Tissue scaffolds for neural tissue growth have a plurality of microchannels disposed within a sheath. Each microchannel comprises a porous wall having a thickness of ≤about 100 μm that is formed from a biocompatible and biodegradable material comprising a polyester polymer. The polyester polymer may be polycaprolactone, poly(lactic-co-glycolic acid) polymer, and combinations thereof. The tissue scaffolds have high open volume % enabling superior (linear and high fidelity) neural tissue growth, while minimizing inflammation near the site of implantation in vivo. In other aspects, methods of making such tissue scaffolds are provided. Such a method may include mixing a reduced particle size porogen with a polymeric precursor solution. The material is cast onto a template and then can be processed, including assembly in a sheath and removal of the porogen, to form a tissue scaffold having a plurality of porous microchannels.

Methods and compositions for reducing a ratio of collagen III to collagen I in wounded skin, treating wounds and accelerating healing is provided with a surfactant polymer dressing comprising FL2 siRNA, collagen and a poloxamer.

Sheet structures for regenerating damaged or diseased mammalian tissue that are formed from acellular dermal mammalian tissue. The acellular dermal mammalian tissue includes extracellular matrix (ECM) and a supplemental bioactive component. The supplemental bioactive component can comprise a nucleic acid, such as RNA, and/or a cell, such as an embryonic stem cell. The sheet structures induce angiogenesis and, thereby, regeneration of new mammalian tissue.

A prosthetic polylactide or collagen-containing scaffold material for treating osseous defects and neogenesis of bone, obtained by printing a scaffold composed of strings of polylactide and porous microstructures which allow passage and ingrowth of bone tissue. A soluble mixture of BSP and/or collagen is provided, and BSP and/or collagen is applied onto the strings and in the pores of the printed body to obtain a prosthetic material which induces tissue-directed ingrowth of bone tissue as well as repair and healing of damaged or diseased bone tissues and lesions. The prosthetic material is osseo-inductive and osseo-conductive. The BSP in the prosthetic scaffold material induces a tissue-directed growth of osseous tissue. No undirectional callous or overgrowing bone and cartilage tissue is observed.

The present invention provides a method for preparing an injectable thermosensitive chitosan/TEMPO-oxidized cellulose nanofibers hydrogel. The injectable thermosensitive chitosan/TEMPO-oxidized cellulose nanofibers hydrogel exhibits superior biocompatibility through addition of TEMPO-oxidized cellulose nanofibers, and excellent cell proliferation and bone regeneration through cellular interaction, and is gelled in vivo, thus being highly useful as a filler for wound healing and bone regeneration. In addition, the injectable thermosensitive chitosan/TEMPO-oxidized cellulose nanofibers hydrogel exhibits excellent porosity, has an interconnected structure and is thermogelling, based on thermosensitivity of undergoing a sol-gel transition depending on temperature, thus inducing rapid gelation in vivo and facilitating bone regeneration upon implantation in vivo.

Provided is a compression resistant implant configured to fit at or near a bone defect to promote bone growth. The compression resistant implant comprises a biodegradable polymer in an amount of about 0.1 wt % to about 20 wt % of the implant and a freeze-dried oxysterol in an amount of about 5 wt % to about 90 wt % of the implant. Methods of making and use are further provided.

Compositions and peptides for enhancing formation of cartilage in a site of a cartilage injury or defect, or joint condition, and methods of the use of the compositions and peptides in such treatments. Examples of the sites may include a knee, ankle, wrist, shoulder, elbow, patella, hip, vertebrae, femoral head, temporomandibular joint, glenoid of the scapula, jaw, and growth plate.

The present invention provides new classes of phenol compounds, including those derived from tyrosol and analogues, useful as monomers for preparation of biocompatible polymers, and biocompatible polymers prepared from these monomeric phenol compounds, including novel biodegradable and/or bioresorbable polymers. These biocompatible polymers or polymer compositions with enhanced bioresorbabilty and processability are useful in a variety of medical applications, such as in medical devices and controlled-release therapeutic formulations. The invention also provides methods for preparing these monomeric phenol compounds and biocompatible polymers.

A no-sting skin protectant film forming composition is formulated with a film forming polymer having both polar and nonpolar characteristics, a no-sting nonpolar solvent system, and at least one skin health ingredient. The no-sting skin protectant film forming composition is configured to form a protective film on a skin surface after the solvent system evaporates.

An implantable drug-delivery device for repairing a crushed peripheral nerve. The drug-delivery device includes a matrix formed of a biopolymer and an erythropoietin (EPO) entrapped in the matrix. After in vivo implantation of the drug-delivery device, the EPO elutes over a period of 1 day to 12 weeks. Also disclosed is a method for repairing a crushed peripheral nerve using the implantable drug-delivery device.