78

Dental Journal
(Majalah Kedokteran Gigi)

2021 June; 54(2): 78–81

Original article

Effect of formula milk on the roughness and hardness of tooth 
enamel

Amaliyah Nur Irianti, Sri Kuswandari and Al Supartinah Santoso 

Department of Pediatric Dentistry, 
Faculty of Dentistry, Universitas Gadjah Mada,
Yogyakarta – Indonesia

ABSTRACT
Background: Demineralisation and remineralisation is a natural process in tooth enamel. It is influenced by the content of calcium 
and phosphorus in saliva, which concentrations are affected by the consumption of food, including formula milk. Demineralisation and 
remineralisation determine the roughness and hardness of the enamel surface. Purpose: This study compared the effect of formula milk 
on the roughness and hardness of tooth enamel. Methods: Maxillary premolar extracted teeth were demineralised with 37% phosphoric 
acid for 90 seconds and then divided into four treatment groups. For four days, the teeth were immersed twice a day in cow formula 
for five and ten minutes (Group I and II) and soy formula for five and ten minutes (Group III and IV). Before and after the immersion 
in milk, the teeth were submerged in artificial saliva. The enamel surface roughness and hardness were measured three times using a 
surface roughness tester and a Vickers microhardness tester, before and after demineralisation and after immersion in milk. Data were 
analysed using Kruskal–Wallis and post hoc Mann–Whitney tests. Results: There was no significant difference (p=0.88) observed in 
the roughness reduction among the treatment groups. The highest increase in hardness was noted for the ten-minute cow formula milk 
group (93.27 ± 16.00). The increase of hardness was higher after immersion for ten minutes. A substantial difference (p=0.03) was 
seen in the increase of hardness between the treatment groups. Conclusion: Immersion in cow and soy formula milk for five and ten 
minutes does not reduce the enamel roughness, but it increases the enamel hardness.

Keywords: demineralisation; enamel hardness; enamel roughness; milk formula; remineralisation

Correspondence: Sri Kuswandari, Department of Pediatric Dentistry, Faculty of Dentistry, Universitas Gadjah Mada. Jl. Denta 1,    
Sekip Utara, Bulaksumur, Yogyakarta, 55281 Indonesia. Email: kuswandarisri@gmail.com

INTRODUCTION

Enamel is the outermost tooth layer and the hardest 
tissue in the human body. The components in enamel 
are inorganic materials (95%), organic materials (1–2%) 
and water (2–4%). Most of the inorganic materials are 
hydroxyapatite (Ca10(PO4)6(OH)2) crystals containing 
mineral ions, especially calcium and phosphate.1 Saliva 
is a source of calcium and phosphate, which maintains 
the mineral saturation of teeth. Its role is to inhibit 
demineralisation at low pH and to initiate remineralisation 
when the pH returns to normal.2 Demineralisation is                                                             
the process of removing mineral ions, especially 
calcium and phosphate, from the hydroxyapatite (HA)                                                                                                   
crystals of the tooth enamel. Remineralisation is the 

process of restoring the mineral ions in the HA crystals.3 
The required calcium and phosphate can be obtained                           
from the consumption of food and drink, including formula 
milk.

Formula milk is frequently consumed by children. 
It contains protein, fat, calcium, phosphorus, zinc and 
other minerals. The calcium ions that are present in saliva 
have a buffering effect on dental plaque, preventing 
demineralisation and promoting remineralisation.4 Formula 
milk is made from animal milk or plants such as soybean. 
Some children are allergic to animal milk lactose, therefore 
they consume milk derived from plants, such as soy milk.5 
Soy milk contains more protein, but the amino acids are 
not as complete as in cow protein.  The calcium content is 
also lower than in cow milk.6

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i2.p78–81

mailto:kuswandarisri@gmail.com
https://e-journal.unair.ac.id/MKG/index
http://dx.doi.org/10.20473/j.djmkg.v54.i2.p78-81


79Irianti et al./Dent. J. (Majalah Kedokteran Gigi) 2021 June; 54(2): 78–81

Milk can decrease the pH of plaque ten minutes 
after being consumed because of the fermentation of 
carbohydrates. The pH will increase 20 minutes later 
because hydrolysis of milk protein occurs.7 There are 
various ways for infants and children to consume formula 
milk, such as bottle feeding, spoon feeding, drinking 
using a straw or cup feeding. In this way, a contact is 
established between milk and teeth. The longer and more 
frequently milk is consumed, the longer the enamel is 
exposed to calcium and phosphorus, which results in higher 
remineralisation.8 

Surface roughness and hardness indirectly indicate the 
occurrence of demineralisation and remineralisation of 
hard tooth tissue.9  Demineralisation in enamel starts with 
the release of minerals, especially calcium and phosphate, 
which causes the surface to become softer and rougher.10 
Hardness is defined as the resistance of a solid material 
to penetration.11 Calcium and phosphate ions form HA 
crystals in enamel and the number of HA crystals formed 
affects the thickness of the enamel.12 The purpose of this 
study was to compare the different effects of immersion in 
cow milk formula and soy formula on the roughness and 
hardness of the enamel surface.

MATERIALS AND METHODS

This is a quasi-experimental laboratory (in vitro) study 
using 12 caries-free maxillary premolar extracted teeth. 
After separating from the root, the crown was cut 
mesiodistally to obtain the labial and lingual surfaces and 
then cultivated in resin. In this way, 24 specimens were 
prepared. The enamel surface was coated with nail polish, 
except for a circular work area with a diameter of 5 mm.5 
The first measurement of roughness and hardness of the 
enamel surface was done prior to the demineralisation 
with 37% phosphoric acid (H3PO4) for 90 seconds.

13 Then, 
specimens were immersed for three hours in artificial saliva 
with a pH of 7.0. Thereafter, the second measurement was 
done. The specimens were grouped into four treatment 
groups. Group I was immersed in cow formula milk 
for five minutes and group II for ten minutes. Group III 
was immersed in soy formula milk for five minutes and 
group IV for ten minutes. For four days, the immersion 
was done twice a day (07:30 and 16:30) at a temperature 

of 37 °C.8 The milk was produced by Morinaga™ (PT. 
Kalbe Morinaga, Indonesia). The composition of both 
milk formulas was similar, namely, calcium, phosphorus, 
magnesium, iron, zinc and docosahexaenoic acid (DHA) 
in the same proportions, but the soy formula contained also 
arachidonic acid (AA), phospholipids, nucleotides, and 
other ingredients. The third measurement was done after 
the immersion was completed.

The surface roughness of the tooth enamel was measured 
using a surface roughness tester (Starrett SR300, Taylor 
Hobson, Berwyn, PA, USA).13 The value of the roughness 
was obtained from the motion signal of a diamond-shaped 
stylus moving along a straight line on the enamel surface. 
The roughness was expressed as roughness average (Ra) 
and stated in μm. The roughness was measured at three 
different points on each research object. The magnitude of 
indentation was determined using a microhardness tester 
(HMV-2, Shimadzu, Japan) by looking at the area of the 
imprint on the indenter. A load of 100 grams was applied 
for ten seconds onto the enamel surface.8,14 The enamel 
surface hardness was obtained from the tooth resistance 
to indentation. The units in the enamel surface hardness 
test were expressed in Vickers hardness (HV). The enamel 
surface hardness was measured at three different points on 
each research object and obtained as an average of three 
measurements. The data were analysed using the Kruskal–
Wallis test (p<0.05) and the post hoc Mann –Whitney test 
(p<0.05).

RESULTS

The Kruskal–Wallis test on mean and standard deviation 
of surface roughness reduction based on milk type and 
immersion time (Table 1) showed no significant difference 
(p>0.05) between the treatment groups. The largest average 
reduction in enamel surface roughness was observed after 
immersion in soy formula for ten minutes, followed by 
immersion in cow and soy formula for five minutes. The 
reduction in surface roughness was lowest after immersion 
in cow formula for ten minutes, namely 0.21 ± 0.06.

The Kruskal–Wallis test on mean and standard 
deviation of increased surface hardness based on milk 
type and immersion time (Table 2) exhibited a significant 
difference (p< 0.05) between the treatment groups.                                                                       

Table 1. The averages and standard deviations of the enamel surface roughness based on formula milk and immersion time and the 
Kruskal–Wallis test results in μm

Treatment group N
Before immersion 

(x ± SD)
After immersion 

(x ± SD)
Reduction of enamel surface 

roughness (x ± SD)
Kruskal–Wallis test

X2 Df p
Group I 6 0.98 ± 0.29 0.73 ± 0.22 0.25 ± 0.18

0.66 3 0.82
Group II 6 0.91 ± 0.19 0.70 ± 0.15 0.21 ± 0.06

Group III 6 0.82 ± 0.20 0.57 ± 0.14 0.25 ± 0.13

Group IV 6 0.74 ± 0.12 0.48 ± 0.05 0.26 ± 0.12
Description: N: Number of research objects; Df: Degrees of freedom; X2: Chi square; p: Probability 

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i2.p78–81

https://e-journal.unair.ac.id/MKG/index
http://dx.doi.org/10.20473/j.djmkg.v54.i2.p78-81


80 Irianti et al./Dent. J. (Majalah Kedokteran Gigi) 2021 June; 54(2): 78–81

The highest average increase in hardness was observed 
after immersion in cow formula for ten minutes, namely 
93.27 ± 16.00. Using the post hoc Mann–Whitney test, 
the mean comparison of the increase in enamel surface 
hardness between the treatment groups (Table 3) displayed 
only significant differences (p<0.05) between the groups of 
teeth immersed in soy formula for five minutes and those 
immersed in cow formula for ten minutes and between the 
groups of teeth immersed in soy formula for five minutes 
and those immersed in soy milk formula for ten minutes.

DISCUSSION

The study showed that there was no significant difference 
in enamel surface roughness between the treatment groups 
using the length of time and milk immersion as variables. 
However, the enamel surface hardness differed significantly 
using the same variables. There were considerable 
differences between the groups of teeth immersed in soy 
formula for five minutes and those immersed in cow formula 
for ten minutes and between groups of teeth immersed in 
soy formula for five minutes and those immersed in soy 
milk formula for ten minutes. The results agree with those 
reported by Yendriwati et al.,8 who observed that the       
longer and the more frequently the enamel was exposed 
to calcium and phosphorus contained in drinks, the more 
minerals were incorporated into the enamel, increasing its 
hardness. 

The increase in enamel surface roughness is the result 
of increased porosity.15 When remineralisation occurs, 
calcium and phosphate ions repair the enamel damage 

caused by demineralisation.16 The formed hydroxyapatite 
crystals reduce the interprismatic gap and enamel 
microporosity, which smoothens the surface of the porous 
part and decreases the surface roughness.17 After five 
minutes, the average reduction in enamel surface roughness 
after immersion in cow formula milk was not different 
compared to that of using soy formula milk. However, 
after ten minutes, the average reduction in enamel surface 
roughness after immersion in cow formula milk was lower 
than that using soy formula milk. 

In the demineralisation process, hydroxyapatite crystals 
dissolve and release calcium and phosphate ions. This 
process results in larger interprismatic gaps and reduces the 
enamel surface hardness. When remineralisation occurs by 
incorporating calcium and phosphorus ions, hydroxyapatite 
crystals are regenerated and fill the voids. According 
to several studies, the crystals formed are amorphous 
and differ from previous hydroxyapatite crystals. This 
may increase the surface hardness of the remineralised 
enamel, but it changed the hydroxyapatite crystals.18 

The study showed that there were significant differences 
after immersing the teeth in soy formula for five and ten 
minutes. The longer immersion allows the integration of 
more calcium and phosphorus ions, which leads to a higher 
degree of the remineralisation.

Milk prevents the demineralisation process according to 
several mechanisms. Milk protein can be adsorbed onto the 
enamel surface and inhibits the enamel demineralisation. 
In addition, milk fat that is adsorbed onto the enamel 
surface may act as a protection, and enzymes in the milk 
can reduce the acidogenic stage of plaque bacteria.12 Milk 
contains proteins that bind calcium and phosphate ions. The 
remineralisation process starts with the attachment of milk 
proteins to the enamel surface. The calcium and phosphorus 
ions in milk can diffuse into the enamel subsurface.19 
The ions can occupy the empty HA crystal space because 
of demineralisation and initiate the remineralisation by 
forming hydroxyapatite crystals.17,20 The newly formed 
hydroxyapatite crystals fill the interprismatic gaps of the 
enamel. This process decreases the roughness and increases 
the surface hardness of the enamel.14 The following is 
the general chemical equation for the demineralisation 
and remineralisation process: 8 H+ + (Ca10(PO4)6(OH)2) 
→ 6 (HPO4)

2- + 10 Ca2+ + 2 H2O (demineralisation); 
10 Ca2+ + 6 (H2PO4)

2- + 14 OH- → Ca10(PO4)6(OH)2 
(remineralisation).

Table 2. The averages and standard deviations of the enamel surface hardness based on formula milk and immersion time and the 
Kruskal–Wallis test results (as HV)

Treatment group N
Before immersion 

(x ± SD)
After immersion 

(x ± SD)
Increase in enamel surface 

hardness (x ± SD)
Kruskal–Wallis test

X2 Df p
Group I 6 170.43 ± 12.05 248.41 ± 23.31 77.98 ± 13.29

9.34 3 0.025
Group II 6 170.88 ± 24.86 264.15 ± 34.60 93.27 ± 16.00
Group III 6 124.23 ± 23.66 190.45 ± 20.68 66.22 ± 9.32
Group IV 6 130.30 ± 37.28 211.53 ± 39.33 81.23 ± 6.31

Description: N: Number of research objects; Df: Degrees of freedom; X2: Chi square; p: Probability

Table 3. Post hoc Mann–Whitney test comparing the increasing 
average of the treatment groups

Comparison
between groups

Post hoc Mann–Whitney test

Z p

Group I
Group II -1.92 0.06
Group III -1.60 0.11
Group IV -0.48 0.63

Group II
Group III -2.40 0.02*
Group IV -1.12 0.26

Group III Group IV -2.25 0.03*
Description: Z: Statistical value of Z table, p: Probability;              
*: Significant

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i2.p78–81

https://e-journal.unair.ac.id/MKG/index
http://dx.doi.org/10.20473/j.djmkg.v54.i2.p78-81


81Irianti et al./Dent. J. (Majalah Kedokteran Gigi) 2021 June; 54(2): 78–81

The demineralisation process results in the damage 
of the HA crystals, which starts with a bond formation 
between the (PO4

3-) ion and the free H+ ion, causing the 
dissolution of the apatite crystal. The H+ ion binds to an 
OH- ion to form H2O and it binds to a PO4

3- ion to form 
HPO4

2-. When in contact with the ionic acid, HPO4
2- turns 

into H2PO4.
17 The diffusion of calcium and phosphorus ions 

into the enamel surface can initiate the remineralisation.18 
HA crystals can undergo atomic replacement, which leads 
to a change in the chemical formula HA. It can be concluded 
that teeth immersed in cow formula and soy formula for 
five and ten minutes might not decrease the roughness of 
the enamel surface, but it might increase the hardness of it. 
The hardness of the enamel surface of teeth immersed in 
soy formula for ten minutes was higher than that immersed 
in soy formula for five minutes.

REFERENCES

 1.  Lacruz RS, Habelitz S, Wright JT, Paine ML. Dental enamel 
formation and implications for oral health and disease. Physiol Rev. 
2017; 97(3): 939–93. 

 2.  Cummins D. The development and validation of a new technology, 
based upon 1.5% arginine, an insoluble calcium compound and 
fluoride, for everyday use in the prevention and treatment of dental 
caries. J Dent. 2013; 41 Suppl 2: S1-11. 

 3.  Abou Neel EA, Aljabo A, Strange A, Ibrahim S, Coathup M, Young 
AM, Bozec L, Mudera V. Demineralization-remineralization 
dynamics in teeth and bone. Int J Nanomedicine. 2016; 11:                   
4743–63. 

 4.  Sharma A, Sharma D, Singh S, Sharma A, Sharma M. Milk and 
its products: Effect on salivary pH. Int Healthc Res J. 2018; 2(6): 
140–5. 

 5.  Widanti HA, Herda E, Damiyanti M. Effect of cow and soy milk 
on enamel hardness of immersed teeth. J Phys Conf Ser. 2017; 884: 
012006. 

 6.  Maurice-Van Eijndhoven MHT, Hiemstra SJ, Calus MPL. Short 
communication: Milk fat composition of 4 cattle breeds in the 
Netherlands. J Dairy Sci. 2011; 94(2): 1021–5. 

 7.  Telgi RL, Yadav V, Telgi CR, Boppana N. In vivo dental plaque 
pH after consumption of dairy products. Gen Dent. 2013; 61(3):     
56–9. 

 8.  Yendriwati, Sinaga RM, Dennis D. Increase of enamel hardness 
score after cow milk immersion of demineralized tooth: An in vitro 
study. World J Dent. 2018; 9(6): 439–43. 

 9.  R a ha rdjo A , G r a cia E , R isk a G, Ad iat m a n M, Ma ha r a n i 
DA. Potential side effects of whitening toothpaste on enamel 
roughness and micro hardness. Int J Clin Prev Dent. 2015; 11(4):                                          
239–42. 

10.  Carvalho TS, Lussi A. Combined effect of a fluoride-, stannous- and 
chitosan-containing toothpaste and stannous-containing rinse on the 
prevention of initial enamel erosion-abrasion. J Dent. 2014; 42(4): 
450–9. 

11.  McCabe JF, Walls AWG. Bahan kedokteran gigi. 9th ed. Sunarintyas 
S, editor. Jakarta: EGC; 2015. p. 19–20. 

12.  Safavi MS, Walsh FC, Surmeneva MA, Surmenev RA, Khalil-
Allafi J. Electrodeposited hydroxyapatite-based biocoatings: Recent 
progress and future challenges. Coatings. 2021; 11(1): 110. 

13.  Makmur SA, Utomo RB. Pengaruh aplikasi gel Theobromine terhadap 
kekasaran permukaan email gigi desidui pasca demineralisasi. 
ODONTO Dent J. 2019; 6(2): 95–8. 

14.  Vidyahayati IL, Utomo RB, Soeprihati IT. Pengaruh konsentrasi gel 
Theobromine terhadap ketahanan kekerasan permukaan email gigi 
desidui. ODONTO Dent J. 2019; 6(1): 8–13. 

15.  Champigneux P, Renault-Sentenac C, Bourrier D, Rossi C, Delia 
M-L, Bergel A. Effect of surface roughness, porosity and roughened 
micro-pillar structures on the early formation of microbial anodes. 
Bioelectrochemistry. 2019; 128: 17–29. 

16.  Hamba H, Nakamura K, Nikaido T, Tagami J, Muramatsu T. 
Remineralization of enamel subsurface lesions using toothpaste 
containing tricalcium phosphate and fluoride: An in vitro μCT 
analysis. BMC Oral Health. 2020; 20(1): 292. 

17.  Mukarromah A, Dwiandhono I, Imam DNA. Differences in surface 
roughness of enamel after whey-extract application and CPP-ACP in 
post extracoronal-tooth bleaching. Maj Kedokt Gigi Indones. 2018; 
4(1): 15–21. 

18.  Amaechi BT. Remineralization therapies for initial caries lesions. 
Curr Oral Heal Reports. 2015; 2(2): 95–101. 

19.  Vandenplas Y, Castrellon PG, Rivas R, Gutiérrez CJ, Garcia LD, 
Jimenez JE, Anzo A, Hegar B, Alarcon P. Safety of soya-based infant 
formulas in children. Br J Nutr. 2014; 111(8): 1340–60. 

20.  Tyagi SP, Garg P, Singh UP, Sinha DJ. An update on remineralizing 
agents. J Interdiscip Dent. 2013; 3(3): 151–8. 

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 https://e-journal.unair.ac.id/MKG/index
DOI: 10.20473/j.djmkg.v54.i2.p78–81

https://e-journal.unair.ac.id/MKG/index
http://dx.doi.org/10.20473/j.djmkg.v54.i2.p78-81