Abstract: The present invention provides novel biomaterials comprising one or more of Mg, Zn and F ions in a carbonate-containing biphasic calcium phosphate (BCP) system. The biomaterial may contain Mg, Zn, F, Mg and Zn, Mg and F, Zn and F, or Mg, Zn and F. The biomaterial may be substantially similar in composition to bone mineral (a carbonate apatite). The biomaterial may feature slow release of Mg, Zn, F, Ca, and P ions. The biphasic calcium phosphate, BCP, may be a mixture of unsubstituted hydroxyapatite (HA) and unsubstituted.-TCP, Ca3(PO4)2. BCP of varying HA/.-TCP ratios may be produced by sintering calcium-deficient apatite, for instance having a Ca/P<1.5, 1.6, 1.67, 1.75 or 1.8 that has been prepared either by a precipitation or by a hydrolysis method or by a solid-state reaction. The amount of each component (by weight %) present in the biomaterials may be as follows: Mg 0.5 to 12 wt %, Zn 1 to 12 wt %, F 0.1 to 4 wt %, calcium 20 to 40 wt %, phosphate 10 to 20 wt %, and carbonate (CO3) 1 to 20 wt %.

Abstract: The present invention provides compositions including saturated calcium phosphate (sCaP) solutions, that may be prepared from mixtures of calcium deficient apatite and one or more of sodium fluoride and zinc chloride, or F or Zn ions. The solutions may be prepared from mixtures of calcium compounds and one or more of sodium or potassium phosphates, sodium or potassium fluoride and zinc salts with, for instance, either phosphoric or hydrochloric acids. Such compositions may be useful for increasing occlusion of dentin tubules, decreasing bacterial attachment to dentin tubules, decreasing bacterial growth or colonization on tooth surfaces such as enamel and dentin surfaces including on dentin tubules, increasing resistance to acid dissolution, inhibiting dental caries formation and progression and tooth decay and inhibiting development of tooth hypersensitivity.

Abstract: The present invention provides compositions including saturated calcium phosphate (sCaP) solutions, that may be prepared from mixtures of calcium deficient apatite and one or more of sodium fluoride and zinc chloride, or F or Zn ions. The solutions may be prepared from mixtures of calcium compounds and one or more of sodium or potassium phosphates, sodium or potassium fluoride and zinc salts with, for instance, either phosphoric or hydrochloric acids. Such compositions may be useful for increasing occlusion of dentin tubules, decreasing bacterial attachment to dentin tubules, decreasing bacterial growth or colonization on tooth surfaces such as enamel and dentin surfaces including on dentin tubules, increasing resistance to acid dissolution, inhibiting dental caries formation and progression and tooth decay and inhibiting development of tooth hypersensitivity.

Abstract: An adherent bioactive calcium phosphate coating is formed on a titanium or titanium alloy substrate by immersing the substrate in an acidic calcium phosphate solution to form a non-apatitic calcium phosphate coating on the substrate. In a second step the coated substrate can be converted to a less reactive coating by being immersed into a basic or neutral solution to convert the coating into an apatite. However if a relatively reactive coating is desired, the second step can be dispensed with.

Abstract: The present invention provides novel biomaterials comprising one or more of Mg, Zn and F ions in a carbonate-containing biphasic calcium phosphate (BCP) system. The biomaterial may contain Mg, Zn, F, Mg and Zn, Mg and F, Zn and F, or Mg, Zn and F. The biomaterial may be substantially similar in composition to bone mineral (a carbonate apatite). The biomaterial may feature slow release of Mg, Zn, F, Ca, and P ions. The biphasic calcium phosphate, BCP, may be a mixture of unsubstituted hydroxyapatite (HA) and unsubstituted .-TCP, Ca3(PO4)2. BCP of varying HA/.-TCP ratios may be produced by sintering calcium-deficient apatite, for instance having a Ca/P<1.5, 1.6, 1.67, 1.75 or 1.8 that has been prepared either by a precipitation or by a hydrolysis method or by a solid-state reaction. The amount of each component (by weight %) present in the biomaterials may be as follows: Mg 0.5 to 12 wt %, Zn 1 to 12 wt %, F 0.1 to 4 wt %, calcium 20 to 40 wt %, phosphate 10 to 20 wt %, and carbonate (CO3) 1 to 20 wt %.

Abstract: The present invention provides a method for mineralizing commercially available guided bone regeneration membranes. The method comprises the steps of (a) providing a commercially available guided bone regeneration membrane, (b) applying a mineralizing solution, and (c) microwaving the membrane. The method may further comprise (d) rinsing the membrane in a solution such as distilled water and (e) drying the membrane. The mineralizing solution may be a solution capable of supplying or delivering a mineral such as calcium or zinc. The invention further provides guided bone regeneration membranes made by the methods described. The guided bone regeneration membrane comprises a mineral, such as, for instance calcium or zinc at a weight percent of at least 5%, at least 10%, at least 12%, at least 15%, at least 18%, at least 20% or at least 25% (weight percent) of the membrane. Further, the invention provides methods for enhancing bone regeneration and methods for inhibiting bacterial infection and inflammation.

Abstract: Compositions useful in the prevention and treatment of osteoporosis and for bone and fracture repair. Slow-releasing calcium phosphate-based materials are disclosed, incorporating Mg, Zn, F and carbonate, which will promote bone formation and inhibit bone resorption and thus be agents for the cited uses.

Abstract: A composition and method for producing interconnective macroporous, resorbable and injectable calcium phosphate-based cements (MICPCs). The composition of the invention sets to poorly crystalline apatitic calcium phosphate after mixing a powder component and an aqueous solution. The multiphasic calcium phosphate components in the cement resorb at different rates allowing the timely replacement by new bone. The interconnected macroporosity in the cement allows for vascularization, entrapment of growth factors, cell colonization and tissue ingrowth. This MICPC can be used for dental and medical applications relating to bone repair, augmentation, reconstruction, regeneration, and osteoporosis treatment, and also for drug delivery, and as scaffolds for tissue engineering.

Abstract: A method for forming a highly adherent coating of a desired calcium phosphate phase on titanium-based substrates for use as orthopedic and dental implants. The calcium phosphate phase coating is electrochemically deposited onto the substrate from a metastable calcium phosphate electrolyte solution using a modulated electrical potential under pH, temperature and electrolyte composition and concentration conditions favorable for forming the desired calcium phosphate.