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Brazilian Journal of Oral Sciences
Piracicaba Dental School - UNICAMP
EISSN: 1677-3225
Vol. 6, Num. 20, 2007, pp. 1283 - 1288

Brazilian Journal of Oral Sciences, Vol. 6, No. 20, January - March 2007, pp. 1283 - 1288

Research on staphylococcus spp in biofilm formation in water pipes and sensibility to antibiotics

Marcelo Lancellotti 1, Mônica Pereira de Oliveira1 , Fernando Antonio de Ávila1*

1Department of Veterinary and Agrarian Science (Faculdade de Ciências Agrárias e Veterinárias), State University in São Paulo (Universidade Estadual Paulista), Jaboticabal, SP, Brazil.
Correspondence to: Fernando Antonio de Ávila Universidade Estadual Paulista - Faculdade de Ciências Agrárias e Veterinárias Departamento de Patologia Veterinária Laboratório de Microbiologia Rodovia Prof. Paulo Donato Castellane, Km 05 CEP 14884-900 - Jaboticabal - SP - Brazil Phone (055-21-16-3209-26-52) Fax - (055-21-16-3202-42-75) E-mail: favila@fcav.unesp.br

Received for publication: August 23, 2006
Accepted: February 26, 2007

Code Number: os07008

Abstract

Water from dental equipment presents risks for surgeon-dentists as well as for patients because it might work as a means of dissemination/transmission of microorganisms. The objective of this study was to verify the quality of the water used in dental equipment by means of microbiological analysis, accomplishing the count of Staphylococcus spp. There have been collected 160 samples of water from reservoirs, taps used for hand washing, air-water syringes, and high-speed handpieces, in 40 dental offices in the city of Barretos, São Paulo. The rules concerning bacteriological analysis in cfu/mL from Standard Methods for the Examination of Water and Wastewater have been followed. The analysis of the results has made it possible to verify that out of the total of samples, 28% did not meet the standards of potability established by the American Dental Association. Regarding the origin of analyzed S. aureus, the most contaminated sites were high-speed handpieces in private offices (76%) and in dental care plan offices (71%), followed by air-water syringe in dental care plan offices (64%). For S. epidermidis samples, the most contaminated sites were high-speed handpieces in SUS (Brazilian Government Health System) dental offices (22%) and in dental care plan offices (14%). The most contaminated sites were dental offices that saw patients under dental care plans. Concerning tested antibiotics, the ones that presented better results as to sensibility to strain S. epidermidis were vancomycin and ciprofloxacin (100%) and, as to sensibility to strain S. aureus, it was ciprofloxacin (97%).

Key Words: Staphylococcus spp, cross contamination, biofilm, dental office, water line

Introduction

In Dentistry, the control of cross infection is advised with the objective of reducing or eliminating the exposure of patients and dental staff to microorganisms, thus avoiding disease transmission. Therefore, a number of international entities, which regulate the dental practice, have launched standards for infection control, introducing measures for risk reduction and assurance of safer dental treatments. On the other hand, an important issue in the prevention of contamination at the dental office has been neglected: the quality of water used in the treatment1.

Mills2 says that the water line of dental equipment presents itself as an ideal means for microbial colonization and proliferation due to the extensive surface and a mild flow within the pipes. As a consequence of the bacterial biofilm, which is formed inside the pipes, the water deriving from the air-water syringe and the high-speed handpiece might have a high concentration of microorganisms.

The list of microorganisms, which have already been identified in the water supply of dental equipment, is long and variable1: Bacillus subtilis, Enterecoccus ssp, Lactobacillus ssp, Pseudomonas aeruginosas. Nevertheless, the literature is scarce regarding the isolation of Staphylococcus spp, a microorganism which is usually found in the clinical dental environment2.

For Barbeau3, Staphylococcus, which usually takes part in the regular microbiota of the host, does not take part in the biofilm of such water line; however, it might become opportunistic pathogens before a systemic unbalanced scene; therefore, there is a 10-fold increase of pathogenic bacteria over the surface and dental biofilm in individuals presenting poor dental health. Such fact might favor the introduction of bacteria in injured oral tissues as well as increase the reflux of such microorganisms for the water line pipe, which, whenever set by the air-water syringe and the high-speed handpiece, contaminate the surface of the dental equipment, predisposing to cross contamination risk among patients and staff by aerosol formation4.

Considering the possibility of forming biofilm in water pipes, which contain bacteria populations deriving from a number of sources, such as water tanks with no maintenance, contaminated reservoirs, and the reflux of water from patients themselves during the surgical act, it is important to think about the control of the quality of water in dental equipment, reducing the risk of cross infection.

Therefore, the objective of the present study was to isolate and identify strains of S. aureus and S. epidermidis in water from dental offices in the city of Barretos-SP and to evaluate the sensibility of bacteria as to different antibiotics.

Material and Methods

During the period from January to July, 2005, there have been analyzed 160 samples of water from 40 dental offices strategically located in every neighborhood in the city of Barretos, São Paulo, in a way that such sampling represented the whole city. At these dental offices, water was collected from four different sites (high-speed handpiece, taps used for hand washing, water reservoir, and air-water syringe), and such equipment was not subjected to previous disinfection and collection was carried out during the afternoon, after four hours of equipment usage. In every dental office chosen for the research, the following items have been analyzed: kind of water reservoir (on the floor or in PET plastic bottles), water source (filtered, city supply system, or distilled), and equipment usage time.

Out of the total of collected samples, 14 derived from dental care plan offices, 9 came from SUS (Brazilian Government Health System) dental offices, and 17 came from private dental offices. Regarding 14 dental care plan offices, eight used filtered water and six used tap water from the city supply system, eleven used 500-mL PET bottles and three used reservoirs on the floor. As to 9 SUS dental offices, they all used tap water from the city supply system and individual 2000-mL reservoirs on the floor. All 17 private dental offices used filtered water and 500-mL PET bottles as reservoir. Two-hundred-mL was collected from each of the 160 samples, deriving from 40 dental offices with four samples each. Such samples were stored in previously sterilized 250-mL collection bottles with screw cap in a total of 160 collection bottles. Water from reservoirs on the floor was collected using 200-mL sterile disposable syringes. Water from high-speed handpieces was collected setting the pedal and pouring the flow in the collection bottle; the first flow was set apart for 30 seconds. Water from air-water syringes was directly drained inside the collection bottle. Samples of tap water were directly collected in the bottle. To every water sample, it was added 0.5-mL sodium thiosulphate in the final concentration of 10mg/L5. Samples were stored in thermal boxes with ice and transported to the microbiology lab of the Veterinary Pathology Department at FCAVJ-UNESP.

Water samples were filtered in 0.55-µm Millipore® filters, in a total of 200mL5. Following, every filter was placed in the center of Petri dishes containing Staphylococcus agar medium 110, which were incubated in a sterilizer at the temperature of 37ºC for 24-48 hours. Colonies with suspicion of belonging to gender Staphylococcus of white or yellow color and with shiny colonies formed over the culture medium were stained by the Gram method for observation of their morphotinctorial characteristics.

Three colonies were picked from each sample and only colonies presenting positive morphotinctorial characteristics for the Staphylococcus gender were subjected to biochemical identification tests by means of evidences such as coagulase, catalase, hemolysis, mannitol fermentation, and Dnase.

Positive reference samples used in this work were: S. aureus ATCC 6538 and S. epidermidis ATCC 12228 (Fundação André Tosello - Campinas - SP).

Water quantitative bacteriologic analysis in cfu/mL were carried out using 0.55-µm Millipore® filter and they followed recommendations by the Standard Methods for the Examination of Water and Wastewater5.

Each isolated one was tested by the disc diffusion method, according to recommendations by NCCLS6 as to the susceptibility of the following antibiotics: ampicillin (10µg), amoxicillin (20µg), amoxicillin + clavulanic acid (10µg), azitromicin (15µg), cefazolin (30?µg), clindamycin (2µg), cloranphenicol (30µg), ciprofloxacin (5µg), novobiocin (10µg), oxacillin (6µg), and vancomycin (30µg).

Every result was subjected to the Fisher's exact test, at levels of 1 and 5% of probability in order to determine if differences were significant7.

Results

From January to July, 2005, 160 samples of water from dental offices were studied. Out of the total of analyzed samples, 91.0 (57.0%) strains of Staphylococcus spp were isolated. From these, 77.0 (85.0%) were positive for S. aureus and 14.0 (15.0%) were positive for S. epidermidis.

From 40 studied dental offices, 15.0 (38.0%) used reservoir on the floor and 25.0 (62.0%) used plastic PET bottles. Among the reservoirs, 19.0 (47.0%) were supplied with tap water, 17.0 (43.0%) with filtered water, and 4.0 (10.0%) with distilled water.

There was no statistically significant difference among samples which had been collected from reservoirs on the floor and plastic PET bottles, seeing that the contamination on these sites does not depend on the kind of water used (tap, filtered, or distilled) (table 1).

Regarding the period of usage for dental offices, eight (20.0%) had been used for less than five years and 32.0 (80%) had been used for more than five years. Therefore, we might say that, according to Fisher's Exact Test, equipment contamination by water does not depend on the period of usage of the dental office.

As to the origin of 77 analyzed strains of S. aureus, there have been isolated 13.0 (76.0%) samples from high-speed handpiece of private offices, 10.0 (71.0%) samples from high-speed handpiece of dental care plan offices, and 9.0 (64%) samples from air-water syringe (table 1).

As to the origin of 14 analyzed strains of S. epidermidis, there have been isolated 2.0 (22.0%) from air-water syringe of SUS dental offices, 2.0 (14.0%) from air-water syringe of dental care plan offices, and 2.0 (12.0%) from tap water of private offices. The most contaminated sites were dental care plan offices, followed by SUS dental offices and private dental offices (table 1).

Table 2 presents count results for Staphylococcus spp in cfu/mL of water samples that had been compared to the maximum standard of 200 cfu/mL recommended by the American Dental Association (ADA). Out of the total of analyzed samples, 65.0 (72.0%) were within standards recommended by ADA and 26.0 (28.0%) did not meet such potability standards.

Concerning the antibiotic sensibility and resistance profile, it can be observed that 97.0% samples of S. aureus were sensible to ciprofloxacin, 92.0% to amoxil + clavulanic acid, 91% to vancomycin, and 78% of samples were resistant to oxacillin and clindamycin (table 3).

For the studied profile of S. epidermidis, the antibiotics vancomycin and ciprofloxacin presented the best efficiency (100%), seeing that oxacillin (79.0%) and clindamycin (71.0%) were the ones that presented worse efficiency.

Discussion

According to the literature, water supplying the equipment is one source for cross contamination inside the dental office as it might work as a means of dissemination/transmission of microorganisms8.

ADA9 has established as a goal for surgeon-dentists a maximum bacterial load of 200 cfu/mL in water from air-water syringes and high-speed handpieces10.

In this research, out of 91 samples of positive analyzed water for Staphylococcus spp, 65.0 were within potability standards recommended by ADA and 26.0 did not meet such standards, being able to be considered potential source of post-surgical and cross infection, seeing that the most contaminated site was high-speed handpiece, followed by air-water syringe, tap, and reservoir, these data are similar to Aguiar and Pinheiro11 and Kohno et al12.

According to Prevost et al.13, the quality of water used for supplying the dental equipment cannot work as an indication of quality for affluent water since the water used for supplying the equipment presented an average of 15 cfu/mL whereas the effluent water was from 5.6x104 to 9.0x106 cfu/mL. These data are also confirmed in this work, as most samples of contaminated water from tap and reservoir do not exceed 200 cfu /mL.

In the present study, reservoirs on the floor as well as plastic PET bottles did not present differences as to water contamination, even being filtered water. This fact makes us believe that biofilm, which is formed in the inner wall of the water line pipe, is the cause of contamination of air-water syringes (21.0%) and high-speed handpieces (35.0%), seeing that it was used drinkable water, confirming then the results by Willians et al.14. It was still observed that the contamination of water in dental equipment does not depend on the period of usage of such equipment, which is in agreement with what has been stated by Watanabe8.

In this study, sites where water has presented the highest levels of contamination were dental care plan offices, followed by SUS dental offices and private dental offices. Such fact might be a consequence of the fact that most dental care plans are medical-dental ones and patients are the same ones that go to the hospital environment12.

Many surveillance studies have shown an increase in the prevalence of S. aureus resistant to oxacillin (SARO)15. SARO is recognized as one of the main causes of nosocomial outbreak, although with a great variation in several hospitals all over the country, in a rate from 26.6 to 71.0% 16. The lethality assigned to infections caused by SARO is approximately 4.5 to 50%15.

The oxacillin susceptibility tests have presented results similar to the ones found in the literature, 78% of isolated strains were resistant to such antimicrobial, with a little higher prevalence than the ones verified in the literature, which present 50 to 70% of the isolated ones resistant17, national data report 66 to 68 % of isolated ones resistant to oxacilina16, and national multicentrical data inform a total of 87% of resistance to S. epidermidis.

Regarding such facts, it might be concluded that the source of water contamination for air-water syringes and high-speed handpieces might be the reflux of water contaminated with S. aureus and S. epidermidis for hoses/water lines14. Concerning studied dental offices, dental care plan offices presented the highest level of contamination of water that comes in and out of the dental equipment.

It is also believed that patients with dental care plans have a higher level of appointments as they usually follow a treatment sequence, whereas patients from SUS and private dental offices go to the outpatient ward to solve emergency problems, which makes the dental care plan patient more likely to have contamination.

Strains S. aureus were sensible to the following antibiotics: ciprofloxacin, amoxil + clavulanic acid, and vancomycin, whereas strains S. epidermidis were sensible to ciprofloxacin and vancomycin, these data are similar to Miragaia et al.16 and Chang et al17.

In conclusion, it is worth suggesting that entities responsible for the dentistry practice, such as the Federal Board of Dentistry (CFO) and the Regional Board of Dentistry (CRO), as well as Schools of Dentistry should adopt measures for controlling cross infection within dental offices in order to assure better safety conditions for dentists, assistants, and patients through specialized training and valorization of life quality.

Acknowledgements

The authors gratefully acknowledge the financial support provided by CAPES and CNPq.

References

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  2. Mills SE. Waterborne pathogens and waterline. Dent Clin North Am. 2003; 47: 545-57.
  3. Barbeau J. Waterborne biofilms and dentistry: the changing face of infection control. J Can Dent Assoc. 2000; 66: 539-41.
  4. Fiehn NE, Larsen T. The effect of drying dental unit waterline biofilms on the bacterial load of dental unit water. Int Dent J. 2002; 52: 251-54.
  5. American Public Health Association. American Water Works Association. Water Environment Federation. Standard methods for examination of water and wastewater. 20th ed. Washington: APHA; 1999. 9.29-9.30.
  6. National Committee for Clinical Laboratory Standards. Approved Standard M2-A7, 1995. Performance standard for antimicrobial disk susceptibility test, vol. 15, n. 14, Approved Standard NCCLS, Villanova, Pa.
  7. S.A.S. INSTITUTE INC. S.A.S/Stat User's guide, release 6, 12 TS level 0020. Cary. 1999. p.519-48.
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  9. American Dental Association. ADA statement on dental unit waterlines. July 2004. Available from: http://www.ada.org/prof/resources/positions/statments/lines.asp [2003 Sept 16].
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  11. Aguiar CM, Pinheiro JT. Avaliação bacteriológica da qualidade de água utilizada nos equipos odontológicos. Rev. Assoc Paul Cir Dent. 1999; 53: 228-35.
  12. Kohno S, Kawata T, Kaku M, Fuita T, Tsutsui K, Ohtani J et al. Bactericidal effects of acidic electrolyzed water on dental unit waterline. Jpn J Infect Dis. 2004; 57: 52-4.
  13. Prevost AP, Robert M, Charland R, Barbeau J. Doctor, Would you drink water from your dental unit? N Y State Dent J. 1995; 61: 22-8.
  14. Williams HN, Kelley J, Folineo D, Williams GC, Hawley CL, Sibiski J. Assessing microbial contamination in clean water dental units and compliance with disinfection protocol. J Am Dent Assoc. 1994; 125: 1205-11.
  15. Aires De Sousa M, Crisostomo MI, Santos Sanches I, WU JS, Fuzhong J, Tomasz A, De Lencastre H. Frequent recovery of a single clonal type of multidrug-resistant Staphylococcus aureus from patients in two hospitals in Taiwan and China. J Clin Microbiol. 2003, 41: 159-63.
  16. Miragaia M, Couto I, Pereira Sandro FF, Sandro FF, Kristinsson KG, Westh H et al. Molecular characterization of methicillin-resistant Staphylococcus epidermidis: evidence of geographic dissemination. J Clin Microbiol. 2003; 40: 430-8.
  17. Chang MR, Carvalho NCP, Oliveira ALL, Moncada PMF, Moraes BA et al. Surveillance of pediatric infections in a teaching hospital in Mato Grosso do Sul, Brazil. Braz J Infect Dis. 2003; 7: 149-60.

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