6363

Research Report

Dental Journal
(Majalah Kedokteran Gigi)

2016 June; 49(2): 63–66

Histological changes during orthodontic tooth movement due 
to hyperbaric oxygen therapy

Arya Brahmanta,1 Soetjipto,2 and IB Narmada3
1Departemen of Orthodontic, Faculty of Dentistry, Universitas Hang Tuah 
2Departemen Biochemistry, Faculty of Medicine, Universitas Airlangga 
3Departemen of Orthodontic, Faculty of Dental Medicine, Universitas Airlangga 
Surabaya - Indonesia

abstract

Background: Mechanical force of orthodontics causes changes in periodontal ligament vascularization and blood flow, resulting 
in biochemical and cellular changes as well as changes in the contour of the alveolar bone and in the thickness of the periodontal 
ligaments. Hyperbaric oxygen (HBO) therapy is one of many solutions stimulating the growth of new blood vessels and increasing tissue 
oxygenation. Thus, HBO plays a role in recovery of periodontal ligament and osteoblasts. Purpose: This study aimed to determine the 
effects of HBO therapy for seven days on periodontal ligament size and osteoblast number in the tension site during bone remodeling 
in tooth movement. Method: The study was true experimental laboratories with completely randomized control group post test only 
design. Twenty-four males guinea pigs were randomly divided into three groups. K0 was the control group without any treatment, K1 
was the group given a mechanical orthodontic pressure, and K2 was the group treated with the addition of hyperbaric oxygen therapy. 
The maxillary incisors were moved distally by elastic separator. After HBO therapy on day 7, all of the groups were sacrificed, and 
then periodontal ligament size and osteoblast number were analyzed by one-way Anova and LSD statistical tests. Result: The results 
showed significant differences in the size of the periodontal ligament and the number of osteoblasts in the tension site among the groups 
(p<0.05). Conclusion: HBO therapy at 2.4 ATA for 7 days is effective in recovery of periodontal ligament and increased osteoblast 
number during bone remodeling in tension area of orthodontic tooth movement.

Keywords: periodontal ligament; osteoblast; tooth movement; hyperbaric oxygen; bone remodeling 

Correspondence: Arya Brahmanta, Department of Orthodontic, Faculty of Dentistry, Universitas Hang Tuah. Jl. Arif Rahman Hakim 
150 Surabaya, Indonesia. E-mail: arya.brahmanta@hangtuah.ac.id, Phone: 031-5945864, Fax: 031-591219. 

introduction

Orthodontic tooth movement is indicated by remodeling 
changes in dental and paradental tissues, including 
periodontal ligament, alveolar bone, dental pulp and 
gingiva. Periodontal ligament (PDL) is a connective tissue 
that attaches tooth to the alveolar bone, it plays a crucial role 
in the adaptation process of teeth to physiological forces 
as well as to orthodontic forces.1 These forces induced by 
strains would alter PDL vascularity and blood flow.2

During orthodontic tooth movement, the periodontal 
vasculature is severely impaired by chronic inflammation 
or excessive mechanical force. This leads to a hypoxic 
microenvironment of the periodontal cells and enhances 

the expression of various cytokines and growth factors that 
may regulate angiogenesis and alveolar bone remodeling.3 
Orthodontic forces are known to occlude periodontal 
ligament vessels on the pressure side of the dental root, 
decreasing the blood perfusion of the tissue.4

In other words, orthodontic tooth movement is 
stimulated by the force exerted on the periodontal tissue that 
affect the remodeling of the alveolar bone as a result. When 
a force greater than capillary blood pressure applied to a 
tooth, hyaline zone might occur in the direction of the force. 
This hyaline zone, free of cells, is a necrotic area created 
by osteoclast activity originated from the tension site. In 
the tension site, osteoblasts are produced during bone 
apposition process.5 During orthodontic tooth movement, 

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
DOI: 10.20473/j.djmkg.v49.i2.p63-66

http://dx.doi.org/10.20473/j.djmkg.v49.i2.p63-66


64 Brahmanta, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 June; 49(2): 63–66

therefore, osteoblasts in the tension side are generated from 
osteoprogenitor cells, which reside within the PDL.6

The bone remodeling is characterized by activation, 
resorption, reversal, and formation, in both tension 
and compression tooth sites during orthodontic tooth 
movement.2,7 Orthodontic force application induces several 
biological process leading to resorption in the pressure sites 
and apposition in the tension site. Histological changing 
occur for 5 days followed by its reversal in next 5 to 7 
days and a late wave of bone formation between 7 and 14 
days.8

Hyperbaric oxygen (HBO) therapy increases the amount 
of oxygen dissolved in blood (oxygen tension) which can 
then increase the amount of oxygen delivered to hypoxic 
tissues reducing the effects of hypoxia. Vascular endothelial 
growth factor (VEGF) has been identified as one of the 
primary growth factors responsible for neovascularization 
during wound healing and embryonic development. Oxygen 
tension is a key regulator of VEGF expression in vitro and 
in vivo.9 HBO therapy is the inhalation of 100% oxygen 
inside a hyperbaric chamber pressurized to greater than 1 
atmosphere absolute (ATA; 760 mm Hg). 

HBO therapy, consequently, is potential because it 
stimulates the growth of new blood vessels and results in a 
substantial increase in tissue oxygenation that can enhance 
wound healing. HBO therapy can also promote collagen and 
adenosinetriphosphate (ATP) synthesis, capillary ingrowth, 
and osteoblastic and osteoclastic activities. The stimulation 
of osteogenesis by HBO has been reported applied in animal 
experiments and clinical treatments. Oxygen tension has a 
triggerinrole in bone remodeling. Increased oxygen tension 
causes cellular differentiation to osseous tissue, whereas 
decreased oxygen tension results in cartilage formation. 
There is a parallelism between the increasing of oxygen 
tension and the increasing of osteoblast and osteoclast 
activities.10 This study aimed to evaluate periodontal 
ligament size and osteoblast number in the tension site 
due to 2.4 ATA hyperbaric oxygen therapy during bone 
remodeling in tooth movement. 

materials and methods

The study was true experimental laboratories with 
completely randomized control group post test only design. 
Ethical permission was obtained from ethics and scientific 
research committee of experimental animal use in Faculty 
of Dental Medicine, Universitas Airlangga. Twenty-four 
male guinea pigs (Cavia cobaya) aged three to four months 
and weighed 300-400 grams. The guinea pigs, fed with a 
standard pellet diet and tap water ad libitum, were randomly 
divided into three equal groups. The materials used were 
100% pure oxygen in hyperbaric animal chamber, 10% 
ketamine injection as anesthetic drug, a dose of 0.1-0.2 
ml/kg for acepromazine 0.5 ml, 10% buffered formalin, 
Betadine solution, and cotton. 

T h e  p r o c e d u r e  o f  t h i s  s t u d y  w a s  b e g a n  w i t h 
acclimatization of animals for 48 hours. Guinea pigs were 
divided into three groups, namely (K0) as the control 
group, (K1) as the orthodontic group and (K2) as the HBO 
group. An orthodontic force triggering orthodontic tooth 
movement on the maxilla by using elastic separator was 
administered to groups K1 and K2. The force (reciprocal) 
was measured with a gauge during the experiment. In Group 
K2, treated with orthodontic force day for 14 days and then 
with daily HBO therapy at 2.4 ATA for 90 minutes in 7 
days, from day 8 to day 14. HBO therapy was conducted 
by using a veterinary hyperbaric chamber model.

The guinea pigs were monitored during the experiment, 
and all of the groups were sacrificed on the fourteenth day 
of the experiment. The maxillary teeth were dissected and 
placed in 10% buffered formalin. Afterwards, histological 
section were prepared with HE, and then observed by 
using a microscope. The photos were taken to measure 
the number of osteoblasts seen on the microscope with an 
enlargement 400x. Meanwhile, the size of the periodontal 
ligament on 1/3 apical in the tension site was observed 
with an enlargement 40x. Each histological section was 
observed and calculated as many as three times in the 
field of view.

The data were statistically measured by using Statistical 
Package for the Social Science (SPSS) version 20 program. 
The statistically significant differences among the HBO 
group, the orthodontic group and the control group were 
determined and evaluated by using one way Anova and 
LSD tests (p<0.05).

results

The data obtained showed that there were differences 
of the periodontal ligament size in the tension site in each 
group. In the control group, the mean was 6.886 mm, the 
mean of the orthodontic group was 11.563 mm, and the 
mean of the HBO group was 5.030 mm (Table 1). The 
data also showed that the number of osteoblasts increased 
in all of those treatment groups. The highest number found 
in the group treated with HBO 14.571 (cell/field of view). 
Meanwhile, in the control group, the mean was 13.142, and 
in the orthodontic group the mean was 4.833 (Table 2). 

The statistical hypothesis was conducted with a standard 
analytic significance of 95 percent (P=0.05) by using SPSS. 
The statistical results showed that there were significant 
differences among all of the groups. The statistical results 
of one way Anova test and LSD test showed that there were 
significant differences of the periodontal ligament size in 
the tension site (Figure 1) between the orthodontic group 
and the HBO group (p<0.005). The periodontal ligament 
size in the tension site of treatment group decreased with 
1.856, thickness decreases, approaching normal size to 
control group (Figure 2).

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
DOI: 10.20473/j.djmkg.v49.i2.p63-66

http://dx.doi.org/10.20473/j.djmkg.v49.i2.p63-66


6565Brahmanta, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 June; 49(2): 63–66

There were also significant differences of the number of 
osteoblasts among all of the groups (Figure 3). The number 
of Osteoblast in the tension site increase with 9.74 mm, 
compared to K0 group (Figure 4).

discussion

The results showed that Group K2 given the orthodontic 
force + therapy at 2.4 ATA for 90 minutes in 7 days had 
wider periodontal ligament size in the tension site than 
Group K0 as the control group and Group K1 as the 
orthodontic group. 

7 
 

 

 

 

 

 

 
Table 1. The size of periodontal ligament observed in the control, orthodontic and HBO groups (mm) 
 
 
 
 
 
 
 

 

 

Table 2. The number of Osteoblasts found in the control, orthodontic and HBO groups (cell/field of 
view) 

 
 
 
 
 
 
 
 
 
 
 

                                  

         (A)    (B)          (C) 

Figure 1. Histological section of ligament periodontal in the control group (A), in the orthodontic 
group (B), and in the Orthodontic + HBO group (C) with magnification 40x. 

 

            Groups  Mean      ±      SD 

Control     6.886    ±   2.572 

Orthodontic  11.563    ±   8.831 

Orthodontic + HBO    5.030    ±   3.411 

            Groups  Mean        ±      SD 

Control   13.142      ±     5.573 

Orthodontic    4.833      ±     1.602 

Orthodontic +HBO  14.571      ±     6.320 

A

7 
 

 

 

 

 

 

 
Table 1. The size of periodontal ligament observed in the control, orthodontic and HBO groups (mm) 
 
 
 
 
 
 
 

 

 

Table 2. The number of Osteoblasts found in the control, orthodontic and HBO groups (cell/field of 
view) 

 
 
 
 
 
 
 
 
 
 
 

                                  

         (A)    (B)          (C) 

Figure 1. Histological section of ligament periodontal in the control group (A), in the orthodontic 
group (B), and in the Orthodontic + HBO group (C) with magnification 40x. 

 

            Groups  Mean      ±      SD 

Control     6.886    ±   2.572 

Orthodontic  11.563    ±   8.831 

Orthodontic + HBO    5.030    ±   3.411 

            Groups  Mean        ±      SD 

Control   13.142      ±     5.573 

Orthodontic    4.833      ±     1.602 

Orthodontic +HBO  14.571      ±     6.320 

B

7 
 

 

 

 

 

 

 
Table 1. The size of periodontal ligament observed in the control, orthodontic and HBO groups (mm) 
 
 
 
 
 
 
 

 

 

Table 2. The number of Osteoblasts found in the control, orthodontic and HBO groups (cell/field of 
view) 

 
 
 
 
 
 
 
 
 
 
 

                                  

         (A)    (B)          (C) 

Figure 1. Histological section of ligament periodontal in the control group (A), in the orthodontic 
group (B), and in the Orthodontic + HBO group (C) with magnification 40x. 

 

            Groups  Mean      ±      SD 

Control     6.886    ±   2.572 

Orthodontic  11.563    ±   8.831 

Orthodontic + HBO    5.030    ±   3.411 

            Groups  Mean        ±      SD 

Control   13.142      ±     5.573 

Orthodontic    4.833      ±     1.602 

Orthodontic +HBO  14.571      ±     6.320 

C

Figure 1. Histological section of ligament periodontal in the 
control group (A), in the orthodontic group (B), and in 
the Orthodontic + HBO group (C) with magnification 
40x.

8 
 

 

Figure 2. The size of ligament periodontal observed in the control group (A), in the orthodontic group 
(B), and in the Orthodontic + HBO group (C). 

 
 

        
(A)                                      (B)                                      (C) 

Figure 3. Histological section of Osteoblasts in the control group (A), in the orthodontic group (B), 
and in the orthodontic + HBO group (C) with magnification 400x. 

 

6,886 

11,563 

5,030 

0

2

4

6

8

10

12

Control (A) Ortho (B) Ortho+HBO (C )

mm 

Control Ortho Ortho +HBO

Figure 2. The size of ligament periodontal observed in the 
control group (A), in the orthodontic group (B), and 
in the Orthodontic + HBO group (C).

Table 1. The size of periodontal ligament observed in the 
control, orthodontic and HBO groups (mm)

 Groups Mean ± SD

Control  6.886 ± 2.572

Orthodontic 11.563 ± 8.831

Orthodontic + HBO  5.030 ± 3.411

Table 2. The number of Osteoblasts found in the control, 
orthodontic and HBO groups (cell/field of view)

 Groups Mean ± SD

Control 13.142 ± 5.573

Orthodontic  4.833 ± 1.602

Orthodontic +HBO 14.571 ± 6.320

8 
 

 

Figure 2. The size of ligament periodontal observed in the control group (A), in the orthodontic group 
(B), and in the Orthodontic + HBO group (C). 

 
 

        
(A)                                      (B)                                      (C) 

Figure 3. Histological section of Osteoblasts in the control group (A), in the orthodontic group (B), 
and in the orthodontic + HBO group (C) with magnification 400x. 

 

6,886 

11,563 

5,030 

0

2

4

6

8

10

12

Control (A) Ortho (B) Ortho+HBO (C )

mm 

Control Ortho Ortho +HBO

A

8 
 

 

Figure 2. The size of ligament periodontal observed in the control group (A), in the orthodontic group 
(B), and in the Orthodontic + HBO group (C). 

 
 

        
(A)                                      (B)                                      (C) 

Figure 3. Histological section of Osteoblasts in the control group (A), in the orthodontic group (B), 
and in the orthodontic + HBO group (C) with magnification 400x. 

 

6,886 

11,563 

5,030 

0

2

4

6

8

10

12

Control (A) Ortho (B) Ortho+HBO (C )

mm 

Control Ortho Ortho +HBO

C

8 
 

 

Figure 2. The size of ligament periodontal observed in the control group (A), in the orthodontic group 
(B), and in the Orthodontic + HBO group (C). 

 
 

        
(A)                                      (B)                                      (C) 

Figure 3. Histological section of Osteoblasts in the control group (A), in the orthodontic group (B), 
and in the orthodontic + HBO group (C) with magnification 400x. 

 

6,886 

11,563 

5,030 

0

2

4

6

8

10

12

Control (A) Ortho (B) Ortho+HBO (C )

mm 

Control Ortho Ortho +HBO

B

Figure 3. Histological section of Osteoblasts in the control 
group (A), in the orthodontic group (B), and in the 
orthodontic + HBO group (C) with magnification 
400x.

9 
 

 
Figure 4. The number of osteoblasts in the tension site of the control group (A), in the orthodontic 

group (B), and in the Orthodontic + HBO group (C).
 

13.142 

4.833 

14.571 

0

2

4

6

8

10

12

14

16

18

Control (A) Ortho (B) Ortho+HBO (C )

Cell/field of view 

Control Ortho Ortho +HBO

Figure 4. The number of osteoblasts in the tension site of the 
control group (A), in the orthodontic group (B), and 
in the Orthodontic + HBO group (C).

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
DOI: 10.20473/j.djmkg.v49.i2.p63-66

http://dx.doi.org/10.20473/j.djmkg.v49.i2.p63-66


66 Brahmanta, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 June; 49(2): 63–66

HBO therapy, involving the administration of 100% 
oxygen at atmospheric pressures greater than 1 ATA, 
has been proposed as an adjunctive therapy to improve 
the outcomes of patients suffering from bone fractures, 
osteoradionecrosis, and distraction osteogenesis, as well 
as of patients with bone grafts and dental implants.11 HBO 
therapy can increase hemoglobin saturation with oxygen 
from 97% to 100%, and HBO can also increase plasma 
saturation with oxygen. When breathing 100% oxygen, the 
arterial oxygen tension is raised 6 fold when under 1 ATA, 
14 fold under 2 ATA, and 22 fold under 3 ATA. It can raise 
tissue oxygen tension to a maximum of 500 mmHg at 3 
ATA, and can also increase oxygen delivery to up to 60 
ml per liter of blood. This condition is enough for the basic 
metabolic tissue needs of reparative tissues in the human 
body without hemoglobin contribution. This represents the 
main path of the mechanism of HBO action.12

HBO therapy has been known as a process depended 
on oxygen to influence cellular proliferation positively. 
According to Broussard et al., fibroblasts cannot proliferate 
in tissue cultures in the absence of oxygen.10,12 Thus, HBO 
may promote angiogenesis, which is vital for bone healing. 
HBO therapy might increase expression of VEGF, which is 
one of the key factors that stimulates angiogenesis.9

HBO therapy can increase nodules bone formation and 
activity in alkaline phosphatase osteoblast. The surface 
of alkaline phosphatase is a protein that can participate 
in proliferation of regulations, migration, and cell 
differentiation of osteoblast.10 In conclusion, periodontal 
ligament size thickness decreases, approaching normal 
size and osteoblast number were increased during tooth 
movement in the tension site due to the provision of HBO 
therapy 2.4 ATA for 90 minutes in 7 days.

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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
DOI: 10.20473/j.djmkg.v49.i2.p63-66

http://dx.doi.org/10.20473/j.djmkg.v49.i2.p63-66