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.

A method for controlling generation of biologically desirable voids in a composition placed in proximity to bone or other tissue in a patient by selecting at least one water-soluble inorganic material having a desired particle size and solubility, and mixing the water-soluble inorganic material with at least one poorly-water-soluble or biodegradable matrix material. The matrix material, after it is mixed with the water-soluble inorganic material, is placed into the patient in proximity to tissue so that the water-soluble inorganic material dissolves at a predetermined rate to generate biologically desirable voids in the matrix material into which bone or other tissue can then grow.

The present invention relates to compositions and methods useful for treating structures of the vertebral column, including vertebral bodies. In one embodiment, a method for promoting bone formation in a vertebral body comprising providing a composition comprising a PDGF solution and a biocompatible matrix and applying the composition to at least one vertebral body. Promoting bone formation in a vertebral body, according to some embodiments, can increase bone volume, mass, and/or density leading to an increase in mechanical strength of the vertebral body treated with a composition of the present invention.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.

This invention relates to the field of medical technology, and can be used in dentistry and traumatology, in particular when creating dental implants. Namely, the invention relates to the development and creation of a method for producing a dental implant characterized by high strength, as well as increased ability to activate the process of osteogenesis and osseointegration. The implant obtained by this method is characterized by high biocompatibility, bactericidal properties (reduces pronounced dystrophic and necrotic processes of living tissue), and an increased level of implant surface strength.

A method of making infused bone particles employs the following steps: cutting or shaving whole bone into bone particles, washing the bone particles, demineralizing or decalcifying at least partially the whole bone or bone particles and infusing the bone particles with a supernatant of biologic material or a polyampholyte cryoprotectant or a combination of both to create infused bone particles. The step of infusing includes exposing the bone particles to a negative pressure or vacuum to draw the supernatant and/or the polyampholyte cryoprotectant into the bone particles, or alternatively, exposing the demineralized whole bone to a positive pressure to drive the supernatant and/or the polyampholyte cryoprotectant into the bone. The resultant method creates an infused bone grafting composition having bone particles taken from whole bone, demineralized or decalcified at least partially and infused with one or more of a supernatant of biologic material or a polyampholyte cryoprotectant or both.

A method for controlling generation of biologically desirable voids in a composition placed in proximity to bone or other tissue in a patient by selecting at least one water-soluble inorganic material having a desired particle size and solubility, and mixing the water-soluble inorganic material with at least one poorly-water-soluble or biodegradable matrix material. The matrix material, after it is mixed with the water-soluble inorganic material, is placed into the patient in proximity to tissue so that the water-soluble inorganic material dissolves at a predetermined rate to generate biologically desirable voids in the matrix material into which bone or other tissue can then grow.

Compositions of small molecules, matrices, and isolated cells including methods of preparation, and methods for differentiation, trans-differentiation, and proliferation of animal cells into the osteoblast cell lineage were described. Examples of osteogenic materials that were administered to cells or co-cultured with cells are represented by compounds of Formula II, IV, and VI independently or preferably in combination with a matrix to afford bone cells. Small molecule-stimulated cells were also combined with a matrix, placed with a cellular adhesive or material carrier and implanted to a site in an animal for bone repair. Matrix pretreated with compounds of Formula II, IV, and VI were also used to cause cells to migrate to the matrix that is of use for therapeutic purposes.

Provided herein is technology relating to lipid compositions containing bioactive fatty acids and particularly, but not exclusively, to compositions and methods related to the production and use of structured lipid compositions containing sciadonic and/or pinoleic acid alone or in combination with other bioactive fatty acids including, but not limited to, eicosapentaenoic acid, docosahexaenoic acid, conjugated linoleic acid, and non-β-oxidizable fatty acid analogues such as tetradecylthioacetic acid.

Scaffolds for use in bone tissue engineering include a skeleton and a host component. Methods of preparation of scaffolds include identification of biodegradation properties for the skeleton and the host component. The skeleton is constructed to form a three-dimensional shape. The skeleton is constructed of a first material and has a first rate of biodegradation. The host component fills the three-dimensional shape formed by the skeleton. The host component is constructed of a second material and has a second rate of biodegradation. The first rate of biodegradation is slower than the second rate of biodegradation.