Real-Time Photocatalytic Measurement of Dental Materials in an Open System

Abstract

It is common to encounter discrepancies between in vitro and in vivo studies, particularly when assessing the antibiofilm efficacy of dental materials. Typically, dental materials are tested in a closed system where fresh nutrients are not replenished, the test conditions are static, and the same planktonic bacteria persist. However, real environments are characterized by the continuous supply of fresh nutrients, dynamic saliva flow, and the periodic removal of planktonic bacteria through swallowing. To address these differences, we used an open system approach using microfluidic chips that simulate the nutrient and fluid flow conditions of the mouth. This setup enables the spatiotemporal development of biofilms, facilitates real-time observation, and provides deeper insights into the biofilm formation and removal processes. Photocatalytic dental materials are particularly suitable for use with microfluidic chips, as these devices allow real-time tracking of biofilm dynamics, both with and without light exposure. Nitrogen-doped titanium dioxide effectively produces reactive oxygen species (ROS) under visible light conditions, even when embedded in a resin matrix. These ROS have been shown to inhibit Enterococcus faecalis biofilms. The evaluation of the photocatalytic effects of dental materials using microfluidic chips showed that both new and established biofilms were disrupted by ROS production. ROS weakens the interface between the biofilm and dental material, allowing the biofilm mass to be removed by fluid flow. Furthermore, the open system provided by microfluidic chips demonstrated higher accuracy in evaluating antibiofilm efficiency than the conventional system did. Thus, the developed microfluidic chip is a novel and promising tool for assessing antibiofilm properties, with potential applications in various fields.

Keywords

biofilm titanium dioxide light reactive oxygen species microfluidics enterococcus faecalis

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References

Ahmad Fauzi

Ireland

Sherriff

Bandara

HMHN

. 2022. Nitrogen doped titanium dioxide as an aesthetic antimicrobial filler in dental polymer. Dent Mater. 38(1):147–157.

Ansari

Khan

Ansari

Cho

. 2016. Nitrogen-doped titanium dioxide (N-doped TiO2) for visible light photocatalysis. New J Chem. 40(4):3000–3009.

Asahi

Morikawa

Irie

Ohwaki

2014. Nitrogen-doped titanium dioxide as visible-light-sensitive photocatalyst: designs, developments, and prospects. Chem Rev. 114(19):9824–9852.

Atsumi

Ishihara

Kadoma

Tonosaki

Fujisawa

2004. Comparative radical production and cytotoxicity induced by camphorquinone and 9-fluorenone against human pulp fibroblasts. J Oral Rehabil. 31(12):1155–1164.

Cai

Strømme

Melhus

Engqvist

Welch

2014. Photocatalytic inactivation of biofilms on bioactive dental adhesive. J Biomed Mater Res B Appl Biomater. 102(1):62–67.

Characklis

Cooksey

. 1983. Biofilms and microbial fouling. Adv Appl Microbiol. 29:93–138.

Chun

Mosayyebi

Butt

Carugo

Salta

2022. Early biofilm and streamer formation is mediated by wall shear stress and surface wettability: a multifactorial microfluidic study. Microbiologyopen. 11(4):e1310. doi:10.1002/mbo3.1310

Dawes

Watanabe

Biglow-Lecomte

Dibdin

G-H.

1989. Estimation of the velocity of the salivary film at some different locations in the mouth.J Dent Res. 68(11):1479–1482.

Dette

Pérez-Osorio

Kley

Punke

Patrick

Jacobson

Giustino

Jung

Kern

2014. TiO2 anatase with a bandgap in the visible region. Nano Lett. 14(11):6533–6538.

10.

Dong

Yang

Zhang

Xiu

Ding

Shan

Mou

2022. Photocatalytic Cu2WS4 nanocrystals for efficient bacterial killing and biofilm disruption. Int J Nanomedicine. 17:2735–2750.

11.

Dunnill

Parkin

. 2011. Nitrogen-doped TiO₂ thin films: photocatalytic applications for healthcare environments. Dalton Trans. 40(8):1635–1640.

12.

Eidsvåg

Bentouba

Vajeeston

Yohi

Velauthapillai

2021. TiO₂ as a photocatalyst for water splitting—an experimental and theoretical review. Molecules. 26(6):1687. doi:10.3390/molecules26061687

13.

Han

Lou

Feng

Hong

Yao

Qin

Ouyang

Zhang

, et al. 2022. Spatiotemporal release of reactive oxygen species and NO for overcoming biofilm heterogeneity. Angew Chem Int Ed Engl. 61(33):e202202559. doi:10.1002/anie.202202559

14.

Huang

Zhao

Young

Zhang

Walter

Chen

Nakouzi

Taylor

Loring

Wang

, et al. 2020. Photo-production of reactive oxygen species and degradation of dissolved organic matter by hematite nanoplates functionalized by adsorbed oxalate. Environ Sci Nano. 7(8):2278–2292.

15.

Kristoffersen

Erga

Hamre

Frette

. 2014. Testing fluorescence lifetime standards using two-photon excitation and time-domain instrumentation: rhodamine B, coumarin 6 and lucifer yellow. J Fluoresc. 24(4):1015–1024.

16.

Lecuyer

Rusconi

Shen

Forsyth

Vlamakis

Kolter

Stone

. 2011. Shear stress increases the residence time of adhesion of Pseudomonas aeruginosa. Biophys J. 100(2):341–350.

17.

Lee

J-H

Kaplan

Lee

. 2008. Microfluidic devices for studying growth and detachment of Staphylococcus epidermidis biofilms. Biomed Microdevices. 10(4):489–498.

18.

Lee

M-Y

Yoon

H-W

Kim

K-M

Kwon

J-S.

2024. Antibacterial efficacy and osteogenic potential of mineral trioxide aggregate-based retrograde filling material incorporated with silver nanoparticle and calcium fluoride. J Dent Sci. 19(3):1783–1791.

19.

Lee

Yoon

Lee

Kim

Shin

Kwon

JS.

2024. Mineral trioxide aggregate in membrane form as a barrier membrane in guided bone regeneration. J Dent Sci. 19(3):1653–1666.

20.

Zhou

Huang

Liao

Cheng

Ren

2021. Reactive oxygen species in pathogen clearance: the killing mechanisms, the adaption response, and the side effects. Front Microbiol. 11:622534. doi:10.3389/fmicb.2020.622534

21.

Liu

Fan

Tian

Yang

Sun

2019. Nitrogen-doped black TiO₂ spheres with enhanced visible light photocatalytic performance. SN Appl Sci. 1:487. doi:10.1007/s42452-019-0502-8

22.

Chen

Wang

Zhu

2024. Synthesis of polymerizable betulin maleic diester derivative for dental restorative resins with antibacterial activity. Dent Mater. 40(6):941–950.

23.

Pantaroto

Ricomini-Filho

Bertolini

da Silva

JHD

Neto

NFA

Sukotjo

Rangel

Barão

. 2018. Antibacterial photocatalytic activity of different crystalline TiO₂ phases in oral multispecies biofilm. Dent Mater. 34(7):e182–e195. doi:10.1016/j.dental.2018.03.011

24.

Popescu

Cremer

Tudor

Lupu

A-R.

2016. ROS-mediated cytotoxicity and macrophage activation induced by TiO₂ nanoparticles with different in vitro non-cellular photocatalytic activities. South East Eur J Immunol. 2(1):1–8.

25.

Postek

Pacocha

Garstecki

2022. Microfluidics for antibiotic susceptibility testing. Lab Chip. 22(19):3637–3662.

26.

Prakobphol

Burdsal

Fisher

. 1995. Quantifying the strength of bacterial adhesive interactions with salivary glycoproteins. J Dent Res. 74(5):1212–1218.

27.

Salm

Arendarski

Kramer

. 2023. High frequency of Enterococcus faecalis detected in urinary tract infections in male outpatients—a retrospective, multicenter analysis, Germany 2015 to 2020. BMC Infect Dis. 23(1):812. doi:10.1186/s12879-023-08824-6

28.

Scanlon

Dunnill

Buckeridge

Shevlin

Logsdail

Woodley

Catlow

CRA

Powell

Palgrave

Parkin

, et al. 2013. Band alignment of rutile and anatase TiO₂. Nat Mater. 12(9):798–801.

29.

Stuart

Schwartz

Beeson

Owatz

. 2006. Enterococcus faecalis: its role in root canal treatment failure and current concepts in retreatment. J Endod. 32(2):93–98.

30.

Tang

Niu

Jin

Lin

Cui

2022. Geometric structure design of passive label-free microfluidic systems for biological micro-object separation. Microsyst Nanoeng. 8:62. doi:10.1038/s41378-022-00386-y

31.

Thongsri

Thaitalay

Srisuwan

Khophai

Suksaweang

Rojviriya

Panpisutd

Patntirapong

Gough

2024. Rattanachan, enhanced remineralisation ability and antibacterial properties of sol-gel glass ionomer cement modified by fluoride containing strontium-based bioactive glass or strontium-containing fluorapatite. Dent Mater. 40(4):716–727.

32.

Venkei

Ungvári

Eördegh

Janovák

Urbán

Turzó

2020. Photocatalytic enhancement of antibacterial effects of photoreactive nanohybrid films in an in vitro Streptococcus mitis model. Arch Oral Biol. 117:104837. doi:10.1016/j.archoralbio.2020.104837

33.

Yang

Fan

Yan

Jiang

Doucette

Fillmore

Walker

2018. Influence of culture media, pH and temperature on growth and bacteriocin production of bacteriocinogenic lactic acid bacteria. AMB Express. 8(1):10. doi:10.1186/s13568-018-0536-0

34.

Zhang

X-Y

Sun

Abulimiti

P-P

Z-Y.

2019. Microfluidic system for observation of bacterial culture and effects on biofilm formation at microscale. Micromachines (Basel). 10(9):606. doi:10.3390/mi10090606

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