131131

Research Report

Dental Journal
(Majalah Kedokteran Gigi)
2017 September; 50(3): 131–137

Deoxypyridinoline and mineral levels in gingival crevicular fluid 
as disorder indicators of menopausal women with periodontal 
disease

Agustin Wulan Suci Dharmayanti1 and Banun Kusumawardani2
1Department of Biomedical
2Department of Pathology Anatomy
Faculty of Dentistry, Universitas Jember
Jember-Indonesia

abstract

Background: Menopause is a phase of a woman’s life marked by menstruation cycle cessation and an increased risk of periodontal 
disease. It can be caused by estrogen deficiency which alters the microenvironment in the sulcular gingival area and influences the 
composition and flow of gingival crevicular fluid (GCF). GCF has been widely studied as a non-invasive diagnostic and predictive tool 
for periodontal diseases. However, insufficient reports exist that explore its role as a predictive or diagnostic tool for bone loss detection 
in menopausal women. Purpose: This study aimed was to investigate deoxypyridinoline (DPD) and mineral levels that could be utilized 
as disorder indicators in menopausal women with periodontal disease. Methods: This study represents a form of analytical observation. 
Eighty-four patients of the Dental Hospital, University of Jember who fulfilled certain criteria were recruited. The subjects were divided 
into two main groups based on the presence of periodontal disease, (gingivitis=26; periodontitis=58) which were subsequently divided 
into three sub-groups based on their menopausal phase (pre-menopausal=26; perimenopausal=40; post-menopausal=18). GCF was 
collected using paper points from the buccal site of a posterior maxillary tooth with each subject having their GCF taken on only one 
occasion. DPD analysis was conducted by means of an ELISA test. The analysis of calcium, magnesium and sodium incorporated the 
use of an Atomic Absorption Spectroscope (AAS), while that of phosphor was by means of a spectrophotometer. Statistical analyses 
were performed using a comparison and correlation test (p<0.05). Results: There were significant differences in DPD and the mineral 
level of GCF in menopausal women with periodontal diseases (p<0.05). DPD and mineral levels showed significant correlation to 
those of menopausal women with periodontal diseases and a pH of GCF. Conclusion: DPD and mineral level in GCF could be used 
as disorder indicators in menopausal women with periodontal diseases 

Key words: menopause; periodontal disease; deoxypyridinoline; mineral; gingival crevicular fliud

Correspondence: Agustin Wulan Suci Dharmayanti, Department of Biomedical, Faculty of Dentistry, Universitas Jember. Jl. Kalimantan 
no. 37 Jember 68121, Indonesia. E-mail: agutinwulan.fkg@unej.ac.id

introduction

The menopause is a phase in a woman’s life marked 
by menstruation cycle cessation and changes in sex 
hormone production, the latter of which increases the risk 
of periodontal disease in menopausal females. Periodontal 
disease constitutes tooth support tissue inflammation caused 
by periopathogens ultimately resulting in tooth loss.1 A 
previous study showed that the incidence of periodontal 

disease in menopausal women was higher than in sexually 
productive women. This might be caused by a sex hormone 
deficiency, especially estrogen, which plays a pivotal role 
in periodontal tissue remodeling and repair. A number of 
researchers inferred that there was a relationship between 
periodontitis and the menopause. However, further study is 
required to explain that relationship more fully.1–6 

Estrogen deficiency is regarded as affecting the 
microenvironment in the sulcular gingival area, thereby 

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.v50.i3.p131-137

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p131-137
mailto:agustinwulan.fkg@unej.ac.id


132 Dharmayanti and Kusumawardani/Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 131–137

influencing the composition and flow of gingival crevicular 
fluid (GCF). GCF is a physiological fluid, as well as an 
inflammatory exudate, originating in the gingival plexus 
of blood vessels in the gingival corium, subjacent to the 
epithelium lining of the dentogingival space. GCF is 
composed of serum and locally generated components 
including: tissue breakdown products, inflammatory 
mediators, leukocytes, bacteria, and mineral electrolytes. 
Recently, GCF has been explored and extensively 
investigated because of its many biochemical components 
offering several advantages, particularly that of detecting 
exchanges which occur both locally or systemically in the 
periodontal tissue.7,8 GCF has been widely studied as a 
non-invasive diagnostic and predictive tool in combating 
periodontal diseases. However, reports investigating the 
protein and mineral component of GCF as a predictive 
or diagnostic tool for bone loss detection in menopausal 
women remain insufficient in number.1,7,8

In this recent study, certain parameters potentially 
applicable as disorder indicators in menopausal women 
with periodontal disease were investigated. From the 
authors’ perspective, they offer encouraging potential 
as an early menopause diagnostic tool in the drive to 
improve women’s health. The parameters included 
deoxypyridinoline (DPD) representing a specific bone 
tissue breakdown product and mineral components such as: 
calcium, phosphor, magnesium, and sodium, constituting 
minerals or electrolytes active in inflammation and bone 
metabolism. 

materials and methods

This study constitutes an analytical observation 
approved by the Ethical Commission of the Faculty of 
Dentistry, Universitas Gadjah Mada. Having been recruited 
by the Dental Hospital, Universitas Jember, all 84 patients 
signed an informed concern agreement giving them the 
legal status of research subjects.

The participants were interviewed before completing 
a questionnaire regarding their menstruation cycles and 
menopausal symptoms. The criteria applied for participants 
to be accepted as study subjects included the following: 
female, 45 to 70 years old and systemic disease-free. 
Subjects were excluded from the study if they were pregnant 
or nursing, were smokers, regularly consumed alcohol, and 
had received periodontal treatment during the previous 6 
months, had taken antibiotics during the previous year, 
regularly used mouthwash, received hormone therapy or 
received calcium and/or mineral therapy. The study subjects 
(n=84) were divided into two main periodontal disease-
based groups determined according to a periodontal index 
(Russel’s modification). The criteria of the index included 
the following factors: where gingivitis showed no loss 
attachment and pocket, but there was bleeding on probing 
(n=26); periodontitis showed loss attachment more than 
equal to 3 mm, a periodontal pocket more than 33 mm existed 

and bleeding on probing occurred (n=58).1Thereafter, the 
main groups were divided into three sub-groups based 
on their menopausal phase: premenopausal (regular 
menstrual cycles in the past 3 months) or <50 years old 
(n=26), perimenopausal (experienced a menstrual period 
within the past 12 months but a missed period or irregular 
cycles during the past 3 months) or 50-55 years old (n=40), 
postmenopausal (no menstrual period during the previous 
12 months) or >55 years old (n=18).9,10

GCF was collected between 08.00 and 13.00 because 
levels of DPD peak during the morning hours. GCF was 
taken from the buccal site of the posterior tooth infected with 
gingivitis or periodontitis. GCF was only taken once from 
each subject. Prior to GCF sampling, the tooth element had 
to be cleaned of saliva, blood, plaque, debris, and calculus 
supragingiva. GCF was absorbed using three absorbent 
paper points number 20. Each paper point was inserted in 
the buccal sulcus in a parallel position for approximately 
60 seconds. It was then inserted into a 0.5 ml Eppendorf 
tube and sealed with paraffin tape before being placed in a 
deep-freezer at -300C for DPD and mineral analysis.1

The paper point was centrifuged at 2200 rpms for 
20 minutes. The tube lip of the Eppendorf (1.5 ml) was 
subsequently perforated with a 30G needle and closed. After 
the paper point had been inserted into the tube, 50 ml 0.02 
M 30G needle PBS pH 7.0-7.2 was added and incubated for 
five minutes. It was then centrifuged at 2200 rpms for 20 
minutes, the resulting solution being collected in a 1.5 ml 
Eppendorf tube. Thereafter, 10 ml 0.02 M PBS pH 7.0-7.2 
was added and centrifuged at 2200 rpms for 20 minutes. 
DPD analysis was conducted by means of an enzyme linked 
immunosorbent assay (ELISA) kit (Elabioscience, China). 
The procedures of ELISA test followed those contained in 
the manual booklet.1

For the purposes of mineral analysis, this study used 
two paper points, one of which was subjected to calcium, 
magnesium and sodium analysis by an atomic absorbance 
spectrophotometer (AAS), the other being subjected to 
phosphor analysis by a spectrophotometer. The sample 
preparation of GCF was the same as that for a DPD assay. 
However, the solution collected was added to100µL 
distilled water and 100 µL 0.02 M PBS pH 7.0-7.2, before 
being centrifuged at 2200 rpms for 20 minutes.1,11

All variables compared the DPD and mineral level 
of GCF in menopausal women with periodontal diseases 
using a one-way analysis of variance (ANOVA) (p<0.05) 
test. Then, the variables were analyzed by means of 
least significant differences (LSD) (p<0.05) multiple 
comparison. All variables were subsequently analyzed by 
multiple regressions and Pearson’s correlation (p<0.05). 
This analysis was conducted to establish the association 
or correlation between variables. 

results

The characteristics of 84 middle-aged women who 
participated as subjects in this study are shown in Table 1. 

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.v50.i3.p131-137

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133133Dharmayanti and Kusumawardani/Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 131–137

The majority of participants who experienced periodontitis 
were aged approximately 49 years old. Based on intra-oral 
status, they had approximately 26 remaining teeth and a 
periodontal index of around 2.8. Moreover, the pH level 
of GCF participants suffering from periodontitis was just 
above 7 (slightly alkaline). 

Table 1 show that there were significant differences 
between the DPD and mineral levels in the GCF of 
menopausal women with periodontal diseases (p<0.05). 
The pre-menopausal women with gingivitis registered 
the lowest DPD and mineral level in their GCF, with the 
exception of magnesium (2.67±2.21, mean±SD). The 
lowest magnesium level was recorded in postmenopausal 
women with periodontitis (0.96±0.21, mean±SD). The 
highest level could be seen among those women then 
experiencing the menopause. Premenopausal women 
presented the highest magnesium level (gingivitis 
subjects=2.67±2.21; periodontitis subjects=1.64±0.23). 
In contrast, perimenopausal women presented the 
highest level of DPD (gingivitis subjects=77.28±9.26; 
periodontitis subjects=144±25.91) and phosphorous 
( g i n g i v i t i s  s u b j e c t s = 6 7 . 4 3 ± 6 . 4 7 ;  p e r i o d o n t i t i s 
subjects=71.81±6.26), while postmenopausal individuals 
presented the highest level of calcium (gingivitis 
subjects=5.51±0.89; periodontitis subjects=5.28±0.11) 
and sodium (gingivitis subjects=621.33±6.65; periodontitis 
subjects=644.83±24.55). 

Figure 1 illustrates multiple comparisons based on the 
mean difference in DPD and the mineral level of GCF 
between groups. With regard to the mean of the DPD level, 
there were significant differences between groups (p<0.05), 
except for menopausal women with gingivitis (p>0.05). 
Within the mean of the mineral level, there were varying 
significance values. With regard to the calcium level, there 
were significant differences between the groups (p<0.05), 
except between the postmenopausal with gingivitis to 
peri- and postmenopausal with periodontitis, and the 
perimenopausal to postmenopausal with periodontitis 
(p>0.05). Phosphor levels between groups showed 
almost no significant differences (p>0.05), except 
pre- and postmenopausal with periodontitis to pre- 
and postmenopausal with gingivitis, and gingivitis to 
periodontitis in perimenopausal (p<0.05). Turning to 
magnesium levels, almost all groups presented significant 
differences (p<0.05), except perimenopausal with gingivitis 
to premenopausal with periodontitis, and perimenopausal 
to postmenopausal with periodontitis (p>0.05). For sodium 
levels, there were significant differences between the 
groups (p<0.05), except perimenopausal to postmenopausal 
with gingivitis, premenopausal with periodontitis to peri- 
and postmenopausal with gingivitis, and perimenopousal 
to postmenopausal with peridontitis (p>0.05).

Table 1. Descriptions of characteristic of subjects (n=84)

Variable

Gingivitis Periodontitis

P value*Pre-
menopause 

(n=6)

Peri-
menopause 

(n=14)

Post-
menopause 

(n=6)

Pre-
menopause 

(n=20)

Peri-
menopause 

(n=26)

Post-
menopause 

(n=12)

Age  
(years)

46.33 
(2.73)

52.13 
(2.28)

62.50 
(3.73)

45.95 
(2.26)

53.03 
(2.58)

60
(2.27)

-

Teeth 26.83 (2.40) 26.79 (3.56) 23.33 (2.66) 26.60 (3.35) 24.38 (2.33) 21.75 (1.36) -

PI
0.43

(0.20)
0.52

(0.16)
0.45

(0.19)
2.81

(1.29)
2.86

(0.51)
3.04

(1.67)
-

pH
6.92

(0.08)
6.82

(0.13)
6.92

(0.08)
7.21

(0.17)
7.18

(0.14)
7.24

(0.14)
0.000*

DPD  
(nmol/l)

61.91 
(1.74)

77,28 
(9,26)

72.41 
(2.14)

92,17 
(9,21)

144,25 
(25,91)

107.31 
(10,00)

0.000*

Ca  
(ppm)

2.42
(0.39)

4.50
(1.07)

5.51
(0.89)

3.25
(0.68)

5.32
(0.84)

5.28
(0.99)

0.000*

P  
(ppm)

63.83 
(6.79)

67.43 
(6.97)

64.17 
(1.17)

69.55 
(4.68)

71.81 
(6.26)

67.00 
(2.22)

0.003*

Mg  
(ppm)

2.67
(2.21)

1.68
(0.16)

1.22
(0.08)

1.64
(0.23)

0.99
(0.25)

0.96
(0.21)

0.000*

Na  
(ppm)

572.17 
(12.35)

619.71 
(14.41)

621.33 
(6.65)

609.40 
(16.30)

642.73 
(20.42)

644.83 
(24.55)

0.000*

Data was expressed as a mean (SD, standard deviation) for all variables.
P value was derived from one-way analysis of variance 
* significantly different among the groups (p<0.05)
n, number of study subjects; PI, periodontal index based on Russel’s modification; pH, acid base degree of GCF; DPD, 
deoxypyridinoline; Ca, calcium; P, phosphor; Mg, magnesium; Na, sodium. 

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.v50.i3.p131-137

http://e-journal.unair.ac.id/index.php/MKG
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134 Dharmayanti and Kusumawardani/Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 131–137

According to a correlation analysis (Table 2), a 
correlation existed in most of the variables between 
the periodontal disease of menopausal women and pH. 
Although the correlation power varied for each variable, 
the levels of DPD, calcium, magnesium, and sodium 
demonstrated a significant and strong correlation with 
menopausal women suffering from periodontal diseases 
(p<0.05, R2>0.5), except for phosphor which had a 
moderate correlation with menopausal women presenting 
periodontal diseases (p<0.05, R2=0.3). Moreover, DPD, 
phosphor, magnesium, and sodium levels demonstrated 
a significant correlation (p<0.05) and varying correlation 
power with the pH of GCF, a weak to strong correlation. 
However, there was correlation between the calcium level 
and pH of GCF (p>0.05, R2<0.1) (Table 2).

discussion

This study confirmed gingival sulcus microenvironment 
changes indicated by significant pH shifts in the GCF. 
The pH of GCF in menopausal women with periodontitis 
was more alkaline than that of counterparts suffering 
from gingivitis (Table 1). This could be due to initial 
inflammation in gingival triggered by acid-sensitive 
proteolytic bacteria colonization, such as Porphyromonas 
gingivalis, in the gingival sulcus area where the bacteria 
induced protein metabolism and increased the pH of the 
GCF. Saccharolytic bacteria, Fusobacterium nucleatum and 
Prevotella intermedia, are initially colonized on the surface 
of periodontal pocket and decrease the pH in the gingival 
sulcus area. The acidity is caused by the bacteria utilizing 
glucose in that location and producing lactic acid. There 
is subsequent bacteria change to asaccharolytic bacteria 
colonization, Porphyromonas gingivalis. These bacteria 
result in the fermentation of amino acids into organic acids 
generating a high pH.8

In the present study, the highest level of DPD was found 
in perimenopausal subjects with periodontitis. Moreover, 
the DPD level in such subjects was higher than that in 
subjects suffering from gingivitis. Statistically, menopausal 
women with gingivitis demonstrated a similar DPD 
level. However, menopausal women with periodontitis 
presented a significant difference in DPD levels. This might 
provoke alveolar bone loss during the menopause with the 
periodontitis related to inflammation in periodontal tissue 
exacerbating estrogen deficiency in menopausal women. 
Moreover, differences existed in the collagen composition 
between the gingiva and alveolar bone, where the gingiva 
is largely composed of type I, III and V, with collagen and 
alveolar bone and periodontal ligament being formed from 
type I collagen. In contrast, DPD is a collagen cross-link 
of bone-specific type I collagen, resulting in high levels of 
DPD level in menopausal women with periodontitis.1

With regard to GCF mineral level observation, the study 
showed that the levels of minerals (calcium, phosphor and 
sodium) in the GCF of menopausal women with gingivitis 
were significantly lower than in those of menopausal women 
with periodontitis (p<0.05). Magnesium level in the GCF of 
menopausal women with gingivitis was significantly higher 
than in their counterparts with periodontitis (p<0.05). These 
variations might be related to the severity of inflammation 
and hormonal changes in menopausal women. 

The highest calcium level occurred in post-menopausal 
women with gingivitis, the calcium level of periodontitis was 
higher than gingivitis. Furthermore, the calcium level was 
statistically similar in perimenopausal and postmenopausal 
women with periodontitis (p>0.05). The calcium level 
in GCF in perimenopausal and postmenopausal females 
was higher than in their premenopausal counterparts with 
periodontitis and gingivitis. This suggests that the levels 
of steroid sex hormones and estrogen, in perimenopausal 
and postmenopausal individuals, are influenced to a greater 
extent by the calcium level in GCF than by the inflammation 

Table 2. Association between periodontal disease in menopausal women and pH to DPD level and minerals in GCF

Variable
Periodontal diseases in menopausal womena pHb

β coefficient R square P value* β coefficient R square P value*

DPD (nmol/l) 24.399 0.569‡ 0.000* -481.999 0.521‡ 0.000*

Ca (ppm) 1.479 0.698‡ 0.039* 1.042 0.077 0.242

P (ppm) 71.543 0.332† 0.035* 21.591 0.236# 0.015*

Mg (ppm) 3.174 0.634‡ 0.000* 7.300 0.337† 0.001*

Na (ppm) 541.929 0.512‡ 0.000* 381.217 0.267# 0.007*

a Multiple regression test 
b Pearson’s correlation test
β coefficient was adjusted for periodontal disease, menopause phase, pH of GCF
* significant correlation between variables (p<0.05)
#significant but weak correlation
†significant and moderate correlation 
‡significant and strong correlation
pH, acid base degree of GCF; DPD, deoxypyridinoline; Ca, calcium; P, phosphor; Mg, magnesium; Na, sodium. 

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.v50.i3.p131-137

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p131-137


135135Dharmayanti and Kusumawardani/Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 131–137

process of periodontal disease. Moreover, estrogen levels 
tend to fluctuate during the perimenopausal phase before 
stabilizing fully in the postmenopausal phase. Calcium 
enhancement was associated with calcium ion mobilization 
from bone surface to extracellular fluid, thereby inducing 
bone loss. Several studies have suggested that estrogen 
deficiency in perimenopausal and postmenopausal women 
inhibited calcium absorption on bone surfaces and induced 
alveolar bone destruction. Inhibition of calcium absorption 
may cause calcium on the bone surface to be released. This 
calcium may subsequently be discharged into the immediate 
blood stream and then be excreted through the epithelium 
of gingival into the sulcus gingiva that is dissolved in 
GCF.12,13 The amount of calcium release in GCF depends 
on the GCF flow during periodontitis which is higher than 
during gingivitis. The higher the GCF flow, the greater the 
calcium level in GCF.14

Although the study revealed no significant differences 
between the phosphor level of GCF in the groups (p>0.05), 
the phosphor level of perimenopausal women with 
periodontal diseases was higher than that of their pre- 
and postmenopausal counterparts. This could be related 
to calcium levels in GCF whose phosphor, in phosphate 

form, iss often bound with calcium. If the calcium level in 
GCF increases, the phosphor level in GCF also rises. Most 
phosphor is located in bones and teeth, about 85% of the 
total within the human body, with small amounts bound 
with calcium, magnesium, and sodium in extracellular 
fluid.15 Changes in phosphor levels can often be associated 
with bone and teeth disorders. However, phosphor levels 
in the osteoporosis serum of postmenopausal women was 
lower than that of their counterparts without osteoporosis.16 

Calcium and phosphate homeostasis is related to the 
biological effects of calctonin in bone metabolism.17

In this study, the lowest magnesium level in GCF was 
during the post-menopause with periodontitis phase. The 
level of periodontitis was significantly lower than that of 
gingivitis in menopausal women. However, perimenopausal 
women with gingivitis had a statistically similar magnesium 
level to that of pre- and postmenopausal women with 
periodontitis (p>0.05). It is suggested that inflammation 
and estrogen deficiency could decrease the magnesium 
level in GCF and cause bone loss. Magnesium is one of the 
minerals involved in bone turnover that plays a role in bone 
formation.17 Magnesium deficiency inhibits osteocalcin 
synthesis and secretion, subsequently inducing disruption of 

Figure 1. Bar diagrams showing deoxypyridinoline and mineral levels in GCF and the significant differences in inter-group comparisons 
of: a) deoxypyridinoline levels b) calcium levels c) phosphor levels d) magnesium levels and e) sodium levels. Data presented 
includes: mean and standard errors and significant differences of the LSD multiple comparison test. * Significant differences 
in the gingivitis and periodontitis of menopausal women (p<0.05); † Significant differences in periodontitis (p<0.05) in 
menopausal women; § Significant differences in gingivitis (p<0.05) in menopause women; * Significant differences in 
gingivitis and periodontitis in menopausal women (p<0.05) except for gingivitis in perimenopausal individuals and gingivitis 
and periodontitis in one menopausal phase; † Significant difference in periodontitis of menopausal women (p<0.05) except 
in one menopausal phase; § Significant difference in the gingivitis of menopausal women (p<0.05) except in one menopausal 
phase.

13 
 

 
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en

op
au

se

Po
st

m
en

op
au

se

Gingivitis Periodontitis

N
a 

L
ve

l o
f G

C
F

  
(p

pm
) 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 1. Bar diagrams showing deoxypyridinoline and mineral levels in GCF and the significant differences 
in inter-group comparisons of: a) deoxypyridinoline levels b) calcium levels c) phosphor levels d) 
magnesium levels and e) sodium levels.  
Data presented includes: mean and standard errors and significant differences of the LSD multiple 
comparison test. * Significant differences in the gingivitis and periodontitis of menopausal women (p<0.05); 
† Significant differences in periodontitis (p<0.05) in menopausal women; § Significant differences in 
gingivitis (p<0.05) in menopause women; *ʹ Significant differences in gingivitis and periodontitis in 
menopausal women (p<0.05) except for gingivitis in perimenopausal individuals and gingivitis and 
periodontitis in one menopausal phase; †ʹ Significant difference in periodontitis of menopausal women 

a b 

c d 

e 

13 
 

 
  

  

† 

† 

0
20
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Pr
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Gingivitis Periodontitis

 D
P

D
 L

ev
el

 in
 G

C
F

 
 (n

m
ol

/ L
) 

§ 

§ 
§ 

  

  † 

0
1
2
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Pr
em

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op

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op
au

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Po
st

m
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op
au

se

Gingivitis Periodontitis

C
a 

L
ev

el
 in

 G
C

F
  

(p
pm

) 

   
    

0
10
20
30
40
50
60
70
80

Pr
em

en
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se

Pe
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m
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st

m
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au

se

Gingivitis Periodontitis

P
 L

ev
el

 in
 G

C
F

  
(p

pm
) 

§ 

§ 
§ 

  

    

0
0,5

1
1,5

2
2,5

3

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em

en
op

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se

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op
au

se

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st

m
en

op
au

se

Gingivitis Periodontitis

M
g 

L
ev

el
 in

 G
C

F
  

(p
pm

) 

§ 
§ §   

  † 

0
100
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300
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600
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800

Pr
em

en
op

au
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Pe
ri

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se

Pr
em

en
op

au
se

Pe
ri

m
en

op
au

se

Po
st

m
en

op
au

se

Gingivitis Periodontitis

N
a 

L
ve

l o
f G

C
F

  
(p

pm
) 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 1. Bar diagrams showing deoxypyridinoline and mineral levels in GCF and the significant differences 
in inter-group comparisons of: a) deoxypyridinoline levels b) calcium levels c) phosphor levels d) 
magnesium levels and e) sodium levels.  
Data presented includes: mean and standard errors and significant differences of the LSD multiple 
comparison test. * Significant differences in the gingivitis and periodontitis of menopausal women (p<0.05); 
† Significant differences in periodontitis (p<0.05) in menopausal women; § Significant differences in 
gingivitis (p<0.05) in menopause women; *ʹ Significant differences in gingivitis and periodontitis in 
menopausal women (p<0.05) except for gingivitis in perimenopausal individuals and gingivitis and 
periodontitis in one menopausal phase; †ʹ Significant difference in periodontitis of menopausal women 

a b 

c d 

e 

13 
 

 
  

  

† 

† 

0
20
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100
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Pr
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au

se

Po
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m
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Gingivitis Periodontitis

 D
P

D
 L

ev
el

 in
 G

C
F

 
 (n

m
ol

/ L
) 

§ 

§ 
§ 

  

  † 

0
1
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Pr
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m
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Po
st

m
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op
au

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Gingivitis Periodontitis

C
a 

L
ev

el
 in

 G
C

F
  

(p
pm

) 

   
    

0
10
20
30
40
50
60
70
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Pr
em

en
op

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op
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au
se

Pe
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m
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se

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st

m
en

op
au

se

Gingivitis Periodontitis

P
 L

ev
el

 in
 G

C
F

  
(p

pm
) 

§ 

§ 
§ 

  

    

0
0,5

1
1,5

2
2,5

3

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em

en
op

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m
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em

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m
en

op
au

se

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st

m
en

op
au

se

Gingivitis Periodontitis

M
g 

L
ev

el
 in

 G
C

F
  

(p
pm

) 

§ 
§ §   

  † 

0
100
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300
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Pr
em

en
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Pe
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em

en
op

au
se

Pe
ri

m
en

op
au

se

Po
st

m
en

op
au

se

Gingivitis Periodontitis

N
a 

L
ve

l o
f G

C
F

  
(p

pm
) 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 1. Bar diagrams showing deoxypyridinoline and mineral levels in GCF and the significant differences 
in inter-group comparisons of: a) deoxypyridinoline levels b) calcium levels c) phosphor levels d) 
magnesium levels and e) sodium levels.  
Data presented includes: mean and standard errors and significant differences of the LSD multiple 
comparison test. * Significant differences in the gingivitis and periodontitis of menopausal women (p<0.05); 
† Significant differences in periodontitis (p<0.05) in menopausal women; § Significant differences in 
gingivitis (p<0.05) in menopause women; *ʹ Significant differences in gingivitis and periodontitis in 
menopausal women (p<0.05) except for gingivitis in perimenopausal individuals and gingivitis and 
periodontitis in one menopausal phase; †ʹ Significant difference in periodontitis of menopausal women 

a b 

c d 

e 

13 
 

 
  

  

† 

† 

0
20
40
60
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100
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Pr
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au

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Gingivitis Periodontitis

 D
P

D
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ev
el

 in
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C
F

 
 (n

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/ L
) 

§ 

§ 
§ 

  

  † 

0
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m
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st

m
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Gingivitis Periodontitis

C
a 

L
ev

el
 in

 G
C

F
  

(p
pm

) 

   
    

0
10
20
30
40
50
60
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Pr
em

en
op

au
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Pe
ri

m
en

op
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m
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au
se

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m
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se

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m
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se

Gingivitis Periodontitis

P
 L

ev
el

 in
 G

C
F

  
(p

pm
) 

§ 

§ 
§ 

  

    

0
0,5

1
1,5

2
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3

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em

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op

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se

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au
se

Pe
ri

m
en

op
au

se

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st

m
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op
au

se

Gingivitis Periodontitis

M
g 

L
ev

el
 in

 G
C

F
  

(p
pm

) 

§ 
§ §   

  † 

0
100
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600
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Pr
em

en
op

au
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Pe
ri

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op
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m
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Pr
em

en
op

au
se

Pe
ri

m
en

op
au

se

Po
st

m
en

op
au

se

Gingivitis Periodontitis

N
a 

L
ve

l o
f G

C
F

  
(p

pm
) 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 1. Bar diagrams showing deoxypyridinoline and mineral levels in GCF and the significant differences 
in inter-group comparisons of: a) deoxypyridinoline levels b) calcium levels c) phosphor levels d) 
magnesium levels and e) sodium levels.  
Data presented includes: mean and standard errors and significant differences of the LSD multiple 
comparison test. * Significant differences in the gingivitis and periodontitis of menopausal women (p<0.05); 
† Significant differences in periodontitis (p<0.05) in menopausal women; § Significant differences in 
gingivitis (p<0.05) in menopause women; *ʹ Significant differences in gingivitis and periodontitis in 
menopausal women (p<0.05) except for gingivitis in perimenopausal individuals and gingivitis and 
periodontitis in one menopausal phase; †ʹ Significant difference in periodontitis of menopausal women 

a b 

c d 

e 

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.v50.i3.p131-137

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p131-137


136 Dharmayanti and Kusumawardani/Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 131–137

calcium and electrolyte homeostasis. Estrogen deficiency-
related menopause could induce inflammation.16Magnesium 
levels decreased following the inflammation and severity 
of periodontal disease. 18Inflammation causes magnesium 
deficiency which increases the levels of P substances. P 
substance levels increase pro-inflammatory cytokines that 
induce osteoclast activation and bone loss.19

Sodium is contained in bone, extracellular fluid, serum 
and tissue. The sodium in bone constitutes a reserve 
source for the body and is utilized when the sodium level 
in serum is low in order to meet muscle tissue, heart and 
neural needs. Moreover, in extracellular fluid, sodium is 
the major cation which plays a role in cellular osmotic 
gradient regulation. In females, its level is affected by 
age-related hormone production.20 The sodium levels 
in this study increased in postmenopausal women with 
periodontal diseases. Statistically, there were significant 
differences in sodium levels between the groups (p<0.05), 
except for perimenopausal women with gingivitis compared 
to postmenopausal women with gingivitis, premenopausal 
women with periodontitis compared to postmenopausal 
women with gingivitis and perimenopausal women with 
periodontitis compared to postmenopausal women with 
gingivitis (p>0.05). It was suggested that menopause-related 
estrogen deficiency affected sodium levels in GCF. Sodium 
level in the GCF of periodontitis patients was higher than 
in that of individuals with gingivitis. It was suggested that 
the change was related to GCF flow rate which is higher in 
cases of periodontitis compared to gingivitis. Consequently, 
the amount of sodium extracted from intracellular and 
extracellular sources due to GCF in periodontitis-afflicted 
patients was also higher than in their counterparts suffering 
from gingivitis.14 Borras described how the sodium level in 
GCF correlated with loss attachment in periodontal disease 
with sodium in GCF passing through damaged connective 
and alveolar bone tissue.21 Moreover, sodium served as a 
transporter of other ions, such as calcium, magnesium, and 
phosphor, enabling them to pass through cell membranes 
and the epithelium cell layer.8

Based on the results of the correlation test, significant 
correlation existed between DPD and minerals in the GCF 
of menopausal women with periodontal disease and the 
pH of GCF. However, there was no significant correlation 
between the calcium levels and pH of GCF. This might be 
explained by certain roles of calcium in GCF. Two major 
points of view exist regarding calcium levels in GCF. In 
the first, calcium enhancement is associated with calcium 
ion mobilization from bone surface to extracellular fluid 
inducing bone loss. Bone loss also occurs during the 
menopause because of periodontal disease. Menopause-
related estrogen deficiency causes oral microenvironment 
changes triggering bacteria colonization on dental surface 
and gingival tissue. It also results in the loss of estrogen 
receptors on periodontal tissue that play a role in fibroblast 
proliferation and differentiation. Bacteria colonization 
and virulence-induced inflammation and host response 

both activate cytokine pro-inflammation and induce bone 
matrix degradation and bone destruction. Furthermore, the 
cytokines cause altered permeability in the junctional and 
sulcular epithelium with spaces between cells becoming 
wider, so that intercellular and extracellular components, 
such as leukocytes, electrolyte, bone degradation products 
and inorganic bone matrix components pass through the 
epithelium to the sulcus gingival area.1,5,8 

It was also revealed that the calcium level increased in 
GCF owing to plaque genesis.14 Initially, the colonization of 
saccharolytic bacteria on dental surfaces altered the acidity 
of GCF and induced inflammation. This condition promoted 
bacterial colonization, by saccharolytic and asaccharolytic 
strains, which resulted in the alkalinity of GCF. Changes 
in pH to alkaline induced the proliferation of anaerobic 
bacteria which were acid sensitive and whose products 
negatively affected calcium absorption resulting in calcium 
being excreted into GCF. Nevertheless, calcium in GCF 
promoted protein precipitation on enamel surfaces whose 
accumulation causes dental plaque and calculus.8,14

Furthermore, changes in the mineral component in 
GCF might be related with the symptoms of menopause 
that middle-aged women often report. In this study, 
perimenopausal and postmenopausal women with 
periodontal disease had higher calcium and phosphate 
levels than their pre-menopausal counterparts, although the 
levels found in the serum might be equal. Hypercalcemia 
and hyperphosphatemia in menopausal women result in 
cardiovascular and renal diseases.22 These conditions might 
be related to estrogen deficiency inducing oxidative stress in 
some organs. Estrogen therapy in post-menopausal women 
can, therefore, reduce cardiovascular disease.23

While in the study reported here the magnesium level 
in peri- and post-menopausal women with periodontal 
diseases was lower than that of pre-menopausal women, 
it might occur in the serum of peri- and post-menopausal 
women. Hypomagnesia associated with estrogen deficiency 
and periodontal inflammation could cause reactive 
oxidative stress (ROS) accumulation that manifests itself 
in depressive syndrome.22 Hirose et al.9 argue that the 
depressive symptoms of middle-aged women is related 
to mood disorders and oxidative stress. In conclusion, the 
DPD and mineral level in GCF could be used as disorder 
indicators in menopausal women with periodontal diseases. 
However, this study needs further research in order to 
investigate the mechanism of DPD and mineral component 
of GCF as specific and sensitive parameters for menopausal 
women.

acknowledgement

This research was supported by an Universitas Jember 
Research Grant. 

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.v50.i3.p131-137

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p131-137


137137Dharmayanti and Kusumawardani/Dent. J. (Majalah Kedokteran Gigi) 2017 September; 50(3): 131–137

references 

 1.  Dharmayanti AWS. Deoxypyridinoline level in gingival crevicular 
fluid as alveolar bone loss biomarker in periodontal disease. Dent J 
(Maj Ked Gigi). 2012; 45(2): 102–6. 

 2.  Mariotti A. Sex steroid hormones and cell dynamics in the 
periodontium. Crit Rev Oral Biol Med. 1994; 5(1): 27–53. 

 3.  Markou E, Eleana B, Lazaros T, Antonios K. The influence of 
sex steroid hormones on gingiva of women. Open Dent J. 2009; 3: 
114–9.

 4.  Yoshihara A, Hayashi Y, Miyazaki H. Relationships among bone 
turnover, renal function and periodontal disease in elderly Japanese. 
J Periodontal Res. 2011; 46: 491–6. 

 5.  Bhardwaj A, Bhardwaj S. Effect of menopause on women's 
periodontium. J Midlife Health. 2012; 3(1): 5–9. 

 6.  Guiglia R, Di-Fede O, Lo-Russo L, Sprini D, Rini G, Campisi G. 
Osteoporosis, jawbones and periodontal disease. Med Oral Patol 
Oral Cir Bucal. 2013; 18(1): e93–9. 

 7.  Khurshid Z, Mali M, Naseem M, Najeeb S, Zafar M. Human gingival 
crevicular fluids (GCF) proteomics: an overview. Dent J. 2017; 5: 
1–8. 

 8.  Barros SP, Williams R, Offenbacher S, Morelli T. Gingival crevicular 
as a source of biomarkers for periodontitis. Periodontol 2000. 2016; 
70(1): 53–64. 

 9.  Hirose A, Terauchi M, Akiyoshi M, Owa Y, Kato K, Kubota T. 
Depressive symptoms are associated with oxidative stress in middle-
aged women: a cross-sectional study. Biopsychosoc Med. 2016; 10: 
1–6. 

10.  Phipps AI, Ichikawa L, Bowles EJA, Carney PA, Kerlikowske 
K, Miglioretti DL, Buist DSM. Defining menopausal status in 
epidemiologic studies: a comparison of multiple approaches and 
their effects on breast cancer rates. Maturitas. 2010; 67(1): 60–6. 

11.  Ardiani DK, Dharmayanti AWS, Pujiastuti P. Kadar fosfor (P) dalam 
cairan sulkus gingiva pada penderita penyakit periodontal. IDJ. 2014; 
3(1): 1–9.

12.  Sharma R, Sharma P, Kumar P, Gupta G. Role of magnesium in 
post-menopausal women with osteoporosis and osteopenia. Asian 
J Pharm Clin Res. 2016; 9:198–9.

13.  Hosthor SS, Mahesh P, Priya SA, Sharada P, Jyotsna M, Chitra S. 
Quantitative analysis of serum levels of trace elements in patients 
with oral submucous fibrosis and oral squamous cell carcinoma : a 
randomized cross-sectional study. J Oral Maxillofac Pathol. 2014; 
18(1): 46–51. 

14.  Koregol AC, More SP, Nainegali S, Kalburgi N, Verma S. Analysis of 
inorganic ions in gingival crevicular fluid as indicators of periodontal 
disease activity: a clinico-biochemical study. Contemp Clin Dent. 
2011; 2(4): 278–82. 

15.  Penido MGMG, Alon US. Phosphate homeostasis and its role in 
bone health. Pediatr Nephrol. 2012; 27: 2039–48. 

16.  Razmandeh R, Nasli-Esfahani E, Heydarpour R, Faridbod F, Ganjali 
MR, Norouzi P, Larijani B, Khoda-Amorzideh D. Association of 
zinc, copper and magnesium with bone mineral density in Iranian 
postmenopausal women – a case control study. J Diabetes Metab 
Disord. 2014; 13: 1–6.

17.  Gur A, Colpan L, Nas K, Cevik R, Sarac J, Erdogan F, Duz MZ. 
The role of trace minerals in the pathogenesis of postmenopausal 
osteoporosis and a new effect of calcitonin. J Bone Min Metab. 2002; 
20: 39–43. 

18.  K asu ma N. Cor relat ion bet we en mag nesiu m a nd a l ka l i ne 
phosphatase from gingival crevicular fluid periodontal diseases. 
Dent J (Maj Ked Gigi). 2015; 48(3): 130–4. 

19.  He LY, Zhang XM, Liu B, Tian Y, Ma WH. Effect of magnesium 
ion on human osteoblast activity. Braz J Med Biol Res. 2016; 49(7): 
1–6. 

20.  Fijorek K, Püsküllüoğlu M, Tomaszewska D, Tomaszewski R, Glinka 
A, Polak S. Serum potassium, sodium and calcium levels in healthy 
individuals - literature review and data analysis. Folia Med Cracov. 
2014; 54(1): 53–70. 

21.  Boras VV, Brailo V, Rogić D, Puhar I, Bosnjak A, Badovinac A, 
Rogulj AA. Salivary electrolytes in patients with periodontal disease. 
RJPBCS. 2016; 7(2): 8–14.

22.  Moe SM. Disorders involving calcium, phosphorus, and magnesium. 
Prim Care. 2008; 35(2): 1–19. 

23.  Terauchi M, Honjo H, Mizunuma H, Aso T. Effects of oral estradiol 
and levonorgestrel on cardiovascular risk markers in postmenopausal 
women. Arch Gynecol Obstet. 2012; 285: 1647–56. 

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.v50.i3.p131-137

http://e-journal.unair.ac.id/index.php/MKG
http://dx.doi.org/10.20473/j.djmkg.v50.i3.p131-137