Bioscience Journal  |  2021  |  vol. 37, e37038  |  ISSN 1981-3163 
 

1 

 

 
 

Matheus Albino SOUZA1  , Fernanda Duda BONATTO2 , Afonso Cristiano Fleck da SILVA2 ,  

Ezequiel Santin GABRIELLI1 , Felipe Trentin MOTTER2 , Larissa PIUCO2 ,  

Karen Barea de Paula DUARTE3 , Charise Dallazem BERTOL4 ,  

Luciana Grazziotin ROSSATO-GRANDO5 , Carlo Theodoro Raimundy LAGO6 , Doglas CECCHIN1 , 

Juliane BERVIAN7 , João Paulo De CARLI8 , Francisco MONTAGNER9  
 
1 Department of Endontics, School of Dentistry, University of Passo Fundo, Passo Fundo, Rio Grande do Sul, Brazil. 
2 Private Practice, Passo Fundo, RS, Brazil. 
3 Postgraduate Program in Dentistry, Federal University of Rio Grande do Sul, Porto Alegre, Rio Grande do Sul, Brazil. 
4 Department of Pharmacy, Pharmacy Course, University of Passo Fundo, Passo Fundo, Rio Grande do Sul, Brazil. 
5 Department of Toxicology, Pharmacy Course, University of Passo Fundo, Passo Fundo, Rio Grande do Sul, Brazil. 
6 Department of Restorative Dentistry, School of Dentistry, University of Passo Fundo, Passo Fundo, Rio Grande do Sul, Brazil. 
7 Department of Pediatric Dentistry, School of Dentistry, University of Passo Fundo, Passo Fundo, Rio Grande do Sul, Brazil. 
8 Department of Oral Medicine, School of Dentistry, University of Passo Fundo, Passo Fundo, Rio Grande do Sul, Brazil. 
9 Department of Endodontics, School of Dentistry, Federal University of Rio Grande do Sul, Porto Alegre, Rio Grande do Sul, Brazil.  

 
Corresponding author: 
João Paulo De Carli 
Email: joaodecarli@upf.br 
 
How to cite: SOUZA, M.A., et al. Effect of reciprocating instrumentation on chlorhexidine substantivity on human dentin: chemical analysis 
followed by confocal laser microscopy. Bioscience Journal. 2021, 37, e37038. https://doi.org/10.14393/BJ-v37n0a2021-54518 

 
Abstract 
The present research analyzed the reciprocating instrumentation associated to chlorhexidine (CHX) 
substantivity as its correlation with E. faecalis viability in ex vivo root canals. Eighty extracted single-rooted 
human teeth were used, being 40 to high-performance liquid chromatography (HPLC) and 40 to confocal 
laser scanning microscopy (CLSM). In both, teeth were decoronated and the cervical third was prepared. In 
the CLSM analysis, the root canals were inoculated with E. faecalis for 14 days. Samples were divided into 4 
groups (n=10) according to instrumentation technique: no instrumentation and irrigation with distilled water 
(control); manual instrumentation (K-File); rotary instrumentation (ProTaper Next); and reciprocating 
instrumentation (Reciproc R25). Two percent chlorhexidine was applied as irrigating substance in 
experimental groups. Longitudinal grooves resulted in 2 halves root and 20 proof bodies in each group. 
Samples were divided by chance in two groups (n=10) and the outcomes were evaluated after two days and 
one week. The retained chlorhexidine and live cells after instrumentation techniques in each evaluation time 
was measured by HPLC and CLSM, respectively. Specific analysis was applied for experimental tests (p≤0.05). 
Both rotary as well as reciprocating techniques significantly reduced the amount of chlorhexidine on dentin 
in all observation periods (p<0.05). After evaluation times, all experimental groups presented lower live cells 
compared to control, but without statistically difference. Intragroup comparisons in times of evaluation 
showed no differences in instrumentation techniques, in chlorhexidine retention and number of live cells 
(p>0.05). Reciprocating instrumentation does not interfere on chlorhexidine substantivity. 
 
Keywords: Chromatography. Enterococcus faecalis. Ex vivo. Human Tooth. Root Canal Preparation. 
 
 
 

EFFECT OF RECIPROCATING INSTRUMENTATION ON 
CHLORHEXIDINE SUBSTANTIVITY ON HUMAN DENTIN:  
CHEMICAL ANALYSIS FOLLOWED BY CONFOCAL LASER 

MICROSCOPY 

https://orcid.org/0000-0002-9412-3807
https://orcid.org/0000-0002-4873-4287
https://orcid.org/0000-0001-8933-9817
https://orcid.org/0000-0002-9825-4222
https://orcid.org/0000-0003-2285-8027
https://orcid.org/0000-0003-4680-9991
https://orcid.org/0000-0002-6779-2765
https://orcid.org/0000-0001-7596-315X
https://orcid.org/0000-0003-4574-855X
https://orcid.org/0000-0002-9018-5373
https://orcid.org/0000-0001-8851-5233
https://orcid.org/0000-0001-5718-3539
https://orcid.org/0000-0002-4705-6226
https://orcid.org/0000-0002-7850-0107


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2 

Effect of reciprocating instrumentation on chlorhexidine substantivity on human dentin: chemical analysis followed by confoca l laser 
microscopy 

1. Introduction 

Microorganisms are the primary etiologic agents of endodontic infection, promoting the progression 
of pulp and periapical diseases (Rôças and Siqueira 2010). Among these microorganisms, Enterococcus 
faecalis (E. faecalis) is a gram-positive and facultative bacteria, which is strongly resistant and usually 
associated with endodontic failure (Williams et al. 2006). So, auxiliary chemical substances as well as 
endodontic apparatus are very important in performing effective chemo-mechanical preparation, with the 
aim of providing endodontic decontamination (Dal Bello et al. 2019).  

Different auxiliary chemical substances can be used for root canal disinfection. Chlorhexidine (CHX) 
has broad-spectrum antimicrobial action (Rôças et al. 2016) and ability to be adsorbed in the dentin walls, 
providing antimicrobial effects over time (substantivity) (Böttcher et al. 2015). On the other hand, the use 
of reciprocating files is recommended to perform root canal shaping, because this technique applies less 
stress to the instrument and increase resistance to flexural fatigue (Gavini et al. 2012), removes bacteria  
(Neves et al. 2016) and induces lower apical extrusion of bacteria and debris during instrumentation (Alves 
et al. 2018). 

However, CHX substantivity is time dependent (Souza et al. 2012) and reciprocating method is faster, 
providing less time of contact of the auxiliary chemical substance with the root dentine (Guelzow et al. 2005), 
reducing the antimicrobial properties of these chemical agents during endodontic therapy (Souza et al. 
2018a). In addition, the use of reciprocating instrumentation results in lower CHX retention in the root dentin 
(Souza et al. 2018b). Finally, there are no studies correlating CHX retention in the root dentin with bacterial 
viability in the literary search carried out by the authors, in root canals prepared using the reciprocating 
technique.  

Thus, the objective of this research was to analize the reciprocating instrumentation on chlorhexidine 
substantivity and its correlation with E. faecalis viability in ex vivo human root canals. The null hypotheses 
were (i) reciprocating instrumentation does not interfere on CHX substantivity and (ii) there is no correlation 
between the amount of retained CHX and bacterial viability in infected root canals. 
 
2. Material and Methods 

The experiment was analized by the Research Ethical Committee of UPF (process 669.390). Eighty 
freshly extracted single-rooted human teeth of upper central and lateral incisors group were elected. The 
dental organs belonged to patients aged 20-30 years. The methodology of this work was based on previous 
studies (Souza et al. 2012; Ran et al. 2015). Each sample was prepared by sectioning its coronary portion, 
establishing the root remnant at a length of 15mm. The pulp tissue remaining in the root canals was removed 
with distilled water (DW) and mechanical instrumentation with a #08 K file (Dentsply Maillefer, Ballaigues, 
Switzerland). The cervical third was prepared using Largo drill #3 (Dentsply Maillefer) and DW. The working 
length (WL) was established by introducing #10 K-file up to the apical foramen and subtracting 1.0 mm from 
the length. Root canals with an apical diameter larger than the K # 15 file were not included. The 
methodology was divided into two sections: CHX quantification with High-performance Liquid 
Chromatography (HPLC) and bacterial viability analysis by Confocal laser scanning microscopy (CLSM). 
 
CHX quantification with HPLC: chemo-mechanical preparation 

The 40 samples were randomly divided into four groups (n=10), according to the instrumentation 
technique:  

(1) Control group - Irrigation with 5 mL of DW was performed, using 5-mL syringe with 19-G needle 
centered within the canal, 3 mm short of the WL. Then, root canals were dried with sterile paper points.  

(2) Manual instrumentation - The step-back technique was used for widening the root canals. Manual 
K files was worn, starting with file # 15 and ending with file # 30 in WL. The step-back instrumentation was 
performed using four K files larger than the last file used for apical preparation. It started with file k # 35 
ending with file # 50, gradually decreasing 1mm of WL with each increase in diameter of the file. 

(3) Rotary instrumentation. ProTaper Next instruments (Dentsply Tulsa Dental Specialties, Johnson 
City, TN, USA) were used in a handpiece powered by electric engine (VDW Silver Reciproc Motor, VDW), at 



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SOUZA, M.A., et al. 

speed of 300 rpm in a crown-down manner, using a gentle in-and-out motion, according to manufacturer’s 
instructions. X1 shaping file moved apically to 2 mm before reaching WL, followed by reaching full WL. Files 
X2 and X3 were used to finish the preparation of the apical third in the WL. Instrumentation was performed 
in pecking movements. The instruments were regularly cleaned to remove debris. When the instrument 
reached the WL, and showed free rotation in the root canal, it was removed. At this point, the next 
instrument of the sequence was used. 

(4) Reciprocating instrumentation. Reciproc R25 (VDW GMBH, Munich, Germany) was inserted into 
the root canal, in pecking movements the instrumentation was recommended in thirds, starting with the 
cervical third. After 3 movements in and out of the root canal, the file was removed for cleaning. Irrigation 
was performed interspersed with instrumentation, until the file reached the WL. Finally, the file was inserted 
up to 1 mm short of the WL with brushing motion against the lateral walls and irrigation was performed. The 
file was activated in an electric engine (VDW GMBH), using the predefined set recommended by the 
manufacturer. 
 
CHX quantification with HPLC: irrigation regimen 

CHX was the auxiliary chemical substance used for root canal preparation. The applied formulation 
was Natrosol-based gel at 2% concentration (Natupharma, Passo Fundo, RS, Brazil). DW was the irrigation 
solution.  

Irrigation was performed with DW in a volume of 5mL in all samples from the experimental groups. 
The root canal was previously filled with CHX until extravasation before using each manual instrument (8 
times) and rotary instrumentation (3 times) and also before progression in each third of the reciprocal 
instrumentation (3 times). After the use of each instrument or progression in each third in the reciprocating 
instrumentation, irrigation with 5 mL of DW was performed.  

Final irrigation with 3 mL of 17% EDTA (Natupharma, Passo Fundo, RS, Brazil) for 1 minute followed 
by irrigation with 5 mL of DW was performed in all groups in order to remove the smear layer. Then, root 
canals were dried with sterile paper points.  
 
CHX quantification with HPLC: CHX quantification 

Longitudinal grooves were performed on root free surfaces with diamond disk, avoiding the inner 
part of the root canal. Fracture was made with chisel and hammer, providing 2 halves of each root and 20 
samples per group. Samples from each group were randomly divided into 2 subgroups (n=10) and 
substantivity was evaluated after 48 hours and 7 days. Samples were stored at 37 °C and 100% relative 
humidity during evaluation times. 

The collected samples were stored in a 1 and 5 mL microtube, and an extracting solution (acetonitrile: 
1% formic acid, 20:80) was added. The microtubes were heated in a water bath at 80º C for 20 minutes and 
sonicated for 10 minutes. Contents were transferred to 1.5-mL microtubes and centrifuged at 6.000 rpm for 
15 minutes. Supernadants were diluted 10 times, and 20 µL were injected into the HPLC system (Flexar, 
Perkin Elmer, Burnsville, MN, USA). CHX was assayed by using isocratic separation with methanol:water 
(63:37, v/v). Triethylamine (0.4%) was added to the mobile phase, and the pH was adjusted to 3.7 with 
chloridric acid. Flow rate of 1.0-mL/min was maintained with diode array detector set at 260 nm, ayielding 
a total run time of 8 minutes. Twenty microliters of each sample were injected into HPLC system equipped 
with isocratic pump, diode array detector, degasser, and manual injection system (all HPLC components and 
Chromera WorkStation software were from Perkin Elmer, Burnsville, MN, USA). Chromatographic 
separations were performed using reverse-phase column (250 x 4mm, 5-mm LiChrospher 100 RP-18). The 
column was protected by a guard column (4 x 4mm, 5-mm LiChrospher 100 RP-18; Merck Millipore, 
Frankfurt, Germany) and maintained at temperature of 22 ± 2 °C. 
 
 
 
 
 



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Effect of reciprocating instrumentation on chlorhexidine substantivity on human dentin: chemical analysis followed by confoca l laser 
microscopy 

Bacterial viability analysis by CLSM: Specimen preparation 

Two longitudinal grooves were made on the outer root surface of the samples. The grooves extended 
close to the root canal. In addition, two circumferential grooves around the entire root were made at a 
distance of 5mm and 10mm from the root canal entrance. These preparations were performed with a 
diamond disk, avoiding touching the inner portion of the root canal. 
 
Bacterial viability analysis by CLSM: Culture and inoculum preparation 

The samples were standardized as to the inner diameter of the canal. WL was established as 
described above. Samples were increased in the WL up to a #15 file with renewed irrigation of DW at each 
instrument change. Finally, the canals were filled with 17% EDTA, which remained inside for 1 minute, 
followed by final irrigation with 5 mL of DW and drying samples with absorbent paper tips. 

Roots were sterilized at 120 oC in autoclave (Kavo, Joinville, SC, Brazil) for 30 minutes. Four samples 
were randomly selected for sterilization control. Sterile paper point was placed in contact with canal walls 
for 15 seconds and transported to microtube containing 1 mL of 0.9% saline solution (Basso, Caxias do Sul, 
RS, Brazil). The material was homogenized and 100 µL aliquot was cultivated on blood agar. Samples were 
incubated at 37º C for 48 hours and showed no bacterial growth. 

The reference strain was E. faecalis (ATCC 19433), which was cultivated in brain-heart infusion (BHI) 
broth (Acumedia–Neogen, Lansing, MI, USA) for 24 h at 37 oC in bacteriological incubator (Kavo, Joinville, 
SC, Brazil). The turbidity degree was adjusted to McFarland's 1.0 scale, corresponding to 3.0x108 CFU/mL 
and optical density from 0.25 to 550 nm. A 100-μL culture aliquot was inoculated into the root canal of each 
sample at WL. The bacterial contamination process was maintained for 14 days. Every 48 hours, intercalating 
with the inoculum, an aliquot of sterile BHI was inserted into the samples. 

The control of contamination by E. faecalis was performed with an aliquot of a specimen randomly  
collected from each group once a week. Gram stain test, blood agar culture, catalase, and esculin tests were 
carried out, verifying the absence of other microorganisms. 
 
Bacterial viability analysis by CLSM: chemo-mechanical preparation 

The 40 samples were irrigated with 5 mL of DW and randomly distributed into four groups (n=10): 
control group (DW), manual, rotary and reciprocating instrumentation. Procedures previously described for 
control and experimental groups, as well as for the irrigation regimen, were adopted in this evaluation.  
 
Bacterial viability analysis by CLSM: bacterial viability analysis 

The complete fracture of longitudinal grooves was made with a chisel and hammer, providing 2 
samples of 5 mm from the middle third of each root and 20 samples per group. Samples from each group 
were randomly divided into 2 subgroups (n=10) and bacterial viability was evaluated after 48 hours and 7 
days. Samples were stored at 37 °C under 100% relative humidity during the evaluation periods. 

After each evaluation period, sample were placed over a glass coverslip (0.17-mm thick) (Precision 
Glass Line; CRAL Ltda, Cotia, Brazil). The Live/Dead BacLight Bacterial Viability kit L-13152 (Molecular Probes, 
Invitrogen, Eugene, OR) was used to determine bacterial viability. SYTO9 probe (excitation at 488 nm and 
emission at 525 nm) labels all bacteria in a population, whereas propidium iodide probe (excitation at 488 
nm and emission at 560 nm) penetrates only bacteria with damaged plasmatic membrane. Thus, bacteria 
incubated in the presence of the 2 fluorescent markers simultaneously in green color if alive and in red color 
if dead. The dye was applied over the dentin sample for 15 minutes at 1:1 ratio (total volume of 20 mL). 
Subsequently, topographic analysis of sample was performed. Fluorescence from the stained cell was viewed 
using a CLSM (Olympus  Europa  Holding  GmbH, Hamburg, Germany). Simultaneous dual-channel imaging 
was used to display green and red fluorescence. The confocal ‘‘stack’’ with 1-mm step size and format of 
512x512 pixels from a random area was obtained from each sample, using 60x oil lens. Images were acquired 
through Olympus FluorView Version 1.7 software (Olympus Europa Holding GmbH). At least 10 mm of the 
scanning included the subsurface level of the dentin. For the viability evaluation, quantitative analysis was 
performed with the bio Image L software (The MathWorks Inc, Natick, MA). Briefly, the software produces 



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SOUZA, M.A., et al. 

information on the total biofilm population as well as on independent subpopulations represented by green 
and red fluorescent colors. The software evaluated the subpopulation of green and red cells as living and 
dead cells in each sample of each group, assigning a value for this sample. To remove the green background, 
the noise reducing factor was adjusted to 0.9. 
 
Statistical analysis 

In the HPLC evaluation, means and standard deviations of CHX substantivity for all groups were 
calculated in milligrams per milliliter (mg/mL), representing the volume of extracted solution containing CHX 
retained on the dentinal surface. Normal data distribution was confirmed by the Kolmogorov-Smirnov test 
(p>0.05). Results were statistically analyzed by two-way ANOVA and Scheffe post-hoc tests (α=0.05). 

In the CLSM evaluation, normal distribution was confirmed by the Lilliefors test. The mean and 
standard deviations of the amount of live cells were analyzed by two-way ANOVA followed by Tukey test 
(p<0.05).  

Correlation between amount of retained CHX and live cells was performed by Spearman rank 
correlation co-efficient. 

All data were analyzed using SPSS 11.0 software (IBM SPSS Statistics 20; SPSS, Chicago, IL). 
 
3. Results 

Data about substantivity (in mg/mL) are presented in table 1. Manual instrumentation presented 
higher CHX retention, whereas rotary and reciprocating instrumentation induced significantly lower CHX 
retention, in all observation periods (p<0.05). There was no statistical significant differences in all 
instrumentation techniques, presenting similar amount of CHX retained in 48 hours and 7 days (p>0.05).  
 
Table 1. Means (standard deviation) of substantivity of all groups (in mg/mL) on human dentin according 
to instrumentation techniques and evaluation times. 

Instrumentation technique 48 hours 7 days 

Control 0.000 (0.000)A,a 0.000 (0.000)A,a 

Manual 0.137 (0.015)C,a 0.104 (0.010)C,a 

Rotary 0.083 (0.018)B,a 0.067 (0.019)B,a 

Reciprocating 0.082 (0.019)B,a 0.060 (0.016)B,a 

Different capital letters in each column indicate statistically significant difference (p<0.05). Different lowercase letters in the row 
indicate statistically significant difference (p<0.05). 

 
Mean and standard deviation of the amount of live cells (green) of all groups are presented in table 

2. After 48 hours and 7 days, all experimental groups presented lower number of live cells compared to the 
control group, with no statistically significant difference between them (p>0.05). There was no significant 
difference when periods were compared within the same group. Representative images of each group on 
different evaluation times are shown in figure 1. 

The Spearman rank correlation co-efficient revealed no correlation between CHX retaining (HPLC 
evaluation) and live cells (CLSM evaluation) (p>0.05). 
 
Table 2. Mean and standard deviation of live cells according to instrumentation techniques and evaluation 
times. 

Instrumentation technique 48 hours 7 days 
Control 720.0 (182.4)A,a 514.5 (138.3)A,a 

Manual 255.9 (172.4)B,a 133.3 (84.0)B,a 

Rotary 136.6 (121.0)B,a 88.3 (40.0)B,a 

Reciprocating 120.2 (71.4)B,a 124.4 (64.5)B,a 

Different capital letters in each column indicate statistically significant difference (p<0.05). Different lowercase letters in the row 
indicate statistically significant difference (p<0.05). 
 



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6 

Effect of reciprocating instrumentation on chlorhexidine substantivity on human dentin: chemical analysis followed by confoca l laser 
microscopy 

 
Figure 1. Representative images of confocal laser scanning microscopy of each group on different 
evaluation times. A – control group (48 hours); B – manual instrumentation (48 hours); C – rotary 

instrumentation (48 hours); D – reciprocating instrumentation (48 hours); E – control group (7 days); F – 
manual instrumentation (7 days); G – rotary instrumentation (7 days); H – reciprocating instrumentation (7 

days). 
 
4. Discussion 

During root canal instrumentation, some areas are not touched by endodontic instruments (Versiani 
et al. 2018), requiring auxiliary chemical substances to eliminate microorganisms (Böttcher et al. 2015; Rôças 
et al. 2016). However, some microorganisms remain (Souza et al. 2018a) and penetration of fluids occurs 
when the seal fails (Ricucci et al. 2013), leading recontamination. Chlorhexidine adsorbs to surfaces, being 
released in the form of active cation, allowing antimicrobial activity over time (Böttcher et al. 2015). Then, 
the prevention of recontamination may be achieved (Gomes et al. 1996), justifying the importance to 
evaluate CHX substantivity and the influence of reciprocating instrumentation on this property in the present 
study.  

CHX substantivity has been measured in previous studies through HPLC (Souza et al. 2012; Souza et 
al. 2018b), as it provides an accurate estimative of the CHX amount that is retained on root dentin (Souza et 
al. 2012). However, it does not assess whether retention is effective in reducing microorganisms. For this 
reason, CLSM was used in the present study to assess the relationship between CHX retention and its 
antimicrobial action. This method evaluates the viability of microorganisms on the infected dentin by 
assessing membrane permeability without disturbing attached cells. Furthermore, this assessment is 
compatible with clinical conditions that demonstrate that no inactivation of antimicrobial substances is 
achieved during endodontic treatment. (Böttcher et al. 2015). The high sensibility and costs for performing 
can be a limitation of this kind of test.  

The use of alternative systems is indicated due to the ease of preparation of the root canal and 
providing a reduced number of endodontic instruments and clinical time (Rasimick et al. 2010). Moreover, 
these systems reduce the contact time of CHX with root canal walls and its retention on the dentinal surface 
(Souza et al. 2018b). However, there are no studies in literature showing if lower CHX retention interferes 
on its antimicrobial activity over time. Böttcher et al. (2015) revealed that CHX was detected for 48 hours 
and 7 days with low percentage of viable cells, also presenting increase in the number of viable cells after 
30 days, becoming similar to saline. Thus, the present study evaluated the retention and antimicrobial 
activity of CHX associated with reciprocating instrumentation after 48 hours and 7 days, comparing with 
manual and rotary techniques. 

According to the present methodology, human dentin was infected with E. faecalis for two weeks, as 
described by Souza et al. (2018a). This time is sufficient for the formation of biofilm and an adequate 
parameter to observe decontamination protocols (Guerreiro-Tanomaru et al. 2013). In this scenario, the 
present results show high prevalence of live E. faecalis cells in all experimental groups after both evaluation 
times. These results are in agreement with a previous study, in which the isolated use of the chemo-
mechanical preparation also resulted in high prevalence of E. faecalis (Souza et al. 2018a). In addition to its 



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SOUZA, M.A., et al. 

ability to penetrate dentinal tubules, E. faecalis is highly resistant and presents several virulence factors, 
ability to survive with limitation and lack of nutrients (Ran et al. 2015), which can help explain the high levels 
of living cells in all tested groups. 

The present results revealed higher CHX retention on human dentin after manual instrumentation. 
This finding is not in accordance with a previous study, in which manual and rotary instrumentation resulted 
in higher CHX retention compared to reciprocating preparation (Souza et al. 2018b), which can be explained 
by the experimental design of the rotary instrumentation in each study. In the present study, Pro-Taper Next 
composed of 3 files was used, renewing CHX 3 times, whereas in the previous study Pro-Taper Universal 
composed of 5 files was used, renewing CHX 5 times. Thus, the lower number of CHX applications the lower 
the chlorhexidine molecules into the tooth, using this rotary technique. 

Some mitigating factors can become shorter the CHX lifespan on human dentin, reducing the 
effectiveness of chemical agents in root canals. Proteins, collagen, dead microorganisms and dentin debris 
tend to have influence in this effectiveness (Rasimick et al. 2010). However, it could not be observed in the 
present results, since a significant reduction in the concentration of retained chlorhexidine was not observed 
after one week in all instrumentation techniques, when compared to a period of two days.  These results are 
in accordance with other studies, in which CHX retention after 7 days was similar when compared to the first 
evaluation time, and whose significant reduction was observed only after 30 days (Souza et al. 2012; Souza 
et al. 2018b). Thus, CHX retention on human dentin provides antimicrobial activity in a satisfactory clinical 
time. 

Regardless of instrumentation technique, the association with CHX resulted in lower levels of live E. 
faecalis cells after CLSM evaluation, when compared to control group in the present study. This antimicrobial 
activity was preserved over time, after 7 days. The interaction of CHX positive molecular charge and negative 
charge of microbial cell walls induces modification in the osmotic equilibrium of the bacterial cell. It increases 
cell permeability, which allows chlorhexidine molecules to penetrate and eliminate bacteria (Dametto et al. 
2005). This mechanism is observed over time by the gradual releasing of CHX molecules, providing 
antimicrobial activity after its use in root canals (Böttcher et al. 2015). In addition, CHX maintains the 
integrity of the dentine substrate for root canal filling, being another way to prevent recontamination by 
effective material adhesion and sealing of the root canal space (Moreira et al. 2009). Thus, the use of CHX in 
association with instrumentation techniques represents a significant alternative to be used in chemo-
mechanical preparation. 

Böttcher et al. (2015) revealed that higher  amount of CHX retained after HPLC was associated with 
low percentage of viable cells in E. faecalis biofilms. This finding is not in accordance with results of the 
present study. Despite the lower CHX retention on root dentin after rotary and reciprocating 
instrumentation, it did not interfere on the effectiveness against E, faecalis, since the amount of live cells 
was similar when compared to manual instrumentation. These results confirm the first (i) and second (ii) 
hypotheses of the present study. The association of instrumentation techniques with CHX can be the 
explanation for differences between studies, with rotary and reciprocating instruments exerting some effect 
on E. faecalis reduction, even with lower CHX retention. Our results show that conventional chemo-
mechanical preparation is not enough to provide adequate decontamination of root canals. The present 
study suggests the use of auxiliary decontamination resources, such as ultrasonic activation and 
photodynamic therapy, in order to improve the bacterial reduction, as shown by Souza et al. (2018a). Thus, 
favorable environment is created, providing better conditions to endodontic therapy success and healing of 
apical tissues.  
 
5. Conclusions 

Under the study limitations, it was observed that reciprocating instrumentation does not interfere 
on CHX substantivity, maintaining the antimicrobial activity against E. faecalis in the same effectiveness level 
when manual or rotary instrumentation is used.  
 
Authors' Contributions: SOUZA, M.A., CECCHIN, D., and MONTAGNER, F.: conception and design, acquisition of data, analysis and interpretation 
of data, drafting the article; SILVA, A.C.F., PIUCO, L., BONATTO, F.D. and GABRIELLI, E.S.: acquisition of data, analysis and interpretation of data, 
drafting the article; MOTTER, F.T., DUARTE, K.B.P., BERTOL, C.D. and ROSSATO-GRANDO, L.G.: analysis and interpretation of data, drafting the 
article; DE CARLI, J.P., BERVIAN, J. and LAGO, C.T.R.: drafting the article. All authors have read and approved the final version of the manuscript. 



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8 

Effect of reciprocating instrumentation on chlorhexidine substantivity on human dentin: chemical analysis followed by confoca l laser 
microscopy 

Conflicts of Interest: The authors declare no conflicts of interest. 
 
Ethics Approval: Approved by Research Ethics Committee of University of Passo Fundo. Number: 669.390. 
 
Acknowledgments: Not applicable. 
 

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https://doi.org/10.1016/j.joen.2018.04.007
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https://doi.org/10.1016/j.joen.2016.03.019
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Bioscience Journal  |  2021  |  vol. 37, e37038  |  https://doi.org/10.14393/BJ-v37n0a2021-54518 

 
 

 
9 

SOUZA, M.A., et al. 

Received: 7 May 2020 | Accepted: 26 July 2020 | Published: 2 July 2021 

 

 

  

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