4.8 Article

An Amorphous Peri-Implant Ligament with Combined Osteointegration and Energy-Dissipation

期刊

ADVANCED MATERIALS
卷 33, 期 45, 页码 -

出版社

WILEY-V C H VERLAG GMBH
DOI: 10.1002/adma.202103727

关键词

amorphous titania nanotubes; energy dissipation; osteointegration; tooth periodontal ligament

资金

  1. National Key R&D Program of China [2020YFA0710401, 2020YFA0710403, 2020YFA0710404, 2018YFC1105301, 2018YFC1105302, 2018YFC1105304]
  2. National Natural Science Foundation of China [51532001, 51772011, 51802010, 52073008, 81922019, 51772006, 31670993]
  3. National Youth Topnotch Talent Support Program [QNBJ2019-3]
  4. Beijing Municipal Science & Technology Commission Projects [Z181100002018001]
  5. Peking University Medicine Fund [PKU2020LCXQ009]

向作者/读者索取更多资源

The development of a bioinspired peri-implant ligament with enhanced osteointegration and energy-dissipation capabilities presents new possibilities for creating high-performance implanted materials with increased lifespans. This artificial ligament, based on a polymer-infiltrated, amorphous, titania nanotube array, increases bone-implant contact and reduces effective stress transfer from implant to peri-implant bone, achieving results not previously seen with titanium implants.
Progress toward developing metal implants as permanent hard-tissue substitutes requires both osteointegration to achieve load-bearing support, and energy-dissipation to prevent overload-induced bone resorption. However, in existing implants these two properties can only be achieved separately. Optimized by natural evolution, tooth-periodontal-ligaments with fiber-bundle structures can efficiently orchestrate load-bearing and energy dissipation, which make tooth-bone complexes survive extremely high occlusion loads (>300 N) for prolonged lifetimes. Here, a bioinspired peri-implant ligament with simultaneously enhanced osteointegration and energy-dissipation is presented, which is based on the periodontium-mimetic architecture of a polymer-infiltrated, amorphous, titania nanotube array. The artificial ligament not only provides exceptional osteoinductivity owing to its nanotopography and beneficial ingredients, but also produces periodontium-similar energy dissipation due to the complexity of the force transmission modes and interface sliding. The ligament increases bone-implant contact by more than 18% and simultaneously reduces the effective stress transfer from implant to peri-implant bone by approximate to 30% as compared to titanium implants, which as far as is known has not previously been achieved. It is anticipated that the concept of an artificial ligament will open new possibilities for developing high-performance implanted materials with increased lifespans.

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