Comparative antimicrobial efficacy of selected root canal irrigants on commonly isolated microorganisms in endodontic infection

Sandeep Dubey; Suparna Ganguly Saha; Balakrishnan Rajkumar; Tapan Kumar Dhole

doi:10.4103/ejd.ejd_141_16

European Journal of Dentistry, Table of Contents

CC BY-NC-ND 4.0 · Eur J Dent 2017; 11(01): 012-016
DOI: 10.4103/ejd.ejd_141_16

Original Article

Dental Investigation Society

Comparative antimicrobial efficacy of selected root canal irrigants on commonly isolated microorganisms in endodontic infection

Sandeep Dubey

¹Department of Conservative Dentistry and Endodontics, College of Dental Sciences and Hospital, Indore, Madhya Pradesh, India

,

Suparna Ganguly Saha

¹Department of Conservative Dentistry and Endodontics, College of Dental Sciences and Hospital, Indore, Madhya Pradesh, India

,

Balakrishnan Rajkumar

²Department of Conservative Dentistry and Endodontics, Babu Banarasi Das College of Dental Sciences, Lucknow, Uttar Pradesh, India

,

Tapan Kumar Dhole

³Department of Microbiology, Sanjay Gandhi Postgraduate Institute of Medical Sciences, Lucknow, Uttar Pradesh, India

› Author Affiliations

Abstract

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Key words:

Agar disc diffusion method - BioPure MTAD - Candida albicans - Enterococcus faecalis

INTRODUCTION

Reduction or elimination of microflora during root canal treatment is achieved by the combined effect of both chemomechanical preparation and intracanal medications.[1],[2] The removal of microorganisms and other irritants from the confines of the root canal is conducted by means of the mechanical action of instruments and the flow and backflow of the irrigating solutions.[3],[4]

BioPure MTAD (Dentsply/Tulsa, Tulsa, OK, USA), which is a mixture of a tetracycline isomer, citric acid, anda detergent)[5] has been recommended as a final rinse irrigant because of its antimicrobial properties and its ability to remove the smear layer.[6],[7] It is less cytotoxic than most of the endodontic medicaments.[8],[9]

Aztreonam, which is a synthetic monocyclic beta-lactam antibiotic, has a molecular structure different from older beta-lactam antibiotics as it has a less complex nucleus.[1O] Ithas shown excellent activity against Gram-negative bacilliY [11]

Metronidazole, a nitroimidazole compound, is a broad-spectrum antibiotic and exhibits activity against anaerobic bacteria and protozoa. It demonstrates effective antibacterial activity against anaerobic cocei as well as Gram-negative and Gram-positive bacilli. ln the treatment of periodontal disease, it has been used both topically and systemically.[12]

The objective ofthis research was to assess and compare the antibacterial and antifungal effectiveness of BioPure MT AD, aztreonam, and metronidazole against obligate anaerobic bacteria, i.e., Bacteroides fragilis and Propionibacterium acnes, facultative anaerobic bacteria, i.e., EnterococcusJaecalis,and yeast, i.e., Candida albicans.

MATERIALS ANO METHODS

The microorganisms selected for this study, i.e., B. fragilis ATCC 25285 (Group 1), P. acnes ATCC 6921(Group 2), E. Jaecalis ATCC 29212 (Group 3), and C. albicans ATCC 10231(Group 4), were obtained from the American type culture collection and stored ata temperature of -10°C to -20°C in a freezer.

Strains of the selected microorganisms were reactivated in the respective media ata given temperature and time.

Groups 1 and 2 - Activated in brain-heart infusion broth supplemented with hemin and menadione at 37°C for 48 h.

Group 3- Activated in brain-heart infusion broth for 24 h at37°C.

Group 4- Activated inSabouraud dextrose agar broth at 37°C for 24 h.

After the revival of microorganisms, four to five well-isolated colonies of each strain were picked up with a sterile loop, later dissolving them in respective test tu bes containing O.85% of 5 mlsterile saline to create a turbidity of0.5McFarlandscale(1.5 x 10SCFU/ml)for the preparation of inoculum. The resulting suspension was then spread on agar plates with the help of a sterile cotton swab in a form so that a lawn growth was observed.

The media used for the four groups were as follows:

Group 1 - Wilkins-Chalgren agar plate (HiMedia,Mumbai).

Group 2 - Brain-heart infusion medium (HiMedia, Mumbai) with 1% glucose.

Group 3 - Mueller-Hinton agar plate (HiMedia, Mumbai).

Group 4- Sabouraud dextrose agar plate (HiMedia, Mumbai).

Antibiotic disc preparation

Antibiotic solution of BioPure MT AD was prepared by mixing powder and diluent.

Sterilized Whatman paper no. 1was used to prepare 6-mm dia meter discs, which were later soaked in 40 )-ll of normal saline and BioPure MTAD, respectively.

The company-made aztreonam and metronidazole antibiotic discs (BD Diagnostic, India) were also used for the test.

These antibiotic discs were then aseptically transplanted to the agar plate formerly incubated wit h microorganisms.

For Group 1 and Group 2, agar plates BioPure MT AD, aztreonam, metronidazole, and normal saline containing discs, and for Group 3 and Group 4, agar plates, BioPure MT AD, aztreonam, and normal saline prepared discs were transferred aseptically.

Group 1and Group 2 agar plates were incubated in an anaerobic environment created using the Anoxomat system (Mart Microbiology BV, Netherlands) for 48 h.

Group3and Group4 plates were incubated for 48 hat

37°C under the aerobic conditions, in an atmosphere of

10% C0 , in a C02 incubator (New Brunswick, USA). All assays were repeated five times. Measurement of zones of inhibition was conducted by a Vernier caliper.

RESULTS

The results obtained were statistically evaluated using one.way ANOVA test and the intergroup comparison was done using Bonferroni multiple comparison test. Value of P < 0.001 was considered statistically significant.

Bacteroides fragilis (Group 1) [Tables 1a] and [b]
Propionibacterium acnes (Group 2) [Tables 2a] and [b]
Enterococcus faecalis (Group 3) [Tables 3a] and [b]
Candida albicans (Group 4) [Tables 4a] and [b].

DISCUSSION

Disc diffusion technique, a well-established method for antimicrobial research, has been applied in this study.[13],[14] This method has an advantage that chemical properties of tested medicaments do not alter during the procedure and also it is less technique sensitive.[15]

Anoxomat system was used for anaerobic culture in the current study as earlier research[16] had shown that with the use of this system commendable growth is achieved, in terms of density and colony size.Evidently, the Anoxomat method is considerably reliable and appears tosupport the growth of strict anaerobes efficiently. Zone of inhibition around specimens was measured in the present study using a Vernier caliper at three different points as clone in previous studies.[17],[18] ln the present study, all assays were repeated five times to establish reproducibility.[19]

Tabulated results demonstrated that metronidazole produced the maximum zone of inhibition against B. fragilis [Graph 1]. Vijaykumar et al.[20] and Whelan et al.[21] demonstrated that metronidazole was effective against B. fragilis, which is in agreement with the results obtained in the current study.

Antimicrobial efficacy against P. acnes in the existing study was shown to be maximum by metronidazole [Graph 2]. Effect of metronidazole on P. acnes has been reported with mixed findings in the literature. Gaetti-Jardim Júnior et al.[22] determined the positive antibacterial effect of metronidazole against P. acnes, and the results obtained were in accordance with the present study. Similarly, Effa t Khodeinae et al. [23] demonstrated that 2% metronidazole showed adequate efficacy against P. acnes while evaluating the efficacy of 2% metronidazole gel against acne vulgaris. ln contrast to the above results, few studies reveal no effect of metronidazole against P. acnes) [24]

Table 1
Table 1a: Effect of root canal irrigants and their values of zone of inhibition against Bacteroides fragilis
Irrigants	Zone of inhibition (mm), mean±SD	Effect
ANOVA F=681.96, P.0.001 (significant). SD: Standard deviation
BioPure MTAD	26.75±1.02	Sensitive
Metronidazole	30.00±1.63	Sensitive
Aztreonam	28.25±1.02	Sensitive
Normal saline	0±0.0	Resistant

Table 2
Table 1b:lntergroup comparison of mean zone of inhibition size for the irrigants against Bacteroides fragilis
	t	p	Slgnlficance
1 - BioPura MTAD, 2- Matronidazola, 3 - Aztreonam,4- Normal salina
1 versus 2	4.22	<0.001	Significant
1 versus 3	1.94	0.0	Nonsignificant
1 versus 4	34.71	<0.001	Significant
2 versus 3	2.27	0.0	Nonsignificant
2 versus 4	38.93	<0.001	Significant
3 versus 4	36.66	<0.001	Significant

Table 3
Table 2a: Effect of root canal irrigants and their values of zone of inhibition against Propionibacterium acnes
Irrigants	Zone of inhibition (mm), mean±SD	Effect
ANOVA F=307.37, P.0.001 (significant). SD: Standard deviation
BioPure MTAD	26.00±0.82	Sensitive
Metronidazole	29.25±1.82	Sensitive
Aztreonam	0±0.0	Resistant
Normal saline	0±0.0	Resistant

Table 4
Table 2b: lntergroup comparison of mean zone of inhibition size of irrigants against Propionibacterium acnes
	t	p	Significance
1 - BioPura MTAD, 2- Matronidazola, 3- Aztreonam,4- Normal salina
1 versus 2	7.96	<0.001	Significant
1 versus 3	63.68	<0.001	Significant
1 versus 4	63.68	<0.001	Significant
2 versus 3	71.64	<0.001	Significant
2 versus 4	71.64	<0.001	Significant
3 versus 4	0.0	0.0	Nonsignificant

Table 5
Table 3a: Effect of root canal irrigants and their values of zone of inhibition against Enterococcus Faecalis
Irrigants	Zone of inhibition (mm), mean±SD	Effect
ANOVA F=516.12, P.0.001 (significant). SD: Standard deviation
BioPure MTAD	29.25±1.63	Sensitive
Aztreonam	8.5±1.23	Sensitive
Normal saline	0.0±0.0	Resistant

Table 6
Table 3b: Intergroup comparison of mean zone of inhibition size for irrigants against Enterococcus faecalis
	t	p	Significance
1 -BioPure MTAD, 2 -Aztreonam, 3 -Normal saline
1 versus 2	24.9	<0.001	Significant
1 versus 3	35.10	<0.001	Significant
2 versus 3	10.20	<0.001	Significant

Table 7
Table 4a: Effect of root canal irrigants and their values of zone of inhibition against Candida albicans
Irrigants	Zone of inhibition (mm), mean±SD	Effect
ANOVA F=430.50, P.0.001 (significant). SD: Standard deviation
BioPure MTAD	8.50±0.82	Sensitive
Aztreonam	0.0±0.0	Resistant
Normal saline	0.0±0.0	Resistant

Table 8
Table 4b: Intergroup comparison of mean zone of inhibition size of irrigants against Candida albicans
	t	p	Significance
1 -BioPure MTAD, 2 -Aztreonam, 3 -Normal saline
1 versus 2	25.50	<0.001	Significant
1 versus 3	25.50	<0.001	Significant
2 versus 3	00.00	00.00	NonSignificant

electron transport components, i.e., ferredoxin, which are capable of donating electrons to metronidazole, developing highly reactive nitro radical anions that kill susceptible organisms by a radical-mediated mechanism.[18] This could be a possible reason for its highantimicrobialefficacy againstB.Jragilis andP. acnes.

ln the present study, metronidazole was not used to test antimicrobial efficacy for E.Jaecalis and C. albicans because it is ineffective against facultative anaerobes. Literature has already proven its lacks of antimicrobial effect against E. Jaecalis.[19] Krishna et al.[25] in their study demonstrated that 10% metronidazole was not effective against E. Jaecalis among the tested intracanal medicaments. Yujra et al.[26] demonstrated that long-standing metronidazole therapy preferred the establishment of C. albicans in the oral cavity of rats.

ln the current study, maximum mean zone of inhibition against E. Jaecalis was revealed by BioPure MTAD [Graph 3], which is in accordance with severa!other studies.[7] Newberry et al.[8] in their study identified that seven out of the eight tested strains of E.Jaecalis growth were affected when MTAD was used as a final irrigant. The presence of doxycycline defines the superior antimicrobial effect of MTAD against E. Jaecalis).[9] However, results of this research are in contradiction to reports which refute the antimicrobial effect of MTAD against E.JaecalisY [10]

Graph 1: Comparison of mean zone of inhibition of root canal irrigantsBioPure MTAD

Graph 2: Comparison of mean zone of inhibition of root canal irrigants against Propionibacterium acnes

Graph 3: Comparison of mean zone of inhibition of root canal irrigants against Enterococcus faecalis

ln the present study, antifungaleffect against C. albicans was shown only by MTAD this result obtained was in agreement with the result given by Arslan et al.) [27] who demonstrated antimicrobial action of MTAD against C. albicans and E.Jaecalis. The antifungal effect of MTAD can be attributed to the better flow and penetration properties of doxycycline.[12] Contrary to the above results, a study conducted by Ashari et al.[18]showed that MT AD is ineffective against C. albicans and its substantivity may be altered when used in conjunction with NaOCl.

MTAD in the current research has revealed su bstantial zone of inhibition against both B. fragilis and P. acnes. This may be possibly due to the occurrence of doxycycline as earlier research has confirmed the action of doxycycline on B. fragilis and P. acnes [11] in inhibiting the protein synthesis.

Aztreonam in the present study showed significant antimicrobial efficacy against B. fragilis and mild antibacterialactivity against E.faecalis butwascompletely inactive against P. acnes and C. albicans microorganisms. Aztreonam,a bactericida!antibiotic, acts by interrupting with the formation of the bacterial cell wall.[2] It causes lysis and death of Gram-negative bacteria by binding to the penicillin-bindingprotein-3 (PBP-3)[3]which might be the reason for its activity against B. fragilis. Poor affinity has been shown for the PBP-3 of Gram-positive and anaerobic bacteria which could be the reason behind its mild activity against E. Jaecalis.

CONCLUSIONS

On the basis of results obtained in the current study, it may bestated that BioPure MTAD can be recommended as an effective alternative to the currently used root canal irrigants due to its superior antimicrobial properties against bothaerobic and anaerobic microbial organisms as well as C. albicans. Metronidazole and aztreonam, on the other hand, are, however, not significantly efficacious against all strains of microbes commonly present in the root canat thus limiting their use as an effective antimicrobial root canal irrigant.

Although the present study was dane with strict adherence to all the scientific protocols, still further studies are required to evaluate the efficacy of the different irrigants, which may further widen their horizon in the field of endodontics.

Financial support and sponsorship

Nil.

References

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Figures

Graph 1: Comparison of mean zone of inhibition of root canal irrigantsBioPure MTAD

Graph 2: Comparison of mean zone of inhibition of root canal irrigants against Propionibacterium acnes

Graph 3: Comparison of mean zone of inhibition of root canal irrigants against Enterococcus faecalis