The present invention relates to a bioactive compound delivery assembly, a method for stabilization and/or encapsulation of bioactive compound compositions, a method for solid-supported transfection of living cells as well as a use of the bioactive compound delivery assembly.

One aspect of the invention provides a method of sequentially inducing macrophage conversion in a wound. The method includes: (a) administering IL-4 to induce conversion of a first population of wound macrophages in the wound to M2A macrophages; and then (b) administering IL-10, dexamethasone, or a dexamethasone analog to induce conversion of a second population of wound macrophages in the wound to M2C macrophages.

The technology described herein is directed to compositions comprising at least a first porous biomaterial layer and a second impermeable biomaterial layer and methods relating thereto. In some embodiments, the compositions and methods described herein relate to wound healing, e.g. repair of wounds and/or tissue defects.

A biologic composition responsive to inflammation has an allograft scaffold matrix for injection or implantation. The allograft scaffold matrix has donor quiescent and/or senescent cells. The donor quiescent and/or senescent cells react in response to signaling of inflammation from host cells or matrix. The reaction to signaling causes the donor quiescent and/or senescent cells to secrete anti-inflammatory cytokines and secrete exosomes to initiate regeneration of the area of the inflammation. The biologic composition further has a cryoprotectant. The cryoprotectant is a polyampholyte, preferably the polyampholyte is an ε-poly-L-lysine. The cryoprotectant is not DMSO or glycerol based. The cryoprotectant is suitable for direct implantation without washing from the allograft scaffold matrix in either a diluted or non-diluted state.

The present disclosure provides click-crosslinked hydrogels and methods of use.

A medical device, the medical device including a substrate defining a surface; a plasma polymer layer bound to and coating the surface; and a bactericide layer bound to the plasma polymer layer, the plasma polymer layer being between the substrate and the bactericide layer. Also, a method for coating a surface of a substrate of a medical device with a bactericide layer, the method including: exposing the surface to a plasma to form a plasma polymer layer bound to the surface; and binding a bactericide layer to the plasma polymer layer.

A plasma coating device for treating a wound comprises a plasma chamber having: one or more electrodes, a gas supply inlet, a plasma outlet exposed to ambient pressure, and an ignition system operatively connected to the electrodes for providing a non-thermal equilibrium plasma within the plasma chamber. An aerosol delivery system is operable to introduce a bioresorbable material as an aerosol into the plasma, to produce a coating on the wound surface.

The present invention relates to a composition for bone grafting, comprising nucleic acids, a bone graft material, and a cationic polymer, and a bone graft kit for manufacturing the same. The composition for bone grafting, of the present invention, has been confirmed to promote the formation of a cushioning force that can respond to physiological stress and the formation of new bones at grafted sites, and has been confirmed to improve bone grafting convenience, and thus is expected to be effectively usable in the treatment of bone diseases.

A method has been developed for repairing a cartilage lesion. The method includes bringing a three-dimensional porous substrate into direct contact with prepared bone. The three-dimensional porous substrate is fixedly coupled to a three-dimensional scaffold such that the substrate supports the scaffold. The three-dimensional porous substrate comprises at least three layers of woven fibers. The substrate is configured to be inserted into bone tissue including cartilage lesions such that the substrate and the scaffold replace the bone tissue including the cartilage lesions. The substrate and scaffold are further configured such that after the substrate and the scaffold have replaced the bone tissue including the cartilage lesions, the substrate and scaffold promote growth and integration of new bone tissue into the implant.

Compositions including a collagen glycosaminoglycan scaffold and osteoprotegerin are described. The compositions are useful in methods for promoting osteogenesis and attenuating bone resorption.