Startseite Formation of nano hydroxyapatite – a straightforward way to bioactivate bone implant surfaces
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Formation of nano hydroxyapatite – a straightforward way to bioactivate bone implant surfaces

  • Berthold Nies , Sophie Rößler und Antje Reinstorf
Veröffentlicht/Copyright: 23. Mai 2013
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International Journal of Materials Research
Aus der Zeitschrift International Journal of Materials Research Band 98 Heft 7

Abstract

Bioactivity has been a field of biomaterials research for more than 25 years. However, clinical application of bioactive implants is progressing rather slowly and is still limited to a few types of bone implants. The increased understanding of the molecular mechanisms underlying bioactivity has opened up new attractive opportunities to render conventional implant materials such as metals, ceramics and even polymers bioactive. In particular, biomimetic nano hydroxyapatite coatings and in-situ mineralising surfaces induced by incorporation of mineralisation seeds are applicable to a wide variety of implant types and materials. They have the potential to set new standards for the improved performance of orthopaedic implants whilst complying with the economic constraints on healthcare.

Keywords: Bioactivity; Nano hydroxyapatite; Bone implant; Mineralisation seeds
* Correspondence address, Dr. Berthold Nies, InnoTERE GmbH (Bioinnovationszentrum), Tatzberg 47 – 49, D-01307 Dresden, Germany, Tel.: +49 351/7 96 57 15, Fax: +49 351/7 96 57 13, E-mail:

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Received: 2007-2-12
Accepted: 2007-4-27
Published Online: 2013-05-23
Published in Print: 2007-07-01

© 2007, Carl Hanser Verlag, München

Artikel in diesem Heft

  1. Contents
  2. Contents
  3. Editorial
  4. Editorial
  5. Basic
  6. Diffusional decomposition of supersaturated solid solutions at grain boundaries
  7. Characterization of oriented protein-ceramic and protein-polymer-composites for cartilage tissue engineering using synchrotron μ-CT
  8. Effect of ageing on optical and thermal properties of YBa2Cu3O7–δ
  9. Calorimetric study and thermodynamic assessment of the SrO–Ga2O3 system
  10. Re-determination of transition temperatures in the Fe–Al system by differential thermal analysis
  11. Applied
  12. Novel corrosion protective coatings for aluminium alloys and steels based on oxidic nanoparticles
  13. Novel biomimetically based ice-nucleating coatings
  14. Biomimetically inspired hybrid materials based on silicified collagen
  15. Magnesium sponges as a bioabsorbable material – attributes and challenges
  16. Morphology of bony tissues and implants uncovered by high-resolution tomographic imaging
  17. Review
  18. The effects of metal implants on inflammatory and healing processes
  19. Formation of nano hydroxyapatite – a straightforward way to bioactivate bone implant surfaces
  20. Drug-eluting stent technologies for vascular regeneration
  21. Fiber structures for the regenerative medicine
  22. Stimuli-responsive polymer layers for advanced cell culture technologies
  23. Notifications
  24. Robert W. Cahn: 1924–2007
  25. DGM News
https://doi.org/10.3139/146.101510
Schlagwörter für diesen Artikel
Bioactivity; Nano hydroxyapatite; Bone implant; Mineralisation seeds

Artikel in diesem Heft

  1. Contents
  2. Contents
  3. Editorial
  4. Editorial
  5. Basic
  6. Diffusional decomposition of supersaturated solid solutions at grain boundaries
  7. Characterization of oriented protein-ceramic and protein-polymer-composites for cartilage tissue engineering using synchrotron μ-CT
  8. Effect of ageing on optical and thermal properties of YBa2Cu3O7–δ
  9. Calorimetric study and thermodynamic assessment of the SrO–Ga2O3 system
  10. Re-determination of transition temperatures in the Fe–Al system by differential thermal analysis
  11. Applied
  12. Novel corrosion protective coatings for aluminium alloys and steels based on oxidic nanoparticles
  13. Novel biomimetically based ice-nucleating coatings
  14. Biomimetically inspired hybrid materials based on silicified collagen
  15. Magnesium sponges as a bioabsorbable material – attributes and challenges
  16. Morphology of bony tissues and implants uncovered by high-resolution tomographic imaging
  17. Review
  18. The effects of metal implants on inflammatory and healing processes
  19. Formation of nano hydroxyapatite – a straightforward way to bioactivate bone implant surfaces
  20. Drug-eluting stent technologies for vascular regeneration
  21. Fiber structures for the regenerative medicine
  22. Stimuli-responsive polymer layers for advanced cell culture technologies
  23. Notifications
  24. Robert W. Cahn: 1924–2007
  25. DGM News
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