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Abstract

The objective in this study was to enhance osteogenic responses (in vitro and in vivo) to roughened titanium (Ti) dental implants through the formation of superhydrophilic TiO₂ nanonetwork surface structure. Sandblasting and acid etching (SLA) was used to roughen the Ti surface. An electrochemical anodization process was then used to form a superhydrophilic TiO₂ nanonetwork on the SLA Ti surfaces. The pore size of the nanonetwork structure ranged from a few nanometers to more than 100 nm, which is on the same scale as many biological species. Human bone marrow mesenchymal stem cells were used as an in vitro test model. The TiO₂ nanonetwork structure was shown to have a significantly positive effect on hydrophilicity, protein adsorption, cell adhesion, cell migration, cell mineralization, and the gene and protein expression of osteogenic markers. The osseointegration of an anodized SLA screw-type Ti dental implant was investigated in vivo via implantation in the femur of New Zealand white rabbits for durations of 4 or 12 wk. The presence of a superhydrophilic surface TiO₂ nanonetwork was shown to significantly enhance the bone-to-implant contact of the roughened SLA screw-type Ti dental implants. Overall, the proposed superhydrophilic TiO₂ nanonetwork structure on the roughened SLA Ti surface proved highly effective in enhancing osteogenic responses in vitro and in vivo.

Keywords

dental implants surface properties nanostructures hydrophilicity bone-implant interface osseointegration

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References

Alayan

Vaquette

Saifzadeh

Hutmacher

Ivanovski

2017. Comparison of early osseointegration of SLA® and SLActive® implants in maxillary sinus augmentation: a pilot study. Clin Oral Implants Res. 28(11):1325–1333.

Bello

Fouillen

Badia

Nanci

2017. A nanoporous titanium surface promotes the maturation of focal adhesions and formation of filopodia with distinctive nanoscale protrusions by osteogenic cells. Acta Biomater. 60:339–349.

Blatt

Pabst

Schiegnitz

Hosang

Ziebart

Walter

Al-Nawas

Klein

. 2018. Early cell response of osteogenic cells on differently modified implant surfaces: sequences of cell proliferation, adherence and differentiation. J Craniomaxillofac Surg. 46(3):453–460.

Ducy

Karsenty

1998. Genetic control of cell differentiation in the skeleton. Curr Opin Cell Biol. 10(5):614–619.

Harada

Tagashira

Fujiwara

Ogawa

Katsumata

Yamaguchi

Komori

Nakatsuka

1999. Cbfa1 isoforms exert functional differences in osteoblast differentiation. J Biol Chem. 274(11):6972–6978.

Herrero-Climent

Lázaro

Vicente Rios

Lluch

Marqués

Guillem-Martí

Gil

. 2013. Influence of acid-etching after grit-blasted on osseointegration of titanium dental implants: in vitro and in vivo studies. J Mater Sci Mater Med. 24(8):2047–2055.

Hou

Syam

Lan

Huang

Chan

Tsai

Saito

Liu

Chou

, et al. 2020. Development of a surface-functionalized titanium implant for promoting osseointegration: surface characteristics, hemocompatibility, and in vivo evaluation. Appl Sci. 10(23):8582.

Jiang

Jin

Geng

Deng

Lin

Zhao

2019. Maintenance and restoration effect of the surface hydrophilicity of pure titanium by sodium hydroxide treatment and its effect on the bioactivity of osteoblasts. Coatings. 9(4):222.

Karjuna

Ganapathy

2020. Surface modifications on osseointegration of dental implants—a literature review. Drug Invent Today. 14(4):525–529.

10.

Langowski

JKA

Rummenie

Pieters

RPM

Kovalev

Gorb

van Leeuwen

. 2019. Estimating the maximum attachment performance of tree frogs on rough substrates. Bioinspir Biomim. 14(2):025001.

11.

Liu

Zhang

Liu

Chen

Zhou

2015. The nanoscale geometry of TiO₂ nanotubes influences the osteogenic differentiation of human adipose-derived stem cells by modulating H3K4 trimethylation. Biomaterials. 39:193–205.

12.

Masrouri

Faraji

Pedram

Sadrkhah

2020. In-vivo study of ultrafine-grained CP-Ti dental implants surface modified by SLActive with excellent wettability. Int J Adhes Adhes. 102:102684.

13.

Najeeb

Mali

Syed

AUY

Zafar

Khurshid

Alwadaani

Matinlinna

. 2019. Advanced dental biomaterials. In: Khurshid

Najeeb

Zafar

Sefat

, editors. Dental implants materials and surface treatments. Cambridge (UK): Woodhead Publishing. p. 581–598.

14.

Nakashima

Zhou

Kunkel

Zhang

Deng

Behringer

de Crombrugghe

2002. The novel zinc finger-containing transcription factor osterix is required for osteoblast differentiation and bone formation. Cell. 108(1):17–29.

15.

Nasrollahi

Banerjee

Qayum

Banerjee

Pathak

2017. Nanoscale matrix topography influences microscale cell motility through adhesions, actin organization, and cell shape. ACS Biomater Sci Eng. 3(11):2980–2986.

16.

Nevins

Parma-Benfenati

Sava

Quinti

Galletti

Mendoza-Azpur

Valdivia

Koo

Kim

. 2018. Clinical and histologic evaluations of immediately placed SLA dental implants. Int J Periodontics Restorative Dent. 38(2):165–170.

17.

Brammer

YSJ

Teng

Engler

Chien

Jin

2009. Stem cell fate dictated solely by altered nanotube dimension. Proc Natl Acad Sci U S A. 106(7):2130–2135.

18.

Perng

Kao

Yang

Lin

Chu

Wang

Chiou

. 2008. Culturing adult human bone marrow stem cells on gelatin scaffold with pNIPAAm as transplanted grafts for skin regeneration. J Biomed Mater Res A. 84A(3):622–630.

19.

Sartoretto

Calasans-Maia

Resende

Câmara

Ghiraldini

Barbosa Bezerra

Granjeiro

Calasans-Maia

. 2020. The influence of nanostructured hydroxyapatite surface in the early stages of osseointegration: a multiparameter animal study in low-density bone. Int J Nanomedicine. 15:8803–8817.

20.

Scarano

Piattelli

Quaranta

Lorusso

2017. Bone response to two dental implants with different sandblasted/acid-etched implant surfaces: a histological and histomorphometrical study in rabbits. BioMed Res Int. 2017:8724951.

21.

Tugulu

Löwe

Scharnweber

Schlottig

2010. Preparation of superhydrophilic microrough titanium implant surfaces by alkali treatment. J Mater Sci Mater Med. 21(10):2751–2763.

22.

Lin

Zhang

. 2020. Biomechanical and morphometric evaluation of a strontium-incorporated implant and four commercially available implants: a study in rabbits. Int J Oral Maxillofac Implants. 35(3):531–541.

23.

Yang

Huang

. 2019. Multiform TiO₂ nano-network enhances biological response to titanium surface for dental implant applications. Appl Surf Sci. 471:1041–1052.

24.

Zhao

Schwartz

Wieland

Rupp

Geis-Gerstorfer

Cochran

Boyan

. 2005. High surface energy enhances cell response to titanium substrate microstructure. J Biomed Mater Res A. 74A(1):49–58.

25.

Zhu

Robey

Boskey

2008. Osteoporosis. In: Marcus

Feldman

Kelsey

, editors. The biochemistry of bone. 3rd ed. San Diego (CA): Academic Press. p. 191–240.

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TiO 2 Nanonetwork on Rough Ti Enhanced Osteogenesis In Vitro and In Vivo

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