A particle comprising hydroxyapatite, β-tricalcium phosphate, α-tricalcium phosphate, and/or bioactive glass is provided. The particle can be useful in bone graft compositions further comprising a carrier. The composition can include a quadphasic particle having hydroxyapatite, β-tricalcium phosphate, α-tricalcium phosphate, bioactive glass, and a carrier. The particle can have a size in the range of 50 microns to 2.5 mm. A method of repairing a bone defect is also provided. The method can include a step of applying the bone graft composition to a subject having the bone defect, such as a spinal bone defect. The subject receiving the bone graft composition can be a mammal, namely a human, pet, or domestic animal.

The present disclosure relates to several embodiments of a stent. For example, the present disclosure describes a stent comprising a material selected from a biocompatible material, a bioabsorbable material, and combinations thereof; and particles selected from biocompatible amorphous particles, bioabsorbable amorphous particles, and combinations thereof.

The stent may also include a coating of a material selected from a biocompatible material, a bioabsorbable material, and combinations thereof; nanocapsules and a therapeutic agent encapsulated in the nanocapsules.

The stent disclosed herein enables the walls of an airway or blood vessel to be supported, while there is controlled delivery of the therapeutic agent to said airway or blood vessel to prevent, cure, alleviate or repair symptoms of disease.

Provided herein are glycosylated peptide amphiphiles (GPAs), supramolecular glyconanostructures assembled therefrom, and methods of use thereof. In particular, provided herein are glycosaminoglycan (GAG) mimetic peptide amphiphiles (PAs) and supramolecular GAG mimetic nanostructures assembled therefrom that mimic the biological activities of GAGs, such as heparin, heparan sulfate, hyaluronic acid etc.

The present disclosure relates generally to materials and medical devices impregnated with antimicrobial compounds. More specifically, the materials are medical matrix materials comprising nanopores or nanochannels in which the antimicrobial compounds are disposed. In other embodiments, medical matrix materials comprises nanomaterials and antimicrobials distributed throughout the material. The materials described herein are useful for a broad spectrum of medical devices and consumer products. The present disclosure further provides methods of making the antimicrobial materials and medical devices disclosed herein.

Artificial cartilage materials for repair and replacement of cartilage, such as load-bearing and articular cartilage. The artificial cartilage materials can include a hydrogel with an internal polymer support network that impart the hydrogel mechanical properties similar to that of natural cartilage. In some examples, the hydrogels include a cross-linked cellulose network and a double network of polyvinyl alcohol (PVA) and polyacrylamide-methyl propyl sulfonic acid (PAMPS) polymers. The hydrogels may include specific formulations of different polymers to impart mechanical properties that are within a cartilage equivalent range. The artificial cartilage materials may include a porous base that is bonded to the hydrogel for interfacing with surrounding tissues and promoting ingrowth of bone and/or cartilage. Thus, the materials may be well suited for forming a synthetic graft, such as an osteochondral graft, for implantation into a patient's body.

Aspects of the disclosure relate methods and a synthetic cell delivery device for treating trauma present relative to the inner surface of a hollow organ such as an esophagus.

A modular engineered tissue construct includes a plurality of fused self-assembled, scaffold-free, high-density cell aggregates. At least one cell aggregate includes a plurality of cells and a plurality of biocompatible and biodegradable nanoparticles and/or microparticles that are incorporated within the cell aggregates. The nanoparticles and/or microparticles acting as a bulking agent within the cell aggregate to increase the cell aggregate size and/or thickness and improve the mechanical properties of the cell aggregate as well as to deliver bioactive agents.

An article having anti-microbial effect is provided. The article includes an occlusive layer and a substrate having a nanostructured surface. The nanostructured surface is coated with a metal oxide layer and the metal oxide layer includes a metal oxide.

Disclosed is a biocomposite product with high microbial activity obtained by using bee bread, the method of obtaining this product and using of this biocomposite material for the coating of products like artificial materials, packaging, etc. to be used in areas requiring hygiene or their use as an intermediate raw material.

The invention is related to the nanofibrous wound dressing that has been developed to be used in the treatment of various types of skin wounds including chronic and acute wounds in the biomedical sector, wherein said wound dressing comprises a bioactive agent that promotes the process of wound healing.