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

Hou, Junyu; Xiao, Zuohui; Liu, Zengqian; Zhao, Hewei; Zhu, Yansong; Guo, Lin; Zhang, Zhefeng; Ritchie, Robert O.; Wei, Yan; Deng, Xuliang

doi:10.1002/adma.202103727

Cited by 25 publications

(19 citation statements)

References 71 publications

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“…This composite shows a several-fold enhancement of PLA toughness as well as outstanding improvement in load-bearing capacity and viscoelastic figure of merit, which can be attributed to the amorphous phase of alumina as well as the lamellar structure . Recently, the use of amorphous TiO 2 and intergranular ACP phase for mechanical enhancement in artificial biomaterials was also demonstrated. , …”

Section: Discussionmentioning

confidence: 92%

“…72 This abnormal phenomenon can be attributed to the presence of IAC, which can strengthen interfacial connections between mineral nanoblocks by coordinating with crystal minerals owing to the abundant unsaturated bonds in amorphous materials. 74 Besides the interfacial enhancement, amorphous materials always have excellent energy dissipation capacity, 75 the mechanical properties of IAC themselves can be controlled to tune the mechanical performance of the biomaterials. Aichmayer et al detected an enamel-like layer composed of IAC (primary ACP and ACC), crystal calcite, and fluorapatite in the mandible of crayfish.…”

Section: Discussionmentioning

confidence: 99%

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Role of Inorganic Amorphous Constituents in Highly Mineralized Biomaterials and Their Imitations

et al. 2022

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A highly mineralized biomaterial is one kind of biomaterial that usually possesses a high content of crystal minerals and hierarchical microstructure, exhibiting excellent mechanical properties to support the living body. Recent studies have revealed the presence of inorganic amorphous constituents (IAC) either during the biomineralization process or in some mature bodies, which heavily affects the formation and performance of highly mineralized biomaterials. These results are surprising given the preceding intensive research into the microstructure design of these materials. Herein, we highlight the role of IAC in highly mineralized biomaterials. We focused on summarizing works demonstrating the presence or phase transformation of IAC and discussed in detail how IAC affects the formation and performance of highly mineralized biomaterials. Furthermore, we described some imitations of highly mineralized biomaterials that use IAC as the synthetic precursor or final strengthening phase. Finally, we briefly summarized the role of IAC in biomaterials and provided an outlook on the challenges and opportunities for future IAC and IAC-containing bioinspired materials researches.

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Section: Discussionmentioning

confidence: 92%

Section: Discussionmentioning

confidence: 99%

Role of Inorganic Amorphous Constituents in Highly Mineralized Biomaterials and Their Imitations

et al. 2022

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“…As calculated by integrating the area of the closed-loop at a maximum loading of 1200 μN, the nanonetwork HAp shows a significant enhancement of the value of 1.25 nJ as compared to intrinsic HAp of 0.11 nJ. Moreover, an energy dissipation index, which is the relative contribution of energy dissipation ( W p ) to the total absorbed energy ( W t = W p + W e ), , where W e is the elastically stored energy that was used to further confirm the enhanced energy dissipation of the nanonetwork HAp. The nanonetwork HAp shows a significant enhancement in Wt of 1.28 nJ compared to the Wt of intrinsic HAp (0.15 nJ), giving an energy dissipation index of 97.8% for the nanonetwork HAp as compared to the intrinsic HAp with 71.8% (see Figure S6).…”

Section: Resultsmentioning

confidence: 99%

Bioinspired Nanonetwork Hydroxyapatite from Block Copolymer Templated Synthesis for Mechanical Metamaterials

et al. 2022

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Inspired by Mantis shrimp, this work aims to suggest a bottom-up approach for the fabrication of nanonetwork hydroxyapatite (HAp) thin film using self-assembled polystyrene-block-polydimethylsiloxane (PS-b-PDMS) block copolymer (BCP) with a diamond nanostructure as a template for templated sol–gel reaction. By introducing poly(vinylpyrrolidone) (PVP) into precursors of calcium nitrate tetrahydrate and triethyl phosphite, which limits the growth of forming HAp nanoparticles, well-ordered nanonetwork HAp thin film can be fabricated. Based on nanoindentation results, the well-ordered nanonetwork HAp shows high energy dissipation compared to the intrinsic HAp. Moreover, the uniaxial microcompression test for the nanonetwork HAp shows high energy absorption per volume and high compression strength, outperforming many cellular materials due to the topologic effect of the well-ordered network at the nanoscale. This work highlights the potential of exploiting BCP templated synthesis to fabricate ionic solid materials with a well-ordered nanonetwork monolith, giving rise to the brittle-to-ductile transition, and thus appealing mechanical properties with the character of mechanical metamaterials.

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“…TiO

_2

nanotube arrays constitute a multifunctional materials system that has attracted significant interest in a broad range of applications during the past decade, ranging from solar cells and photocatalysts to sensors, implants and tissue cultivation platforms. [ 1–7 ] This versatility across different scientific disciplines can be traced back to highly tunable structural and electronic properties that affect physics, chemistry as well as biomedical features of TiO

_2

nanotubes. While key structure–property relationships have been unveiled, recipes for tailored nanotube synthesis have been proposed which include anodization [ 8 ] as well as post‐anodization modification.…”

Section: Introductionmentioning

confidence: 99%

Conductive Tracks in Carbon Implanted Titania Nanotubes: Atomic‐Scale Insights from Experimentally Based Ab Initio Molecular Dynamics Modeling

Holm

Kupferer

Mändl

et al. 2022

Advcd Theory and Sims

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Ion implantation of titania nanotubes is a highly versatile approach for tailoring structural and electrical properties. While recently self-organized nanoscale compositional patterning has been reported, the atomistic foundations and impact on electronic structure are not established at this point. To study these aspects, ab initio molecular dynamic simulations based on atomic compositions in C implanted titania nanotubes according to elastic recoil detection analysis are employed. Consistent with experimental data, carbon accumulates in chainlike precipitates, which are favorable for enhancing conductivity, as revealed by density-functional theory electronic ground states calculations are demonstrated.

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

Cited by 25 publications

References 71 publications

Role of Inorganic Amorphous Constituents in Highly Mineralized Biomaterials and Their Imitations

Role of Inorganic Amorphous Constituents in Highly Mineralized Biomaterials and Their Imitations

Bioinspired Nanonetwork Hydroxyapatite from Block Copolymer Templated Synthesis for Mechanical Metamaterials

Conductive Tracks in Carbon Implanted Titania Nanotubes: Atomic‐Scale Insights from Experimentally Based Ab Initio Molecular Dynamics Modeling

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