Vol 49 No 3 Juli-Sept 2016.indd


133133

Research Report

Dental Journal
(Majalah Kedokteran Gigi)
2016 September; 49(3): 133–136

Topical application of 1% ZnSO4 on oral ulcers increases the 
number of macrophages in normal or diabetic conditions of 
wistar rats

Rochman Mujayanto,1 Kus Harijanti,2 and Iwan Hernawan2
1Department of Oral Medicine, Faculty of Dentistry, Universitas Islam Sultan Agung, Semarang-Indonesia
2Department of Oral Medicine, Faculty of Dental Medicine, Universitas Airlangga, Surabaya-Indonesia

ABSTRACT

Background: Therapy for chronic ulcer in diabetic patient is by modifying local inflammation response using drugs that acts as 
immunomodulator, neuromodulator and growth factors stimulator. Topical zinc is one of drug that can modifiy local inflammation 
response, immunostimulation or immunosuppresion. Purpose: This study was to prove about the number of macrophage in oral ulcer 
between normal and diabetes microscopically and the difference if treated by 1% ZnSO4 gel topically. Method: Ulcer in lower labial 
mucosa was made in normal and diabetic Wistar rats (induced by STZ), then applied 1% ZnSO4 gel and CMC-Na gel as control. They 
were decapitated in third and fifth day and specimen was made by processing lower labial mucosa Result: Microscopically, the result 
showed the number of macrophages in oral ulcer in diabetic condition was significantly higher than normal and the application of 
1% ZnSO4 increased the number of macrophages in fifth day. Conclusion: The number of macrophages was higher in diabetic than 
normal condition, and was proven that topical application of 1% ZnSO4 increased the number macrophages of oral ulcer diabetic 
and normal condition.

Keywords: macrophage; diabetes; ZnSO4 1% gel

Correspondence: Rochman Mujayanto, Department of Oral Medicine, Faculty of Dentistry, Universitas Islam Sultan Agung. 
Jl. Kaligawe Km 4,5 Semarang 50164, Indonesia. E-mail: rochman.mujayanto@unissula.ac.id.

INTRODUCTION

Chronic ulcers is one of complications experienced 
by diabetic patients. It is caused by a deviating local 
inflammatory response which is marked by the number of 
persistent inflammatory cells. This condition is caused by 
a decreased chemokine expression which, in turn, leads 
to a slower production of growth factor and a slower 
inflammatory cell infiltration.1,2 The amount of persistent 
macrophages in a diabetic condition influences the healing 
process of ulcers, resulting in a continuous cell deterioration 
and increasing expressions of interleukin-1β (IL-1β), tumor 
necrosis factor-α (TNF-α) and matrix metalloproteinases 
(MMPs).3-5

A study proposed a calculation of macrophages in ulcers 
both in normal and diabetic conditions using a mathematical 
formula, concluding that the amount of macrophages in the 

 

 

 
 

diabetic condition keeps increasing and thus becomes more 
persistent than the normal condition’s. The model study,
however, the formula has not been proven.6

  Polyuria  in  diabetic  patients  causes  excessive 
Zn  excretion  (hyperzincuria),5,7-11 resulting  in  Zn 
deficiency.12,13 The  topical  Zn  application  on  ulcer  of  a
diabetic  patient  helps  the  healing  process  more  than  the
systemic  Zn  application.11 The  topical  Zn  application 
on  ulcer  will  increase  the  concentration  bioavailability 
of  Zn  approximately  1.000-3.000 μmol/L. Zn  may  help 
autodebridement process, influencing MMP to eliminate 
any necrotic tissues and facilitate keratinocyte migration
in the re-epitelisation process.8

Zinc sulphate (ZnSO4) is one of active substances that
can be topically absorbed by oral mucosa and recommended
to  heal  oral  ulcers  and  prevent  recurrent  ones.14-16 The 
topical application of 0,5% ZnSO4 for oral suspension is

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.i3.p133-136

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134 Mujayanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 September; 49(3): 133–136

effective in reducing oral lesions in patients with oral herpes 
simplex.17 The gels of 1% ZnSO4 may reduce perioral 
lesions and pains of any patients who infected by herpes 
simplex virus (HSV),18,19 and speed up the healing process 
of post dental extraction scars by reducing the amount of 
macrophages and increasing fibroblast poliferation as well 
as capillaries.20

This study aimed to microscopically observe differences 
in the amount of macrophages in both normal and diabetic 
conditions and the influences of topical 1% ZnSO4 on the 
amount of macrophages in the diabetic rats’ oral ulcers.

MATERIALS AND METHOD 

The method employed in this research was the true 
experimental post test only control group design, using 
Wistar rats as the laboratory animals. The rats were 
divided into two groups, 24 normal Wistar rats and 24 
normal Wistar rats which later were made diabetic. The 
preparation of the laboratory animals, treatment application 
and tissues retrieval were performed in the animal house 
of the Biochemistry laboratory in the Faculty of Medicine, 
Universitas Airlangga. The tissues processing and the 
creation of histological preparation were performed in the 
laboratory of Anatomic Pathology at the regional public 
hospital of Dr. Soetomo, Surabaya. The identification and 
the calculation of the amount of the macrophages were 
performed in the laboratory of Anatomic Pathology at the 
hospital of Islam Sultan Agung Semarang.

The Wistar rats which were made diabetic had been 
fasting for 4 hours before being induced with streptozotocin 
(STZ) (bioWORLD, Dublin, Ohio, USA) dissolved into 
citric buffer at pH 4.5, in order to empty their stomachs and 
reduce the risks of aspiration. The amount of STZ needed 
was 150mg/kg of the weight of a Wistar rat, dissolved 
with a concentration of 22.5mg/ ml STZ in citrate buffer 
solutions. The STZ solutions then were injected through 
intraperitoneal according to the appropriate dose for each 
rat. The induction process was only performed once. In 
order to avoid sudden hypoglycemic post injection, the rats 
received 10% sucrose or dextrose during the first night. 
The blood sugar level of the rats during fasting hours was 
observed every morning. The fasting rats did not receive 
food and the cages were devoid of husks for six hours. Any 
meaningful hyperglicemia condition would be found two 
days post induction.21

A scar was made in the lower labial mucosa using the 
tip of round burniser in 2 mm diameter which had been 
heated for ±15 seconds with a bunsen burner. The tip of 
burnisher then was touched the lower labial mucosa of 
each Wistar rat for one second in 2 mm deep. We spread 
some gels of 20% benzocaine as a topical anesthesia in the 
lower labial mucosa of each rat 5 minutes before and after 
ulcer was made. The observations were performed at the 
24th and 48th hours after the scars being made. At the 24th 
hour observation, a decay in the lower labial mucosa with 

a thin, white base with 3 mm diameter was visible. In the 
48th hours post-trauma, a deep ulcer with a yellowish base 
in the lower labial mucosa was visible (Figure 1).

The applications of gels of sodium carboxymethyl 
cellulose (CMC Na) and 1% ZnSO4 were performed after 
the ulcers were formed in the oral mucosa of the rats. 
The gels were applied using cotton buds in the morning 
and the evening until the days when the animals’ tissues 
would be retrieved, which were the 3rd dan 5th days. The 
rats did not receive food or drink for 30 minutes after the 
gel applications.

Several Wistar rats were randomly selected from 
each group according to the predetermined amount of 
samples. The selected rats were then terminated on the 
3rd and 5th days. Their lower lips were cut and used in the 
tissues processing to produce histological preparations 
and calculated their macrophages cells. The microscopic 
preparations were observed using a microscope with a 
camera DS Fi2 300 megapixel (Nikon H600L, Konan, 
Minota-ku, Tokyo, Japan), while the tissues were calculated 
using software (Optilab.Image Raster v21, Sleman, 
Yogyakarta, Indoneisa).

A B 

Figure 1. The illustration of a macroscopic ulcer in the oral 
mucose of a rat with a scar made by the tip of burnisher 
in 2mm diameter. In the 24th hours after trauma, a scar 
of the mucose with a thin, white base in 3mm diameter 
was observed (A). In the 48th hour post-trauma, a 
deep ulcer in the mucose with a yellowish base was 
observed (B). 

Table 1. The average amount of macrophages in the treatment 
groups on the 3rd and 5th days 

3rd day 5th day

Normal + CMC Na 464 144

Diabetes + CMC Na 352 183

Normal + Zn SO4 414 303

Diabetes + Zn SO4 194 324

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.i3.p133-136

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135135Mujayanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 September; 49(3): 133–136

RESULTS

The Kolmogrov Smirnov (one-sample K-S) test showed 
that the data from each variable of each treatment group 
on the 3rd and 4th days were normally distributed. The next 
data testing employed the independent sample t test by 
comparing the data on the 3rd and 5th days from the normal 
and diabetic groups with CMC Na therapy and from the 
normal and diabetic groups with ZnSO4 therapy.

On the 3rd day, the amount of macrophages of the 
diabetic group applied with CMC showed a less meaningful 
distinction from the normal one’s, while on the 5th day, the 
amount of macrophages showed a meaningful distinction 
although it was larger than the normal group’s. In the 
comparison between the amount of macrophages with 
ZnSO4 and omitted the one with CMC Na both in the normal 
and diabetic conditions, the amount of macrophages on the 
5th day increased after the application of ZnSO4.

DISCUSSION

The macrophages in the healing process of ulcers 
manage inflammatory and angiogenesis processes. The 
macrophage proliferation responds to pathogen, hemostasis 
process in tissues, inflammation, resolution, and repair 
processes. The macrophages remove cytokines and 
growth factor which influence various cells and induce 
cytokines (anti-inflammation), glucocorticood, and glucose 
metabolism and lipid.5,22-24 During an inflammation 
in normal condition, the macrophages increase shortly 
between 3rd and 5th days.25

The macrophages coming from monocytes that migrate 
to the tissues will increase in numbers for two days (48 
hours) around an ulcer and stay there for the next five 
days. Once the inflammation can be controlled by the 
macrophages, the healing process will begin from the 3rd 
day until the 5th day, marked by the migration and increase 
of fibroblast, proliferation of endothelial cells and then the 
emergence of granulation tissue. 2,5,11,26,27

Diabetes reduces the amount or quality of insulin 
receptor or makes it resistant to peripheral tissue, resulting 
in insulin binding, or afinity, or insulin’s decreased 
sensitivity.5,7,28 The reduced quality of insulin receptor 
will disturb the functionality of mitochondria in producing 
ATP as the source of cell energy. ATP is a product of 
glucose metabolism in the intercells which enters through 
FLUT-4 in the cell membranes. GLUT-4 is activated by 
the signal transduction sent by the insulin receptor which 
is linked to insulin.28 The disturbed mitochondria may 
cause disturbances in the neutrophil apoptosis during 
the autophagocytosis process which is supported by the 
macrophages, disturbances in the macrophages migration 
to the tissue, and increase pro-inflammatory cytokine 
(IL-6 dan TNF-α) which is produced by pro-inflammatory 
macrophages (M1).1,2,4,5,22-24,28,29

A normal person’s body contains 2-3 grams of zinc 
which influences cell metabolisms. In the cell membranes, 
there is a transporter in which ionic zinc may enter 
(ZIP=Zirt-Irt-Protein) and exit (ZnT=Zinc transport) to 
maintain the amount of ionic zinc in cytoplasm. Ionic zinc 
inside the cytoplasm serves as a pro-antioxidant which 
helps zinc superoxide dismutase enzyme to scavenge ROS 
which is a sideline product of glucose metabolism (in the 
cells).30,31 

In a normal condition, the amount of zinc will increase 
15-20% in the edges of ulcer on the 24th hour after 
inflammation phase. During a formation of granulation 
tissue and epitherial proliferation, the amount of Zn will 
increase up to 30%.8 In diabetic patients, the amount of Zn 
in blood (hypozincemia) decrease which in turn will reduce 
the amount of Zn in the tissues.8,9,11,13,16

During an inflammation in diabetic patients, there 
is an increase in the amount of neutrophil that results in 
an imbalance between the amount of neutrophil and of 
macrophages. In fact, the balance between the two are 
necessary in the ulcer healing process.2 Neutrophil will 
increase dramatically on the 48th hour of the inflammation26 
and increasingly stimulate the amount of macrophages. 
After that, neutrophil will experience apoptosis.2 Deficit 

Figure 2. The average amount of macrophages in the treatment groups on the 3rd and 5th days.

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.i3.p133-136

http://dx.doi.org/10.20473/j.djmkg.v49.i3.p133-136


136 Mujayanto, et al./Dent. J. (Majalah Kedokteran Gigi) 2016 September; 49(3): 133–136

zinc will influence the amount and function of leukocyte 
(neutrophil-granulocyte/PMN and monosit) and reduce 
neutrophil chemotaxis which, in turn, will reduce the 
performance of phagocytosis.30

Therapy on chronic ulcers towards diabetic patients may 
be performed by modifying the deviating local inflammatory 
response2 with the use of several drugs which serve as 
imunomodulator, neuromodulator, and growth factors 
stimulator, during one or more phases of ulcer healing.32 
Zinc is one of the topical immunomodulators used to modify 
local immune responses which may stimulate immune 
response or suppress immune response.31,33 

Zinc serves to manage proliferation process, differentiation 
and cell apoptosis. During an inflammation phase, zinc 
helps the functions of neutrophil and macrophages. Zinc 
affects the production of pro-inflammatory cytokine (IL-1 
β, IL-6 and TNF-α) which helps chemotaxis process and 
phagocytosis of neutrophil.8,16,18,19,31,34 Ions of topical zinc 
applied to ulcers will pass epitelium after an hour, enter the 
sub-epitelium and then be absorbed in the blood circulation. 
The deeper the damage in epitelium is, the more zinc will 
enter blood circulation.8 

Zinc influnces chemokine phorbol myristate acetate 
(PMA) which serves a role in the attachment of monocyte 
in the endothelial cells and monocyte chemoattractant 
protein-1 (MCP-1) which serves in the monocyte 
migration to the tissue, becoming macrophages. Zinc in 
the monocyte-macrophages serves as a pro-inflammation 
or anti-inflammation, depending on its concentration in the 
cells,34,35 but not an antioxidant and does not take part in 
phagocytosis.31 Diabetic patients are recommended to use 
topical zinc application to heal their ulcers.8,11

In conclusion, the amount of macrophages in the 
diabetic condition was greater than the one in the normal 
condition microscopically. The application of 1% ZnSO4 
increased the amount of macrophages in both normal and 
diabetic conditions, and clinically the application of 1% 
ZnSO4 showed a faster ulcer recovery process in the oral 
mucosa.

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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.i3.p133-136

http://dx.doi.org/10.20473/j.djmkg.v49.i3.p133-136