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Volume 6

Journal of Oral Hygiene & Health

Endodontics & Orthodontics 2018

August 17-18, 2018

AUGUST 17-18, 2018 TOKYO, JAPAN

ANNUAL CONGRESS ON

Endodontics, Orthodontics,

Prosthodontics and Dental Implants

Evaluation of

in vitro

biofilm removal with l2% and 10% sodium hypochlorite

Seyedeh Zahra Rahmani

1

, Mohammad Smiee

1

, Seyedeh Paria Rahmani

1

, Look Vander Sluis

2

and Ferananda Hoffmann Busanello

3

1

Tabriz University of Medical Sciences, Iran

2

University of Groningen, Netherlands

3

Federal University of Rio Grande, Brazil

Introduction & Aim:

Biofilms are communities of microorganisms attached to a surface and embedded in a matrix of

polysaccharides and proteins forming a slimy layer. Oral bacteria have the capacity to form biofilms on distinct surfaces.

Bacteria also form dense colonies on root canal walls and features like isthmuses and lateral canals. Microbial communities

in biofilms are remarkably difficult to eradicate with antimicrobial agents for reasons that have yet to be adequately explained.

Studies have shown that sodium hypochlorite (NaOCl) is the most effective anti-microbial irrigant used during endodontic

treatment. The aim of this study is to evaluate the structure of biofilms and presence of EPS before and after the use of NaOCl

2% and 10%.

Materials & Methods:

Dual species biofilms of

Streptococcus oralis

J22 and

Actinomyces naeslundii

T14VJ1 were grown under

statical conditions and in a Constant Depth Film Fermenter (CDFF). Biofilms grown in the CDFF mimic better the basal layer

of an oral

in vivo

biofilm. For the statical conditions, a confined space was created over saliva coated dentin discs with supply

of 20 ml of modified BHI each 24 h for 4 and 10 days. For the CDFF, saliva coated hydroxyapatite discs biofilm was grown for

96 h at 37

o

C under continuous supply modified BHI at a rate of 45 ml/h. The system was equipped with 15 sample holders and

each sample holder contained 5 saliva coated hydroxyapatite discs, recessed to a depth of 250 mm. After growing the biofilms

NaOCl 2% and 10% were applied for 60 s and 300 s for removing the biofilm. Optical Coherence Tomography (OCT) was used

for high-resolution, real-time imaging of a three-dimensional structure of the biofilm. Confocal Laser Scanning Microscopy

(CLSM) was used to visualize the biofilm matrix, structure and condition of bacteria (LIVE/DEAD staining).

Results:

In the statical biofilm group, OCT images showed reduction of biofilm thickness after applying the NaOCl 2% and

10% and there was a very fluffy structure observable. In the CDFF group, OCT images showed bubble formation in the biofilm

after using NaOCl 10%, but the irrigant did not reduce the thickness of the biofilm or on its consistency. The bubble formation

was also observed in CLSM images. The CLSM showed reduction of the biofilm structure but mostly living bacteria were found

in the remaining biofilm.

Conclusion:

Due to our study our simple irrigation methods are not efficient enough for biofilm removal and we suggest to use

irrigants in several times with increased applying time to achieve better biofilm removal and better treatment results.

rzahra75@gmail.com

J Oral Hyg Health 2018, Volume 6

DOI: 10.4172/2332-0702-C1-009