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Nanostructured Titanium with Ultrafine-Grained Structure as Advanced Engineering Material for Biomedical Application. / Rezyapova, L.R.; Safargalina, Z.A.; Usmanov, E.I.; Valiev, R.R.; Minasov, T.B.; Valiev, R.R.

In: Advanced Engineering Materials, Vol. 26, No. 19, 01.10.2024.

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Rezyapova, L.R. ; Safargalina, Z.A. ; Usmanov, E.I. ; Valiev, R.R. ; Minasov, T.B. ; Valiev, R.R. / Nanostructured Titanium with Ultrafine-Grained Structure as Advanced Engineering Material for Biomedical Application. In: Advanced Engineering Materials. 2024 ; Vol. 26, No. 19.

BibTeX

@article{97fc70d8ea7f4e948c2d947a0fb3deb2,
title = "Nanostructured Titanium with Ultrafine-Grained Structure as Advanced Engineering Material for Biomedical Application",
abstract = "Titanium and its alloys are popular materials for medical application, particularly in implant devices, where high mechanical properties and osseointegration are critical factors for successful implantation. In this work, the progress in the studies of nanostructured commercially pure Grade 4 titanium (nanoTi) is demonstrated, in which an ultrafine-grained structure with nanoscale grain size is formed using severe plastic deformation processing. Nanostructured Grade 4 Ti has a very high strength, and its physical nature and strengthening mechanisms are analyzed herein. NanoTi proved also to have very high osseointegration during in vivo experiments. At the same time, the highest biofunctionality is demonstrated by the etched nanoTi samples with pronounced surface roughness, the latter being revealed from precise roughness measurements. The present study provided convincing evidence of accelerated bone formation on nanoTi, which is very promising for manufacture of dental and maxillofacial implants. {\textcopyright} 2024 Wiley-VCH GmbH.",
keywords = "in vivo experiment, nanostructured titanium, osseointegration, strengthening mechanisms, surface modification, surface roughness, Bone, Medical applications, Metal implants, Titanium alloys, Advanced engineerings, Engineering materials, In-vivo experiments, Nano-structured, Nanostructured titania, Osseointegration, Strengthening mechanisms, Surface-modification, Titania, Ultrafine grained structure, Surface roughness",
author = "L.R. Rezyapova and Z.A. Safargalina and E.I. Usmanov and R.R. Valiev and T.B. Minasov and R.R. Valiev",
note = "Export Date: 19 October 2024 Адрес для корреспонденции: Valiev, R.Z.; Institute of Physics of Advanced Materials, 32 Zaki Validi St., Russian Federation; эл. почта: ruslan.valiev@ugatu.su Сведения о финансировании: Russian Science Foundation, RSF, 22‐19‐00445, 075-15-2022-1114 Текст о финансировании 1: The authors acknowledge the support in part from Russian Science Foundation (grant no. 22\u201019\u201000445) and in part by the Mega\u2010grant State Program (agreement 075\u201015\u20102022\u20101114 dated by June 30, 2022). Текст о финансировании 2: The authors acknowledge the support in part from Russian Science Foundation (grant no. 22-19-00445) and in part by the Mega-grant State Program (agreement 075-15-2022-1114 dated by June 30, 2022).",
year = "2024",
month = oct,
day = "1",
doi = "10.1002/adem.202400394",
language = "Английский",
volume = "26",
journal = "Advanced Engineering Materials",
issn = "1438-1656",
publisher = "Wiley-Blackwell",
number = "19",

}

RIS

TY - JOUR

T1 - Nanostructured Titanium with Ultrafine-Grained Structure as Advanced Engineering Material for Biomedical Application

AU - Rezyapova, L.R.

AU - Safargalina, Z.A.

AU - Usmanov, E.I.

AU - Valiev, R.R.

AU - Minasov, T.B.

AU - Valiev, R.R.

N1 - Export Date: 19 October 2024 Адрес для корреспонденции: Valiev, R.Z.; Institute of Physics of Advanced Materials, 32 Zaki Validi St., Russian Federation; эл. почта: ruslan.valiev@ugatu.su Сведения о финансировании: Russian Science Foundation, RSF, 22‐19‐00445, 075-15-2022-1114 Текст о финансировании 1: The authors acknowledge the support in part from Russian Science Foundation (grant no. 22\u201019\u201000445) and in part by the Mega\u2010grant State Program (agreement 075\u201015\u20102022\u20101114 dated by June 30, 2022). Текст о финансировании 2: The authors acknowledge the support in part from Russian Science Foundation (grant no. 22-19-00445) and in part by the Mega-grant State Program (agreement 075-15-2022-1114 dated by June 30, 2022).

PY - 2024/10/1

Y1 - 2024/10/1

N2 - Titanium and its alloys are popular materials for medical application, particularly in implant devices, where high mechanical properties and osseointegration are critical factors for successful implantation. In this work, the progress in the studies of nanostructured commercially pure Grade 4 titanium (nanoTi) is demonstrated, in which an ultrafine-grained structure with nanoscale grain size is formed using severe plastic deformation processing. Nanostructured Grade 4 Ti has a very high strength, and its physical nature and strengthening mechanisms are analyzed herein. NanoTi proved also to have very high osseointegration during in vivo experiments. At the same time, the highest biofunctionality is demonstrated by the etched nanoTi samples with pronounced surface roughness, the latter being revealed from precise roughness measurements. The present study provided convincing evidence of accelerated bone formation on nanoTi, which is very promising for manufacture of dental and maxillofacial implants. © 2024 Wiley-VCH GmbH.

AB - Titanium and its alloys are popular materials for medical application, particularly in implant devices, where high mechanical properties and osseointegration are critical factors for successful implantation. In this work, the progress in the studies of nanostructured commercially pure Grade 4 titanium (nanoTi) is demonstrated, in which an ultrafine-grained structure with nanoscale grain size is formed using severe plastic deformation processing. Nanostructured Grade 4 Ti has a very high strength, and its physical nature and strengthening mechanisms are analyzed herein. NanoTi proved also to have very high osseointegration during in vivo experiments. At the same time, the highest biofunctionality is demonstrated by the etched nanoTi samples with pronounced surface roughness, the latter being revealed from precise roughness measurements. The present study provided convincing evidence of accelerated bone formation on nanoTi, which is very promising for manufacture of dental and maxillofacial implants. © 2024 Wiley-VCH GmbH.

KW - in vivo experiment

KW - nanostructured titanium

KW - osseointegration

KW - strengthening mechanisms

KW - surface modification

KW - surface roughness

KW - Bone

KW - Medical applications

KW - Metal implants

KW - Titanium alloys

KW - Advanced engineerings

KW - Engineering materials

KW - In-vivo experiments

KW - Nano-structured

KW - Nanostructured titania

KW - Osseointegration

KW - Strengthening mechanisms

KW - Surface-modification

KW - Titania

KW - Ultrafine grained structure

KW - Surface roughness

UR - https://www.mendeley.com/catalogue/f7f04d55-90ba-3b71-b0ee-e7b23ccf2902/

U2 - 10.1002/adem.202400394

DO - 10.1002/adem.202400394

M3 - статья

VL - 26

JO - Advanced Engineering Materials

JF - Advanced Engineering Materials

SN - 1438-1656

IS - 19

ER -

ID: 126384819