Antimicrobial resistance of aerobes and facultative anaerobes isolated from the oral cavity

Gaetti-Jardim, Ellen Cristina; Marqueti, Antônio Carlos; Faverani, Leonardo Perez; Gaetti-Jardim Júnior, Elerson

doi:10.1590/S1678-77572010000600004

Abstract

OBJECTIVES: This study evaluated the resistance to antimicrobials of aerobes and facultative anaerobes isolated from patients wearing complete dentures, patients with gingivitis and periodontitis, and periodontally health subjects. MATERIAL AND METHODS: Three hundred and four isolates were tested. The minimal inhibitory concentrations of the drugs were evaluated through the agar dilution method using Mueller-Hinton agar. RESULTS: The most active antimicrobial drugs were the carbapenems (meropenem and imipenem), and resistance to these drugs was restrict to 1.6-2.3% of the isolates, as well as ciprofloxacin and rifampin. Microbial resistance to ampicillin, amoxicillin/clavulanic acid, cefoxitin, cephalothin, amikacin, chloramphenicol and nalidixic acid was particularly high. In most cases, the resistance to β-lactams was mediated by the production of hydrolytic enzymes, especially in gram-negative enteric rods, while enterococci did not evidence production of these enzymes. The association amoxicillin/clavulanic acid was not effective in 28.3% of the tested isolates. CONCLUSIONS: The results of this investigation confirmed that the oral cavity of patients with periodontitis and gingivitis, and particularly edentulous patients wearing complete dentures could harbor microorganisms with several antimicrobial resistance markers, and these microorganisms are frequently implicated in multiresistant, systemic, oral or nosocomial infections.

Periodontitis; Gingivitis; Bacteria; Anti-bacterial agents

ORIGINAL ARTICLE

Antimicrobial resistance of aerobes and facultative anaerobes isolated from the oral cavity

Ellen Cristina Gaetti-Jardim^I; Antônio Carlos Marqueti^I; Leonardo Perez Faverani^I; Elerson Gaetti-Jardim Júnior^II

^IMSc, Graduate student, Department of Pathology and Propedeutics, Araçatuba Dental School, UNESP, Araçatuba, SP, Brazil

^IIDDS, MSc, PhD, Associate Professor of Microbiology, Department of Pathology and Propedeutics, Araçatuba Dental School, UNESP, Araçatuba, SP, Brazil

^{Corresponding address} Corresponding address: Dr. Elerson Gaetti Jardim Júnior - Faculdade de Odontologia de Araçatuba-UNESP Rua José Bonifácio, 1193 - 16015-050 - Araçatuba, SP - Brasil Phone/Fax: +55-18-3636-2797/3636-3200 e-mail: egaettij@foa.unesp.br

ABSTRACT

OBJECTIVES: This study evaluated the resistance to antimicrobials of aerobes and facultative anaerobes isolated from patients wearing complete dentures, patients with gingivitis and periodontitis, and periodontally health subjects.

MATERIAL AND METHODS: Three hundred and four isolates were tested. The minimal inhibitory concentrations of the drugs were evaluated through the agar dilution method using Mueller-Hinton agar.

RESULTS: The most active antimicrobial drugs were the carbapenems (meropenem and imipenem), and resistance to these drugs was restrict to 1.6-2.3% of the isolates, as well as ciprofloxacin and rifampin. Microbial resistance to ampicillin, amoxicillin/clavulanic acid, cefoxitin, cephalothin, amikacin, chloramphenicol and nalidixic acid was particularly high. In most cases, the resistance to β-lactams was mediated by the production of hydrolytic enzymes, especially in gram-negative enteric rods, while enterococci did not evidence production of these enzymes. The association amoxicillin/clavulanic acid was not effective in 28.3% of the tested isolates.

CONCLUSIONS: The results of this investigation confirmed that the oral cavity of patients with periodontitis and gingivitis, and particularly edentulous patients wearing complete dentures could harbor microorganisms with several antimicrobial resistance markers, and these microorganisms are frequently implicated in multiresistant, systemic, oral or nosocomial infections.

Key words: Periodontitis. Gingivitis. Bacteria. Anti-bacterial agents.

INTRODUCTION

Oral cavity may act as a reservoir for superinfecting microorganisms commonly associated to systemic and opportunistic infections¹² especially in elderly wearing complete dentures⁵. In addition, either use or misuse of antimicrobial drugs associated with poor oral hygiene would facilitate the colonization of the oral cavity by these microorganisms, as well as the dissemination of their resistance genes amongst the members of oral microbiota^10,12.

The use of complete dentures⁵ or the development of periodontitis^1,10 may create suitable nutritional conditions for superinfecting pathogens, such as Gram-negative enteric rods, pseudomonads, and enterococci, which may be commonly associated with refractory oral and nosocomial infections. Moreover, the loss of the balance between the host's immune response and the microbiota's virulence has resulted in several oral infections, such as denture stomatitis and endodontic, periodontal or periapical infections.

However, in case of history of previous use of antimicrobials or immune suppression, the clinician may suspect of the participation of facultative anaerobes and aerobes in the infectious process. These microorganisms have presented a very diverse antimicrobial susceptibility profile in comparison to strict anaerobes⁴. In addition, in spite of the role that facultative anaerobes and aerobes would play in head and neck infections, most of dentists have been instructed to prescribe antimicrobial drugs only directed against strict anaerobes⁴.

Although local and surgical procedures have remained the basis of odontogenic infections treatment, antimicrobial drugs may act as adjuvants in this therapeutic, especially in anatomical sites where surgical procedures could not be performed. However, the determination of resistance patterns to antimicrobial drugs of oral microorganisms has not constituted a routine procedure⁹.

This study evaluated the frequency of antimicrobial resistance among isolates of aerobic and facultative anaerobic bacteria harvested from the oral cavity of patients wearing complete dentures, patients with gingivitis and chronic periodontitis, and periodontally healthy subjects.

MATERIAL AND METHODS

Study Population

A total of 250 patients (84 males and 166 females; mean age 43.03 years), followed up within an 8-year period at the Araçatuba Dental School, UNESP, Brazil, from February, 1998 to March, 2008 were enrolled in this study. Forty-one patients wore complete dentures, 89 exhibited gingivitis, 70 chronic periodontitis and 50 were periodontally healthy, following the criteria described in the literature²³. Demographic and additional characteristics of the patients are presented in Table 1.

Thumbnail

Thirteen patients had received amoxicillin or ampicillin due to medical prescription three months before sample collection, while two patients received azithromycin. Two patients had used trimethoprim/sulfamethoxazole for treatment of oral minor infections, respiratory or urinary infections. Exclusion criteria included: diabetes, systemic diseases and other chronic infections (except for periodontitis or gingivitis), prosthetic heart valves, previous endocarditis, transplants, pregnant or lactating women, and history of antimicrobial drug use within the period of three months before sample collection. Since it is not possible to determine with accuracy of antimicrobial drug use in individuals with history of self-medication, it was established that these patients should be excluded from the study.

A written informed consent form approved by the Institutional Review Board of Araçatuba Dental School, UNESP (Proc.27/2000 and 34/2006) was signed by all participants. After sample collection, the dentate patients were referred to restorative and periodontal treatment, while edentulous patients were directed to prosthetic dentistry.

Microorganisms

Clinical samples of resting saliva, oral mucosa, tongue, and both supragingival and subgingival biofilm were collected from periodontally healthy subjects and patients with gingivitis and periodontitis. Supragingival samples were obtained by scaling; subgingival samples were obtained by using 3 sterile paper points (Dentsply Ind. Co. Ltd., Petrópolis, RJ, Brazil), which were inserted into the apical region of periodontal pockets or gingival crevices for 60 s. Oral mucosa samples were collected by a sterile swab, while saliva was collected by using Salivette devices (Cortisol-Salivette, Sarstedt AG & Co., Nümbrecht, Nordrhein-Westfalen, Germany). In the edentulous patients wearing complete dentures, clinical samples from palate, dorsum of tongue, and fornix were collected by using swabs⁵. Clinical samples were transferred to a VMGA III medium¹⁸. The clinical samples of subgingival biofilm were pooled before transportation.

Clinical specimens were inoculated in peptone water and ethyl violet azide broth (Difco Laboratories, Detroit, MI, USA), and incubated both at room temperature and 37°C, for 3-7 days. After that, from the bacterial growth observed in peptone water, aliquots of 0.1 ml were transferred to Eosin Methylene Blue agar, SS agar, MacConkey agar (Difco Laboratories) and Brilliant Green agar. From the tubes containing EVA broth, 0.1 mL was transferred to Bile Esculin agar (Difco Laboratories). Agar plates were incubated in aerobiosis, at 37°C, for 48 h¹⁰.

Clinical specimens were also diluted in VMG I¹⁸ and plated on tryptic soy agar (TSA), supplemented with both 0.5% yeast extract and 5% horse blood, and incubated in aerobiosis, at 37°C, for 48 h, for isolation of non-enteric aerobes and facultative anaerobes. The isolates were identified by Gram staining, colony morphology on agar plates, respiratory test, catalase assay, and biochemical identification kits (API Test System, BioMérieux, Marcelle l´Etoile, Provence-Alpes-Côte d'Azur, France).

A total of 304 isolates were subjected to susceptibility tests, as follows: Bukholderia cepacia complex (5 isolates), Citrobacter freundii (7 isolates), Enterobacter cloacae (18 isolates), E. intermedius (6 isolates), E. sakazakii (9 isolates), Enterococcus sp. (18 isolates), E. faecalis (31 isolates), E. faecium (8 isolates), Escherichia coli (6 isolates), Klebsiella oxytoca (11 isolates), K. pneumoniae (3 isolates), Morganella morganii (17 isolates), Pantoea agglomerans (7 isolates), Proteus mirabilis (5 isolates), P. vulgaris (7 isolates), Providencia alcalifaciens (6 isolates), Pseudomonas aeruginosa (15 isolates), P. fluorescens (4 isolates), Serratia sp. (9 isolates), S. liquefaciens (9 isolates), Staphylococcus sp. (9 isolates), S. aureus (10 isolates), S. epidermidis (17 isolates), S. hominis (8 isolates), Streptococcus sp. (9 isolates), S. oralis (7 isolates), S. sanguinis (9 isolates), S. mitior (4 isolates), S. salivarius (11 isolates), S. mutans (7 isolates), S. pneumoniae (6 isolates), and S. pyogenes (6 isolates).

Antimicrobial Susceptibility Tests

All isolates were examined for susceptibility to antimicrobial agents by agar dilution method¹⁹. When CLSI antimicrobial breakpoints were not established, the breakpoints adopted by the British Society for Antimicrobial Chemotherapy³ were followed. Mueller-Hinton agar (MHA) was used for all isolates. In tests involving oral streptococci, 5% horse blood was added to MHA plates in order to support microbial growth.

Thus, five pure colonies of each bacterial strain were inoculated into 2 mL of sterile Mueller Hinton broth or brain heart infusion broth supplemented with yeast extract (oral streptococci) and incubated at 37°C for 12-24 h. The turbidity was adjusted to match a 0.5 McFarland turbidity standard. The bacterial inocula were standardized in 10⁵ cells⁹ and transferred to Mueller-Hinton agar plates containing the antimicrobial agent and control plates (without drugs), using a Steer's replicator (Cefar Diagnostica Ltda, São Paulo, SP, Brazil). The test and control agar plates were incubated aerobically or under CO₂ (10% CO₂ + conventional atmosphere, for oral streptococci) at 37ºC, for 48 h.

A total of 14 antibiotics or associations were tested. The antibiotics tested consisted of the following drugs: amikacin, ampicillin, amoxicillin/clavulanic acid, cefoxitin, cephalothin, chloramphenicol, ciprofloxacin, doxycycline, gentamicin, imepenem, meropenem, nalidixic acid, rifampin, and tetracycline. Antimicrobials were tested in twofold dilution series ranging from 0.06 to 256 µg/mL. After incubation, the organisms were classified as sensitive or resistant, according to CLSI¹⁹ and BSAC³ guidelines. E. coli ATCC 25922, S. aureus ATCC 29213, P. aeruginosa ATCC 27853, and E. faecalis ATCC 29212 were used in the assays involving facultative anaerobes.

Detection of β-lactamases

The isolates resistant to β-lactams were also tested for β-lactamase activity by both chromogenic cephalosporin and biological method⁹. These two methods were performed because nitrocefin-based β-lactamase assays have not proven useful in detecting β-lactamase production by some microorganisms. In all tests, S. aureus ATCC 29213 was used as the positive control of β-lactamase production.

The chromogenic cephalosporin β-lactamase assay using cefinase disks was performed according to the manufacturer's instructions (Calbiochem, San Diego, California, USA).This description was briefly the following: 6-mm-diameter filter paper disks impregnated with nitrocefin were moistened with 0.85% NaCl, and several fragments of the tested microorganisms' colonies were transferred to the disk. After 10-60 min, the disks were examined regarding the appearance of a pink-red coloration, which has been characteristic of the degradation of nitrocefin.

In the biological method, 20 µL of the resistant isolate cultures were plated on the surface of Mueller-Hinton agar containing 0.5 µg/mL of the tested β-lactam to which the tested microorganism showed to be resistant. These plates were then incubated in aerobiosis at 37°C, for 48 h. After this incubation period, the cultures were exposed to chloroform fumes for 20 min. and then covered with 5 mL of semi-solid brain heart infusion (BHI) agar (0.7% agar) previously inoculated with 10⁶ cells of S. pyogenes FOA-94F14 sensitive to all tested β-lactams in a concentration of <0.06 ¼g/mL. The Petri dishes were then incubated under aerobiosis for 24 h at, 37°C. After incubation, presence or absence of streptococcal growth was checked. The presence of this growth halo was indicative of the β-lactam degradation.

Statistical analysis

Differences between clinical parameters and the frequency of pathogen detection or presence of microbial resistance for each subject were analyzed by the Chi-square, Mann-Whitney or Fisher's exact test. Inter-relationships among different microorganisms were evaluated using the Spearman's correlation coefficient test.

RESULTS

Significant levels of resistance were observed for all β-lactams, excepting for imepenem and meropenem, which respectively presented 2.3% and 1.6% of resistance. The most prominent resistance was observed for ampicillin, amoxicillin and cephalothin, which respectively reached 44.4%, 43.1% and 33.2% (Table 2). Enteric gram-negative rods and pseudomonads were the most resistant isolates. Out of 304 tested isolates, 178 were resistant to at least one β-lactam, representing 58.6% of all tested microorganisms, and 112 resistant isolates were β-lactamases producers, which represented 36.8% of all tested isolates and 62.9% of all β-lactam resistant bacteria. These hydrolyzing enzymes seemed to be the major mechanism of resistance to this class of antimicrobials, excepting for enterococci, which did not produce such compounds.

Thumbnail

The association amoxicillin/clavulanic acid was active on less than half of ampicillin or amoxicillin resistant isolates. Resistance to this association was detected in 28.3% of the targeted microorganisms and it was particularly frequent in E. cloacae, genera Klebsiella, Serratia and Pseudomonas, as well as in B. cepacia complex, E. faecium, P. agglomerans, P. alcalifaciens and S. aureus.

In relation to cephalosporins, the resistance to both cefoxitin and cephalothin was disseminated in all tested microbial genera, particularly in pseudomonads, E. cloacae, staphylococci, and enterococci. Some isolates of E. cloacae, K. oxytoca, P. agglomerans, P. alcalifaciens and Serratia sp. presented a broad spectrum resistance to β-lactam antibiotics, and produced β-lactamases that were active on penicillins and cephalosporins. This would suggest that the oral cavity of dentate patients and, particularly, edentulous patients wearing complete dentures could harbor bacterial strains able to produce broad spectrum β-lactamases.

The results presented in Table 2 show that carbapenems were the only β-lactams that had a significant antimicrobial activity on enterococci, staphylococci, pseudomonads and Enterobacteriaceae. The resistance to imepenem was similar to that observed to meropenem and restricted to a few isolates of staphylococci, P. aeruginosa, E. faecium and M. morganii.

Variable levels of resistance to aminoglycosides were also observed. Resistance to amikacin was more prevalent among gram-positive cocci of genera Enterococcus, and Staphylococcus, while gentamicin resistance was common in P. aeruginosa, P. alcalifaciens, C. freundii, and E. cloacae (Table 2). Resistance to chloramphenicol, doxycycline, nalidixic acid and, specially, tetracycline was frequent in most of the targeted microorganisms, while rifampin was effective against most of these isolates, excepting for some gram-negative enteric rods, staphylococci, and pseudomonads. The resistance to ciprofloxacin was almost restricted to staphylococci and streptococci, besides an isolate of E. intermedius and other isolate of P. aeruginosa (Table 3).

Thumbnail

The main relationship between periodontal conditions and the presence of resistant microorganisms was linked to higher prevalence of enteric Gram-negative in patients with periodontitis or gingivitis, and these bacteria were less susceptible to antimicrobial agents. Antimicrobial use in the period prior to sample collection, and consumption of tobacco and alcohol did not significantly affect the occurrence of resistant microorganisms. The results suggest that factors that increase the presence of enteric bacteria in the oral cavity eventually collaborate with the increase in the prevalence of resistant microorganisms. Table 4 presents the prevalence of resistant microorganisms in edentulous patients wearing complete dentures, periodontally healthy subjects, patients with gingivitis and patients with periodontitis.

Thumbnail

The results presented in Table 4 showed a close correlation between the presence of microorganisms resistant to β-lactams and the use of complete dentures (Chi-square test, p<0.01) and to a lesser extent, patients with periodontitis (Chi-square test, p=0.012) or gingivitis (Chi-square test, p=0.02). The same phenomenon was also detected in relation to resistance to aminoglycosides and chloramphenicol. However, the occurrence of tetracycline-, quinolone- and/or rifampin-resistant microorganisms was similar in periodontally healthy subjects and patients with gingivitis. The levels of resistance to rifampin were reduced and a low prevalence of such isolates was observed from all dentate patients.

DISCUSSION

The patterns of susceptibility to antimicrobial drugs amongst aerobes and facultative anaerobes have evidenced the presence of a multiresistance phenotype, both in isolates from human resident microbiota and from exogenous environment^8,16. Accordingly, antibiotic resistance raised among commensal bacteria has been supposed to represent a major feature in the development of resistance within bacterial pathogens. In addition, the detection of resistant bacteria in commensal microbiota has pointed to the oral cavity as a possible source for transmission of genes associated to antimicrobial resistance in pathogenic bacteria¹².

β-Lactam agents, such as penicillins, cephalosporins and carbapenems, have been among the most frequently prescribed antibiotics worldwide. In this investigation, most of the tested microorganisms showed to be resistant to ampicillin. The levels of resistance to ampicillin in isolates of Enterobacteriaceae was similar to those described by literature^1,6,11, however, they were lower than those reported by Gonçalves, et al.¹² (2007).

The association between β-lactams and β-lactamase inhibitors has been frequently used in the treatment of odontogenic infections, particularly those infections where the patient had presented a history of previous use of β-lactams. However, in refractory mixed infections where aerobes and facultative anaerobes had been involved, this association has seemed to lead to a poor treatment outcome, since the expression of combined resistance to ampicillin and to amoxicillin/clavulanic acid has been frequent in gram-negative enteric rods and staphylococci, as shown in Table 1 and also described in literature^6,12.

Enterococci have been often associated to refractory odontogenic infections, such as dental abscesses and both endodontic and periapical infections. The results presented here have evidenced that these cocci were just susceptible to carbapenems, ciprofloxacin, gentamicin and rifampin. On the other hand, enterococci resistant to ampicillin were also resistant to amoxicillin/clavulanic acid association, which was not in agreement with the findings of Ferrari, Cai and Bombana⁷ (2005). These authors reported a high susceptibility to ampicillin and a variable susceptibility to ciprofloxacin for enterococci from endodontic infections, while Das, et al.⁶ (2006) verified a high resistance of E. faecalis strains to gentamicin and ciprofloxacin.

The cephalosporins have greatly varied in susceptibility to β-lactamases. Cephalothin has been more resistant to hydrolysis by β-lactamases of staphylococci, whereas cefoxitin has been more resistant to β-lactamases produced by aerobic gram-negative rods³. Table 1 not only confirms these data, but also shows a disseminated resistance to both cefoxitin and cephalothin among aerobic gram-positive cocci and gram-negative bacilli, as also reported in literature^6,16.

It has been verified that carbapenems are the only β-lactams active against most of enteric microorganisms and other facultative anaerobes and aerobes², particularly staphylococci²⁰ and enteric gram-negative bacilli²⁰. However, some resistance to carbapenems in aerobes and facultative anaerobes has been described, especially in gram-negative enteric rods, coagulase-positive staphylococci and several species of genera Streptococcus and Enterococcus^13,15. The resistance to imepenem was similar to that observed to meropenem and restrict to a few isolates of staphylococci, P. aeruginosa, E. faecium, and M. morganii. This was also observed by Pillar, et al.²⁰ (2008).

In this present investigation, most of isolates resistant to β-lactam were β-lactamase producers. However, 37.1% of the β-lactam resistant microorganisms were not β-lactamase producers. Some of these "non-producers" could be producers of non-exportable β-lactamases, as it has been previously reported for some gram-negative bacteria¹⁴. Another explanations for this fact would be that these "non-producers" could harbor other mechanisms of resistance (e.g.: alteration of structure of penicillin-binding proteins), or that the method's sensitivity did not allow the detection of these enzymes⁸.

Both the production of low affinity penicillin binding proteins²¹ and the impermeability of the outer membrane to these drugs could also be involved in the resistance to β-lactams, even in β-lactamase producers. In this sense, enterococci in general and E. faecium in particular would be intrinsically more resistant to penicillin and ampicillin than the other streptococci. Ampicillin and amoxicillin resistance in E. faecium have occurred due to the expression of the low-affinity class B penicillin-binding protein 5 (PBP5). However, higher levels of resistance in clinical isolates have been only rarely associated with increased levels of PBP 5 expression²². More commonly, mutations that have been presumed to lower the affinity for β-lactam antibiotics have been identified within pbp5 genes of highly resistant clinical isolates²¹.

Aminoglycoside antibiotics have not been usually recommended in the treatment of odontogenic infections. However, its use in association with other drugs, especially β-lactams, has been frequent in oral surgery. The susceptibility to gentamicin and amikacin was high among most of the tested microorganisms, but some enterococci were highly resistant to amikacin. On the other hand, resistance to gentamicin was more concentrated on C. freundii, E. cloacae, P. aeruginosa, and some staphylococci.

The activity of gentamicin and amikacin against most aerobes and facultative anaerobes has been well described in literature^11,12,16, and these drugs have been the most frequently used in nosocomial and opportunistic infections involving these microorganisms. However, resistance has been observed in Enterobacteriaceae and Pseudomonadaceae, ranging from 1.0% to 17.9% in gram-negative enteric rods for amikacin and from 2.8% to 38.5% for gentamicin^11,24. An expressive resistance to these drugs has also been detected for staphylococci and enterococci, as well as genus Klebsiella^6,11,17.

Chloramphenicol has been a broad spectrum antimicrobial largely used in the treatment of nosocomial infections, particularly when Enterobacteriaceae species were involved and its use has been rare in dentistry. Table 3 shows that enterococci were the most resistant to chloramphenicol amongst the tested microorganisms. Moreover, some resistance was disseminated in most target microorganisms. On the other hand, this phenomenon has been described mainly in enterococci and streptococci viridans, although some enteric gram-negative rods resistant to this drug have been detected^11,12. The results presented here, however, would not justify the use of this antimicrobial agent in the treatment of serious infections involving these superinfecting bacteria.

The resistance to ciprofloxacin was manly restricted to some isolates of genera Staphylococcus and Streptococcus, while just two isolates of gram-negative rods (E. intermedius and P. aeruginosa) were resistants amongst the tested microorganisms. This was in accordance with most of available data in literature^1,11,12. However, it contrasted with Huang, et al.¹⁵ (2007), who showed high levels of resistance to ciprofloxacin in oxacillin-resistant S. aureus (100%), extended spectrum β-lactamase (ESBLs) producers K. pneumoniae (82%), S. marcescens (40%), streptococci (33%), and P. aeruginosa (9%). Since this drug has not been either frequently used by Brazilian dentists or as part of self-medication, it would be possible that the antimicrobial resistance profiles of isolates from hospitals would have been significantly different from those observed in commensal microbiota, as described by Pillar, et al.²⁰ (2008).

Resistance to tetracycline also has been often registered in facultative anaerobes and aerobes, which have seemed to be disseminated in the human and animal microbiota^11,12. This phenomenon could be related to its extensive use in medicine, veterinary and dentistry. The distribution of the resistance to tetracycline, as observed in Table 2, was similar to that previously reported^11,16, and slightly higher than the results of Gonçalves, et al.¹² (2007). The resistance to tetracycline was similar between gram-positive cocci and gram-negative bacilli, as previously observed¹⁶, while resistance to doxycycline was more prevalent among gram-negative enteric rods and pseudomonades, which represented 76.9% of all resistant isolates. The most commonly detected doxycycline resistant species were C. freundii, E. cloacae, P. aeruginosa, and P. alcalifaciens. The high resistance of pseudomonades from oral cavity to doxycycline was previously reported by Barbosa, Mayer and Saba-Chujfi¹ (2001). These results did not support the use of doxycycline or tetracycline in life threatening infections.

Rifampin has been widely used in the treatment of several life threatening infections as well as minor oral infections for many years⁴. In the clinical samples, the low frequency of rifampin resistance was relevant and confined to staphylococci and the genera Providencia and Serratia, as well as to pseudomonades. However, these authors showed that the rifampin resistance ranged from 17.2% to 30.0% among enterococci, while Ferrari, Cai and Bombana⁷ (2005) detected this resistance in 58.3% of enterococci. On the other hand, the present investigation found that all enterococci were susceptible to rifampin, and these results seem to endorse rifampin as an important therapeutic alternative in mixed and nosocomial infections, particularly where clinical signs evidenced the participation of multi-drug resistant microorganisms.

Although patients with periodontitis and edentulous patients are considerably older than patients with gingivitis and periodontally healthy patients, the influence of age on the distribution of resistant microorganisms is reduced when data from patients with the same age and with different periodontal status are compared, showing that this factor alone does not seem relevant. Moreover, a great proportion of bacterial strains presented resistance to ampicillin, amoxicillin and amoxicillin/clavulanic acid and some isolates of E. cloacae, K. oxytoca, P. agglomerans, P. alcalifaciens, and Serratia sp. presented a broad spectrum resistance to β-lactam antibiotics, producing β-lactamases active on penicillins and cephalosporins.

The presence of the enterobacteria and pseudomonads and other superinfecting microorganisms may be relevant in gingivitis and periodontitis etiology, especially in immunosuppressed patients^1,10. However, the role of enteric bacteria in the periodontal diseases etiology remains unclear, and it must be an alert to clinicians who use systemic antibiotics, such as ciprofloxacin, as an adjunct in the periodontitis treatment in these patients⁹.

CONCLUSIONS

The results of this investigation confirmed that the oral cavity of patients with periodontitis and gingivitis, and particularly edentulous patients wearing complete dentures could harbor microorganisms with several antimicrobial resistance markers, and these microorganisms are frequently implicated in multiresistant, systemic, oral or nosocomial infections.

ACKNOWLEDGEMENTS

This study was partially supported by grants from The State of São Paulo Research Foundation (Process #1998/6555-2 and 2007/54851-0).

Received: March 13, 2009

Modification: March 25, 2010

Accepted: May 30, 2010

1- Barbosa FCB, Mayer MPA, Saba-Chujfi E, Cai S. Subgingival occurrence and antimicrobial susceptibility of enteric rods and pseudomonads from Brazilian periodontitis patients. Oral Microbiol Immunol. 2001;16:306-10.
2- Baudry PJ, Nichol K, DeCorby M, Mataseje L, Mulvey MR, Hoban DJ, et al. Comparison of antimicrobial resistance profiles among extended-spectrum-beta-lactamase-producing and acquired AmpC beta-lactamase-producing Escherichia coli isolates from Canadian intensive care units. Antimicrob Agents Chemother. 2008;52:1846-9.
³
- British Society for Antimicrobial Chemoterapy. BSAC methods for antimicrobial Susceptibility testing. [online]. Version 7.1. London: BSAC; 2008. Available from: <http://www.bsac.org.uk/_db/_documents/version_7_1_february_2008.pdf>
4- Brook I. Microbiology and principles of antimicrobial therapy for head and neck infections. Infect Dis Clin North Am. 2007;21:355-91.
5- Daniluk T, Fiedoruk K, Zciepuk M, Zaremba ML, Rozkiewicz D, Cylwik-Rokicka D, et al. Aerobic bacteria in the oral cavity of patients with removable dentures. Adv Med Sci. 2006;51(Suppl. 1):86-90.
6- Das RN, Chandrashekhar TS, Joshi HS, Gurung M, Shrestha N, Shivananda PG. Frequency and susceptibility profile of pathogens causing urinary tract infections at a tertiary care hospital in western Nepal. Singapore Med J. 2006;47:281-5.
7- Ferrari PHP, Cai S, Bombana AC. Effect of endodontic procedures on enterococci, enteric bacteria and yeasts in primary endodontic infections. Int Endod J. 2005;38:372-80.
8- Ferreira da Silva M, Vaz-Moreira I, Gonzalez-Pajuelo M, Nunes OC, Manaia CM. Antimicrobial resistance patterns in Enterobacteriaceae isolated from an urban wastewater treatment plant. FEMS Microbiol Ecol. 2007;60:166-76.
9- Gaetti-Jardim E Jr, Landucci LF, Lins AS, Vieira EMM, Oliveira SR. Susceptibility of strict and facultative anaerobes isolated from endodontic infections to metronidazole and beta-lactams. J Appl Oral Sci. 2007;15:539-45.
10- Gaetti-Jardim E Jr, Nakano V, Wahasugui TC, Cabral FC, Gamba R, Avila-Campos MJ. Occurrence of yeasts, enterococci and other enteric bacteria in subgingival biofilm of HIV-positive patients with chronic gingivitis and necrotizing periodontitis. Braz J Microbiol. 2008;39:257-61.
11- Gionechetti F, Zucca P, Gombac F, Monti-Bragadin C, Lagatolla C, Tonin E, et al. Characterization of antimicrobial resistance and class 1 integrons in Enterobacteriaceae isolated from Mediterranean herring gulls (Larus cachinnans). Microb Drug Resist. 2008;14:93-9.
12- Gonçalves MO, Coutinho-Filho WP, Pimenta FP, Pereira GA, Pereira JAA, Mattos-Guaraldi AL, et al. Periodontal disease as reservoir for multi-resistant and hydrolytic enterobacterial species. Lett Appl Microbiol. 2007;44:488-94.
13- Hälgren A, Abednazari H, Ekdahl C, Hanberger H, Nilsson M, Sammuelson A, et al. Antimicrobial susceptibility patterns of enterococci in intensive care units in Sweden evaluated by different MIC breakpoint systems. J Antimicrob Chemother. 2001;48:53-62.
14- Handal T, Olsen I, Walker CB, Caugant DA. Beta-lactamase production and antimicrobial susceptibility of subgingival bacteria from refractory periodontitis. Oral Microbiol Immunol. 2004;19:303-8.
15- Huang SS, Lee SC, Lee N, See LC, Tsai MH, Shieh WB. Comparison of in vitro acitivities of levofloxacin, ciprofloxacin, ceftazidime, cefepime, imepenem, and piperacillin-tazobactam against aerobic bacterial pathogens from patients with nosocomial infections. J Microbiol Immunol Infect. 2007;40:134-40.
16- Khosravi AD, Mehdinejad M, Heidari M. Bacteriologic findings in patients with ocular infection and antibiotic susceptibility patterns of isolated pathogens. Singapore Med J. 2007;48:741-3.
17- Leibovici L, Vidal L, Paul M. Aminoglycoside drugs in clinical practice: an evidence-based approach. J Antimicrob Chemother. 2009;63:246-51.
18- Möller AJR. Microbial examination of root canals and periapical tissues of human teeth. Odontologisk Tidskrift. 1966;74:1-380.
¹⁹
- National Committee for Clinical Laboratory Standards. Methods for dilution antimicrobial susceptibility tests for bacteria that grow aerobically. 6^th ed. Document M7-A6. Wayne: NCCLS; 2003.
20- Pillar CM, Torres MK, Brown NP, Shah D, Sahm DF. In vitro activity of doripenem, a carbapenem for the treatment of challenging infections caused by gram-negative bacteria, against recent clinical isolates from the United States. Antimicrob Agents Chemother. 2008;52:4388-99.
21- Rice LB, Bellais S, Carias LL, Hutton-Thomas R, Bonomo RA, Caspers P, et al. Impact of specific pbp5 mutations on expression of β-lactam resistance in Enterococcus faecium Antimicrob Agents Chemother. 2004;48:3028-32.
22- Rybkine T, Mainardi JL, Sougakoff W, Collatz E, Gutmann L. Penicillin-binding protein 5 sequence alterations in clinical isolates of Enterococcus faecium with different levels of beta-lactam resistance. J Infect Dis. 1998;178:159-63.
23- Tonetti MS, Claffey N, European Workshop in Periodontology group C. Advances in the progression of periodontitis and proposal of definitions of a periodontitis case and disease progression for use in risk factor research. Group C consensus report of the 5th European Workshop in Periodontology. J Clin Periodontol. 2005;32:210-3.
24- Vignoli R, Calvelo E, Cordeiro NF, Lucero R, Ingold E, Quintana A, et al. Association of broad-spectrum antibiotic use with faecal carriage of oxyiminocephalosporin-resistant Enterobacteriaceae in an intensive care unit. J Hosp Infect. 2006;63:306-15.

Corresponding address:

Dr. Elerson Gaetti Jardim Júnior - Faculdade de Odontologia de Araçatuba-UNESP

Rua José Bonifácio, 1193 - 16015-050 - Araçatuba, SP - Brasil

Phone/Fax: +55-18-3636-2797/3636-3200

e-mail:

egaettij@foa.unesp.br

Publication Dates

Publication in this collection
14 Jan 2011
Date of issue
Dec 2010

History

Accepted
30 May 2010
Reviewed
25 Mar 2010
Received
13 Mar 2009

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] 1- Barbosa FCB, Mayer MPA, Saba-Chujfi E, Cai S. Subgingival occurrence and antimicrobial susceptibility of enteric rods and pseudomonads from Brazilian periodontitis patients. Oral Microbiol Immunol. 2001;16:306-10.

[2] 2- Baudry PJ, Nichol K, DeCorby M, Mataseje L, Mulvey MR, Hoban DJ, et al. Comparison of antimicrobial resistance profiles among extended-spectrum-beta-lactamase-producing and acquired AmpC beta-lactamase-producing Escherichia coli isolates from Canadian intensive care units. Antimicrob Agents Chemother. 2008;52:1846-9.

[3] ³
- British Society for Antimicrobial Chemoterapy. BSAC methods for antimicrobial Susceptibility testing. [online]. Version 7.1. London: BSAC; 2008. Available from: <http://www.bsac.org.uk/_db/_documents/version_7_1_february_2008.pdf>

[4] 4- Brook I. Microbiology and principles of antimicrobial therapy for head and neck infections. Infect Dis Clin North Am. 2007;21:355-91.

[5] 5- Daniluk T, Fiedoruk K, Zciepuk M, Zaremba ML, Rozkiewicz D, Cylwik-Rokicka D, et al. Aerobic bacteria in the oral cavity of patients with removable dentures. Adv Med Sci. 2006;51(Suppl. 1):86-90.

[6] 6- Das RN, Chandrashekhar TS, Joshi HS, Gurung M, Shrestha N, Shivananda PG. Frequency and susceptibility profile of pathogens causing urinary tract infections at a tertiary care hospital in western Nepal. Singapore Med J. 2006;47:281-5.

[7] 7- Ferrari PHP, Cai S, Bombana AC. Effect of endodontic procedures on enterococci, enteric bacteria and yeasts in primary endodontic infections. Int Endod J. 2005;38:372-80.

[8] 8- Ferreira da Silva M, Vaz-Moreira I, Gonzalez-Pajuelo M, Nunes OC, Manaia CM. Antimicrobial resistance patterns in Enterobacteriaceae isolated from an urban wastewater treatment plant. FEMS Microbiol Ecol. 2007;60:166-76.

[9] 9- Gaetti-Jardim E Jr, Landucci LF, Lins AS, Vieira EMM, Oliveira SR. Susceptibility of strict and facultative anaerobes isolated from endodontic infections to metronidazole and beta-lactams. J Appl Oral Sci. 2007;15:539-45.

[10] 10- Gaetti-Jardim E Jr, Nakano V, Wahasugui TC, Cabral FC, Gamba R, Avila-Campos MJ. Occurrence of yeasts, enterococci and other enteric bacteria in subgingival biofilm of HIV-positive patients with chronic gingivitis and necrotizing periodontitis. Braz J Microbiol. 2008;39:257-61.

[11] 11- Gionechetti F, Zucca P, Gombac F, Monti-Bragadin C, Lagatolla C, Tonin E, et al. Characterization of antimicrobial resistance and class 1 integrons in Enterobacteriaceae isolated from Mediterranean herring gulls (Larus cachinnans). Microb Drug Resist. 2008;14:93-9.

[12] 12- Gonçalves MO, Coutinho-Filho WP, Pimenta FP, Pereira GA, Pereira JAA, Mattos-Guaraldi AL, et al. Periodontal disease as reservoir for multi-resistant and hydrolytic enterobacterial species. Lett Appl Microbiol. 2007;44:488-94.

[13] 13- Hälgren A, Abednazari H, Ekdahl C, Hanberger H, Nilsson M, Sammuelson A, et al. Antimicrobial susceptibility patterns of enterococci in intensive care units in Sweden evaluated by different MIC breakpoint systems. J Antimicrob Chemother. 2001;48:53-62.

[14] 14- Handal T, Olsen I, Walker CB, Caugant DA. Beta-lactamase production and antimicrobial susceptibility of subgingival bacteria from refractory periodontitis. Oral Microbiol Immunol. 2004;19:303-8.

[15] 15- Huang SS, Lee SC, Lee N, See LC, Tsai MH, Shieh WB. Comparison of in vitro acitivities of levofloxacin, ciprofloxacin, ceftazidime, cefepime, imepenem, and piperacillin-tazobactam against aerobic bacterial pathogens from patients with nosocomial infections. J Microbiol Immunol Infect. 2007;40:134-40.

[16] 16- Khosravi AD, Mehdinejad M, Heidari M. Bacteriologic findings in patients with ocular infection and antibiotic susceptibility patterns of isolated pathogens. Singapore Med J. 2007;48:741-3.

[17] 17- Leibovici L, Vidal L, Paul M. Aminoglycoside drugs in clinical practice: an evidence-based approach. J Antimicrob Chemother. 2009;63:246-51.

[18] 18- Möller AJR. Microbial examination of root canals and periapical tissues of human teeth. Odontologisk Tidskrift. 1966;74:1-380.

[19] ¹⁹
- National Committee for Clinical Laboratory Standards. Methods for dilution antimicrobial susceptibility tests for bacteria that grow aerobically. 6^th ed. Document M7-A6. Wayne: NCCLS; 2003.

[20] 20- Pillar CM, Torres MK, Brown NP, Shah D, Sahm DF. In vitro activity of doripenem, a carbapenem for the treatment of challenging infections caused by gram-negative bacteria, against recent clinical isolates from the United States. Antimicrob Agents Chemother. 2008;52:4388-99.

[21] 21- Rice LB, Bellais S, Carias LL, Hutton-Thomas R, Bonomo RA, Caspers P, et al. Impact of specific pbp5 mutations on expression of β-lactam resistance in Enterococcus faecium Antimicrob Agents Chemother. 2004;48:3028-32.

[22] 22- Rybkine T, Mainardi JL, Sougakoff W, Collatz E, Gutmann L. Penicillin-binding protein 5 sequence alterations in clinical isolates of Enterococcus faecium with different levels of beta-lactam resistance. J Infect Dis. 1998;178:159-63.

[23] 23- Tonetti MS, Claffey N, European Workshop in Periodontology group C. Advances in the progression of periodontitis and proposal of definitions of a periodontitis case and disease progression for use in risk factor research. Group C consensus report of the 5th European Workshop in Periodontology. J Clin Periodontol. 2005;32:210-3.

[24] 24- Vignoli R, Calvelo E, Cordeiro NF, Lucero R, Ingold E, Quintana A, et al. Association of broad-spectrum antibiotic use with faecal carriage of oxyiminocephalosporin-resistant Enterobacteriaceae in an intensive care unit. J Hosp Infect. 2006;63:306-15.