Immobilizing Bactericides on Dental Resins via Electron Beam Irradiation

Abstract

Polymerizable bactericides, such as quaternary ammonium compound–based monomers, have been intensively studied as candidates for immobilizing antibacterial components on dental resin. However, they predominantly exhibit a bacteriostatic behavior, rather than bactericidal, as the immobilized components are left with insufficient molecular movement to disrupt the bacterial surface structure through contact-mediated action. In this study, we developed a novel strategy to increase the density of the immobilized bactericide and enhance its antibacterial/antibiofilm properties by combining a surface-grafting technique with electron beam irradiation. A solution of the quaternary ammonium compound–based monomer, 12-methacryloyloxydodecylpyridinium bromide (MDPB), was coated on polymethyl methacrylate (PMMA) resin specimens at the concentrations of 30, 50, and 80 wt%. The coated resins were subsequently exposed to 10 MeV of electron beam irradiation at 50 and 100 kGy, followed by thermal stabilization at 60 °C. The antibacterial effect was evaluated by inoculating a Streptococcus mutans suspension on the coated PMMA resin samples, which exhibited bactericidal effects even after 28 d of aging (P < 0.05, Tukey’s honestly significant difference test). Transmission electron microscopy and bacteriolytic activity evaluation revealed that the S. mutans cells had sustained membrane depolarization. Furthermore, the antibiofilm effects against S. mutans and bacteria collected from human saliva were assessed. The thickness and the percentage of membrane-intact cells of the S. mutans and multispecies biofilms formed on the MDPB-immobilized surfaces were significantly lower than the uncoated PMMA specimens, even after 28-d aging (P < 0.05, Tukey’s honestly significant difference test). Thus, the immobilization of antibacterial MDPB via electron beam irradiation induced rapid membrane depolarization, increasing membrane permeability and eventually causing cell death. Our strategy substantially enhances the antibacterial properties of the resinous materials and inhibits biofilm formation, therefore demonstrating significant potential for preventing infectious diseases in the oral environment.

Keywords

biomaterials anti-bacterial compounds biofilms bacteria dental materials polymer

Get full access to this article

View all access options for this article.

References

Amdjadi

Nojehdehian

Najafi

Ghasemi

Seifi

Dashtimoghadam

Fahimipour

Tayebi

. 2017. Ultraviolet-induced surface grafting of octafluoropentyl methacrylate on polyether ether ketone for inducing antibiofilm properties. J Biomater Appl. 32(1):3–11.

Anjum

Moreau

Riquet

. 2006. Surface designing of polypropylene by critical monitoring of the grafting conditions. J Appl Polym Sci. 100(1):546–553.

Asención Diez

Demonte

Guerrero

Ballicora

Iglesias

. 2013. The ADP-glucose pyrophosphorylase from Streptococcus mutans provides evidence for the regulation of polysaccharide biosynthesis in Firmicutes: ADP-Glc PPases in Firmicutes. Mol Microbiol. 90(5):1011–1027.

Bajpai

Shrivastava

. 2002. Swelling kinetics of a hydrogel of poly(ethylene glycol) and poly(acrylamide-co-styrene). J Appl Polym Sci. 85(7):1419–1428.

Cheng

Weir

Zhang

Arola

Zhou

HHK

. 2013. Dental primer and adhesive containing a new antibacterial quaternary ammonium monomer dimethylaminododecyl methacrylate. J Dent. 41(4):345–355.

Clough

. 2001. High-energy radiation and polymers: a review of commercial processes and emerging applications. Nucl Instrum Methods Phys Res B. 185(1):8–33.

Dang

Jung

Choi

Jeon

. 2018. Difference in virulence and composition of a cariogenic biofilm according to substratum direction. Sci Rep. 8(1):6244.

Ebi

Imazato

Noiri

Ebisu

. 2001. Inhibitory effects of resin composite containing bactericide-immobilized filler on plaque accumulation. Dent Mater. 17(6):485–491.

Gama-Teixeira

Simionato

MRL

Elian

Sobral

MAP

de Cerqueira Luz

MAA

. 2007. Streptococcus mutans–induced secondary caries adjacent to glass ionomer cement, composite resin and amalgam restorations in vitro. Braz Oral Res. 21(4):368–374.

10.

García-Vargas

González-Chomón

Magariños

Concheiro

Alvarez-Lorenzo

Bucio

. 2014. Acrylic polymer-grafted polypropylene sutures for covalent immobilization or reversible adsorption of vancomycin. Int J Pharm. 461(1–2):286–295.

11.

Gilbert

Moore

. 2005. Cationic antiseptics: diversity of action under a common epithet. J Appl Microbiol. 99(4):703–715.

12.

Gupta

Anjum

Jain

Revagade

Singh

. 2004. Development of membranes by radiation-induced graft polymerization of monomers onto polyethylene films. J Macromol Sci Polym Rev. 44(3):275–309.

13.

Gupta

Büchi

Scherer

. 1994. Cation exchange membranes by pre-irradiation grafting of styrene into FEP films: I. Influence of synthesis conditions. J Polym Sci A Polym Chem. 32(10):1931–1938.

14.

Gupta

Scherer

. 1994. Proton exchange membranes by radiation-induced graft copolymerization of monomers into teflon-FEP films. Chimia. 48(1994):127–137.

15.

Gürsel

Gubler

Gupta

Scherer

. 2008. Radiation grafted membranes. In: Scherer

, editor. Fuel cells I. Berlin (Germany): Springer. p. 157–217. Advances in Polymer Science, vol. 215.

16.

Haryanto Singh

Han

Son

Kim

. 2015. Poly(ethylene glycol) dicarboxylate/poly(ethylene oxide) hydrogel film co-crosslinked by electron beam irradiation as an anti-adhesion barrier. Mater Sci Eng C Mater Biol Appl. 46:195–201.

17.

Hegazy

E-SA

Ishigaki

Dessouki

Rabie

Okamoto

. 1982. The study on radiation grafting of acrylic acid onto fluorine-containing polymers: III. Kinetic study of preirradiation grafting onto poly(tetrafluoroethylene–hexafluoropropylene). J Appl Polym Sci. 27(2):535–543.

18.

Imazato

Imai

Russell

Torii

Ebisu

. 1998. Antibacterial activity of cured dental resin incorporating the antibacterial monomer MDPB and an adhesion-promoting monomer. J Biomed Mater Res. 39(4):511–515.

19.

Imazato

Kohno

Tsuboi

Thongthai

Kitagawa

. 2020. Cutting-edge filler technologies to release bio-active components for restorative and preventive dentistry. Dent Mater J. 39(1):69–79.

20.

Imazato

Torii

Tsuchitani

McCabe

Russell

RRB

. 1994. Incorporation of bacterial inhibitor into resin composite. J Dent Res. 73(8):1437–1443.

21.

Ishigaki

Sugo

Senoo

Okada

Okamoto

Machi

. 1982. Graft polymerization of acrylic acid onto polyethylene film by preirradiation method: I. Effects of preirradiation dose, monomer concentration, reaction temperature, and film thickness. J Appl Polym Sci. 27(3):1033–1041.

22.

Jastrzebska

Kaminski

Grazka

Marowska

Sadlo

Gut

Uhrynowska-Tyszkiewicz

. 2014. Effect of gamma radiation and accelerated electron beam on stable paramagnetic centers induction in bone mineral: influence of dose, irradiation temperature and bone defatting. Cell Tissue Bank. 15(3):413–428.

23.

Karaoğlanoğlu

Akgül

. 2010. The association between the DMFS index and levels of salivary Streptococcus mutans and lactobacilli of subjects living in Erzurum, Turkey. J Dent Sci. 5(2):70–74.

24.

Kim

S-C

Huh

. 2012. E-beam graft polymerization of hydrophilic PEG-methacrylate on the surface of PMMA. J Surf Eng Mater Adv Technol. 2(4):264–270.

25.

Kitagawa

Izutani

Hirose

Hayashi

Imazato

. 2014. Development of an antibacterial root canal filling system containing MDPB. J Dent Res. 93(12):1277–1282.

26.

Mao

Auer

Buchalla

Hiller

K-A

Maisch

Hellwig

Al-Ahmad

Cieplik

. 2020. Cetylpyridinium chloride: mechanism of action, antimicrobial efficacy in biofilms, and potential risks of resistance. Antimicrob Agents Chemother. 64(8):e00576–20.

27.

Nasef

. 2004. Preparation and applications of ion exchange membranes by radiation-induced graft copolymerization of polar monomers onto non-polar films. Prog Polym Sci. 29(6):499–561.

28.

Ohno

Yadomae

Miyazaki

. 1982. Enhancement of autolysis of Streptococcus pneumoniae by lysozyme. Microbiol Immunol. 26(4):347–352.

29.

Pandit

Cai

Jung

Lee

Jeon

. 2015. Effect of brief cetylpyridinium chloride treatments during early and mature cariogenic biofilm formation. Oral Dis. 21(5):565–571.

30.

Paradella

Koga-Ito

Jorge

AOC

. 2008. Ability of different restorative materials to prevent in situ secondary caries: analysis by polarized light-microscopy and energy-dispersive x-ray. Eur J Oral Sci. 116(4):375–380.

31.

Pino-Ramos

Ramos-Ballesteros

López-Saucedo

López-Barriguete

Varca

GHC

Bucio

. 2016. Radiation grafting for the functionalization and development of smart polymeric materials. Top Curr Chem. 374(5):63.

32.

Plessier

Gupta

Chapiro

. 1998. Modification of polypropylene fiber by radiation-induced graft copolymerization of acrylonitrile monomer. J Appl Polym Sci. 69(7):1343–1348.

33.

Stelescu

Airinei

Manaila

Fifere

Craciun

Varganici

Doroftei

. 2019. Exploring the effect of electron beam irradiation on the properties of some EPDM-flax fiber composites. Polym Compos. 40(1):315–327.

34.

Thongthai

Kitagawa

Hirose

Noree

Iwasaki

Imazato

. 2020. Development of novel surface coating composed of MDPB and MPC with dual functionality of antibacterial activity and protein repellency. J Biomed Mater Res B Appl Biomater. 108(8):3241–3249.

35.

Xiao

Y-H

Chen

J-H

Fang

Xing

X-D

Wang

Y-J

. 2008. Antibacterial effects of three experimental quaternary ammonium salt (QAS) monomers on bacteria associated with oral infections. J Oral Sci. 50(3):323–327.

36.

Yasir

Dutta

Willcox

MDP

. 2019. Mode of action of the antimicrobial peptide Mel4 is independent of Staphylococcus aureus cell membrane permeability. PLoS One. 14(7):e0215703.

37.

Yassin

German

Rolland

Rickard

Jakubovics

. 2016. Inhibition of multispecies biofilms by a fluoride-releasing dental prosthesis copolymer. J Dent. 48:62–70.

38.

Zhou

Weir

Zhang

Deng

Cheng

HHK

. 2013. Synthesis of new antibacterial quaternary ammonium monomer for incorporation into CaP nanocomposite. Dent Mater. 29(8):859–870.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.45 MB