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Disinfecting gingival crevices by Non-thermal Atmospheric Pressure Plasma

Sun SY

Department of Biomedical Engineering, Chung Yuan Christian University, Taiwan

Ji H

Department of Biomedical Engineering, Chung Yuan Christian University, Taiwan

Hsu JT

Department of Dentistry, China Medical University, Taiwan

Wang MC

Department of Biomedical Engineering, Chung Yuan Christian University, Taiwan

DOI: 10.15761/MDDE.1000101

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Abstract

Recently, dental visits have gradually increased. According to the statistical data of the Taiwan Food and Drug Administration (TFDA) in 2014, the dental disease visits have reached 35 million. Now, we use toothbrushes and mouthwash to remove dental plaque, to keep periodontal diseases away. Non-thermal Atmospheric Pressure Plasma as an application of the bactericidal method is used in the biomedical field. In this study, we designed a brace plasma reactor, and examined bactericidal effects. The results show that our plasma system can achieve 90% inactivation (D-value) by 120 s, when the peak-to-peak voltage, the frequency of the applied voltage, and the input power were 2.52 kVp-p, 5.092 kHz, and 1.227 W. In addition, the surface temperature of the reactor is below 50 ℃ in the D-value, so the plasma reactor is suitable for oral cavity of human.

Keywords

 Periodontal diseases, non-thermal plasma, ROS, E. coli

Introduction

Periodontal disease that is caused by oral biofilms, which are the co-aggregation of bacteria, can lead to the destruction of periodontium. Subgingival biofilms have the capacity to trigger a series of inflammatory responses, which can destroy the gingival cells and the alveolar bone. If it becomes exacerbated, the result is tooth loss [1]. According to the statistical data of the TFDA in 2014, the number of people seeking dental advice has reached 35 million.

Now, we use toothbrushes and mouthwash to remove dental plaque, to keep periodontal diseases away. Whichever we choose, bacteria still remain in the gingival crevices. In the field of nonsurgical treatment, the conventional mechanical treatment can eradicate microbes by scaling and root planing [2]. One of nonsurgical treatments is antimicrobial photodynamic therapy (aPDT). The principle of aPDT is to match suitable wavelength light with photosensitizer to produce singlet oxygen and other reactive species, the poisonous substances to bacteria [3,4]. The device uisng aPDT requires a LED or laser source to activate the photosensitizers. In this study we introduce an alternatve device which is simple and low cost. Recent research shows that in the biomedical field plasma is effective in disinfecting the ambient air at room temperature. Plasma, a state which is ionized gas, contain a lot of species due to many reaction as shown in table. 1, including ionization, excitation, recombination, dissociation, charge exchange, elastic scattering, chemical reaction. The antimicrobial effect are attributed to the oxidation stress of reactive oxygen species (ROS), as Figure 1, that are generated by plasma, including ozone, OH and hydrogen peroxide etc.

ionization

e- + M → M+ + 2e-

hν + M → M+ + e-

M + A → M + A+ + e-

excitation

e- + M → M → e- + M + hν

recombination

M+ + A- → MA

M+ + e- → M

M+ + e- → M + hν

dissociation

e- + MA → M + A + e-

M + AB → M + A + B

e- + MA → M+ + A + 2e-

charge exchange

A+ + B → A + B+

elastic scattering

e- + M → e- + M

A+ + B → A+ + B

chemical reaction

AB + C → A + BC

Table 1: Plasma collision reaction [5].

In this study, to keep periodontal disease away and to improve the used way, we designed a brace plasma reactor, and examined bactericidal effects. In addition, we detected the components of plasma species by Optical emissions spectroscopy (OES), measuring the input of power. Finally, we measured the temperature of the reactor surface to determine whether the inactivation is thermal-dependent, and it is suitable for the human oral cavity.

materials and Methods

Plasma instrument

Figure 1: The bactericidal principle of ROS. (A) a normal bacterium. (B) the ROS attach to bacterium. (C) The cell membrane of bacterium was affected by ROS, forming Volatile substance. (D) the bacterium died by cell membrane cleavage.

Figures 2 and 3 illustrate the Non-thermal Atmospheric Pressure Plasma System which contains the power generator and reactor used in this study. Covered by epoxy that serves as an insulating layer, copper electrodes (0.3 mm wide, distance of each electrode is 0.3 mm) were used as an inverse sinuous high-voltage. Charge would be accumulated on PCB plate which serves as a dielectric layer. Figure 4 shows the self-designed input power generator.

Figure 2: Schematic illustration of the Non-thermal Atmospheric Dielectric Barrier Discharge (DBD) system.

Figure 3: Schematic illustration of the Non-thermal Atmospheric Dielectric Barrier Discharge (DBD) system.

Figure 4: Power generator. (A) self design circuit; (B) real photograph.

Bactericidal test

                For this antimicrobial experiment, E. coli (ATCC 25922) was used, which is a Gram- negative bacterium that would result in dental caries after being cultured for 12 hr. Bacteria were grown in a lysogeny broth (LB) medium to OD600 = 0.08 ± 0.02, corresponding to approximately 107 colony-forming units per ml (CFU/ml). 5 μl of bacterial solution were dropped onto coverslips (diameter is 5 mm) which were placed on the reactor surface randomly as shown in Figure 5. Briefly, there are approximately 5 × 105 CFU bacteria on the coverslips. After the bacterial solution was run dry, colonies of coverslips of the experimental group were placed on the reactor surface randomly, treated in close system, gathered by sonication bacteria that attached to coverslips and cultured 10 μl of bacteria solution on LB agar in 37 ℃ for 8 hr. Finally, colonies were counted to determine the number on LB agar. Colonies of coverslip of the control group were gathered in the same way as described for the experimental group.

Figure 5: The treatment position.

The antibacterial effect of each treatment was determined by calculating the log reduction, log (N0/N), where N0 is the number of coverslip cells present in an untreated sample and N is the number of coverslips cells present in a treated sample.

Results and Discussion

To apply on the oral of human, the temperature of this plasma reactor surface must keep on 40 ± 5 ℃. When the input parameters are 2.52 kVp-p, 5.092 kHz, and 1.227 W, the temperature of this plasma reactor surface within 43.3 ℃. Under this condition, the maximum intensity of lights of 777.32 nm and 845.74 nm, major inactivating species, are detected by OES.

Effects of plasma on microorganisms:

As shown in Figure 6, there are no obvious differences in bactericidal effects between the three randomly selected points. The decimal reduction time for inactivating 90% of the microbial population is achieved by 120 s, and E. coli was completely inactivated in 4 min.

Figure 6: Bactericidal curve.

Optical Emissions Spectroscopy examination:

As shown in Figure 7 and Figure 8, multitude species are observed when working parameters were Vp-p = 2.52 kV, f = 5.092 kHz and P = 1.227 W.

Figure 7: Gas spectra acquired from 200 nm to 900 nm.

Figure 8: Gas spectra acquired from 700 nm to 1000 nm.

Spectra of N2:

The composition of ambient air is 78% N2, so it is a common species of atmospheric pressure plasma.

Spectra of O:

The spectra are observed at 777.32 nm, 845.74 nm and 927.28 nm.

Spectra of radicals (OH):

The spectra are observed at 297.62 nm and 309 nm.

Our plasma system can generate reactive oxygen atoms and radicals which were recorded as major species of plasma for sterilization [6,7].

Electrical measurements:

Typical voltage, current, and power waveforms and lissajous curve are depicted in Figure 9 and Figure 10 respectively.

Figure 9: Voltage, current and power waveforms.

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Figure 10: Lissajous curve.

The power dissipation is calculated by the product of frequency and the area under the curve.

The examination of thermal of reactor:

When the system is worked, plasma is excited while temperature is raised. There was a signpost where the two lines converged as shown in Figure 11. While the plasma was excited, the temperature rose until it stabilized at 53 ℃. In the D-value, the temperature of the reactor surface is below 50 ℃ by 120 s, so the plasma system won’t cause thermal stimulation in oral cavity.

Figure 11: The surface temperature of plasma device.

Conclusions

This study demonstrates a Non-thermal Atmospheric Pressure Plasma System operating in ambient-condition air. According to the bactericidal curve, it is obvious antimicrobial effect is dependent on treatment time by plasma. The bactericidal effects on different places depend on the degree of evenness of the surface. Results show that 90% inactivation and complete inactivation require about 2 min and 4 min of plasma operation at three random places, respectively, so the generating plasma from our reactor is even. When the input parameters are 2.52 kVp-p, 5.092 kHz, and 1.227 W, detected by OES reveals these ROS of plasma which are provided with oxygen stress to bacteria, including OHO etc.

Acknowledgment

First, we thank Yu-Ching Teng, Yi-Sheng Wu, Yu-Hsiu Wang and Ming-Kuan Chen for assistance in performing experiments. We also appreciate every member of Lab 815 who gave any support and suggestions.

Conflict of Interest

We have no conflict of interest.

References

  1. Darveau RP (2010) Periodontitis: a polymicrobial disruption of host homeostasis. Nat Rev Microbiol 8: 481-490. [crossref]
  2. Hope CK, Hindley JA, Khan Z, de Jong ED, Higham SM (2016) Lethal photosensitization of Porphyromonas gingivalis by their endogenous porphyrins under anaerobic conditions: An in vitro study. Photodiagnosis and Photodynamic Therapy 10: 677-682.
  3. Wilson M (2004) Lethal photosensitisation of oral bacteria and its potential application in the photodynamic therapy of oral infections. Photochemical & Photobiological Sciences 3: 412-418.
  4. Abbas M, Zahra C, Mahvash M, Reza F, Neda M, et al. (2016) Antimicrobial photodynamic therapy using diode laser activated indocyanine green as an adjunct in the treatment of chronic periodontitis: A randomized clinical trial. Photodiagnosis and Photodynamic Therapy 14: 93-97.
  5. Eliasson B, Kogelschatz U (1991) Modeling and applications of silent discharge plasmas. IEEE Transactions on Plasma Science 19: 309-323.
  6. Jung H, Kim DB, Gweon B, Moon SY, Choe W (2010) Enhanced inactivation of bacterial spores by atmospheric pressure plasma with catalyst TiO2. Applied Catalysis B-Environmental 93: 212-216.
  7. Smith Simon A, Anghel SD, Papiu M, Dinu O (2009) Diagnostics and active species formation in an atmospheric pressure helium sterilization plasma source. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms 267: 438-441.

Editorial Information

Editor-in-Chief

Dr. Jui Teng Lin

Article Type

Research Article

Publication history

Received date: August 14, 2016
Accepted date: September 02, 2016
Published date: September 05, 2016

Copyright

©2016 Sun SY. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Citation

Sun SY (2016) Disinfecting gingival crevices by Non-thermal atmospheric pressure plasma. Med Devices Diagn Eng: doi: 10.15761/MDDE.1000101

Corresponding author

Wang MC

Wang MC, Graduate Student, Department of Dentistry, China Medical University, Taiwan, Tel: + 88632654524.

E-mail : samwang@cycu.edu.tw

ionization

e- + M → M+ + 2e-

hν + M → M+ + e-

M + A → M + A+ + e-

excitation

e- + M → M → e- + M + hν

recombination

M+ + A- → MA

M+ + e- → M

M+ + e- → M + hν

dissociation

e- + MA → M + A + e-

M + AB → M + A + B

e- + MA → M+ + A + 2e-

charge exchange

A+ + B → A + B+

elastic scattering

e- + M → e- + M

A+ + B → A+ + B

chemical reaction

AB + C → A + BC

Table 1: Plasma collision reaction [5].

Figure 1: The bactericidal principle of ROS. (A) a normal bacterium. (B) the ROS attach to bacterium. (C) The cell membrane of bacterium was affected by ROS, forming Volatile substance. (D) the bacterium died by cell membrane cleavage.

Figure 2: Schematic illustration of the Non-thermal Atmospheric Dielectric Barrier Discharge (DBD) system.

Figure 3: Schematic illustration of the Non-thermal Atmospheric Dielectric Barrier Discharge (DBD) system.

Figure 4: Power generator. (A) self design circuit; (B) real photograph.

Figure 5: The treatment position.

Figure 6: Bactericidal curve.

Figure 7: Gas spectra acquired from 200 nm to 900 nm.

Figure 8: Gas spectra acquired from 700 nm to 1000 nm.

Figure 9: Voltage, current and power waveforms.

Figure 10: Lissajous curve.

Figure 11: The surface temperature of plasma device.