1http://dx.doi.org/10.20396/bjos.v20i00.8663867

Volume 20
2021
e213867

Original Article

1. Student fellow, Federal University 
Rio Grande do Sul, Porto Alegre, Rio 
Grande do Sul, Brazil.
2. Student fellow, Post-Graduate 
Program in Dentistry, Federal 
University Rio Grande do Sul, Porto 
Alegre, Rio Grande do Sul, Brazil.
3. Post-Doctoral Student fellow, 
Post-Graduate Program in 
Bioscience and Biotechnology 
applied to Pharmacy, Department 
of Clinical Analysis, São Paulo State 
University, Araraquara, Brazil. 
4. Professor of Oral Microbiology 
and Biochemistry and Cariology, 
Department of Preventive and 
Community Dentistry, Federal 
University of Rio Grande do Sul, Porto 
Alegre, Rio Grande do Sul Brazil. 
5. Master degree student, Post-
Graduate Program in Dentistry, 
Federal University Rio Grande do Sul, 
Porto Alegre, Rio Grande do Sul Brazil. 
6. Professor of Periodontology, 
Department of Semiology and 
Clinic, Federal University of Pelotas, 
Pelotas, Rio Grande do Sul, Brazil.

*Corresponding author: 
Francisco Wilker Mustafa Gomes 
Muniz. Federal University of 
Pelotas. Rua Gonçalves Chaves, 
457, Pelotas/RS, Brazil, ZIP Code: 
96015-560. E-mail: wilkermustafa@
gmail.com. Telephone: +55 53 9 
91253611.

Received: January 7, 2021

Accepted: January 28, 2021

Editor: Dr Altair A. Del Bel Cury

Antimicrobial potential of 
essential oils mouthrinses 
with and without alcohol: 
a randomized clinical trial
Matheus Grunevald1, Romulo Cantarelli2, Harry Juan 
Rivera Oballe2, Thais de Cássia Negrini3, Rodrigo Alex 
Arthur4  , Eduardo Liberato da Silva5, Tiago Luís 
Herpich1, Francisco Wilker Mustafa Gomes Muniz6,* 

Aim: This study aimed to compare the microbiological 
potential and gustatory perception of essential oils (EO) 
mouthrinses containing and not containing alcohol. Methods: 
Twenty healthy adult volunteers rinsed with 10mL of the 
following test solutions: EO with alcohol, EO without alcohol, 
or a control solution (saline solution with mint essence). 
A washout period of at least seven days was adopted after a 
single-use protocol of the respective solution. All participants 
used all three tested substances. Antimicrobial potential was 
assessed by counting salivary total viable bacteria both before 
and after each rinse. Gustatory perception was evaluated 
using the Visual Analogue Scale (VAS). Multiple comparisons 
were performed with the Wilcoxon test, using Bonferroni 
correction. Results: Both EO solutions presented a higher 
antimicrobial potential in comparison to the control solution 
(p<0.017). However, no significant difference in antimicrobial 
potential was observed between EO containing or not 
containing alcohol (p=0.218). VAS of EO with alcohol (median: 
2.7) was similar to control solution (median: 1.6) (p=0.287). 
A better gustatory perception was observed of the EO without 
alcohol (median 7.6) when compared to the control solution 
(p<0.0001). When EO groups were compared, EO without 
alcohol also demonstrated a significantly better gustatory 
perception (p=0.001). Conclusion: Mouthrinse containing 
EO without alcohol presented a better taste perception when 
compared to the EO with alcohol, but no difference was 
observed in the antimicrobial potential of both EO solutions 
after a single rinse protocol. 

Keywords: Oils volatile. Bacteria. Mouthwashes. Alcohols. 
Taste perception.

https://orcid.org/0000-0001-8107-413X
https://orcid.org/0000-0002-3945-1752


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Grunevald et al.

Introduction
The control of supragingival biofilm is essential for preventing the development of 
several oral diseases, including gingivitis, periodontitis, and caries. To accomplish 
this, the most common strategy is the mechanical removal of biofilm with tooth-
brushes1. However, the sole use of toothbrushes may not be sufficient to maintain 
healthy conditions in all individuals. Patients with motor or cognitive problems, lack 
of motivation, those undergoing post-surgical phases, and those with orthodontic 
devices may require the use of antimicrobial-containing mouthrinses in order to 
achieve effective biofilm control2,3.

Several antimicrobial substances are available on the general market, among which 
essential oils (EO) present the most favorable results for gingivitis and dental plaque 
control in the long term. The literature constantly demonstrates better results using 
EO mouthrinse as an adjunct to the mechanical control of biofilm when compared 
to other oral hygiene regimens4,5. One study showed that EO presented 36.1% and 
24.1% higher antiplaque and antigingivitis effects, respectively, when compared to a 
placebo solution5.

Alcohol is present in the composition of several mouthrinses as a vehicle solu-
tion, despite the fact that it does not demonstrate important effects on gingivitis or 
plaque control6. Moreover, the flavor of mouthrinses is critical, as flavor may inter-
fere with patients’ adherence to treatment, especially when prescribed for long-term 
use7. Alcohol is likely responsible for the notoriously strong flavors of such solutions, 
which may be unpleasant for most individuals. As a result, over the last few years the 
industry has developed mouthrinses without alcohol. Recently, a randomized clini-
cal trial demonstrated no significant difference in the antiplaque and antigingivitis 
effects of EO with or without alcohol8. However, at the moment, no published study 
has evaluated the impact of alcohol on the gustatory perception of mouthrinses 
containing EO. Therefore, the aim of the present study is to compare the microbi-
ological potential and gustatory perception of EO mouthrinses containing and not 
containing alcohol.

Materials and Methods

Ethical aspects and study design

This is a crossover, randomized, double-blind, clinical trial that followed the Consoli-
dated Standards of Reporting Trials (CONSORT) statement. The study was approved 
by the Ethical Committee of the Associação dos Funcionários do Estado do Rio 
Grande do Sul (protocol #1.020.949). All volunteers signed an informed consent form 
prior to the beginning of the study.

Sample selection

Twenty participants were included in this study (17 women and three men). This  study 
was conducted between April and June of 2015, at the Dental Faculty of the Federal 
University of Rio Grande do Sul. All participants answered a questionnaire and were 



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Grunevald et al.

clinically examined to verify the following eligibility criteria: at least 18 years of age, 
nonsmokers, with at least 24 natural teeth.

The study criteria excluded individuals with a presence or history of periodontitis, 
active dental caries, pregnant or lactating women, users of removable partial den-
tures, those with fixed dental prostheses or orthodontic appliances, both alcohol 
abstainers and alcoholics, and those who had used antibiotics within three months 
prior to the start of the study.

Interventions and gustatory perception assessment

All participants used all three tested substances, with a washout period of at least 
seven days between tests. The solutions were as follows:

• EO+ group: Essential oils in an alcoholic solution (Listerine®, Johnson & Johnson, 
São Paulo, Brazil). Ingredients: Aqua, Sorbitol, Alcohol, Poloxamer 407, Benzoic 
Acid, Sodium Saccharin, Eucalyptol, Aroma (d-limonene), Thymol, Methyl Salicy-
late, Sodium Benzoate, Menthol and CI 42053. 

• EO- group: Essential oils in an aqueous solution (Listerine Zero®, Johnson & John-
son, São Paulo, Brazil). Ingredients: Aqua, Sorbitol, Propylene Glycol, Sodium Lau-
ryl Sulfate, Poloxamer 407, Eucalyptol, Benzoic Acid, Aroma (d-limonene), Thy-
mol, Methyl Salicylate, Sodium Benzoate, Menthol and CI 42053.

• Control group: Saline solution with mint essence.

All participants were instructed not to drink, eat or perform any control of biofilm, 
either chemical or mechanical, within one hour of the experimental procedure. 
Each  participant rinsed for one minute using 10  mL of the predetermined solution. 
In order to assure blindness, all mouthrinses were stored in opaque bottles and coded 
accordingly by an external researcher not involved in any other study process.

The order in which participants used the mouthrinses was randomly determined by 
a researcher not involved in data collection (FWMGM), using a randomizing website 
(randomization.com). The sequence was kept in an opaque envelope until the end 
of all experimental procedures to assure allocation concealment. During this period, 
only the researchers responsible for the randomization had contact with these enve-
lopes. The participants were not aware of which solutions they used at any experi-
mental period. 

Immediately after the rinse was performed, participants’ gustatory perceptions were 
evaluated using a Visual Analogue Scale (VAS). The VAS was composed of a straight 
line of 10cm. Markers on the left indicated the most unpleasant taste, while markers 
on the right indicated the most pleasant taste. The participants were instructed to 
mark at any point on the line based on this scale. Using a ruler, the distance between 
the beginning of the line and the participant’s mark was measured by one researcher 
who was blind to the group allocation (RC).

Microbiological analysis

In order to assess the antimicrobial potential of the test solutions, stimulated saliva 
was collected from all participants both before and after the use of each solution. 



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Grunevald et al.

All participants were asked to chew a piece of unflavored and inert gum to stimulate 
salivary flow. Saliva produced during the first minute was spat out and discarded. 
Participants chewed the gum for an additional five minutes, with the saliva produced 
during this period of time collected in proper sterile and coded bottles. All  pre- and 
post-rinse codified saliva samples were stored on ice and processed within two hours 
of their collection. Pre- and post-rinse saliva samples were kept on ice. Saliva sam-
ples were serially diluted in sterile 0.89% NaCl solution, and aliquots of 25 µl of each 
dilution were plated using the drop technique on the surface of Brain Heart Infusion 
Agar (BHI) supplemented with 5% sheep blood. Plates were incubated aerobically 
at 37°C for 48 hours9. Saliva was collected and analyzed only once. Colony-forming 
units (CFU) were counted on each drop by one blinded researcher (RC) under a ste-
reomicroscope, and were expressed as CFU/ml of saliva according to the formula 
described below:

CFU/ml saliva = (CFU x 1000/25) x 10f (1)

f = dilution factor from serially diluted samples.

Sample size calculation

The primary outcome of the present study was the microbiological potential. 
Therefore, the sample size estimation was based on data from a previously pub-
lished study10. It considered a mean (±standard deviation) of aerobic bacteria 
levels in the essential oil and placebo groups of 11.35±13.11 and 56.41±38.72, 
respectively. When it was considered a power of 90%, an alpha of 5%, and a total 
of 16 individuals were necessary. An attrition rate of 20% was expected, totaling 
20 participants.

Statistical analysis

For each individual, the percentage of reduction in salivary total bacterial viability was 
calculated considering pre- and post-rinse saliva samples. The differences in the 
antimicrobial potential and gustatory perception were analyzed using the Friedman 
test, as a non-normal distribution was detected in both outcomes. We analyzed data 
distribution using the Shapiro-Wilk test. As a p-value <0.001 was detected in the Sha-
piro-Wilk test, multiple pair-wise comparisons were performed using the Wilcoxon 
test. A Bonferroni correction was established, and the new p-value for statistical sig-
nificance was <0.017.

Results
Twenty-four individuals were recruited for the present study, among whom four were 
excluded because they did not fit the inclusion criteria. Reasons for exclusion are 
reported in Figure 1. Among the included individuals, the response rates were 100% 
for all follow-up periods. Furthermore, no adverse events were reported throughout 
the study.



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Grunevald et al.

24 subjects screened

20 subjects randomized (sequence of mouthwash used was randomized)

20 subjects in the
essential oil with

alcohol group

20 subjects in the
essential oil without

alcohol group

20 subjects in
the control group

20 subjects analyzed 20 subjects analyzed 20 subjects analyzed

4 excluded
Diagnosis of periodontitis = 1
Taken antibiotics 3 months

prior the study = 3

Figure 1. Flowchart of the participants in the study.

During microbiological analysis, no differences were found regarding counts of sali-
vary viable bacteria among groups by the pre-rinsing analysis (p=0.387). Table 1 shows 
the mean percentage reduction of the total viable bacteria of all three groups. By com-
paring the percentage of reduction in counts of viable bacteria before and after each 
rinse, a significant reduction was found (p<0.05), with 60.33±29.33, 62.61±39.25 and 
4.16±156.55 in the EO with alcohol, EO without alcohol and control groups, respec-
tively. The antimicrobial potential of both EO mouthrinses was significantly higher 
than that of the control group (p=0.007 for EO with alcohol and p=0.005 for EO with-
out alcohol). However, when both EO groups were compared, no significant difference 
was demonstrated (p=0.218).

Table 1. Mean±Standard deviation values for each time point and groups of the colony forming-units of 
total aerobes.

Group Mean±SD P-value

Before rinsing After rinsing
Mean percent 

reduction
Within groups

Between groups 
(percentage 
reduction)

EO + 1.87x108±1.62x108 0.71x108±1.06x108 60.33±29.33 <0.001# 0.218Ω
0.007µ
0.005α

EO - 3.73x108±12.5x108 0.52x108±1.31x108 62.61±39.25 <0.001#

Control 6.46x108±11.66x108 5.29x108±12.99x108 4.16±156.55 0.029#

P-value 
between 
groups

0.387* 0.074* 0.017*

Legend: SD: standard deviation; *Friedman test; #Wilcoxon test for the comparison within groups; Ω Wilcoxon 
test for the comparison between EO+ and EO- groups; µWilcoxon test for the comparison between control and 
EO+ groups; α Wilcoxon test for the comparison between control and EO- groups.

The gustatory perceptions of all tested solutions are reported in Table 2. These results 
demonstrated a statistically significant difference in gustatory perception among 
groups. The control group reported the worst flavor (median 1.6), the EO- group 
reported the most pleasant gustatory perception (median 7.6), and the EO+ group pre-



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Grunevald et al.

sented an intermediate perception (median 2.7). When groups EO+ and control were 
compared, no statistically significant difference was detected (P=0.287).  However, in 
the comparison between EO- and control groups, a statistically significance differ-
ence was detected, showing a better gustatory preference for the EO- mouthrinse 
(P<0.001). Regarding the comparison between EO groups, a significantly better gus-
tatory preference was observed for the EO- mouthrinse (P=0.001).

Table 2. Gustatory perception after a single rinse with essential oils with alcohol, without alcohol, and 
control substance.

Control EO+ EO- P-value

Median (min./max.) 1.6 (0.0 – 8.4) 2.7 (0.1 – 10.0) 7.6 (0.5 – 9.9) <0.001* α
0.001 Ω
0.301#Mean±SD 2.81±2.72 3.55±2.95 6.90±2.25

Legend: EO+: essential oil with alcohol; EO-: essential oil without alcohol; *Friedman test; #Wilcoxon test for 
the comparison between control and EO+ groups; α Wilcoxon test for the comparison between control and EO- 
groups; Ω Wilcoxon test for the comparison between EO+ and EO- groups.

Discussion
The present study aimed to compare the microbiological potential and gustatory 
perceptions of EO mouthrinses containing and not containing alcohol. Overall, it was 
observed that both solutions presented a significantly higher antimicrobial poten-
tial when compared to a negative control solution. However, both EO solutions pre-
sented similar antimicrobial potential. Regarding the gustatory potential, participants 
reported the EO without alcohol as having the most pleasant taste.

The chemical control of supragingival biofilm may be performed with mouth-
rinses. Among these, chlorhexidine is considered the gold standard substance, as 
it demonstrates a good antiplaque effect and long substantivity; however, several 
adverse events may be detected after long periods of use11-13. Other mouthrinses 
also demonstrate antiplaque and antigingivitis effects with fewer reported adverse 
events, and these substances may be used for longer periods14. However, a strong, 
unpleasant flavor and a burning sensation have been reported by the patients who 
use these mouthrinses.

Among other available mouthrinses, EO may be the most important one for patient 
outcomes5. In low concentrations, EO may inactivate bacterial enzymes, interfering 
with growth velocity and biofilm maturation. Additionally, its utilization may be an 
encouraging factor to enhance patient adherence to this method of supragingival 
biofilm control15. Traditionally, mouthrinses containing EO also contain alcohol in their 
composition. The alcohol is used to dilute or solubilize the oils, and it is also used 
to extend the product’s expire date. One study has shown that alcohol may pres-
ent some antimicrobial effects16, but a systematic review showed that an alcoholic 
vehicle demonstrated very limited effects in terms of antiplaque and antigingivitis 
efficacy6. In addition, short-17 and long-term8 clinical trials have demonstrated no 
statically significant difference in the antiplaque and/or antigingivitis efficacy of EO 
with or without alcohol. 

These results are in accordance with the present study, which demonstrated no sig-
nificant difference in the antimicrobial potential of the two EO solutions. However, fur-



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Grunevald et al.

ther long-term clinical trials are necessary to determine the clinical efficacy of both 
EO mouthrinses. The mechanical process of chewing an inert piece of gum detaches 
microorganisms from mucosal and tooth sites. Using this method, microbial diversity 
found on stimulated saliva is representative of other oral niches. Moreover, stimulated 
saliva has the advantage of carrying a greater microbial diversity than unstimulated 
saliva18. Considering that one of the outcomes of this study was to assess the anti-
microbial effects of EO-containing mouthrinses, it was decided that this study would 
use stimulated saliva to evaluate this effect on a broad load and diversity of microor-
ganisms (which could not be found by using unstimulated saliva).

The presence of alcohol can also negatively affect the gustatory perception of some 
individuals due to the strong flavor4, although a previously published study demon-
strated that alcohol was not capable of interfering in the taste perception of chlorhex-
idine solutions9. The literature reports that the flavor of mouthrinses is an important 
factor in their usage, and it is part of the criteria used by patients when choosing a 
mouthrinse7. It must be highlighted that several mouthrinses are sold on the general 
market. A prescription may or may not be necessary to buy these products, depend-
ing on the laws of different countries. Additionally, as many of these products are 
designed for continuous usage, a pleasant flavor is a pivotal factor for the ongoing 
use of the mouthrinse and adherence to the recommended treatment.

A VAS was used in order to measure participants’ gustatory perceptions. This is a 
valid method for quantifying the taste19,20. In the present study, participants performed 
the evaluation immediately after rinsing, without having access to their previous eval-
uations, which did not allow comparisons. It was found that the most pleasant gus-
tatory perception was reported for the EO not containing alcohol. Therefore, these 
results must be taken into consideration when prescribing an EO mouthrinse, as indi-
viduals with alcohol restrictions and those with higher sensitivity to alcohol should 
not receive an EO mouthrinse with alcohol. 

The present study used commercially available solutions with essential oils. 
 Additionally, a saline solution with mint essence was used. This was a double-blind 
and cross-over study, which reduced the chance of any interference from knowledge of 
which substance was tested. Furthermore, the washout period of at least seven days 
allowed a decrease in any potential residual effects during the study. The order of the 
tested solutions was determined randomly, avoiding any adaptation among the indi-
viduals throughout the study. In the present study, twenty individuals were included. 
Although this number may seem small, previous studies regarding the chemical con-
trol of biofilm have used similarly sized and valid samples21,22.  Regarding  the study 
participants, it is important to highlight that no dropouts occurred and no adverse 
events were reported.

Some limitations to the present study must be acknowledged, such as the fact that 
each rinsing was performed only once. Additionally, the included individuals were 
young and some of them were students of the School of Dentistry of the Federal 
University of Rio Grande do Sul. In this sense, these characteristics may have inter-
fered with the study results, decreasing the external validity of the present study23. 
Therefore, further clinical trials involving only non-health professionals are warranted. 



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Grunevald et al.

In addition, the present study included a higher number of female participants, and a 
lower internal validity might be expected for male individuals.

In conclusion, no significant difference was observed in the antimicrobial potential of 
EO with and without alcohol. However, it was concluded that the mouthrinse contain-
ing EO without alcohol was widely evaluated as having a more pleasant taste when 
compared to the flavor of an EO mouthrinse with alcohol. 

Acknowledgment
This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal 
de Nível Superior - Brasil (CAPES) - Finance Code 001. All other funding was self-sup-
ported by the authors. 

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