositions, compositions including the polymers, and methods of forming and using the polymers and compositions are disclosed. The compositions have reverse thermal gelling properties and transform from a liquid/solution to a gel—e.g., near or below body temperature. The polymers and compositions can be injected into or proximate an area in need of treatment.

A method is described for the production of hybrid structures formed by the coupling of nanofibrous parts and microfibrous parts made with silk fibroin, possibly hierarchically organized into complex structures comprising more than two of said parts; these hybrid structures are used as implantable biomedical devices with tailored biological, geometrical and structural features, such that they can be adapted to different application requirements in the field of regenerative medicine.