Vol 51 No 3 Jul - Sep 2018_pus.indd


138138

Research Report

Dental Journal
(Majalah Kedokteran Gigi)
2018 September; 51(3): 138–142

Effects of liquid ionic silver concentration on caspase-3 and 
p53mt expressions in the oral mucosal epithelium of Wistar 
rats

R. Aries Muharram,1 I. Istiati2 and Pratiwi Soesilawati3
1 Department of Oral and Maxillofacial Surgery
2 Department of Oral and Maxillofacial Pathology
3 Department of Oral Biology
Faculty of Dental Medicine, Universitas Airlangga, Surabaya – Indonesia

ABSTRACT
Background: Silver, especially oxidized silver, has been used as a medicine considered to have bactericidal properties. In the 

present day, ionic silver (Ag+) is also used in the manufacture of cosmetics, socks, food containers, detergents, sprays and other 
products to prevent the spread of germs. Unfortunately, ionic silver is assumed to be toxic not only to bacteria, but also to humans and 
the environment. Therefore, it is essential to identify the optimum dosage of ionic silver considered safe by investigating the effects of 
ionic silver concentration on cell death through activation of mutant p-53 expression by caspase 3 in the oral epithelium. Purpose: 
This research aimed to analyze the effects of concentrated liquid ionic silver (Ag+) on caspase-3 and mutant p53 expression in the 
oral mucosal epithelium. Methods: This research constituted a laboratory-based experimental study with posttest-only design. The 
research subjects consisted of 28 Wistar rats, divided into four treatment groups, namely; KK (with Aquadest), KP 1 (with 5% liquid 
ionic silver), KP 2 (with 10% liquid ionic silver) and KP 3 (with 15% liquid ionic silver). Each rat was then treated orally with 0.5ml 
of liquid ionic silver at fixed concentrations twice a day for seven days. The Wistar rats were then terminated and their tissue samples 
processed by means of histopathological and immunohistochemical staining examination. The monoclonal Caspase-3 and mutant p53 
expressions in each group were evaluated with the data being tabulated and analyzed statistically. Results: Mutant p53 expression 
was also found in the control group. Moreover, the higher the concentration of liquid ionic silver, the greater the elevated Caspase-3 
and mutant p53 expressions. Conclusion:  The concentration of liquid ionic silver plays an important role in elevating Caspase-3 and 
mutant p53 expressions.

Keywords: ionic silver (Ag+); oral epithelium; caspase-3; mutant p53 expression

Correspondence: R. Aries Muharram, c/o: Department of Oral and Maxillofacial Surgery, Faculty of Dental Medicine, Universitas 
Airlangga, Jl. Prof. Dr. Moestopo no. 47, Surabaya, Indonesia. Email: aries-m@fkg.unair.ac.id; ies_id@yahoo.com

INTRODUCTION

Silver has long been considered a remarkable substance, 
having been used to prevent microorganism-related 
infections as long ago as the fifteenth century. Historically, 
silver has also been effective in destroying almost all strains 
of microorganisms. Research into silver, first conducted at 
the beginning of 4000 BC.1,2, confirmed it to be the third 
most widely used metal after gold and copper in ancient 
times. In recent years, silver has not only been widely used 
in a variety of medical procedures, but also for sanitation 
of public facilities such as baths, toilets, hand sanitizers, 

topical therapies outside the body, wound bandages, 
catheters as well as for oral antimicrobial medicine.1,2

Ionic silver can immobilize enzymes during oxygen 
metabolism in viruses, fungi, bacteria and single-celled 
pathogenic microbes. Within minutes, the pathogenic 
microbes can weaken and die before being removed from 
the body by the immune, lymphatic and elimination systems. 
Unlike antibiotic therapy, which is generally harmful to 
animal enzymes, ionic silver tends to maintain the integrity 
of tissue cells. Therefore, ionic silver is considered safe for 
humans, reptiles, plants and other living creatures.3 Liquid 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
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DOI: 10.20473/j.djmkg.v51.i3.p138–142

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139 Muharram, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 138–142

ionic silver (Aquasil®) at a concentration of 15ppm is even 
widely marketed as a mouthwash. 

According to Murphy and Evans (2012), ionic silver can 
be employed during wound healing treatment.4 However, 
in vivo research suggests that ionic silver at concentrations 
of 10 ppm and 32 ppm cannot cause toxic effects to the 
lungs, liver, brain, circulatory system and reproductive 
system.3 Ionic silver at concentrations of 10 ppm and 32 
ppm in the blood vessels is also known to leave the number 
of erythrocytes, granulocytes or granulocytes unaffected. 
Silver is actually contained in the blood vessels, largely 
in the form of ions. However, it remains unclear whether 
the ions circulate through the digestive system or through 
their attachment to blood components. Moreover, ionic 
silver is not found in urine and has no effects on hydrogen 
peroxide production.

 On the other hand, other previous research revealed 
that when ionic silver diffuses into the body through 
the respiratory system, the ions will bind to pulmonary 
epithelial cells and macrophages with the result that 
cell function will be limited.3 According to research 
conducted by Heydarnejad (2014), ionic silver also caused 
toxicity when its dose was increased to 10 ppm on day 7.5 
Researchers at Herald University (2014), even argue that 
nano-silver can trigger the formation of free radicals in 
cells, a condition subsequently leading to changes in the 
shape and quantity of proteins. Other researchers even posit 
that the excess production of free radicals in cells causes 
cancer and nerve disorders, such as Alzheimer’s disease 
and Parkinson’s disease.6 

It has also been accepted that the higher the dose of ionic 
silver administered, the more oxidative stress increases 
resulting in metabolic disturbances in mitochondria. 
In addition, the more reactive oxygen species (ROS) 
generated affects the cell cycle,1,2 leading to either apoptosis 
(programmed cell death) or necrosis (cell destruction). If 
such disruption occurs, in addition to producing apoptosis 
and necrosis in the cell cycle, cells can also undergo 
mutation.5 Caspase-3 is the first signaling protein in 
the apoptosis system which subsequently triggers the 
activation of p53 in cells targeted to initiate the apoptosis 
process. Conversely, mutant p53 expression is a symptom 
of function deviation from p53 often found in cancerous 
tissues, but sometimes also encountered in non-cancer 
patients.

Since ionic silver may precipitate changes in cells, 
turning them from normal to mutant, oral mucosal cells can 
be directly exposed to ionic silver due to oral consumption. 
Ionic silver is assumed to cause local and systemic effects. 
As a result, this research aimed to reveal the systemic effects 
of ionic silver at a concentration of 15 ppm diffused through 
digestion in mutant p53 and caspase-3 expressions in the 
oral mucosal epithelium.3 In this research, the oral mucosal 
epithelial cells of Wistar rats were used since these were 
considered equivalent to those of humans.7 

MATERIALS AND METHODS

Twenty-eight Wistar rats (Rattus norvegicus) aged 3-4 
months, weighing 200 grams and pronounced healthy by 
veterinarians, were used as samples in this research. These 
subjects were obtained from the Department of Biochemical 
Sciences Laboratory, Faculty of Medicine, Universitas 
Airlangga. They were subsequently divided into four 
groups, namely three treatment groups given liquid ionic 
silver and a control group. The first treatment group was 
given 5 ppm of liquid ionic silver. The second 10 ppm of 
liquid ionic silver and, the third 15 ppm of liquid ionic 
silver. Meanwhile, the control group was given distilled 
water. Each of those groups was given 0.5 ml of liquid 
ionic silver at determined concentrations twice a day for 
seven days. 

After seven days, the subjects were sacrificed and 
their cheek mucosa were cut to 3x4 mm in size using 
a no.15 scalpel. The mucosal tissues were soaked in a 
fixative solution, 10% Acetate Buffered Formalin, and 
then processed using an Autotechnicon® tool. The fixed 
specimens were subsequently hydrated with ethanol, before 
a 60-minute clearing process was performed twice with the 
same material and for the same duration. Subsequently, 
media infiltration (embedding process) was performed using 
paraffin wax (Tissue Prep, Fisher Sci., 56-570 C melting 
point). The last procedure was that of casting or blocking 
specimens whereby the mucosal epithelium specimens were 
planted in paraffin. Thereafter, the tissues were observed 
using embedding rings and the paraffin blocks were stored 
at 40 C for 15 minutes to harden. Hematoxylin and eosin 
staining were then carried out.

An analysis of caspase-3 and mutant p53 expressions in 
cheek mucosal specimens in paraffin blocks was performed 
by means of an immunohistochemical staining technique 
using anti-Caspase 3 monoclonal antibodies of the Wistar 
rats (Cleaved Caspase-3 (Asp175), SignalStain® and Cell 
Signaling Technology® (trademarks of Cell Signaling 
Technology, Inc.), mouse monoclonal antibodies, and 
anti- mutant p53 (p53 (DO-7): sc-47698, Santa Cruz 
Biotechnology, Inc.).  Observation was subsequently 
performed using a light microscope at 40x magnification. The 
operational definition of mutant p53 protein and caspase-3 
expressions was indicated by the presence of brown color 
in the basement membrane of the epithelial cells. The 
examiners consisted of a trio of anatomists and histologists. 
The mutant p53 protein and caspase-3 expressions were 
then calculated in 20 fields of view as recommended by 
Pizem and Cor (2003).8 Tho three examiners conducted 
the examination and calculation of samples separately, 
writing the results of each calculation on the worksheet. The 
mean value per field of view was calculated before being 
analyzed statistically8,9 with normality and homogeneity 
tests (One-Sample Kolmogorov-Smirnov Test), followed 
by a One-way ANOVA test with significance of α: 0.05. 
Correlation and regression analysis (post hoc Tukey’s HSD) 
was then conducted on each group.

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p138–142

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140Muharram, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 138–142

RESULTS 

The research was conducted on four groups of male 
Wistar rats, three groups being given silver ions for 
seven days and one control group. The procedure was 
replicated seven times with each group times to identify 
mutant p53 and caspase-3 expressions. Caspase-3 and 
mutant p53 expressions were then examined by staining 
method as shown in Figures 1 and 2. The mean number 
of caspase-3 and mutant p53 expressions rose with the 
increase in Ag+ concentrations as depicted in Figure 3. 
The immunohistochemical staining process using mouse 
antibody monoclonal anti-caspase 3 was performed on 
epithelial cells, the results of which are illustrated in 
Figure 2.

After the data of caspase-3 and mutant p53 expressions 
had been collated, normality analysis was performed by 
means of a Kolmogorov-Smirnov test. The results of 
the normality analysis revealed that the data of mutant 
p53 (p=0.180) and caspase-3 (p=0.743) expressions 
was normally distributed. A homogeneity test then was 
conducted, the results of which showed the p value of the 
group given 5 ppm of liquid ionic silver to be 1.0, p=1.0 for 
the group given 10 ppm of liquid ionic silver, and p=0.122 
for the group given 15 ppm of liquid ionic silver. This 
indicated that the data obtained was homogeneous. Thus, 
one-way ANOVA and Tukey HSD tests were carried out, 
the results of which are shown in Tables 1 and 2.

The results of the one-way ANOVA test on caspase 
3 expressions showed α value of 0.05, whilethose of the 

Tukey HSD test then indicated a p value of 1.0 (p> 0.05) 
at all concentrations. This means that the data obtained was 
homogeneous. Consequently, a One-way ANOVAs was 
conducted as illustrated in Table 1.

At the next stage, a post hoc Tukey HSD test was 
performed whose results indicated that the mean number 
of caspase-3 expressions in the control group was lower 
than those in the treatment groups. There were even 
significant differences in the mean numbers of the caspase-3 
expressions between the control group and all treatment 
groups as well as between the treatment groups (p<0.05). 
Moreover, based on the contents of the above table, the 
greater the concentration of liquid ionic silver, the higher 

Figure 1.  The results of oral immunohistochemistry staining 
on mutant p53 expression in oral epithelium 
exposed to Ag+ at varying concentrations atn a 
magnification of 40x (orange arrows showing mutant 
p53 expression).

Note: Control group (A), Group given 5 ppm of liquid ionic 
silver (B), Group given 10 ppm of liquid ionic silver (C), and 
Group given 15 ppm of liquid ionic silver (D).

Figure 2.  The results of oral immunohistochemistry staining on 
Caspase 3 expression in oral epithelium exposed to Ag+ 
at varying concentrations with a magnification of 40x 
(orange arrows showing Caspase 3 expressions)

Note: Control group (A), Group given 5 ppm of liquid ionic 
silver (B), Group given 10 ppm of liquid ionic silver (C), and 
Group given 15 ppm of liquid ionic silver (D).

 Table 1. Examination results of Caspase-3 expression

Groups
Control 
Group

Treatment 
Group I
(5ppm)

Treatment 
Group II
(10ppm)

Treatment 
Group III
(15ppm)

Control 
Group

-14.000*-9.429*-4.143*

Treatment 
Group I
(5ppm)

-9.857*-5.286*-4.143*

Treatment 
Group II
(10ppm)

-4.571*-5.286*-9.429*

Treatment 
Group III
(15ppm)

-4.571*-9.857*-14.000*

* = Significant

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p138–142

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141 Muharram, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 138–142

the mean number of caspase-3 expressions in the mucosal 
epithelium of Wistar rats. This confirms that the number 
of cells experiencing apoptosis was increasing. 

A post hoc Tukey HSD test was subsequently, carried 
out, the results of which showed that the mean number of 
mutant p53 expressions in the control group was lower than 
those in the treatment groups. In other words, there was a 
significant difference in the mean number of mutant p53 
expressions between the control group and all treatment 
groups with a p value of 0.000 (p<0.05). However, there 
was no significant difference in the mean number of mutant 
p53 expressions between Group II (with 10 ppm of silver 
ions) and Group III (with 15 ppm of silver ions) with a p 
value of 0.122 (p>0.05). Furthermore, based on the contents 
of the table above, the greater the concentration of liquid 
ionic silver, the higher the mean number of mutant p53 
expression in the mucosal epithelium of Wistar rats. 

DISCUSSION

This research represented an in vivo study during which 
the mucosal epithelial cells of Wistar rats were exposed 
to various concentrations (ppm) of liquid ionic silver for 
seven days. Mutant p53 protein expressions were then 
used to detect abnormalities of wild-type p53. Mutant p53 
is a protective genome which the p53 test confirms the 
existence of two types. First, wild-type p53 is responsible 
for supporting damaged cells and directing them to the 
apoptotic pathway. Second, mutant p53 is a special protein 
managing cells in the arrest phase of the cell cycle at both 
the G1 / S and G2 / M stages. In other words, mutant p53 
plays a role in maintaining the cell cycle with the result 
that cell duplication does not occur. The expression of 
mutant p53 can also be considered as a sign that cells will 
be arrested in the subsequent cell cycle.10

Treatment using liquid ionic silver, moreover, can cause 
changes in cell morphology, cell viability, metabolic activity 

and oxidative stress. Liquid ionic silver which diffuses into 
cells can reduce ATP cell contents causing mitochondrial 
damage and elevating reactive oxygen species (ROS) 
production as doses increase. In mitochondria and cell 
nuclei, liquid ionic silver can trigger mitochondrial and 
DNA damage. With the involvement of ROS production 
initiated by silver ions, disruption to both the mitochondrial 
respiratory chain and ATP synthesis will occur, eventually 
causing damage to DNA. 

Another process supporting the passage of liquid ionic 
silver into cells is that of endocytosis through which silver 
can penetrate the nucleus and harm DNA. As a result, a 
number of researchers have evaluated the potential use of 
liquid ionic silver in cancer therapy. However, at certain 
concentrations and an exposure time in excess of seven 
days, mutant p53 expression can emerge, being considered 
a tumor marker.1,2

In this research, mutant p53 expressions also increased 
as the concentration of liquid ionic silver intensified. 
Similarly, Wong (2011) argues that the higher the 
concentration of liquid ionic silver, the greater the toxic 
effect.11 Changes to the mucosal epithelial cell structure 
of Wistar rats were highly visible in the stratum spinosum 
which is the thickest layer. Mutant p53 expression can 
actually be found in normal cells, indicating that a small 
number already existed in Wistar rats. 

This research found that, in the epithelial cells exposed 
to 5 ppm of liquid ionic silver, mutant p53 expressions 
emerged with intact basal structures. In the epithelial cells 
exposed to 10 ppm of liquid ionic silver, the number of 
mutant p53 expressions was higher than in those exposed to 
5 ppm of liquid ionic silver with a stretching basal structure. 
Furthermore, in the epithelial cells exposed to 15 ppm of 
liquid ionic silver, the number of mutant p53 expressions 
was highest with loose basal structures passing into the 
endothelium. Consequently, it can be said that cells exposed 
to the high concentration of liquid ionic silver will become 
cancerous. Researchers at the University of Herald in 2014 
also obtained the same results related to the appearance of 
mutant p53 expressions.6

On the other hand, Caspase is an enzyme inducing 
natural cell death known as apoptosis. Large quantities 
of caspase play a role in this process. The closest caspase 
triggering the apoptosis process is caspase-3 which was 
selected as a sign of apoptotic pathways in this research 
whose results revealed that caspase-3 expressions in each 

Figure 3. p53mt and Caspase-3 expression

Table 2.  Results of Post Hoc Tukey HSD test on mutant p53 
expression

Groups
Control 
Group

Treatment 
Group I
(5ppm)

Treatment 
Group II
(10ppm)

Treatment 
Group III
(15ppm)

Control 
Group

-16.000*-14.429*-5.143*

Treatment 
Group I
(5ppm)

-10.857*-9.286*-5.143*

Treatment 
Group II
(10ppm)

1.571*-9.286*-14.429*

Treatment 
Group III
(15ppm)

1.571*-10.857*-16.000*

* = Significant

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p138–142

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142Muharram, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 138–142

treatment group increased as the concentration of silver ions 
rose. Similarly, Alexander (2009) argues that ionic silver 
liquid therapy constitutes an extremely effective cure for 
infection in living creatures, since considerable numbers of 
microbes experience lysis after exposure to it. This suggests 
that higher concentration of liquid ionic silver can produce 
greater toxic effects.1 

In this research, liquid ionic silver was not only found to 
be effective on microbes, but also induced a change in the 
epithelial cell structure of Wistar rats. In normal epithelial 
cells, the number of caspase-3 expressions was limited, 
while in the epithelial cells exposed to 5 ppm of liquid 
ionic silver caspase-3 expressions emerged with intact 
basal structures. In the epithelial cells exposed to 10 ppm 
of liquid ionic silver, the number of caspase-3 expressions 
was higher than those exposed to 5 ppm of liquid ionic 
silver with a stretching basal structure. Meanwhile, in the 
epithelial cells exposed to 15 ppm of liquid ionic silver, 
the number of caspase-3 expressions was the highest with 
loose basal structures passing into the endothelium. It 
can, therefore, be assumed that cells exposed to the high 
concentration of liquid ionic silver will become cancerous.6 
Finally, it can be concluded that the increase in liquid ionic 
silver concentration is in line with that of mutant p53 and 
caspase-3 expressions in the buccal mucosa epithelium of 
Wistar rats.

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Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p138–142

https://www.universityherald.com/articles/7867/20140303/
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