A malleable polysaccharide soft tissue filler for filling tissue cavities or voids such as those resulting from tumor removal or other tissue resection. The soft tissue filler includes a first cross-linking polysaccharide, preferably a beta-D glucan and a second cross-linking polysaccharide. The soft tissue filler is both porous and malleable and can be formed to accommodate the tissue cavity or void. The soft tissue filler can include an embedded marker for locating on medical imaging. Methods of making the soft tissue filler including lyophilizing an aqueous polysaccharide suspension are disclosed. The second cross-linking polysaccharide provides for increased structural integrity in a high-porosity and malleable soft tissue filler in which the respective cross-linking polysaccharides synergistically provide structural scaffolding for one another. Methods of use are also disclosed.

An injectable medical composition includes an acrylate and a solvent. The composition has a first viscosity at temperatures below body temperature and a second viscosity at body temperature. The first viscosity is lower than the second viscosity.

An injectable medical composition includes an acrylate and a solvent. The composition has a first viscosity at temperatures below body temperature and a second viscosity at body temperature. The first viscosity is lower than the second viscosity.

A composite scaffold having a highly porous interior with increased surface area and void volume is surrounded by a flexible support structure that substantially maintains its three-dimensional shape under tension and provides mechanical reinforcement during repair or reconstruction of soft tissue while simultaneously facilitating regeneration of functional tissue.

A composite scaffold having a highly porous interior with increased surface area and void volume is surrounded by a flexible support structure that substantially maintains its three-dimensional shape under tension and provides mechanical reinforcement during repair or reconstruction of soft tissue while simultaneously facilitating regeneration of functional tissue.

The disclosure relates to an in situ-gelling hydrogel composition based on functionalized zwitterionic polymers. The resulting hydrogels exhibit highly anti-fouling, anti-adhesive, and lubricating properties to enable the fabrication of bulk hydrogels or hydrogel-based coatings of relevance to biomedical applications.

The disclosure relates to an in situ-gelling hydrogel composition based on functionalized zwitterionic polymers. The resulting hydrogels exhibit highly anti-fouling, anti-adhesive, and lubricating properties to enable the fabrication of bulk hydrogels or hydrogel-based coatings of relevance to biomedical applications.

The disclosure relates to an in situ-gelling hydrogel composition based on functionalized zwitterionic polymers. The resulting hydrogels exhibit highly anti-fouling, anti-adhesive, and lubricating properties to enable the fabrication of bulk hydrogels or hydrogel-based coatings of relevance to biomedical applications.

The present invention provides porous biomimetic scaffolds and methods for making the same. The scaffolds have graded pore sizes for enhanced cell penetration. The scaffolds are useful for wound regeneration by facilitating cell penetration into the scaffold interior and due to their inherent immunomodulatory effects. The scaffolds have tissue modeling specification by mimicking the inherent stratified structure of certain tissues.

The present invention provides porous biomimetic scaffolds and methods for making the same. The scaffolds have graded pore sizes for enhanced cell penetration. The scaffolds are useful for wound regeneration by facilitating cell penetration into the scaffold interior and due to their inherent immunomodulatory effects. The scaffolds have tissue modeling specification by mimicking the inherent stratified structure of certain tissues.