|DENTAL SCIENCE - ORIGINAL ARTICLE
|Year : 2015 | Volume
| Issue : 6 | Page : 563-566
The efficiency of 2.5% sodium hypochlorite in preventing inoculation of periapical tissues with contaminated patency files: An ex vivo evaluation
Shravan Kini, S Vidhyadhara Shetty, K Harish Shetty, Aravind Kudva, Pradeep Kumar
Department of Conservative Dentistry and Endodontics, Yenepoya Dental College, Deralakatte, Mangalore, Karnataka, India
|Date of Submission||28-Apr-2015|
|Date of Decision||28-Apr-2015|
|Date of Acceptance||22-May-2015|
|Date of Web Publication||1-Sep-2015|
Dr. Shravan Kini
Department of Conservative Dentistry and Endodontics, Yenepoya Dental College, Deralakatte, Mangalore, Karnataka
Source of Support: None, Conflict of Interest: None
| Abstract|| |
The purpose of this in vitro study was to analyze the effectiveness of 2.5% sodium hypochlorite (NaOCl) in preventing inoculation of periapical tissue with contaminated patency files. Fifty single-rooted teeth with single canals were used in the study. They were randomly divided into five groups of which two were experimental groups, two positive controls, and one negative control group. After root canal preparation, teeth in Group I (experimental) were filled with 2.5 NaOCl and #15 stainless steel K-files contaminated with Streptococcus sanguis (ATCC# 10556) were allowed to pass through the root canal into the culture medium and cultured. Teeth in Group II (experimental) were also filled with NaOCl, but contaminated files used in this group were immersed in 2.5% NaOCl for 10 s prior to being placed in the canal. The negative control used sterile files pass through 2.5% NaOCl into the culture medium. The first positive control used contaminated patency files in teeth with saline. The second positive control group placed contaminated files into broth next to teeth filled with NaOCl (to evaluate potential chlorine leakage). The results were as follows. Both the experimental groups and the negative control group showed no growth. Both the positive control groups 100% growth for S. sanguis. This indicates that the NaOCl present in the canal after irrigation was sufficient to kill the test organism.
Keywords: Sodium hypochlorite, patency files and Streptococcus sanguis
|How to cite this article:|
Kini S, Shetty S V, Shetty K H, Kudva A, Kumar P. The efficiency of 2.5% sodium hypochlorite in preventing inoculation of periapical tissues with contaminated patency files: An ex vivo evaluation. J Pharm Bioall Sci 2015;7, Suppl S2:563-6
|How to cite this URL:|
Kini S, Shetty S V, Shetty K H, Kudva A, Kumar P. The efficiency of 2.5% sodium hypochlorite in preventing inoculation of periapical tissues with contaminated patency files: An ex vivo evaluation. J Pharm Bioall Sci [serial online] 2015 [cited 2021 May 6];7, Suppl S2:563-6. Available from: https://www.jpbsonline.org/text.asp?2015/7/6/563/163542
Microorganisms and their products are the main etiologic factors in dentinal, pulpal and periapical pathology. Hence, the removal of bacteria during treatment, inhibition of regrowth of residual bacteria and prevention of bacterial reentry and decolonization are the key factors for successful endodontic treatment. 
Success of endodontic therapy depends on the use of aseptic techniques.  Care must be taken during the procedures to prevent contamination of instruments by the operator and precautions must be taken to prevent contaminated items from entering the canal.  Previous studies have suggested an improved prognosis when previously infected canal spaces test negative to bacteriological sampling prior to obturation. 
Several instrumentation methods that are currently used to debride and shape root canals advocate the use of patency and recapitulation files. Patency files are defined as "small flexible K files, which passively move through the apical constricture without widening it." The small files used to obtain patency are often the same files initially used to negotiate the canal space. Because patency files are used before the canal space has been thoroughly debrided, the files are subject to contamination by bacteria initially present in the canal. When these contaminated files are reused to check the patency and for recapitulation the bacteria can be reintroduced into the tooth and the periapical tissues. 
Thus, the purpose of this in vitro study was to analyze the effectiveness of 2.5% sodium hypochlorite (NaOCl) in preventing inoculation of periapical tissue with contaminated patency files.
| Materials and Methods|| |
The methodology is described under the following subheadings.
- Sample selection and preparation of tooth samples
- Preparation of inoculum
- Assignment of tooth samples into experimental groups
- Culture apparatus.
Sample selection and preparation of tooth samples
Fifty extracted single-rooted human teeth which were intact, noncarious, nonfractured, un-restored were used in this study. Each tooth was radiographed to confirm the presence of the single canal. Conventional access preparation was made with #4 round diamond (SS white). Standardized canal preparation was done with Protaper rotary NiTi files (Dentsply-maillefer, Ballaigues, Switzerland) in a crown down technique 1 mm short of the apical foramen to a 50 size that is up to F5. The apical foramina are enlarged and kept patent using #15 K-file (Mani Co, Tokyo, Japan) approximately 1 mm beyond the apical foramen. 10 ml of 2.5% NaOCl was used as an irrigant during instrumentation. Final flush was completed with aqueous 17% EDTA (B N Laboratories, Mangalore) to open all dentinal tubules to facilitate bacterial ingress. Canal was then dried with a paper point, cementum was coated with two layers of nail polish and apical patency was confirmed. Ligature wire was wrapped around a cervical portion of the teeth to suspend the teeth into the culture media [Figure 1]. Teeth were autoclaved twice to kill the native bacteria.
|Figure 1: Patency files coated with Streptococcus sanguis passed into the teeth with sodium hypochlorite, and teeth was suspended into culture medium with ligature wire|
Click here to view
Preparation of inoculum
Initially, a stock of Streptococcus sanguis (HiMedia Laboratories, Mumbai) was streaked onto a plate of tryptic soy agar (HiMedia Laboratories Mumbai) with 5% defibrinated sheep blood. The plate was cultured under anaerobic condition for 48 h at 37°C. Single colony was obtained from this plate and inoculated into tryptic soy broth in a test tube and cultured overnight under the same condition. Bacteria obtained from this broth were used to coat the patency files.
Assignments of tooth samples into experimental groups
Fifty teeth were randomly divided into five groups of 10 each:
- Group 1 [Figure 2]: Experimental group - Contaminated files with S. sanguis were placed 2-3 mn beyond apical foramen in teeth filled with NaOCl and into the culture medium
- Group 2 [Figure 3]: Experimental group - Contaminated files with S. sanguis were placed in a fresh solution of NaOCl for 10 s and then placed into the teeth filled with NaOCl
- Group 3 [Figure 4]: First positive control group - Contaminated file passed through saline
|Figure 4: Group 3 (first positive control) specimens showing 100% growth|
Click here to view
- Group 4 [Figure 5]: Second positive control group - Contaminated file placed adjacent to teeth filled with NaOCl
|Figure 5: Group 4 (second positivecontrol) specimens showing 100% growth|
Click here to view
- Group 5 [Figure 6]: Negative control group - Sterile files passed through NaOCl in the root canal.
|Figure 6: Group 5 specimen (sterile files - negative control) showing no growth|
Click here to view
Each test tube contains 2 ml of fresh tryptic soy broth. 1 ml of sodium thiosulfate (B N Laboratories, Mangalore) was added to the tubes to neutralize any residual chlorine that may have leaked into the broth. Teeth were suspended into test tubes with ligature wires wrapped around its cervical portion so that the roots are 3-4 mm into the broth. 15 K-type file coated with S. sanguis was placed into the root canal and extended 2-3 mm beyond the apical foramen. Test tubes were capped, and cultures were allowed to grow for 24 h at 37°C. 100 μl of culture from test tube were spread onto plates of tryptic soy agar with 5% sheep blood and allowed to culture for 48 h at 37°C under anaerobic condition.
| Results|| |
None of the teeth in the negative control (Group 5) group exhibited growth. All of the teeth in the first positive control group (contaminated files placed in teeth filled with saline - Group 3) exhibited growth. All of the teeth in the second positive control group (contaminated files placed adjacent to teeth filled with NaOCl - Group 4) exhibited growth. For experimental Groups 1 and 2, 100% of the ten teeth in each group showed no positive bacterial growth. Fishers exact test showed that Group I, Group II and the negative control group were statistically significant from the positive control groups (P = 0.0005).
| Discussion|| |
Currently, the role of microorganisms in pulpal and periapical diseases is well known, and the anaerobic bacteria are recognized as important pathogens. The predominance of anaerobic microorganisms in the apical third, including the cemental canal, is a common trait in most studies.  Further, the presence of bacteria in the cemental canal has been strongly demonstrated in cases of necrotic pulps with the periapical lesion.  Therefore, from a biological standpoint, it does not seem acceptable to preclude the instrumentation of this portion of the canal.
It is clear that there are two major goals concerning cemental canal instrumentation. The first is to establish apical patency. Establishing apical patency is leaving the apical foramen accessible, free from dentin chips, pulp fragments, and other debris. The second goal is apical cleaning. It is intended to eliminate the infection established in the cemental canal. Therefore, from a biological standpoint, it is recommendable that, in cases of pulp necrosis (with or without periapical lesion), both patency and cleaning of the apical foramen are performed. It is important to remember that the second goal is achieved through the first. 
Several instrumentation methods that are currently used to debride and shape root canals advocate the use of patency and recapitulation files.  Because patency files are used before the canal space has been thoroughly debrided, the files are subject to contamination by bacteria initially present in the canal. If these contaminated files are reused, bacteria can be introduced into the tooth after the canals have been thoroughly debrided. Because patency files are taken through the apical constricture, contaminated files can also potentially introduce bacteria into the periapical tissues.  This may affect the outcome of endodontic treatment and may decrease the chances of success. So it is important to disinfect these patency files with an effective irrigant.
This study demonstrated that patency files contaminated with S. sanguis can be disinfected by 2.5% NaOCl present in the root canal after irrigation. S. sanguis was the chosen organism in the study. It is a Gram-positive asporogenous, facultatively anaerobic, catalase-negative cocci. It is an early colonizer in the formation of dental plaque.  S. sanguis is also commonly found in endodontic infections. Culture studies have shown that in teeth with clinical and radiographic signs of apical periodontitis, streptococci appeared to survive following root canal treatment.  It has been shown to invade cervical and mid root dentin and 60 μ at apical dentin.  Finally, S. sanguis is easily grown on tryptic soy agar with 5% sheep blood. Because of alpha hemolysis, they reduce iron in hemoglobin, resulting in greenish color on blood agar, which is clearly evident in this study.
Sodium hypochlorite was the chosen disinfectant in this study. NaOCl is used in concentration varying from 0.5% to 7%.  The antibacterial effect and tissue dissolving capacity of aqueous hypochlorite is a function of its concentration, but so is its toxicity. At high concentration, severe irritation have been reported, when the solution were inadvertently forced into periapical tissues.  On the other hand, the poorer antimicrobial effectiveness of NaOCl in vivo is somewhat disappointing. One natural explanation to poorer in vivo performance of NaOCl is complex root anatomy in the apical third of the canal.  In addition, the chemical milieu in the canal is different from a test tube. Haapasalo using dentine powder showed that the presence of dentine caused marked delays in the killing of the test organism Enterococcus faecalis (Group D streptococci), by 1% NaOCl.  Considering all these factors, it would be rational to use NaOCl in the concentration of 2.5%, which was the concentration used in this study.
Sodium thiosulfate was added in order to neutralize any leakage of residual chlorine into the culture medium. The first positive control group consisted of contaminated files placed through teeth that did not contain NaOCl. All cultures for this group showed bacterial growth as expected. However, it was possible that leakage of NaOCl into the culture medium could prevent bacterial growth despite the addition of sodium thiosulfate. Therefore, sterilized teeth in the second positive control group were filled with NaOCl to account for possible leakage into the culture medium, and the files were placed on the outside of the teeth.
The present study focused on the ability of a single solution to prevent inoculation of periapical tissues with patency files. Other solutions may be just as effective as NaOCl, using the experimental model outlined above. Also, when the experimental design was chosen, it was assumed that the NaOCl would not be able to prevent inoculation of periapical tissues simply by passing the contaminated file through the NaOCl in the tooth. Therefore, group 2 was added to the design to show the results of prolonged exposure the test organism to NaOCl. Obviously, NaOCl exceeded the expectations of the experiment, and its effectiveness could have been shown without immersing the contaminated files for 10 s.
| Conclusion|| |
The present study demonstrated that patency files contaminated with S. sanguis can be effectively disinfected by 2.5% NaOCl present in the root canal after irrigation which means instrumentation process is completed in this case. However, further studies are needed to show the ability of test solutions to prevent inoculation of periapical tissues throughout the instrumentation process.
| References|| |
Weiss EI, Shalhav M, Fuss Z. Assessment of antibacterial activity of endodontic sealers by a direct contact test. Endod Dent Traumatol 1996;12:179-84.
Linke HA, Chohayeb AA. Effective surface sterilization of gutta-percha points. Oral Surg Oral Med Oral Pathol 1983;55:73-7.
Montgomery S. Chemical decontamination of gutta-percha cones with polyvinylpyrrolidone-iodine. Oral Surg Oral Med Oral Pathol 1971;31:258-66.
Izu KH, Thomas SJ, Zhang P, Izu AE, Michalek S. Effectiveness of sodium hypochlorite in preventing inoculation of periapical tissues with contaminated patency files. J Endod 2004;30:92-4.
Baumgartner JC, Falkler WA Jr. Bacteria in the apical 5 mm of infected root canals. J Endod 1991;17:380-3.
Wayman BE, Murata SM, Almeida RJ, Fowler CB. A bacteriological and histological evaluation of 58 periapical lesions. J Endod 1992;18:152-5.
Souza RA. The importance of apical patency and cleaning of the apical foramen on root canal preparation. Braz Dent J 2006;17:6-9.
Cohen S, Burns RC. Pathways of the Pulp, 7 th
ed. St. Louis: Mosby; 1998. p. 203-57.
Ingle JI, Bakland LK, Baumgartner JC. Ingle Endodontics, Quintessence Publishing; Hamilton, Ontario, BC Decker. 2008. p. 997-8.
Sundqvist G, Figdor D, Persson S, Sjögren U. Microbiologic analysis of teeth with failed endodontic treatment and the outcome of conservative re-treatment. Oral Surg Oral Med Oral Pathol Oral Radiol Endod 1998;85:86-93.
Love RM. Regional variation in root dentinal tubule infection by Streptococcus gordonii
. J Endod 1996;22:290-3.
Hülsmann M, Hahn W. Complications during root canal irrigation - Literature review and case reports. Int Endod J 2000;33:186-93.
Haapasalo HK, Siren EK, Waltimo TM. Inactivation of local root canal medicaments by dentin hydroxylapatite and bovine serum albumin. Int Endod J 2001;33:126-31.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5], [Figure 6]