The present invention relates to an injectable hydrogel composition having the recruitment of endogenous progenitors or stem cells and the induction of vascular differentiation of recruited cells, and more specifically to an injectable hydrogel composition having the recruitment of endogenous progenitors or stem cells and the induction of vascular differentiation of recruited cells, which consists of: a first solution including anionic hyaluronic acid into which a vascular differentiation inducing factor is introduced; and a second solution including a cationic material, wherein a stem cell recruitment factor is further included in the first solution and/or the second solution, and wherein a hydrogel is formed by electrostatic interaction.

In the hydrogel composition of the present invention, it was confirmed that the stem cell recruitment factor was released from the injected hydrogel, and endogenous progenitor cells/stem cells were recruited in the hydrogel, and the induction of angiogenesis was promoted by differentiating into vascular cells by the vascular differentiation inducing factor chemically introduced into hyaluronic acid. In particular, it was confirmed that when the vascular differentiation inducing factor was chemically introduced into hyaluronic acid, a high angiogenesis-inducing effect was observed. Therefore, the hydrogel composition of the present invention has excellent recruitment of endogenous progenitor cells/stem cells and induction of vascular differentiation, and thus, it can be effectively applied to various tissue regenerations and wound treatments in addition to the formation of blood vessels.

This document relates to compositions containing one or more erythropoietin (EPO) polypeptides. For example, this document provides thermoresponsive compositions containing one or more EPO polypeptides and methods for using such thermoresponsive compositions as a delivery system to deliver one or more EPO polypeptides to desired tissue (e.g., to treat a nerve injury and/or a wound). In some cases, thermoresponsive compositions containing one or more EPO polypeptides can be administered (e.g., locally administered) to a mammal having a nerve injury to treat the nerve injury (e.g., to promote wound healing). In some cases, thermoresponsive compositions containing one or more EPO polypeptides can be administered (e.g., locally administered) to a mammal having a wound to treat the wound (e.g., to promote wound healing).

The present invention concerns a method to prepare a filler with a hyaluronic acid, which has improved properties of chemical-physical stability over time and optimal viscosity for cutaneous injection. In particular the method comprises a first step in which the hyaluronic acid is crosslinked, and a subsequent step for the neutralization and hydration of the crosslinked hyaluronic acid.

A thiol-modified hyaluronan, wherein the thiol-modified hyaluronan comprises a plurality of modification groups with a thiol-group in the hyaluronan side-chains, wherein the modification group comprises an amino acid residue with basic side chain and a conjugated terminal naturally occurring amino-thiol as well as a sterile hydrogel composition comprising a crosslinked polymer, wherein the crosslinked polymer is an oxidation product of the thiol-modified hyaluronan and uses of the composition.

A porous hardened material is provided for various medical applications, including strengthening, supporting, moving, reinforcing, separating, isolating, and/or bulking biological substrates. The hardened material is formed from a liquid composition including a fluorinated copolymer and a biocompatible solvent system. The fluorinated copolymer includes a tetrafluoroethylene (TFE) moiety and a vinyl moiety, wherein the vinyl moiety comprises at least one functional group selected from acetate, alcohol, amine, and amide.

Compositions may include a therapeutic that is released from the composition to treat any number of ailments or conditions (e.g., pain, infection, cancer, osteoporosis) or to help accelerate local tissue regeneration (e.g., growth hormone, bone morphogenic protein) or to assist with surgical or therapeutic treatment (e.g., imaging modality), or any of a combination thereof.

A tissue restoration composition in a colloidal phase, includes a copolymer in which a hydrophobic biocompatible polymer and a hydrophilic biocompatible polymer are polymerized and which is dispersed in water. The colloidal phase has increased viscosity by heating the copolymer dispersed in water. The colloidal phase has a viscosity, by the heating, of 20-200,000 cP.

Provided are methods, devices and compositions for reducing and/or inhibiting postsurgical tissue adhesion using a hydrogel film disposed onto a target tissue, thereby providing an adhesion barrier that remains over said target tissue for a prescribed period of time. In some embodiments, the hydrogel film is formed by the gelation of a pre-gel mixture applied onto the target tissue as a plurality of particles having an average maximum dimension, such as diameter, of at most about 500 μm. In some embodiments, the hydrogel film has a minimum storage modulus of 100 Pa. In some embodiments, the pre-gel mixture comprises an ECM digest having a collagen to carbohydrate ratio (by mass) of at least 70:1.

Disclosed are Self-Gelling materials and structures or materials or structures having one or more self-gelling components that overcome existing gel limitations due to hydrogel localization for medical applications by providing, for example, 1) microstructurally, or physically, anchored characteristics to help localize the gel, and the overall printed, or otherwise formed structure, giving structural form to the gel that allows the gel to be localized within the body, and even sutured in place, and mitigates gel migration and extends its residence time; 2) to provide an underlying 3D printed structure to help contain and support the gel after implantation; and more. Self-Gelling 3D printed structures may be further processed via milling to yield deconstructed scaffold micro-granules, with the composition and nano-/micro- structure of the original larger structure. Deconstructed scaffold micro-granules may be hydrated to form a micro-granule embedded gel network that can be injected, giving form to injectable gels.

Cyclic peptide pro-gelator compositions, and methods of therapeutic use, which assemble into macromolecular hydrogel when administered through cleavage by endogenous enzymes upregulated at a site of tissue injury, such as a myocardial infarction.