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

80

The level’s changing of transforming growth factor β2 during 
canine retraction in non-growing age patient 

Adianti and Ameta Primasari 
Department of Oral Biology
Faculty of Dentistry, Universitas  Sumatera Utara 
Medan - Indonesia

abstract

Background: Orthodontic	tooth	movement	occurred	as	a	result	of	alveolar	bone	remodeling	and	collagen	due	to	mechanical	load.	
This	mechanical	load	applied	to	the	tooth	will	exert	a	number	of	cytokine	and	growth	factors.	One	of	the	growth	factors	that	are	often	
associated	with	orthodontic	tooth	movement	is	transforming	growth	factor-β	(TGF-β).	It	has	3	isoforms,	TGF-β1,	TGF-β2,	and	TGF-
β3.	It	has	been	known	that	in	adult	patient,	tooth	movement	rate	was	slower.	Purpose: The	aim	of	this	study	was	to	investigate	the	
changing	level	of	TGF-β2	in	non-growing	patient	due	to	mechanical	load	in	canine	retraction. Method: Gingival	crevicular	fluid	from	
6	subjects	who	undergo	canine	retraction	was	taken	to	investigate	changing	level	of	TGF-β2.	Distal	site	of	each	upper	canine	served	
as	an	experimental	tooth.	The	gingival	crevicular	fluid	from	experimental	tooth	was	taken	just	prior	to	mechanical	load,	at	24h	and	
72h	after	mechanical	load.	Result: ELISA	reader	showed	that	level	of	TGF-β2	was	decreasing	during	experiment	time.	Conclusion: 
It	can	be	concluded	that	in	non-growing	patient,	TGF-β2	has	less	role	in	alveolar	bone	resorption	in	orthodontic	tooth	movement.

Keywords:	Bone	resorption;	non-growing;	orthodontic	tooth	movement;	TGF-β2	

Correspondence: Adianti, c/o: Fakultas Kedokteran Gigi Universitas Sumatera Utara. Jl. Alumni No. 2 Kampus USU Medan, Indonesia. 
e-mail: adianti9090@gmail.com 

Research Report

introduction

Malocclusion has a high impact in individual life 
quality. The prevalence of malocclusion in Indonesia is 
around 80% and in third place after caries and periodontal 
disease. Along with the improvement of the knowledge 
society and the desire to improve the quality of life, the 
demand for orthodontic needs in the community was 
also increased. The aims of orthodontic therapy were 
to corrected dental irregularities and disharmony in jaw 
relations. It utilizes the potential of the periodontal ligament 
and the alveolar bone to adapt to changing mechanical 
circumstances by tissue remodeling. By these adaptations 
teeth can be moved through the alveolar bone and also 
distant skeletal locations can be affected. By these two 
mechanisms a stable occlusion and a proper jaw relation 
can be established.1

There was an increase in the demand for adult 
orthodontic therapy in the past decades. However, our 

knowledge on efficiency of adult tooth movement is 
still incomplete. There is a common believe among the 
orthodontists that orthodontic procedure will be more time-
consuming in adult patient or non-growing age patient than 
in growing age patient. Younger patient had a greater tooth 
movement than adults.2 Another study also showed there 
was a faster initial tooth movement in juvenile than in adult 
animals.3 This finding corroborate another study by Ren,4 
who found that  cellular response in crevicular fluid are less 
responsive to orthodontic force in old rat than in juvenile.

Orthodontic tooth movement is achieved by the 
remodeling of periodontal ligament and alveolar bone 
in response to mechanical loading. This remodeling is 
mediated by the activation of several bones remodeling 
marker. Many studies were done in order to give us 
additional information about this molecular signalization, 
for example TIMP-1, Col-1, RANKL, IL-6, sgp-130, etc.3-7 
One of the growth factor that still has an unclear role in 
orthodontic tooth movement is transforming growth factor 

Dental Journal
(Majalah Kedokteran Gigi)

2015 June; 48(2): 80–83



81

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

81Adianti and Primasari/Dent. J. (Majalah Kedokteran Gigi) 2015 June; 48(2): 80–83

7 
 

 
Figure 1. GCF collection with filter paper strip. GCF was collected at distal site of canine represented 

resorption area. 
 

 

  
Figure 2. Graphic showed mean value of TGF-β2 at just prior to mechanical loading, 24 h after 

mechanical loading, and 72 h after mechanical loading.  
 
 
 

Table 1. The Changing level of TGF-β2 at just prior to application of mechanical load, 24 h and 72 h after 
mechanical load  

 
Time  x ± SD (pg/ L) p 

0h – 24h 0.87864 ± 0.96999 0.077 

0h – 72h 1.86711 ± 0.77038 0.002 

24h – 72h 0.98847 ± 1.28459 0.118 

 
 

 

Time point 

* 

*p<0.05 

Figure 1.  GCF collection with filter paper strip. GCF was 
collected at distal site of canine represented resorption 
area.

7 
 

 
Figure 1. GCF collection with filter paper strip. GCF was collected at distal site of canine represented 

resorption area. 
 

 

  
Figure 2. Graphic showed mean value of TGF-β2 at just prior to mechanical loading, 24 h after 

mechanical loading, and 72 h after mechanical loading.  
 
 
 

Table 1. The Changing level of TGF-β2 at just prior to application of mechanical load, 24 h and 72 h after 
mechanical load  

 
Time  x ± SD (pg/ L) p 

0h – 24h 0.87864 ± 0.96999 0.077 

0h – 72h 1.86711 ± 0.77038 0.002 

24h – 72h 0.98847 ± 1.28459 0.118 

 
 

 

Time point 

* 

*p<0.05 

Figure 2. Graphic showed mean value of TGF-β2 at just prior 
to mechanical loading, 24 h after mechanical loading, 
and 72 h after mechanical loading. 

Table 1. The Changing level of TGF-β2 at just prior to 
application of mechanical load, 24 h and 72 h after 
mechanical load 

Time x ± SD (pg/µL) p
0h – 24h 0.87864 ± 0.96999 0.077
0h – 72h 1.86711 ± 0.77038 0.002*
24h – 72h 0.98847 ± 1.28459 0.118

*p<0.05

β (TGF-β). Some author found it as mediator for suppressed 
osteoclast activity8,9, but in conversely,  others found it may 
contribute to the induction of bone resorption.10,11 TGF-β 
has 3 isoforms, they are TGF-β1, TGF-β2, and TGF-β3. 
Overexpression of TGF-β2 was found to give a result on 
an osteoporosis-like phenotype.12 

Consider there is a role of TGF-β2 in bone remodeling, 
the aim of this study was to investigate the changing level 
of TGF-β2 due to mechanical loading in orthodontic tooth 
movement. This changing level of TGF-β2 was investigated 
at just prior to mechanical load application, 24 hours after 
mechanical load and 72 hours after mechanical load. 

materials and methods

Subjects of this study were 6 patient age 30-35 years old 
who undergo canine retraction in private clinic. Changing 
level of TGF-β2 was investigated in gingival crevicular 
fluid (GCF). ethical approval was obtained from ethic 
Committee and Research Faculty of Dentistry Universitas 
Indonesia. Subjects of this research were selected 
according to these following criteria: (1) no history of bone 
metabolism disease; (2) pocket probing less than 4 mm; 
and (3) no clinical and radiographic sign of gingivitis and 
periodontitis. Subjects were excluded if they were smoker, 
and use of antibiotics or non-steroid anti-inflammatory 
agents in the 6 months prior to the study. Informed consent 
in written form was obtained from the subject before the 
beginning of the study.

GCF samples were collected using filter paper strips 
(Whatman, No. 1) (Figure 1 and 2). Samples were collected 
at distal side of upper right and left canine at just prior to 
mechanical load (0 hour), 24 hours after mechanical load, 
and 72 hours after mechanical load. Teeth were gently 
washed with water, the site under study were isolated 
with cotton rolls, and dried gently with air-syringe before 
paper strips were applied. Paper strips were inserted 1 mm 

subgingivally for 30 seconds. Mechanical load applied to 
teeth was 100 g of force with elastomeric chain. Force 
magnitude was measured with dontrix gauge. Paper strip 
contained TGF-β2 was then diluted with phosphate buffer 
saline pH 7,7 (Gibco) in 1,5 ml eppendorf tube and stored 
in -80°C in Oral Biology Laboratory Faculty of Dentistry 
University of Indonesia.

eLISA assay was done to determinate the level of TGF-
β2 in GCF. eppendorf tube contained filter paper strip and 
phosphate buffer saline were centrifuged at 12000 x 9 rpm 
for 10 minutes to separate supernatant form. eLISA assay 
was done under the standard procedure.

results

The changing level of TGF-β2 due to mechanical 
loading in canine retraction was shown in Figure 2. This 
study showed that there is a changing level of TGF-β2 at 
different time point. Mean value of TGF-β2 level before 
application of mechanical load is 24.06 ± 0.62 pg/µl. At 24 
hour after mechanical load, level of TGF-β2 was slightly 
decreased (23.28 ± 1.05 pg/µl). 72 hours after mechanical 
load, it continued to decrease (22.19 ± 1.03 pg/µl).

T-test dependent was used to evaluated the statistical 
significance (p<0.05) between 0 hour compare to 24 hours, 
0 hours compare to 72 hours, and 24 hours compare to 
72 hours. The results showed at Table 1. There was a 
significance difference at 0 hour compare to 72 hours 



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

82 Adianti and Primasari/Dent. J. (Majalah Kedokteran Gigi) 2015 June; 48(2): 80–83

(p=0.02; p<0.05). However, it was found there were no 
significances different at 0 hour compare to 24 hours and 
24 hours compare to 72 hours.

discussion

Orthodontic tooth movement is a good example to 
easily understanding bone remodeling due to mechanical 
load. In orthodontic treatment, tooth was moved as a result 
of applied force. This force, according to pressure and 
tension theory will cause bone resorption in compressed 
area, and bone formation in stretched area. This movement 
can be controlled by the magnitude of the applied 
force and the biological responses from the periodontal 
ligament (PDL). The force applied on the teeth will cause 
changes in the microenvironment around the PDL due 
to alterations of blood flow, leading to the secretion of 
different inflammatory mediators such as cytokines, growth 
factors, neurotransmitters, colony-stimulating factors 
and arachidonic acid metabolities. As a result of these 
secretions, remodeling of the bone occurs.13 

Monitoring the biological system in clinical situations 
would diminish the gap between basic research and clinical 
implications. It would be advantageous for the clinician 
and the patient if the reactions of the biological system 
could be monitoring during treatment. This would allow 
the adaptation of the treatment to the biological condition 
of the patient. 

TGF-β is a multifunction growth factor that played role 
in bone remodeling. TGF-β is a part of TGF-β super family 
along with activin, nodal, bone morphogenetic proteins 
(BMP) and so on. TGF-β have 3 isoforms, they are TGF-
β1, TGF-β2, and TGF-β3. How its role in orthodontic 
tooth movement was remain unclear. This study was done 
as a pilot study to confirm the present of TGF-β2 due to 
mechanical load in orthodontic tooth movement. Some 
authors found that level of TGF-β is higher in compression 
site than tension site.10,11 Others found that it has the 
same level in both compression and tension site.5 During 
development, TGF-β2 expressed later than TGF-β1 and 
TGF-β3.14 However, 2 days after application of mechanical 
load, tooth movement begins as a result of osteoclast and 
osteoblast remodels the bony socket.13 This is the main 
reason for time interval choosing in this study. 

Subjects of this study were 30-35 years old patient, 
because we need to be sure these subjects has no potential 
adolescent growth to be expected. So there will be no 
growth hormone affected the changing level of TGF-β2. 
Distal site was choose as an experimental site because we 
believe this site will be more represent the bone resorptive 
response than in mesial site in this kind of experimental 
design. GCF sampling was taken from compression site 
because according to erlebacher et	al.,12  overexpression 

of TGF-β2 will cause an osteoporosis-like phenotype. 
Thus, it can be concluded that TGF-β2 may play role in 
bone resorption. 

We have detected a level of TGF-β2 before application 
of mechanical load, this might be because there still remain 
a force used for leveling and aligning. At 24 hours after 
mechanical load, there was a slight decrease level of 
TGF-β2. Its decrease was continued until 72 hours after 
mechanical load. We found a statistical significance in 
comparison of 0 hour and 72 hours after mechanical load 
(p=0.02). This happen because level of TGF-β2 continued 
to decrease at 72 hours after mechanical load. This result 
was different from Uematsu et al because they found 
that in 24 hours after mechanical loading, TGF-β1 was 
reached its peak level before continued to decrease at 
7 days after mechanical loading.10 However, it remains 
unknown whether TGF-β2 exhibits activity similar to that 
of TGF-β1.15 

It seemed like in non-growing patient, TGF-β2 had 
no or less effect on bone remodeling in orthodontic tooth 
movement. This might be an explanation why some 
treatment in orthodontic seems more time-consuming in 
adult than in younger patient, as our previous study showed 
that in juvenile, level of TGF-β2 were increased at 72 hours 
after mechanical loading. Ren3 found that in early state of 
orthodontic tooth movement, mediator response in adult 
was slower than in juvenile. This is why there was a delay 
on initial tooth movement in adult rat.4 On the other hand, 
in a study experimental on rats, TGF-β showed a lack 
responsiveness in old than in young rats.16 This result might 
explain our finding, why in non-growing patient, TGF-β2 
continued to decrease after mechanical loading.

The result of this study might give the orthodontist 
additional information of how bone remodeling marker were 
reacted in adults. However, further study with prolonged 
time is needed to give information about changing level 
pattern of TGF-β2 due to mechanical load in orthodontic 
tooth movement in adult patient.    There was a changing 
of level of TGF-β2 during application of mechanical load 
in orthodontic tooth movement. TGF-β2 was decreased at 
24 h and 72 h after mechanical load. It can be concluded 
that in non-growing patient, TGF-β2 are less responsive to 
mechanical load in orthodontic tooth movement.  

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Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG

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