Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane

Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane

Abstract A layer of micro‐sized periodontal membrane can buffer most chewing forces to protect the interface between the natural tooth root and alveolar bone. Artificial dental implants usually direct contact onto the alveolar bone without a buffer layer, which increases the risk of surface damage....

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Main Authors: Jin Li, Licheng Hua, Weiyuan Wang, Chenjie Gu, Jianke Du, Conghu Hu
Format: Article
Language:English
Published: Wiley 2021-03-01
Series:Biosurface and Biotribology
Online Access:https://doi.org/10.1049/bsb2.12010
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spelling doaj-b244415aacb44b5faf4b1db9952127182021-06-11T13:28:31ZengWileyBiosurface and Biotribology2405-45182021-03-0171232910.1049/bsb2.12010Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membraneJin Li0Licheng Hua1Weiyuan Wang2Chenjie Gu3Jianke Du4Conghu Hu5School of mechanical Engineering and Mechanics Key Laboratory of Impact and Safety Engineering Ministry of Education Ningbo University Zhejiang Ningbo ChinaSchool of mechanical Engineering and Mechanics Key Laboratory of Impact and Safety Engineering Ministry of Education Ningbo University Zhejiang Ningbo ChinaDepartment of stomatology, Zhejiang University School of Medicine Affiliated Hangzhou First People's Hospital Zhejiang Hangzhou ChinaDepartment of Microelectronics and Engineering Ningbo University Zhejiang Ningbo ChinaSchool of mechanical Engineering and Mechanics Key Laboratory of Impact and Safety Engineering Ministry of Education Ningbo University Zhejiang Ningbo ChinaSchool of mechanical Engineering and Mechanics Key Laboratory of Impact and Safety Engineering Ministry of Education Ningbo University Zhejiang Ningbo ChinaAbstract A layer of micro‐sized periodontal membrane can buffer most chewing forces to protect the interface between the natural tooth root and alveolar bone. Artificial dental implants usually direct contact onto the alveolar bone without a buffer layer, which increases the risk of surface damage. The main purpose of this work was the bionic design of a flexible layer of nanowire scaffold on a titanium implant surface according to the function of the periodontal membrane. Millions of nanowires were woven into a superhydrophilic layer of porous scaffold. The evolution of mechanical properties displayed that the biomimetic nanowire scaffold could absorb a maximum of about 1.59 KJ energy per square centimeter by low‐speed impact. The minimum tensile strength of one nanowire was 2 GPa. A biomimetic flexible periodontal membrane connection functioning between the natural tooth root and alveolar bone has great potential value for developing advanced artificial dental implants for dental restorations.https://doi.org/10.1049/bsb2.12010
collection DOAJ
language English
format Article
sources DOAJ
author Jin Li
Licheng Hua
Weiyuan Wang
Chenjie Gu
Jianke Du
Conghu Hu
spellingShingle Jin Li
Licheng Hua
Weiyuan Wang
Chenjie Gu
Jianke Du
Conghu Hu
Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane
Biosurface and Biotribology
author_facet Jin Li
Licheng Hua
Weiyuan Wang
Chenjie Gu
Jianke Du
Conghu Hu
author_sort Jin Li
title Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane
title_short Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane
title_full Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane
title_fullStr Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane
title_full_unstemmed Flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane
title_sort flexible, high‐strength titanium nanowire for scaffold biomimetic periodontal membrane
publisher Wiley
series Biosurface and Biotribology
issn 2405-4518
publishDate 2021-03-01
description Abstract A layer of micro‐sized periodontal membrane can buffer most chewing forces to protect the interface between the natural tooth root and alveolar bone. Artificial dental implants usually direct contact onto the alveolar bone without a buffer layer, which increases the risk of surface damage. The main purpose of this work was the bionic design of a flexible layer of nanowire scaffold on a titanium implant surface according to the function of the periodontal membrane. Millions of nanowires were woven into a superhydrophilic layer of porous scaffold. The evolution of mechanical properties displayed that the biomimetic nanowire scaffold could absorb a maximum of about 1.59 KJ energy per square centimeter by low‐speed impact. The minimum tensile strength of one nanowire was 2 GPa. A biomimetic flexible periodontal membrane connection functioning between the natural tooth root and alveolar bone has great potential value for developing advanced artificial dental implants for dental restorations.
url https://doi.org/10.1049/bsb2.12010
work_keys_str_mv AT jinli flexiblehighstrengthtitaniumnanowireforscaffoldbiomimeticperiodontalmembrane
AT lichenghua flexiblehighstrengthtitaniumnanowireforscaffoldbiomimeticperiodontalmembrane
AT weiyuanwang flexiblehighstrengthtitaniumnanowireforscaffoldbiomimeticperiodontalmembrane
AT chenjiegu flexiblehighstrengthtitaniumnanowireforscaffoldbiomimeticperiodontalmembrane
AT jiankedu flexiblehighstrengthtitaniumnanowireforscaffoldbiomimeticperiodontalmembrane
AT conghuhu flexiblehighstrengthtitaniumnanowireforscaffoldbiomimeticperiodontalmembrane
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