Barralet
Jake Barralet, Montreal CA
Patent application number | Description | Published |
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20090220566 | BIOIMPLANTS FOR USE IN TISSUE GROWTH - Disclosed herein is an implant for use in stimulating tissue growth. The implant comprises a body with a body core and a body surface. The body is made from a non-hydrogel polymer material. A tissue growth stimulating material is disposed within the body core or deposited onto the body surface, in an amount which is sufficient to stimulate tissue growth within the body core or adjacent to the body surface. Also disclosed are implant bodies made from ceramic, metallic materials, and non-copper containing hydrogels. | 09-03-2009 |
20100303888 | COMPOSITION FOR ENHANCING BONE FORMATION - Disclosed herein is a matrix for inducing or enhancing osteoclast differentiation. The matrix comprises a material having an osteoclastogenic agent associated therewith, the agent being releasable from the material in an amount which is sufficient to induce or enhance osteoclast differentiation. | 12-02-2010 |
20110117149 | INORGANIC NANOTUBES - Discloses are stabilized calcium pyrophosphate nanotubes, a process for making calcium pyrophosphate nanotubes comprising agitating at less than 2 OkHz an aqueous suspension of a calcium and a phosphate for a time sufficient to precipitate said inorganic calcium pyrophosphate nanotubes, and uses thereof. | 05-19-2011 |
20130121956 | Composition for Enhancing Bone Formation - Disclosed herein is a matrix for inducing or enhancing osteoclast differentiation. The matrix comprises a material having an osteoclastogenic agent associated therewith, the agent being releasable from the material in an amount which is sufficient to induce or enhance osteoclast differentiation. | 05-16-2013 |
Jake E. Barralet, Montreal CA
Patent application number | Description | Published |
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20090291930 | FIBROUS CALCIUM PYROPHOSPHATE PARTICLES AND METHODS OF MAKING AND USING SAME - Fibrous calcium pyrophosphate particles with a unique fibrous nanostructure are disclosed. The invention includes a composition, comprising fibrous particles, wherein the fibrous particles include fibers and the fibers include calcium and pyrophosphate. Also included are methods for making calcium pyrophosphate particles wherein solutions of calcium salt and pyrophosphate salt are combined to form the particles. Pharmaceutical compositions and methods for treating a patent using the disclosed particles are also described. | 11-26-2009 |
20120232164 | FIBROUS CALCIUM PYROPHOSPHATE PARTICLES AND METHODS OF MAKING AND USING SAME - Fibrous calcium pyrophosphate particles with a unique fibrous nanostructure are disclosed. The invention includes a composition, comprising fibrous particles, wherein the fibrous particles include fibers and the fibers include calcium and pyrophosphate. Also included are methods for making calcium pyrophosphate particles wherein solutions of calcium salt and pyrophosphate salt are combined to form the particles. Pharmaceutical compositions and methods for treating a patent using the disclosed particles are also described. | 09-13-2012 |
20140120149 | CALCIUM SULPHATE BASED COMPOSITE - A composite comprising monetite and calcium sulphate is provided. | 05-01-2014 |
Jake Edward Barralet, Montreal CA
Patent application number | Description | Published |
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20100145469 | BIOCERAMIC IMPLANTS HAVING BIOACTIVE SUBSTANCE - A bioceramic endoprosthesis includes a reservoir or deposition of a bioactive substance, such as an angiogenic growth factor, that can provide a biological function, such as vascularization of the endoprosthesis. Such a bioceramic can be prepared by a low temperature direct rapid prototyping inkjet printing system and process. Such a direct inkjet printing process includes the following: applying a ceramic powder to a substrate; inkjet printing a binder solution onto the ceramic powder so as to form a bound ceramic; inkjet printing a bioactive substance solution onto the bound ceramic, wherein the bioactive substance is printed on the bound ceramic at the low temperature (e.g., room temperature or within +/−10° C. of 25° C.); and repeating the process in order to form the bioceramic endoprosthesis. | 06-10-2010 |
20140305344 | MAGNESIUM PHOSPHATE BIOMATERIALS - There is provide a solid cement reactant comprising a dehydrated magnesium phosphate, and/or an amorphous or partially amorphous magnesium phosphate, and/or Farringtonite. | 10-16-2014 |