The present invention concerns a method for obtaining an implantable cartilage gel for tissue repair of hyaline cartilage, comprising particles of chitosan hydrogel and cells that are capable of forming hyaline cartilage, said method comprising a step for amplification of primary cells in a three-dimensional structure comprising particles of physical hydrogel of chitosan or a chitosan derivative, then a step for re-differentiation and induction of the synthesis of extracellular matrix by said amplified cells, in the same three-dimensional structure, wherein said cells are primary articular chondrocytes and/or mesenchymal stem cells differentiated into chondrocytes. The present invention also concerns the cartilage gel obtained thereby, and its various uses for cartilage repair following a traumatic lesion or an osteoarticular disease such as osteoarthritis. The invention also concerns a three-dimensional matrix comprising particles of physical hydrogel of chitosan or of chitosan derivative, optionally supplemented with an anionic molecule such as hyaluronic acid or a derivative of hyaluronic acid or a complex of hyaluronic acid.

Provided are implants and a glycolytic dependent compound for use in enhancing toxicity of the glycolytic dependent compound towards a cell, tissue and/or organ e.g., a diseased cell, tissue and/or organ, wherein the implant and the glycolytic dependent compound are contacted with the cell, tissue and/or organ in a non-blended form.

Disclosed is a thrombin-free, liquid biological glue for therapeutic use, including fibrinogen and factor VIIa. The ratio of fibrinogen concentration to FVIIa concentration is 20000:1 to 1000:1, with the concentrations being expressed in weight per volume. The fibrinogen concentration is lower than 60 mg/ml. Also disclosed are a kit for preparing such a biological glue, a method to prepare the glue, and a medicament.

This disclosure relates to dermal treatment compositions, such as dermal fillers and tissue glues, and injectable compositions that incorporate one or more cationic steroidal antimicrobials (CSAs). The CSAs are incorporated into the dermal treatment compositions to provide effective antimicrobial, anti-inflammatory, analgesic, anti-swelling and/or tissue-healing properties. A treatment composition includes a component formed from a biologically compatible material suitable for injection into and/or application onto tissue at a treatment site. One or more CSA compounds are mixed with the biologically compatible material so that the one or more CSA compounds are incorporated within the composition, forming a reservoir of CSA compounds within the resulting bolus of the treatment composition after injection and/or application.

The present invention relates generally to agents and devices for promoting hemostasis and, more particularly, to bioresorbable hemostatic pads or patches releasably supported on non-resorbable scaffolds for ease of delivery in the field. A sealant and/or hemostat delivery device comprises a resorbable hemostatic pad having a wound facing side and an opposite back side, with a hemostatic and/or wound sealing agent disposed on the wound facing side; a non-resorbable scaffold having an attachment zone on said scaffold; wherein said hemostatic pad is releasably attached with the back side to the attachment zone. The bond between the scaffold and the resorbable hemostatic pad or wound dressing is either (i) severed prior to removal of the scaffold or (ii) is weakened due to the adhesive bonding them together being moisture-deactivated, or (iii) is released by mechanical disentanglement.

An embolic material contains at least one type of polymer and a liposoluble contrast medium. A method for producing an embolic material includes extruding a raw material that is in a molten state into a solvent, and cooling the raw material so as to solidify the raw material. The raw material contains a polymer and a liposoluble contrast medium.

The present disclosure relates to bone cement formulations that have an extended working time for use in vertebroplasty procedures and other osteoplasty procedures together with cement injectors that include energy delivery systems for on-demand control of cement viscosity and flow parameters. The bone cement formulations may include a liquid component having at least one monomer and a non-liquid component including polymer particles and benzoyl peroxide (BPO). The non-liquid component may be further configured to allow controlled exposure of the BPO to the liquid monomer so as to enable control of the viscosity of the bone cement composition.

The invention discloses a hemostatic composition comprising: a) a biocompatible polymer in particulate form suitable for use in hemostasis, and b) one hydrophilic polymeric component comprising reactive groups.

Once aspect of the present invention relates to methods of embolizing a vascular site in a mammal comprising introducing into the vasculature of a mammal a composition comprising an inverse thermosensitive polymer, wherein said inverse thermosensitive polymer gels in said vasculature, which composition may be injected through a small catheter, and which compsitions gel at or below body temperature. In certain embodiments of the methods of embolization, said composition further comprises a marker molecule, such as a dye, radiopaque, or an MRI-visible compound.

A sealant for sealing a puncture through tissue includes a first section, e.g., formed from freeze-dried hydrogel, and a second section extending from the distal end. The second section may be formed from PEG-precursors including PEG-ester and PEG-amine, e.g., in an equivalent ratio of active group sites of PEG-ester/PEG-amine greater than one-to-one, e.g., such that excess esters may provide faster activation upon contact with physiological fluids and enhance adhesion of the sealant within a puncture. At least some of the precursors remain in an unreactive state until exposed to an aqueous physiological environment, e.g., within a puncture, whereupon the precursors undergo in-situ cross-linking to provide adhesion to tissue adjacent the puncture. For example, the PEG-amine precursors may include the free amine form and the salt form. The free amine form at least partially cross-links with the PEG-ester and the salt form remains in the unreactive state in the sealant before introduction into the puncture.