Disclosed herein are hydrogel precursor solutions, hydrogels, and methods of preparation and uses of the same. The hydrogels may be gelled at room temperature, in the absence of added light or heat, to yield ultra-strong hydrogel fibers suitable for load-bearing applications, or as adhesives or coatings. The hydrogels may include a polymerized polymer containing acrylic acid, additional acrylic acid, an organic acid such as citric acid, and an oxidizing agent such as a persulfate salt. Silver-lignin nanoparticle suspensions may be used to initiate a free radical oxidative decarboxylation reaction in the disclosed compositions. Hydrogels may be prepared from such compositions through incubation leading to gelling. The gelled hydrogels may be stretched or spun into hydrogel fibers having desirable mechanical properties, such as strength, stretchability, and adhesion.

The invention relates to a biocompatible product having a crosslinked matrix, in which a polysaccharide is co-crosslinked with chitosan, a chitosan derivative, or a salt of chitosan, said matrix further comprising a divalent zinc cation.

The invention relates to biodegradable, biocompatible materials to promote regeneration of articular surfaces in the temporomandibular joint and, more particularly, to biomaterials and methods for facilitating fibrochondrocyte and chondrocyte growth in in-vitro and in-vivo environments. The materials include magnesium in solid form and polymer. The materials are effective to grow and regenerate fibrochondrocyte and chondrocyte cells, and restore bone cells.

The present invention relates to an extrudable photocrosslinkable hydrogel comprising a biochemically modified extracellular matrix (ECM) with an electroconductive nanomaterial embedded; a photoinitiator and a solvent, the method for its preparation starting from decellularized extracellular matrices (dECMs) and its applications for preparing electroconductive scaffolds, electroconductive extrudable hydrogels for in situ defect-filling, conductive grafts, in situ or in vitro printed tissues or organs, adhesives for different tissues, or bone adhesives.

Disclosed are a patch comprising a metal-organic framework, in particular a silicone patch comprising a metal-organic framework and a silicone composition, and an artificial skin comprising a metal-organic framework. The patch and artificial skin according to one aspect of the present invention have wound healing properties such as a reduction in the size of a scar area when attached to a scar on the skin, and in particular have an excellent wound healing effect that reduces the scar area by about 50% compared to a control group to which a patch or artificial skin not containing a metal-organic framework is attached, such that the present invention can be used as a patch for cell regeneration or skin would healing, in particular as a silicone patch, and furthermore, can be used as artificial skin.

A biocompatible composite material for controlled release is disclosed, comprising a biocompatible metal oxide structure with a loaded network of pores. The pore network of the biocompatible composite material is filled with a uniformly distributed biologically active micellizing amphiphilic molecule, the size of these pores ranging from about 0.5 to about 100 nanometers. The material is characterized in that when exposed to phosphate-buffered saline (PBS), the controlled release of the active amphiphilic molecule is predominantly diffusion-driven over time.

The present invention relates to a (poly)hybrid implant made of one or more composite materials, having a polymer matrix and a ceramic-inorganic and/or inorganic component, wherein the polymer matrix has at least one component, selected from the group PDLLA; PLGA, PCL, HDPE, PE, UHMWPE, PEAK, PEEK, PP, PUR, and the ceramic-inorganic component has at least one calcium-phosphate-based component, preferably selected from the group HAP, ?-TCP, ?-TCP and CaCO.sub.3. In addition, metallic components can also be introduced, preferably, but not exclusively containing elements such as Mg, Fe, Zn or Sr.

A gallium silica glass composition is described. The glass can be used in variety of biomedical applications

Disclosed herein is a technology for healing bone defects using bioactive silicate glass (BSG) and a 3D osteomimetic composite porous scaffold containing microspheres comprised of poly(lactide-co-glycolide) (PLGA).

Disclosed herein is a technology for healing bone defects using bioactive silicate glass (BSG) and a 3D osteomimetic composite porous scaffold containing microspheres comprised of poly(lactide-co-glycolide) (PLGA).