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Abstract

Implant coatings are frequently applied to modulate tissue response and delivery of drugs. Copper (Cu)-containing coatings on dental implant abutments have been proposed to improve soft tissue integration and reduce the risk for peri-implant infections. However, precise control over Cu loading and release kinetics remains a major challenge. In this study, we introduced a bottom-up coating deposition method based on nanoparticle assembly to allow for local release of Cu ions from implant surfaces. We first doped mesoporous bioactive glass (MBG) nanoparticles with various amounts of Cu. Subsequently, we suspended these Cu-doped MBG (Cu-MBG), Cu-free MBG nanoparticles, or mixtures thereof in chitosan solution and prepared a series of composite coatings on commercially pure titanium disks as model surfaces for transmucosal components of bone implants through electrophoretic deposition (EPD). By changing the Cu-MBG:MBG ratio of the composite coatings, we controlled the Cu release kinetics without changing other coating properties. Human gingival fibroblasts proliferated on the composite coatings except for coatings with the highest amount of Cu, which inhibited their proliferation. The migration rate of human umbilical vein endothelial cells cultured on the composite coatings was highest on coatings containing equal amounts of Cu-MBG and Cu-free MBG. Antibacterial tests confirmed that Cu-containing coatings reduced the growth of Porphyromonas gingivalis up to fivefold compared with uncoated implants. In conclusion, our data indicate that the EPD method is suitable to deposit nanoparticle-based coatings onto dental implants, which enhance endothelial cell migration and reduce bacterial growth.

Impact statement

Precise control over the release of therapeutic agents remains a major challenge for implant coatings. In this study, we introduce a simple and cost-effective way to tune the release of angiogenic and antibacterial copper ions using the electrophoretic deposition technique. Due to the flexibility and mild processing conditions of this technique, our method can also be used to incorporate other therapeutic agents onto implant surfaces.

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References

Saghiri

M.A.

, Freag

, Fakhrzadeh

, Saghiri

A.M.

, and Eid

Current technology for identifying dental implants: a narrative review. Bull Natl Res Cent, 45, 7, 2021.

Abdallah

M.N.

, Badran

, Ciobanu

, Hamdan

, and Tamimi

Strategies for optimizing the soft tissue seal around osseointegrated implants. Adv Healthc Mater, 6, 1700549, 2017.

Schwarz

, Derks

, Monje

, and Wang

Peri-implantitis. J Periodontol, 89, S267, 2018.

Guo

, Gulati

, Arora

, Han

, Fournier

, and Ivanovski

Race to invade: understanding soft tissue integration at the transmucosal region of titanium dental implants. Dent Mater, 37, 816, 2021.

Jennes

M.E.

, Naumann

, Peroz

, Beuer

, and Schmidt

Antibacterial effects of modified implant abutment surfaces for the prevention of peri-implantitis—a systematic review. Antibiotics, 10, 1350, 2021.

Pan

, Zhou

, and Yu

Coatings as the useful drug delivery system for the prevention of implant-related infections. J Orthop Surg Res, 13, 220, 2018.

Barik

, and Chakravorty

Targeted drug delivery from titanium implants: a review of challenges and approaches. Adv Exp Med Biol, 1251, 1, 2020.

Guo

, Gulati

, Arora

, Han

, Fournier

, and Ivanovski

Orchestrating soft tissue integration at the transmucosal region of titanium implants. Acta Biomater, 124, 33, 2021.

Wennerberg

, Sennerby

, Kultje

, and Lekholm

Some soft tissue characteristics at implant abutments with different surface topography—a study in humans. J Clin Periodontol, 30, 88, 2003.

10.

Zhou

, Han

, Xiao

, et al. Accelerated host angiogenesis and immune responses by ion release from mesoporous bioactive glass. J Mater Chem B, 6, 3274, 2018.

11.

Paterson

T.E.

, Bari

, Bullock

A.J.

, et al. Multifunctional copper-containing mesoporous glass nanoparticles as antibacterial and proangiogenic agents for chronic wounds. Front Bioeng Biotechnol, 8, 246, 2020.

12.

Salah

, Parkin

I.P.

, and Allan

Copper as an antimicrobial agent: recent advances. RSC Adv, 11, 18179, 2021.

13.

, Zhou

, Xu

, et al. Copper-containing mesoporous bioactive glass scaffolds with multifunctional properties of angiogenesis capacity, osteostimulation and antibacterial activity. Biomaterials, 34, 422, 2013.

14.

, Xia

, Qiao

, and Liu

Dose-response relationships between copper and its biocompatibility/antibacterial activities. J Trace Elem Med Biol, 55, 127, 2019.

15.

Zhitomirsky

, and Hashambhoy

Chitosan-mediated electrosynthesis of organic–inorganic nanocomposites. J Mater Process Technol, 191, 68, 2007.

16.

Boccaccini

A.R.

, Keim

, Ma

, Li

, and Zhitomirsky

Electrophoretic deposition of biomaterials. J R Soc Interface, 7, S581, 2010.

17.

Besra

, and Liu

A review on fundamentals and applications of electrophoretic deposition (EPD). Prog Mater Sci, 52, 1, 2007.

18.

Gorgin Karaji

, Jahanmard

, Mirzaei

A.H.

, van der Wal

, and Amin Yavari

A multifunctional silk coating on additively manufactured porous titanium to prevent implant-associated infection and stimulate bone regeneration. Biomed Mater, 15, 065016, 2020.

19.

Cheng

, Deng

, Chen

, Jansen

J.A.

, Leeuwenburgh

S.G.C.

, and Yang

Electrodeposited assembly of additive-free silk fibroin coating from pre-assembled nanospheres for drug delivery. ACS Appl Mater Interfaces, 12, 12018, 2020.

20.

Zhitomirsky

, Roether

J.A.

, Boccaccini

A.R.

, and Zhitomirsky

Electrophoretic deposition of bioactive glass/polymer composite coatings with and without HA nanoparticle inclusions for biomedical applications. J Mater Process Technol, 209, 1853, 2009.

21.

Patel

K.D.

, Buitrago

J.O.

, Parthiban

S.P.

, et al. Combined effects of nanoroughness and ions produced by electrodeposition of mesoporous bioglass nanoparticle for bone regeneration. ACS Appl Bio Mater, 2, 5190, 2019.

22.

Meyer

, Rivera

L.R.

, Ellis

, Qi

, Ryan

M.P.

, and Boccaccini

A.R.

Bioactive and antibacterial coatings based on zein/bioactive glass composites by electrophoretic deposition. Coatings, 8, 27, 2018.

23.

Rivera

L.R.

, Cochis

, Biser

, et al. Antibacterial, pro-angiogenic and pro-osteointegrative zein-bioactive glass/copper based coatings for implantable stainless steel aimed at bone healing. Bioact Mater, 6, 1479, 2021.

24.

Rehman

M.A.U.

, Munawar

M.A.

, Schubert

D.W.

, and Boccaccini

A.R.

Electrophoretic deposition of chitosan/gelatin/bioactive glass composite coatings on 316L stainless steel: a design of experiment study. Surf Coat Tech, 358, 976, 2019.

25.

Harcarik

, and Jankovych

Relationship between values of profile and areal surface texture parameters. MM Sci J, 5, 1659, 2016.

26.

Song

, Chen

, Zhang

, et al. Electrophoretic deposition of chitosan coatings modified with gelatin nanospheres to tune the release of antibiotics. ACS Appl Mater Interfaces, 8, 13785, 2016.

27.

Duan

, Jin

, Cui

, et al. A co-delivery platform for synergistic promotion of angiogenesis based on biodegradable, therapeutic and self-reporting luminescent porous silicon microparticles. Biomaterials, 272, 120772, 2021.

28.

Bumgardner

J.D.

, Wiser

, Elder

S.H.

, Jouett

, Yang

, and Ong

J.L.

Contact angle, protein adsorption and osteoblast precursor cell attachment to chitosan coatings bonded to titanium. J Biomater Sci Polym Ed, 14, 1401, 2003.

29.

Xuereb

, Camilleri

, and Attard

N.J.

Systematic review of current dental implant coating materials and novel coating techniques. Int J Prosthodont, 28, 51, 2015.

30.

Corni

, Ryan

M.P.

, and Boccaccini

A.R.

Electrophoretic deposition: from traditional ceramics to nanotechnology. J Eur Ceram Soc, 28, 1353, 2008.

31.

Chen

, Liu

, Yao

, et al. Multilayered bioactive composite coatings with drug delivery capability by electrophoretic deposition combined with layer-by-layer deposition. Adv Biomater Devices Med, 1, 18, 2014.

32.

Chen

, Li

, Yao

, et al. Multilayered drug delivery coatings composed of daidzein-loaded PHBV microspheres embedded in a biodegradable polymer matrix by electrophoretic deposition. J Mat Chem B, 4, 5035, 2016.

33.

Ewald

, Kappel

, Vorndran

, Moseke

, Gelinsky

, and Gbureck

The effect of Cu(II)-loaded brushite scaffolds on growth and activity of osteoblastic cells. J Biomed Mater Res A, 100, 2392, 2012.

34.

Wang

, Ni

, Zhang

, et al. Osteoblast response to copper-doped microporous coatings on titanium for improved bone integration. Nanoscale Res Lett, 16, 146, 2021.

35.

Xia

, and Chang

Well-ordered mesoporous bioactive glasses (MBG): a promising bioactive drug delivery system. J Control Release, 110, 522, 2006.

36.

Fan

, Yang

, Huang

, et al. Luminescent and mesoporous europium-doped bioactive glasses (MBG) as a drug carrier. J Phys Chem C, 113, 7826, 2009.

37.

Sikkema

, Baker

, and Zhitomirsky

Electrophoretic deposition of polymers and proteins for biomedical applications. Adv Colloid Interface Sci, 284, 102272, 2020.

38.

, Huang

, Ren

, and Ji

Inorganic-polymer composite coatings for biomedical devices. Smart Mater Med, 2, 1, 2021.

39.

Yamashita

, Yonehara

, Ding

, Nagai

, Umegaki

, and Matsuda

Electrophoretic coating of multilayered apatite composite on alumina ceramics. J Biomed Mater Res, 43, 46, 1998.

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Tailoring Copper-Doped Bioactive Glass/Chitosan Coatings with Angiogenic and Antibacterial Properties

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