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Abstract

In clinical dentistry practice, supplemental bone surgery or jawbone defect after tooth extraction must be assisted by a bone-filling material. Cobalt-substituted hydroxyapatite (COHA) effectively promotes bone cell growth, reduces the inflammatory response, and is an antibacterial agent. COHA can therefore be used as an alveolar bone-filling material or guided bone regeneration membrane. Meanwhile, COHA can be used in magnetic resonance imaging (MRI) with negative contrast agents and targeting materials without causing metal interference with the image. Hence, COHA has received increasing amounts of attention in recent years. However, the influence of different cobalt precursors on the synthesized COHA is still unknown. Therefore, COHA synthesized from 3 cobalt precursors (cobalt chloride, cobalt nitrate, and cobalt sulfate) was compared in this study. The results show that COHA synthesized by the precursor with the smallest anion radius, cobalt chloride, has a larger particle size (239 nm) and a higher cobalt ion substitution rate (15.6%). When the cobalt ion substitution rate increases, the MRI has a stronger contrast. Bioactivity data indicate that COHAC is more susceptible to degradation and therefore releases more cobalt ions to contribute to the differentiation of bone cells. Based on these studies, COHAC prepared with the cobalt chloride precursor has a higher cobalt ion substitution rate, faster degradation rate, better image contrast, and better bioactivity. It is therefore the preferred choice of bone-filling material for alveolar bone regeneration.

Keywords

in vitro T2-weighted images alveolar bone regeneration biomaterial biocompatibility ceramics cobalt-substituted hydroxyapatite (COHA)

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References

Bowers

Tung

Trinh

Leventhal

Crisco

Kimia

Fleming

. 2008. Effects of ACL interference screws on articular cartilage volume and thickness measurements with 1.5 T and 3 T MRI. Osteoarthritis Cartilage. 16(5):572–578.

Chen

Yuen

Crawford

Chang

Xiao

. 2015. The effect of osteoimmunomodulation on the osteogenic effects of cobalt incorporated beta-tricalcium phosphate. Biomaterials. 61:126–138.

Fan

Crawford

Xiao

. 2010. Enhancing in vivo vascularized bone formation by cobalt chloride–treated bone marrow stromal cells in a tissue engineered periosteum model. Biomaterials. 31(13):3580–3589.

Xiao

Jin

Sun

. 2010. Electrodeposition on nanofibrous polymer scaffolds: rapid mineralization, tunable calcium phosphate composition and topography. Adv Funct Mater. 20(20):3568–3576.

Hsu

Tang

Tseng

. 2007. Gold nanoparticles induce surface morphological transformation in polyurethane and affect the cellular response. Biomacromolecules. 9(1):241–248.

Ignjatović

Ajdukovic

Rajkovic

Najman

Mihailovic

Uskokovic

. 2015. Enhanced osteogenesis of nanosized cobalt-substituted hydroxyapatite. J Bionic Eng. 12(4):604–612.

Ignjatović

Ajduković

Savić

Najman

Mihailović

Vasiljević

Stojanović

Uskoković

. 2013. Nanoparticles of cobalt-substituted hydroxyapatite in regeneration of mandibular osteoporotic bones. J Mater Sci Mater Med. 24(2):343–354.

Joshi

Lin

Aslam

Prasad

Schultz-Sikma

Edelman

Meade

Dravid

. 2009. Effects of shape and size of cobalt ferrite nanostructures on their MRI contrast and thermal activation. J Phys Chem C Nanomater Interfaces. 113(41):17761–17767.

Kolmas

Piotrowska

Kuras

Kurek

. 2017. Effect of carbonate substitution on physicochemical and biological properties of silver containing hydroxyapatites. Mater Sci Eng C Mater Biol Appl. 74:124–130.

10.

Kramer

Itzkowitz

Wei

. 2014. Synthesis and characterization of cobalt-substituted hydroxyapatite powders. Ceram Int. 40(8):13471–13480.

11.

Lin

Kim

El Haj

Dobson

. 2008. Development of superparamagnetic iron oxide nanoparticles (spions) for translation to clinical applications. IEEE Trans Nanobioscience. 7(4):298–305.

12.

Lin

Chuang

Chang

Chiu

Tang

. 2019. The effect of electrode topography on the magnetic properties and MRI application of electrochemically-deposited, synthesized, cobalt-substituted hydroxyapatite. Nanomaterials (Basel). 9(2):E200.

13.

Lin

Chuang

Wang

Tang

. 2018. A comparative study on the direct and pulsed current electrodeposition of cobalt-substituted hydroxyapatite for magnetic resonance imaging application. Materials. 12(1):E116.

14.

Lin

Yao

Huang

Cheng

Tang

. 2019. Long-term in vitro degradation behavior and biocompatibility of polycaprolactone/cobalt-substituted hydroxyapatite composite for bone tissue engineering. Dent Mater. 35(5):751–762.

15.

Loboda

Jazwa

Wegiel

Jozkowicz

Dulak

. 2005. Heme oxygenase-1-dependent and-independent regulation of angiogenic genes expression: effect of cobalt protoporphyrin and cobalt chloride on vegf and il-8 synthesis in human microvascular endothelial cells. Cell Mol Biol (Noisy-le-grand). 51(4):347–355.

16.

Mabilleau

Filmon

Petrov

Baslé

Sabokbar

Chappard

. 2010. Cobalt, chromium and nickel affect hydroxyapatite crystal growth in vitro. Acta Biomater. 6(4):1555–1560.

17.

Marcacci

Kon

Zaffagnini

Giardino

Rocca

Corsi

Benvenuti

Bianco

Quarto

Martin

. 1999. Reconstruction of extensive long-bone defects in sheep using porous hydroxyapatite sponges. Calcif Tissue Int. 64(1):83–90.

18.

Moseke

Gelinsky

Groll

Gbureck

. 2013. Chemical characterization of hydroxyapatite obtained by wet chemistry in the presence of V, Co, and Cu ions. Mat Sci Eng. 33(3):1654–1661.

19.

Quinlan

Partap

Azevedo

Jell

Stevens

O’Brien

. 2015. Hypoxia-mimicking bioactive glass/collagen glycosaminoglycan composite scaffolds to enhance angiogenesis and bone repair. Biomaterials. 52:358–366.

20.

Rezwan

Chen

Blaker

Boccaccini

. 2006. Biodegradable and bioactive porous polymer/inorganic composite scaffolds for bone tissue engineering. Biomaterials. 27(18):3413–3431.

21.

Sarath Chandra

Elayaraja

Thanigai Arul

Ferraris

Spriano

Ferraris

Asokan

Narayana Kalkura

. 2015. Synthesis of magnetic hydroxyapatite by hydrothermal-microwave technique: dielectric, protein adsorption, blood compatibility and drug release studies. Ceram Int. 41(10):13153–13163.

22.

Stanić

Radosavljević-Mihajlović

Živković-Radovanović

Nastasijević

Marinović-Cincović

Marković

Budimir

. 2015. Synthesis, structural characterisation and antibacterial activity of Ag+-doped fluorapatite nanomaterials prepared by neutralization method. Appl Surf Sci. 337:72–80.

23.

Sumathi

Gopal

. 2015. In vitro degradation of multisubstituted hydroxyapatite and fluorapatite in the physiological condition. J Cryst Growth. 422:36–43.

24.

Tahmasebi Birgani

Fennema

Gijbels

de Boer

van Blitterswijk

Habibovic

. 2016. Stimulatory effect of cobalt ions incorporated into calcium phosphate coatings on neovascularization in an in vivo intramuscular model in goats. Acta Biomater. 36:267–276.

25.

Tang

C-M

Tian

Y-H

Hsu

S-H

. 2015. Poly(vinyl alcohol) nanocomposites reinforced with bamboo charcoal nanoparticles: mineralization behavior and characterization. Materials. 8(8):4895–4911.

26.

Utku

Seckin

Goller

Tamerler

Urgen

. 2014. Carbonated hydroxyapatite deposition at physiological temperature on ordered titanium oxide nanotubes using pulsed electrochemistry. Ceram Int. 40(10):15479–15487.

27.

Wang

Wei

. 2016. Development of multifunctional cobalt ferrite/graphene oxide nanocomposites for magnetic resonance imaging and controlled drug delivery. Chem Eng J. 289:150–160.

28.

Wang

Yang

Qin

Liu

. 2016. In vitro study on the degradation of lithium-doped hydroxyapatite for bone tissue engineering scaffold. Mater Sci Eng C Mater Biol Appl. 66:185–192.

29.

Zhou

Fan

Han

Chang

Yuen

Zhang

Xiao

. 2012. Hypoxia-mimicking mesoporous bioactive glass scaffolds with controllable cobalt ion release for bone tissue engineering. Biomaterials. 33(7):2076–2085.

30.

Liu

Wang

Zhang

Chen

Shi

Yang

. 2011. Solvothermal synthesis of cobalt ferrite nanoparticles loaded on multiwalled carbon nanotubes for magnetic resonance imaging and drug delivery. Acta Biomater. 7(9):3496–3504.

31.

Zheng

Yang

Deng

. 2019. Dual therapeutic cobalt-incorporated bioceramics accelerate bone tissue regeneration. Mat Sci Eng C. 99:770–782.

32.

Zhou

Zhao

. 2016. Hypoxia-mimicking co doped tio2 microporous coating on titanium with enhanced angiogenic and osteogenic activities. Acta Biomater. 43:358–368.

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