Glass ionomer cement particles pre-reacted with chlorhexidine: Physical/chemical properties and antimicrobial activity

Glass ionomer cement particles pre-reacted
with chlorhexidine: Physical/chemical
properties and antimicrobial activity
Gomes FS, Campos-Ferreira PV, Macedo RFC, Costa-Oliveira BE, Bauer J. Glass ionomer cement particles pre-reacted with chlorhexidine: Physical/chemical
properties and antimicrobial activity. J Mech Behav Biomed Mater. 2024 Oct;158:106678. doi: 10.1016/j.jmbbm.2024.106678. Epub 2024 Jul 31.
2

CONTENTS
• Introduction
• Aim
• Null hypothesis
• Materials and methods
•
Statistical analysis
• Results
•
Discussion
• Conclusion
• References
3

INTRODUCTION
4
GIC
Ion release
Remineralisation
Chemical
adhesion
Thermal
expansion
Polymerisation
shrinkage
Marginal
gap

5
Low acidity
Fluoride
3680 and 7130
ppm
ART
Chemical
bond
Si-NH
Drug delivery
system

AIM
The objective of the current study is to evaluate the
 Cohesive strength,
 Modulus of elasticity,
 Microhardness,
 Surface roughness,
 Ion release(Ca+2,PO4−,and F−),
 Setting time, and
 Antibacterial activity
7

Null hypothesis
 (1) the incorporation of pre-reacted particles with chlorhexidine (CHX) in
glass ionomer cement (GIC) would not impair the physical/chemical
properties.
 (2) the incorporation of pre-reacted particles with chlorhexidine (CHX) in
glass ionomer cement (GIC) would not enhance the antibacterial
properties
8

MATERIALS AND METHODS
1. Loading of CHX into GIC:
 The commercial GIC used in this study was Bioglass R (Biodinamica,
Parana, Brasil).
 An aqueous solution of 20% chlorhexidine digluconate (Naturalle -
compounding pharmacy) was used. For every 1 ml of CHX, 10 mg of GIC
powder was employed.
 The solution was mixed using a magnetic stirrer (Heidolph instruments,
Schwabach, Germany) for 1 h.
9

 Afterwards, the obtained solutions were centrifuged (4000 rpm) for 10
min and the resulting material was stored in an oven at 37 ◦C for 7 days.
 Experimental GIC powders containing concentrations of 1%, 2.5% and 5%
of particles functionalized with chlorhexidine.
Functionalised GIC + Non functionalized GIC Experimental GIC
11

 The portion corresponding to the liquid of the material was not
changed and the powder/liquid proportion for preparing the material
followed the manufacturer’s recommendations.
 O GIC containing non-functionalized particles was used as a control.
12

2. Fourier-transform infrared spectroscopy (FTIR) powders
analyze:
 To characterize the functionalization of glass ionomer particles with
chlorhexidine, FTIR analyses were conducted before and after the loading
process.
13

3. Cohesive strength and modulus of elasticity:
 Hourglass-shaped specimens (10 mm length, 2 mm width, and 1 mm
thickness) with a cross-sectional area of 1 were fabricated for each
group.
 The materials were inserted into a polymeric matrix, covered with a
polyester strip until complete setting.
14

4. Microhardness:
 The specimens resulting from the cohesive strength tests were fixed onto
an acrylic base and polished for the measurement of the Initial Vicker
Microhardness.
 The HMV-G20 microhardness was used.
15

5. pH test:
 Disk specimens were prepared and are manipulated with a plastic
spatula for GIC.
 The specimens were placed in vials containing 5 mL of distilled water
for 28 days.
 pH readings were then taken at the following intervals: 15 min, 30 min,
1h, 2h, 24h, 48h, 7days, 14days, and 28days.
 The solutions were frozen for subsequent analysis of ,, and ion
release.
16

6. Ions release Ca+2 , PO4 − and F− :
17
Chlorhexidine-Functionalized GICs:
• Bioglass R + 1% CaF6Si-CHX
GIC-CHX 1%
• Bioglass R + 2.5% CaF6Si-CHX
GIC-CHX 2.5%
• Bioglass R + 5% CaF6Si-CHX
GIC-CHX 5%

7. Setting time:
 For the setting time evaluation, a Gilmore needle was used.
18

8. Surface roughness:
 To verify the roughness of the material a Surface Roughness Tester
was used.
 Twelve disc-shaped specimens (10 mm × 1 mm) were prepared for
each group (n = 12), and subjected to a polishing sequence.
 The force applied by the needle was 5N.
19

9. Antibacterial activity
 The experimental GIC discs were placed in a sterile 24-well culture
plate, and sterilized using ultraviolet light for 30 minutes.
20

10. Statistical analysis:
 Statistical analysis was performed using SigmaPlot software.
 All data was subjected to the Shapiro-Wilk test to determine
normality.
 Cohesive strength, modulus of elasticity, microhardness, ions release
and surface roughness data were submitted to ANOVA (One-way) and
Holm-Sidak.
21

RESULTS
1. Fourier-transform infrared spectroscopy
(FTIR) powders analyze:
 Demonstrated the presence of a band at 1580 cm 1
⁻ ,
indicating protonation of the N–H group of
⁺
chlorhexidine. This band suggests direct interaction
with the particle surfaces.
22

2. COHESIVE STRENGTH
 Statistical analysis indicates that functionalization of particles with
chlorhexidine digluconate increases cohesive strength compared to the
control group (Table 2).
23

3. MICROHARDNESS
 The results indicate an increase in microhardness as the concentration
of chlorhexidine increases (Table 2).
4. pH TEST
 The pH of all groups showed an acidic behavior in all periods evaluated.
24

5. Ions release Ca+2 , PO4 − and F−
 The means and standard deviations of fluoride, calcium, and phosphate ion
release are presented in Fig. 4.
 The incorporation of prereacted CHX particles did not alter the release of
fluoride ions, calcium ions, and phosphate ions compared to the control
group.
25

6. SETTING TIME
 The setting time readings indicate that chlorhexidine functionalization
did not alter the property of the material (Table 2).
7. SURFACE ROUGHNESS
 The surface roughness results showed no statistically difference
between the tested groups (Table 2).
26

8. ANTIBACTERIAL ACTIVITY:
 Statistical analysis indicated a significant
difference in CFU counts between the tested
groups.
GIC-CHX 0.12%(positive control),2.5%,5%
>
GIC-CHX 1% and control group.
27

DISCUSSION
 Null Hypothesis: The study initially posited that incorporating
chlorhexidine (CHX) into glass ionomer cement (GIC) would not impair
its properties; this was accepted.
 Rejection of Other Null Hypotheses: The hypotheses suggesting that
CHX would not affect antimicrobial activity and mechanical properties
were rejected.
28

Cohesive strength Ion release
Microhardness Surface roughness
Antibacterial activity Setting time
Durability of restoration pH
Rheology
29
POSITIVE OUTCOMES NO CHANGES
• Therefore, while the incorporation of CHX did result in certain
enhancements, it did not affect other crucial properties of GIC.

 The incorporation of GIC cement particles functionalized with
chlorhexidine has emerged as a promising strategy to improve the
clinical performance of restorations made with glass ionomer, especially
in atraumatic restorative treatments (ART’s).
 ART is recommended for clinical cases involving poor oral hygiene due
to conditions like dementia and physical limitations, requiring effective
cavity-sealing materials.(Frencken et al., 2014)
30

 Importance of Antimicrobial Properties: It is crucial for these materials
to not only seal cavities effectively but also prevent microorganism
proliferation to avoid recurrent carious processes and potential pulp
involvement.(Duque et al., 2017)
 Hospitalized patients require oral health care while in bed, with
chlorhexidine being the most commonly used material for oral hygiene.
 The most used material in special needs patients is glass ionomer through
ART. Therefore, an association of the two materials is strongly desirable.
31

 The successful loading of chlorhexidine onto glass ionomer cement
can be attributed to the presence of silicates in the GIC particles,
which facilitate strong binding interactions between the alkaline
portions of chlorhexidine (NH) molecules and the silanol (Si–OH)
groups present on the surface of the particles.(Moritz and Geszke-
Moritz, 2015)
 Reduction in Bacterial Counts: Studies report a reduction in
bacterial counts during certain evaluation periods.
32

 Bactericidal properties: The experimental groups GIC-CHX 2.5% and
GIC-CHX 5% exhibited significant bactericidal properties.
 Mechanism of Action: Chlorhexidine releases through the natural
degradation of the ionomer surface and ion exchange, leading to
bacterial cell membrane disruption and ultimately bacterial death.
 Findings by Jedrychowski et al. (1983) warn that GIC may deteriorate if
CHX is added at concentrations greater than 5%.
33

 Recently, a systematic review and meta-analysis revealed that there was
no significant difference in the survival of ART restorations when CHX
was used as a pretreatment. (Takahashi et al., 2006).
 The divergent results regarding the mechanical properties resulting
from the incorporation of CHX into the GIC can be attributed to the
different methods of adding CHX, which can be in powder
(chlorhexidine diacetate) or liquid (chlorhexidine digluconate)
potentially altering the powder/liquid ratio or the setting reaction of the
material.
34

 Greater cohesive strength: improves the material's ability to
withstand shear and traction forces, reducing risk of fracture.
 Durability: microhardness suggest enhanced durability and longevity
of GIC dental restorations.
 Surface roughness and setting time remained unchanged, which are
important for preventing bacterial biofilm accumulation and
minimizing patient chair time.
35

 The well-established property of ion release exhibited no significant
alterations between the control and the other experimental groups,
suggesting that the pre-reacted particles with CHX, bound to silanol,
are permeable, facilitating the continuous release of ions.
 Similarly, pH variation showed no discernible difference from the
control group.
36

 These findings highlight the promise of using functionalized GIC
particles at high concentrations as a viable strategy for improving the
mechanical properties and durability of dental restorations without
compromising other critical aspects of the material’s performance.
 Brito et al has evaluated the effect of chlorhexidine-functionalized
bioactive glass (45S5) on mechanical and bioactive properties of
experimental self-etching adhesives.
37
Brito, A.C.R., Ferreira, P.V.C., Cardoso, S.M.N.R., Guimar˜ aes, S.J.A., Gomes, F.S., Cavaleiro-de-Macedo, R.F., Oliveira, B.E.C., De Oliveira,
T.J.L., Dos Santos, A.P.S.A., Bauer, J., 2023. Chlorhexidine-Loaded bioactive glass for incorporation into adhesive systems: mechanical
properties, antibacterial activity, cell viability, and hydroxyapatite precipitation. Int. J. Adhesion Adhes. 124, 103384. https://doi.org/
10.1016/j.ijadhadh.2023.103384

38
1
• Magic Bond (commercial control – hydrophobic adhesive)
2
• Experimental bond without bioglass (experimental control)
3
• Experimental bond + 5% 45S5 glass (wt%)
4
• Experimental bond + 20% 45S5 glass (wt%)
5
• Experimental bond + 5% chlorhexidine-functionalized 45S5
6
• Experimental bond + 20% chlorhexidine-functionalized 45S5
MATERIALS:

Results:-
 The 45S5 CHX group (20%) presented the lowest values of mechanical
properties.
 On the other hand, only groups containing 45S5 previously functionalized
with chlorhexidine were able to prevent biofilm formation.
 SEM and EDS analyses revealed the functionalization of 45S5
bioactive glass with chlorhexidine did not impair the bioactivity of the
newly developed adhesive systems.
39

 Cristiane Duque et al evaluated the effects of incorporating
chlorhexidine (CHX) in the in vitro biological and chemico-mechanical
properties of GIC and in vivo clinical/microbiological follow-up of the
ART with GIC containing or not CHX.
40
Duque C, Aida KL, Pereira JA, Teixeira GS, Caldo-Teixeira AS, Perrone LR, Caiaffa KS, Negrini TC, Castilho ARF, Costa CAS. In vitro and
in vivo evaluations of glass-ionomer cement containing chlorhexidine for Atraumatic Restorative Treatment. J Appl Oral Sci. 2017
Sep-Oct;25(5):541-550. doi: 10.1590/1678-7757-2016-0195
Group 1
• GIC
Group 2
• GIC with
1.25% CHX
Group 3
• GIC with 2.5%
CHX

 Antimicrobial activity of GIC was analyzed using agar diffusion and
anti-biofilm assays.
 A randomized controlled trial was conducted on 36 children that
received ART either with GIC or GIC with CHX.
 Saliva and biofilm were collected for mutans streptococci (MS) counts
and the survival rate of restorations was checked after 7 days, 3
months and one year after ART.
41
Sep-Oct;25(5):541-550. doi: 10.1590/1678-7757-2016-0195

 Results: Incorporation of 1.25% and 2.5% CHX improved the antimicrobial
activity of GIC, without affecting F release and mechanical
characteristics, but 2.5% CHX was cytotoxic.
 Survival rate of restorations using GIC with 1.25% CHX was similar to GIC.
 A significant reduction of MS levels was observed in saliva and biofilm
samples 7 days after treatment.
42
Sep-Oct;25(5):541-550. doi: 10.1590/1678-7757-2016-0195

 Luana Mafra Marti has evaluated the porosity, surface
roughness and anti-biofilm activity of a glass-ionomer cement
(GIC) after incorporation of different concentrations of
chlorhexidine (CHX) gluconate or diacetate.
Marti LM, Becci AC, Spolidorio DM, Brighenti FL, Giro EM, Zuanon AC. Incorporation of chlorhexidine gluconate or diacetate into a
glass-ionomer cement: porosity, surface roughness, and anti-biofilm activity. Am J Dent. 2014 Dec;27(6):318-22.
43

• Control
GROUP 1
• GIC and 0.5% CHX diacetate
GROUP 2
GROUP 3
GROUP 4
• GIC and 0.5% CHX gluconate
GROUP 5
GROUP 6
GROUP 7
MATERIALS:
44

 Results: Regarding GIC porosity, the ANOVA showed that the presence of
CHX increased the porosity proportionally to the increase in
concentrations, without however, presenting interaction between
material and concentration.
 The surface roughness test demonstrated no statistically significant
effect.
 Anti-biofilm activity analysis pointed out a significant effect in reducing
microorganisms with CHX diacetate.
45
Marti LM, Becci AC, Spolidorio DM, Brighenti FL, Giro EM, Zuanon AC. Incorporation of chlorhexidine gluconate or diacetate into a
glass-ionomer cement: porosity, surface roughness, and anti-biofilm activity. Am J Dent. 2014 Dec;27(6):318-22.

LIMITATIONS
 In Vitro Nature: The study was conducted in vitro, which may not fully
reflect clinical conditions
 Chlorhexidine Release Profile: The release profile of chlorhexidine was
not analyzed, limiting insights into the duration of its antimicrobial
activity.
 Single Type of GIC: Only one type of glass ionomer cement (GIC) was
used for loading chlorhexidine, which may affect the generalizability of
the findings.
46

CONCLUSION
 The pre-reacted CHX in GICs was able to confer
antimicrobial activity, improve cohesive strength,
microhardness, and did not impair ion release, setting time,
and roughness.
47

REFERENCES
 Brito, A.C.R., Ferreira, P.V.C., Cardoso, S.M.N.R., Guimar˜ aes, S.J.A., Gomes,
F.S., Cavaleiro-de-Macedo, R.F., Oliveira, B.E.C., De Oliveira, T.J.L., Dos Santos,
A.P.S.A., Bauer, J., 2023. Chlorhexidine-Loaded bioactive glass for incorporation
into adhesive systems: mechanical properties, antibacterial activity, cell
viability, and hydroxyapatite precipitation. Int. J. Adhesion Adhes. 124, 103384.
https://doi.org/ 10.1016/j.ijadhadh.2023.103384.
 Carvalho, N.K., Barbosa, A.F.A., Coelho, B.P., Gonçalves, L.S., Sassone, L.M.,
Silva, E.J.N. L., 2021. Antibacterial, biological, and physicochemical properties
of root canal sealers containing chlorhexidine-hexametaphosphate
nanoparticles. Dent. Mater. 37 (5), 863–874.
https://doi.org/10.1016/j.dental.2021.02.007.
48

 de Castilho, A.R.F., Duque, C., Negrini, T.C., Sacono, N.T., de Paula, A.B.,
De Souza Costa, C.A., Spolidorio, ´ D.M., Puppin-Rontani, R.M., 2013. In
vitro and in vivo investigation of the biological and mechanical behaviour
of resin-modified glassionomer cement containing chlorhexidine. J. Dent.
41, 155–163. https://doi.org/ 10.1016/j.jdent.2012.10.014.
 Chen, L., Wang, Q., Xiong, L., 2017. Molecular dynamics study on structure
stability, lattice variation, and melting behavior of silver nanoparticles. J.
Nanoparticle Res. 19 https://doi.org/10.1007/s11051-017-4003-7.
 Chen, J., Zhao, Q., Peng, J., Yang, X., Yu, D., Zhao, W., 2020.
Antibacterial and mechanical properties of reduced graphene-silver
nanoparticle nanocomposite modified glass ionomer cements. J. Dent. 96,
103332. https://doi.org/10.1016/j. jdent.2020.103332.
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