A formulation, or tissular adhesive, obtained from a platelet-rich blood composition and/or growth factors, and method for the preparation of this adhesive. The preparation method of the adhesive comprises the steps of raising the temperature of the initial blood composition and subsequently activating the composition. Among other advantages, the tissular adhesive is biocompatible and biodegradable, has desirable biological or medical properties provided by the presence of platelets or growth factors, and also has a high adhesiveness and an accelerated coagulation process.

The present invention provides polypeptides comprising or consisting of an amino acid sequence derived from collagen type VI or a fragment, variant, fusion or derivative thereof, or a fusion of said fragment, variant of derivative thereof, wherein the polypeptide, fragment, variant, fusion or derivative is capable of killing or attenuating the growth of microorganisms. Related aspects of the invention provide corresponding isolated nucleic acid molecules, vectors and host cells for making the same. Additionally provided are pharmaceutical compositions comprising a polypeptide of the invention, as well as methods of use of the same in the treatment and/or prevention of microbial infections and in wound care. Also provided are a method of killing microorganisms in vitro and a medical device associated with the pharmaceutical composition.

A coacervate including a catechol-substituted anionic polymer; an adhesive including same; and a method for producing the coacervate are described. More specifically, a coacervate formed by mixing a catechol derivative of a mussel adhesive protein and a catechol-substituted anionic polymer; an adhesive including the coacervate; and a method for producing a coacervate are described. The method includes a step of obtaining a catechol-substituted anionic polymer through catechol substitution of an anionic polymer, and a step of mixing the catechol-substituted anionic polymer and a catechol derivative of a mussel adhesive protein.

A coacervate including a catechol-substituted anionic polymer; an adhesive including same; and a method for producing the coacervate are described. More specifically, a coacervate formed by mixing a catechol derivative of a mussel adhesive protein and a catechol-substituted anionic polymer; an adhesive including the coacervate; and a method for producing a coacervate are described. The method includes a step of obtaining a catechol-substituted anionic polymer through catechol substitution of an anionic polymer, and a step of mixing the catechol-substituted anionic polymer and a catechol derivative of a mussel adhesive protein.

The present disclosure is generally directed to an embolic material in the form of a microparticle. The embolic material generally includes an alkene functionalized biopolymer. For instance, the embolic material may include a methacrylamide functionalized biopolymer. In some examples, the embolic material may further comprise a therapeutic agent, such as doxorubicin.

Disclosures of the present invention describe a double-layer dressing containing silk fibroin and a method for making the same, wherein the double-layer dressing mainly comprises a silk fibroin layer and a calcium-degradation silk fibroin layer connected to the silk fibroin layer, and it is worth emphasizing that, results of animal experiment have proved that this novel double-layer dressing is an outstanding hemostatic wound dressing; Moreover, additional adhesion, resulted from the solidification of tissue fluid, can be effectively prevented from forming between skin wound and wound dressing under the use of this double-layer dressing.

A method of sealing a resected surface of an organ includes applying a synthetic matrix to a resected surface of an organ, and applying an adhesive on the synthetic matrix so that the adhesive penetrates through interstices of the synthetic matrix for contacting an interface between the synthetic matrix and the resected surface of the organ. The method includes curing the adhesive for bonding the synthetic matrix to the resected surface of the organ. The synthetic matrix is a non-woven mesh made of polyglactin 910 or any other synthetic or non-synthetic fabric having a similar porosity or density. The adhesive is a biosynthetic or a synthetic adhesive. After penetrating through the pores of the synthetic matrix and curing, the cured biosynthetic or synthetic adhesive mechanically interlocks with the synthetic matrix for adhering the synthetic matrix to the tissue for creating a sealing barrier.

A method of sealing a resected surface of an organ includes applying a synthetic matrix to a resected surface of an organ, and applying an adhesive on the synthetic matrix so that the adhesive penetrates through interstices of the synthetic matrix for contacting an interface between the synthetic matrix and the resected surface of the organ. The method includes curing the adhesive for bonding the synthetic matrix to the resected surface of the organ. The synthetic matrix is a non-woven mesh made of polyglactin 910 or any other synthetic or non-synthetic fabric having a similar porosity or density. The adhesive is a biosynthetic or a synthetic adhesive. After penetrating through the pores of the synthetic matrix and curing, the cured biosynthetic or synthetic adhesive mechanically interlocks with the synthetic matrix for adhering the synthetic matrix to the tissue for creating a sealing barrier.

The present invention relates to new plasma or new platelet-rich plasma preparations, new cell dissociation methods, new cell associations or compositions, a method of preparation thereof, a use thereof, devices for the preparation thereof and preparations containing such a platelet-rich plasma preparation and cell associations or compositions. Specifically, the invention provides plasma or platelet-rich plasma alone or in cell composition preparations for use in tissue regeneration and bone regeneration and pain reduction.

The present invention relates to a self-assembling polypeptide for use as tissue adhesive. The present invention also relates to the use of a self-assembling polypeptide as tissue adhesive. Further, the invention is directed to the use of a self-assembling polypeptide to glue one or more cosmetic compounds on skin, mucosa, and/or hair. Furthermore, the invention is directed to a self-assembling polypeptide for use in gluing one or more pharmaceutical compounds on tissue, skin, mucosa, and/or hair.