A surgical staple comprising a substrate and one or more coatings which slows the bioabsorption of the substrate. The coating can be selected so as to affect the environment surrounding the staple once the staple is implanted in the patient. The effect on the environment can cause the bioabsorption to occur within a desired time frame.

Provided in this disclosure are chimeric peptides that include a spacer domain, the spacer domain itself, substrates (e.g., implants) coated with the chimeric peptides, and methods for making and using the coated substrates.

The present technology generally relates to a biomaterial that includes a thiolated biopolymer and one or more agents that include growth factors, peptides, or combinations thereof, where the one or more agents are conjugated to the thiolated biopolymer. Also disclosed herein are wound dressings that include the biomaterial of the present technology, methods of treating a wound upon application of the wound dressing, and kits including the wound dressing and instructions for use.

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.

The invention relates to plasmids capable of expressing a protein targeting immune cells when transformed into a lactic acid bacterial cell, wherein the protein is chosen from the group consisting of murine and human CXCL12 1α; CXCL17 and Ym1. The invention further relates to lactic acid bacteria transformed with a said plasmid, as well as the use of said lactic acid bacteria for wound healing in humans and animals.

Compositions or an assembly of a series of biomimetic compounds include chemical structures that mimic or structurally resemble a nucleic acid base pair. Complexes of nanotubes and agents are useful to deliver agents into the cells or bodily tissues of individuals for therapeutic and diagnostic purposes. Exemplary compounds include those of Formula (I), (III), (V) or (VII), or of Formula (II), (IV), (VI) or (VIII). ##STR00001##

The present invention relates to a method for preparing of a nerve conduit using bio-printing technology and a nerve conduit prepared by the same, and it can easily prepare a nerve conduit by simulating a nerve bundle and nerve tissue, and the like, by three-dimensionally printing bio-ink comprising a neuronal regeneration material on one side of a porous polymer scaffold.

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.

Disclosed herein are synthetic hydrogel useful for the generation, storage and administration of cellular structures such as spheroids and organoids.

Pharmaceutical compositions, more specifically poloxamer copolymer-based compositions and hyaluronic acid-based compositions, containing amelogenin, are useful for promoting periodontal or orthopedic soft or hard tissue regeneration, wound closure, and skin regeneration and rejuvenation. The composition can contain a non-biodegradable thermosensitive pharmaceutically acceptable poloxamer copolymer in an amount of 18% to 30% by weight; amelogenin in an amount of 0.005% to 3% by weight; a disaccharide in an amount of 0.05% to 5% by weight; and an amino acid selected from alanine, glycine, isoleucine, leucine, proline, valine, and a mixture thereof in an amount of 0.05% to 5% by weight.