Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

48

The effects of ultrasonic scaling duration and replication on 
caspase-� expression of Sprague Dawley rat's pulp cells

archadian nuryanti, Marsetyawan hnE Soesatyo, dewi agustina, and Siti Sunarintyas 
Graduate Student of Faculty of Dentistry, Universitas Gadjah Mada 
Yogyakarta – Indonesia

abstract

Background: Ultrasonic	scaling	has	been	used	commonly	for	stain	and	calculus	removal	in	dental	clinic	for	over	60years.	Previous	
researches	even	had	proved	that	ultrasonic	scaling	may	give	effects	on	the	surface	of	tooth	root.	Ultrasonic	wave	exposure	for	20	
seconds	or	more	can	increase	caspase-3	activity	as	an	indicator	of	increased	apoptotic	cells	associated	with	tissue	damage.	Purpose: 
This	research	was	aimed	to	investigate	the	effects	of	ultrasonic	scaling	duration	and	replication	on	caspace-3	expression	in	dental	
pulp	cells.	Methods: The	samples	of	this	research	were	54	male	Sprague	Dawley	rats	aged	2	months	old	divided	into	2	groups,	each	
of	which	consisted	of	27	mice.	The	first	group	was	induced	with	stain,	while	the	second	group	was	not.	Each	group	was	divided	into	3	
subgroups	for	ultrasonic	scaling	1,	3,	and	5	times.	Each	subgroup	was	divided	into	3	sub-subgroups	for	duration	procedure	of	15,	30	
and	60	seconds	respectively.	During	scaling	process,	those	rats	were	anesthetized	using	0.1	ml	of	ketamine	and	0.1	ml	of	xylol	added	
to	2	ml	of	distilled	water	injected	intramuscularly	into	their	right	thigh	as	much	as	0.4	ml.	Scaling	was	done	on	buccal	surface	of	right	
first	maxillary	molar	from	cervical	to	occlusal.	The	teeth	were	decalcified	and	embedded	in	paraffin,	then	their	sagittal	plane	was	cut	
for	thickness	of	3µm	and	painted	with	immunohystochemistry	for	detecting	caspace-3	expression	of	cell	within	dental	pulp.	results: 
The	results	showed	that	the	duration	and	replication	of	ultrasonic	scaling	procedures	affected	on	the	expression	of	caspace-3	cells	as	
analyzed	with	Univariate	Analisis	of	Variance	test	(p<0.05).	Conclusion: It	can	be	concluded	that duration	and	replication	of	ultrasonic	
scaling	procedure	on	teeth	with	and	without	stain	enhauced	the	expression	of	caspace-3	in	dental	pulp	cells.	

Keywords:	Duration;	replication;	ultrasonic	scaling;	pulp	cells;	caspace-3

Correspondence: Archadian Nuryanti c/o: Departemen Biomedika, Fakultas Kedokteran Gigi Universitas Gadjah Mada, Jl. Denta No., 
Sekip Utara Yogyakarta 55281, Indonesia. e-mail: archadian_fkgugm@yahoo.com

Research Report

introduction

Ultrasound means sound that can not be heard by 
human ear at frequency above 20,000 Hz. In dentistry, 
ultrasonic waves are used for professional tooth cleaning, 
root canal cleaning, bone implant and surgical procedures.1 
Ultrasonic scaler can also be used for biofilm, stain and 
calculus removal of tooth surface.2 Piezoelectric scaler 
moving back and forth 28000-36000 times even can be 
used to clean tooth surface.3 If ultrasonic waves expose 
on liver cells of rats for 20 seconds or more, the activity of 
caspase-3 as an indicator of increased apoptosis associated 
with tissue damage.4

Ultrasonic waves can cause sonification. Sonification 
mechanism that occurs in ultrasonic scaling procedure even 
can cause acoustic microstreaming mechanism, turbulence 
flow, cavitation, and microjet formation resulting cavitation 
bubbles collapsed and making shock waves.4 If this 
mechanism occurs on tooth surface with stain, the stain will 
be detached from the tooth surface causing partial removal 
of organic and inorganic materials from the tooth surface 
triggering to tooth surface damage. Microstreaming flow 
around the air bubbles generated by ultrasonic waves can 
get into bloodstream, and penetrate cell membrane through 
sonoporation molecular mechanisms.5 Ultrasonic waves 
at a frequency of 20 kHz-2 MHz even can raise small air 

Dental Journal
(Majalah Kedokteran Gigi)

20�5 March; 48(�): 48–52



4�

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

4�Nuryanti, et al./Dent. J. (Majalah Kedokteran Gigi) 2015 March; 48(1): 48–52

bubbles resulting in cell injury.6 It means that duration and 
cavitation of ultrasound exposure can affect on activity of 
cells exposure.7 The increasing of caspase-3 expression 
after ultrasound wave exposure can become an indicator of 
the increasing of apoptosis cells.8 This research was aimed 
to evaluate the effects of ultrasonic scaling duration and 
replication on caspase-3 expression in dental pulp cells of 
teeth with and without stain.

materials and method 

This research is a pra-experimental research since there 
were manipulation, repeatable measurements and control 
group, but without randomization approach.9 This research 
used 54 male Sprague	Dawley rats aged two months old, 
divided into two groups each of which consisted of 27 rats. 
The first group of mice were given a drink with a mixed 
solution of tea and coffee. The solution of tea was made of 
2 grams of black tea powder in pouch packaging brewed 
into 100 ml of boiled water. Meanwhile, the solution of 
coffee was made of 2 grams of ground coffee without pulp 
brewed into 100 ml of boiled water. Both solutions were 
mixed and waited 10 minutes to be drunk by those rats for 
21 days. On the other hand, the second group of mice were 
given a drink with water. 

each group of rats was divided into 3 subgroups with 
ultrasonic scaling 1, 3, and 5 times for each consisted of 9 
rats. each subgroup then was divided into 3 sub-subgroups 
each of which consisted of 3 rats with ultrasonic scaling 
duration of 15, 30 and 60 seconds respectively. During 
scaling process, rats were anesthetized using 0.1 ml of 
ketamine and 0.1 ml of xylol added to 2 ml of distilled water 
injected intramuscularly into their right thigh as much as 
0.4 ml. Scaling was done on the buccal surface of their right 
first maxillary molar, starting from cervical line to occlusal 
surface, using supra-gingival stain tip. Tip was used on the 
tooth surface without pressure. The position of the tip was 
parallel to the axis teeth. 

In addition, the volume of cooling water used was about 
20 ml/ sec. The engine power used was moderate, and 
scaling process was done by one people. The procedure 
was then repeated started from the induction of stain into 
rats to scaling process 3 and 5 times with 21-day pause. 
After scaling, the rats were decapitated, and their teeth 
were extracted. The decalcified teeth then were embedded 
in paraffin, and their sagittal plane was cut for thickness of 
3µm. Those were fixed on object glasses. Deparaffinization 
was conducted using xylol for 3 x 5 minutes, absolute 
alcohol, 96% alcohol, 70% alcohol respectively for 5 
minutes, and dehydration was performed. The slides were 
washed using running water, and then washed by distilled 
water.

Samples were incubated with 3% H2O2 for 15 minutes 
and washed with running water, and later washed with 
distilled water. Cox2 retrieval then was conducted using 
both citrate buffer with pH 6 and decloac for 40 minutes 

at 95° C. After that, the samples were chilled for about 30 
minutes. Those samples then were washed 2x times using 
PBS for 3-5 minutes, and incubated with blocking serum or 
normal serum for 15 minutes. The samples were drained and 
cleaned, then were incubated with anti-caspase-3 antibody 
for 1 hour, and washed 2x times using PBS for 3-5 minutes. 
The samples were incubated again with secondary antibody 
for 20 minutes, and then washed 2x times using PBS for 
3-5 minutes. The samples were incubated again with trikkie 
avidin HRP for 10 minutes, and then washed 2x times using 
PBS for 3-5 minutes. Afterwards, the samples were dropped 
with chromogen DAB (1:50), then left for 2 minutes, and 
washed with water. Counterstain then was performed with 
hematoxylin mayer for 2 minutes, and washed with water. 
Those samples were dipped in alcohol with concentration 
from 70%, 96%, to 100%, and also xylol, followed with 
mounting, and then observed using a microscope at 400X 
magnification.10

results 

Data of the effects of ultrasonic scaling duration and 
replicatin on the expression of caspase-3 in the dental pulp 
cells with and without stain were presented in Table 1. 
The expression of caspase-3 in the dental pulp cells with 
and without stain for once scaling with a duration of 15 
seconds showed relatively equal numbers. The expression 
of caspase-3 cells in the teeth with a stain was increased 
as the increasing of duration and number of replication of 
scaling. In contrast, the expression of caspase-3 cells in 
the teeth without stain was incresed domninantly due to 
the increasing of the duration of scaling. The expression 
of caspase-3 cells for once scaling with a duration of 60 
seconds was higher than those for 3 and 5 times with the 
same scaling duration. Leverne test then was performed 
for homogeneity of the data. The results obtained was p 
= 0.344, which means that the data were homogeneous 
and qualified to be analyzed with Univariate Analisis of 
variance test.

Based on the results of univariate analisis of variance 
test (Table 2), duration and repetition of scaling either 
individually or communaly could affect significantly the 
expression of caspase-3 in the dental pulp cells with and 
without stain (p <0.05). It means that there were significant 
effects of ultrasonic scaling duration and replication on the 
number of cells expressing caspase-3 in the dental pulp cells 
with and without stain.

Based on LSD test, it is also known that there were 
9 types of relations without significant difference of the 
average number of caspase-3 expression (p>0.05). LSD 
test showed that the expression of caspase-3 cells in the 
group induced with stain for once scaling with a duration 
of 15 seconds was not significantly different from that in 
the group without stain with the same scaling duration. 
Similarly, the expression of caspase-3 cells in the group 
induced with stain for three times of scaling with a duration 



Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

50 Nuryanti, et al./Dent. J. (Majalah Kedokteran Gigi) 2015 March; 48(1): 48–52

of 30 seconds had almost the same number to the group 
induced with stain for five times of scaling with a duration 
of 60 seconds.

The effects of ultrasonic scaling duration and replication 
on the expression of caspase-3 in the dental pulp cells with 
and without stain can be seen in Figures 1 and 2. Figure 1 
shows that the increasing of the duration and replication of 
ultrasonic scaling could increase the expression of caspase-
3 in dental pulp cells with stain. Figure 2 shows that the 
increasing of the duration and replication of ultrasonic 
scaling could increase the expression of caspase-3 in dental 
pulp cells without stain.

discussion

Data in Tables 1 and 2 and in Figures 1 and 2 show the 
effects of ultrasonic scaling duration and repetition on the 
expression of caspase-3 in the dental pulp cells with and 
without stain. This is consistent with the explanation that 
the increase in temperature of ultrasonic scaling can damage 
the pulp and disrupt circulatory system resulting in dental 
pulpitis or necrosis.11 The effects caused by ultrasonic wave 
exposure to tissue is thermal, mechanical (cavitation and 
microstreaming), and chemical (sonochemistry). Clinical 
effect is depending on the application technique used.12 

The tip of ultrasonic scaler, actualy can get vibrations, 
and the movements are influenced by the design of the 

scaler. The movements of the tip then can trigger cavitation 
and microstreaming derived from the cooling water of the 
ultrasonic scaler.13 Therefore, it can be said that the longer 
the exposure to ultrasonic waves is, the longer the cavitation 
and acoustic microstreaming mechanisms are. Similarly, 
some in	vitro researches also show that the duration of the 
ultrasonic scaling can affect on tooth surface damage.3 The 
damage of tooth surface then can lead to the increasing of 
cavitation and acoustic microstreaming mechanisms until 
air bubbles are collapsed and a shock wave is emerged. 

However, ultrasonic equipment is still expected to 
be used for dental pulp treatment because it can cause 
more minimal damage than using bur with high speed.14 
Mechanism of ultrasonic scaler actually can clean tooth 
surface from materials due to chipping mechanism of scaler 
probe oscillating.15 This mechanism usually occurs in areas 
with limited view and excessive scaling duration.16 Thus, 
over-instrumentation of ultrasonic scaling must not occur 
since it can lead to damage, from tooth surface to dental 
pulp cells.

table 1. The average number of caspase-3 expression	in dental 
pulp cells

Replication and 
Duration
(second)

Average±Standard 
Deviation of teeth 

with stain 

Average±Standard 
Deviation of teeth 

without stain

1x 15
1x 30
1x 60
3x 15
3x 30
3x 60
5x 15
5x 30
5x 60

14.60± 2.30
20.20± 3.11
33.00± 1.88
29.60± 4.72
51.60± 4.51
69.40± 5.18
43.20± 1.92
66.00± 4.36
80.40± 5.03

14.00 ± 2.88 
23.00± 3.00 
72.60± 4.77 
44.20± 2.78 
44.60± 2.07 
52.60± 3.91 
31.00± 1.87 
40.00± 3.53 
50.40± 3.65

table 2. The results of univariate analysis of variance on the 
caspace-3 expression in dental pulp cells

Source F Sig.

Intercept
Tooth Stain (1) 
Replication (2)
Duration (3)
(1) and (2)
(1) and (3)
(1), (2) and (3)

169346.844
344.178

8651.356
13987.089
5086.422
463.089

3719.511

0.000
0.000
0.000
0.000
0.000
0.000
0.000

12 
 

 
 

Figure 1. Graph of caspase-3 expression in dental pulp cells with stain. 

 

 

 
 

Figure 2. Graph of caspase-3 expression in dental pulp cells without stain. 

  

 

The number of replication scalling 

T
he

 n
um

be
r o

f c
as

pa
se

 3
 

seconds 
seconds 
seconds 

T
he

 n
um

be
r o

f c
as

pa
se

 3
 

The number of replication scalling 

seconds 

seconds 

seconds 
seconds 

figure 1. Caspase-3	 expression in dental pulp cells with 
stain.

12 
 

 
 

Figure 1. Graph of caspase-3 expression in dental pulp cells with stain. 

 

 

 
 

Figure 2. Graph of caspase-3 expression in dental pulp cells without stain. 

  

 

The number of replication scalling 

T
he

 n
um

be
r o

f c
as

pa
se

 3
 

seconds 
seconds 
seconds 

T
he

 n
um

be
r o

f c
as

pa
se

 3
 

The number of replication scalling 

seconds 

seconds 

seconds 
seconds 

figure 2. Caspase-3 expression in dental pulp cells without 
stain.



5�

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
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5�Nuryanti, et al./Dent. J. (Majalah Kedokteran Gigi) 2015 March; 48(1): 48–52

In this research, the increasing of caspase-3 expression 
of dental pulp cell occurred as the increasing of duration 
and replication of scaling. Cell injury occur when the 
cooling water of ultrasonic scaler flows into the dental pulp 
chamber.17 The changes of dental pulp cells, consequently, 
were detected in this research by the increasing expressing 
caspase-3of dental pulp cell.

The increasing of tooth temperature after ultrasonic 
scaling also cause damage in dentin and dental pulp tissue.18 
Over-instrumentation lead to tooth root damage, so the teeth 
will become more sensitive, thus, the longer the duration 
of ultrasonic scaling is, the higher the negative effects will 
be obtained.19 In other words, certain effects of ulrasonic 
wave exposure to dental cells can be considered as normal, 
lysis, apoptosis or necrosis, depending on the duration of 
ulrasonic wave exposure.11

Ultrasonic scaling procedures can also cause cavitation 
and acoustic	 microstreaming mechanisms, shock waves 
and free radical bubbles.21 These mechanisms then can 
lead to the changing of bubbles in the tissues both in size 
and number. Air bubbles will increasingly enlarge until 
they reaches maximum size and eventually burst, and the 
mechanisms occur repeatedly until the ultrasonic wave 
exposure is stopped.22 Therefore, it is suspected as the cause 
change of the dental pulp cells resulting the increasing of 
caspase-3 expression.

The results of this research show that the number of 
caspase-3 expression in dental pulp cells after once scaling 
with a duration of 15 seconds on the tooth surface induced 
with stain was 14.60 ± 2.30, while that on the surface 
without stain was 14.00 ± 2.88. In general, it can be said 
that the number of caspase-3 expression in the group of 
teeth with stain was higher than in the group without stain. 
The number of caspase-3 expression in dental pulp cells 
after five times of scaling with a duration of 60 seconds in 
the group of teeth with stain was 80.40 ± 5.03, while that 
in the group without stain was 50.40 ± 3.65. It indicates 
that ultrasonic wave exposure to the surface of the teeth 
with and without stain cause similar mechanisms in the 
dental pulp cells since the enamel and dentin are porous, 

so the tissues in the pulp chamber can be affected by the 
complex mechanism.

One of indicators of apoptosis cells is caspase-3 
expression.23 Physiologically, apoptosis will be increased 
when deciduous teeth become permanent ones.19 The 
results of univariate analysis of variance that duration 
and replication ultrasonic scaling individually or jointly 
significantly influenced on the number of caspase-3 
expression in dental pulp cells with and without stain 
(p<0.05). It is suspected due to the complex mechanisms 
of the ultrasonic waves, including vibration, acoustic 
microstreaming, cavitation, and bubble rupture in the 
dental pulp chamber. These mechanisms can explain how 
the cooling water enters the pulp chamber and causes 
air bubbles in the pulp tissue and in the blood vessels of 
the pulp. In normal condition, air bubbles are small, but 
with ultrasonic scaling, the volume and number of air 
bubbles become excessive. After the size of the bubbles is 
maximum, the continuing ultrasonic wave exposure will 
cause the bubbles brust. As a results, the bubbles around 
the cells will damage, leading to tooth pain of patients 
during ultrasonic scaling. A mechanism that arises later is 
that the body create a balance with the increased number of 
apoptosis cells as one of indicators of the increased number 
of caspase-3 expression in dental pulp cells.

During ultrasonic scaling procedure, enamel structure 
consisting of organic and inorganic elements will also get 
impact pressure from the tip of the scaler to the tip of the 
tooth surface. The vibration of tip scaler and spray cooling 
can remove stain from the tooth surface. During scaling, 
cavitation and acoustic microstreaming mechanisms also 
occurs, as a result, the cooling water can enter the dental 
pulp chamber due to the nature of the porous enamel and 
dentin. These mechanisms occur because of exposure to the 
cell resulting in changes of the cell membrane, followed by 
membrane permeability, morphology and activity changes 
of cell membrane.23 It takes a duration of 1-1.5 minutes 
for cleaning stain on the tooth surface using ultrasonic 
scaler.24 The longer the duration is, the higher the negative 
effects will be obtained 25 and the higher the permeability 
of cytoplasm will occur.26 It can be said that the ultrasonic 

figure 3. The expressions of caspase-3 in dental pulp cells with stain as follow: A) 1x of scaling for 15 seconds; B) 3x of scaling for 
30 seconds; C) 5x of scaling for 60 seconds. The arrows show the expressions of caspase-3 with IHC staining, dark brown 
among light purple tissues.

13 
 

 
 

 
Figure 3. The expressions of caspase-3 in dental pulp cells with stain as follow: A) 1x of scaling for 

15 seconds; B) 3x of scaling for 30 seconds; C) 5x of scaling for 60 seconds. The arrows 
show the expressions of caspase-3 with IHC staining, dark brown among light purple 
tissues. 

 

A B 

C 

13 
 

 
 

 
Figure 3. The expressions of caspase-3 in dental pulp cells with stain as follow: A) 1x of scaling for 

15 seconds; B) 3x of scaling for 30 seconds; C) 5x of scaling for 60 seconds. The arrows 
show the expressions of caspase-3 with IHC staining, dark brown among light purple 
tissues. 

 

A B 

C 



Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 56/DIKTI/Kep./2012.
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52 Nuryanti, et al./Dent. J. (Majalah Kedokteran Gigi) 2015 March; 48(1): 48–52

waves can alter the number and nature of the cell nucleus 
in apoptosis process.27

The results of LSD test, indicate that the number of 
caspase-3 expression in dental pulp cells the group of teeth 
without stain was not significantly different from the other 
groups of teeth without stain, compared with the group of 
teeth with stain. It is because the tooth surface without stain 
will make the tip directly contact with the enamel surface, 
but because stain is porous, air bubbles can get into the 
pulp chamber during the ultrasonic scaling. Sonification 
can trigger acoustic microstreaming, flow turbulence, 
microjet and shock wave leading to rupture of air bubbles.2 
This mechanism is suspected to be cause of damage to the 
surface of the organic structures and the dental pulp cells.

Sonoporation mechanism is used as a drug delivery by 
penetrating cell membranes.5 Nevertheless, this mechanism 
can give negative effects, such as pulpitis or dental pulp 
necrosis.8 At the time of the evaluation of the number 
of caspase-3 expression, there was the increasing of the 
number of small-sized bubbles which were more numerous 
and larger size as the increasing of the number of scaling 
replication and duration. Most preparations even showed an 
increase in the number and size of air bubbles in the blood 
vessels leading to the rupture of the blood vessels. This 
condition can indicate the occurrence of pulpitis or necrosis 
mechanism after the scaling. It then can be understood that 
one of the effects of ultrasonic waves on a tissues are the 
increasing of local temperature due to mechanical pressure 
passing the tissue. Ultrasonic pressure resulting in small 
bubbles on a live tissue can lead to distortion of the cell 
membrane influenced by flux and activity of ions.20 The 
changes of bubble size that occur periodically even can 
cause expansion, contraction and death for the tissue. These 
side effects can be temporary or permanent. The effects of 
ultrasonic waves can also be reversible and irreversible 
disrupting cell membranes through cavitation mechanism. 
It can be concluded that ultrasonic scaling duration and 
replication on teeth with and without stain can improve the 
number of caspase-3 expression in dental pulp cells.

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