Type of the Paper (Article


Journal of Baghdad College of Dentistry, Vol. 34, No. 1 (2022), ISSN (P): 1817-1869, ISSN (E): 2311-5270 

 

 

44 

Research Article 

Effect of Resin Infiltration and Microabrasion on the 

Microhardness of the Artificial White Spot Lesions 

(An in Vitro Study) 
                          Reem Majeed H.J. Al-Mamoori1*, Aseel Haidar M.J. Al Haidar2  

1 Master student, Department of Pediatric and Preventive Dentistry, College of Dentistry, University of Baghdad. 
2 Assistant professor, Department of Pediatric and Preventive Dentistry, College of Dentistry, University of  

Baghdad. Bab-Almoadham, P.O. Box 1417, Baghdad, Iraq 

                                    *Correspondence: Reem.jasim1901@codental.uobaghdad.edu.iq 

Abstract: Background: White spot lesion is the first visible sign of dental caries that is 

characterized by demineralized lesion underneath an intact surface. Several studies demon-

strated that they could be treated using noninvasive techniques like the use of fluoride or 

casein phosphopeptide and amorphous calcium phosphate. Improvement in aesthetic out-

comes by covering the demineralized enamel is one of the advantages of the use of resin 

infiltration and opalustre microabrasion, which are two new techniques that had been used 

for treatment of white spot lesion. The purpose of this study was to evaluate the impact of 

resin infiltration and microabrasion in the microhardness of the artificial white spot lesions at 

various depths. Material and method: Forty-eight artificially white spot lesions were divided 

into three groups (n=16) according to the depth of the lesion (shallow enamel, deep enamel, 

shallow dentine). Then, each of the main groups was divided into two subgroups (n = 8), the 

first group was treated with resin infiltration, while the second one was treated with Opal-

ustre microabrasion. Assessment of the microhardness was done using Vickers hardness at 

the baseline, after demineralization (formation of the white spot lesion) and after the treat-

ment with the resin infiltration and the microabrasion.  Results: There was a significant 

difference in the microhardness of all the layers after demineralization. Although the hard-

ness values that found among the icon group in the inner enamel and the outer dentine were 

higher than that of the opalustre, statistically there was no significant difference between the 

two materials in all the layers of the white spot lesion. Conclusion: Microhardness values 

decrease as the depth of the white spot lesion increase. There was an increase in the micro-

hardness values after the treatment with the resin infiltration and the microabrasion. 

Keywords: Microabrasion, Microhardness, Resin infiltration, White spot lesions. 

 

Introduction 

     Increase awareness was noticed among people for the importance of the presence of a beautiful 

smile so they are seeking and demanding aesthetic solutions (1,2). 

     White spot lesions (WSLs) are white enamel patches caused by mineral loss in the enamel's sub-

surface layer. Incipient or enamel caries are terms used to describe these areas. They are the precursors to 

dental cavities, and their opaque color can result in cosmetic issues that can last many years (3). 

     To prevent these lesions from developing into cavities, prompt identification and treatment are re-

quired and as these lesions can be remineralized and monitored over time; early diagnosis is crucial (4).  

     The DIAGNOdent 2190, also known as the DIAGNOdent Pen, is a diagnostic device that emits re-

flected fluorescent light at 700–800 nm after pulsed laser irradiation of a carious lesion (5,6). Values be-

tween these lesions can be remineralized and monitored over time; early diagnosis is crucial (4).  

 

Received date : 1202-12-10  

Accepted date : 2022-1-14  

Published date : 2022-3-15  

 

 

 

Copyright: © 2022 by the authors. 

Submitted for possible open access 

publication under the terms and 

conditions of the Creative Commons 

Attribution (CC BY) license 

(https://creativecommons.org/license

s/by/4.0/). 

https://doi.org/10.26477/jbcd

.v34i1.3091 

 

https://creativecommons.org/licenses/by/4.0/
https://creativecommons.org/licenses/by/4.0/
https://doi.org/10.26477/jbcd.v34i1.3091
https://doi.org/10.26477/jbcd.v34i1.3091


         J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022                                                           Al-Mamoori and Al Haidar 
 

 

45 

 

     The DIAGNOdent 2190, also known as the DIAGNOdent Pen, is a diagnostic device that emits re-

flected fluorescent light at 700–800 nm after pulsed laser irradiation of a carious lesion (5,6). Values be-

tween 6 and 20 show enamel lesions, values between 20 and 30 suggested superficial dentinal lesions, 

while values over 30 indicate severe dentinal caries. Several studies looked at the reliability and the va-

lidity of the DIAGNOdent in measuring the WSLs and the smooth surface caries (7,8). 

     For the treatment of WSLs, various treatments have been proposed; some are conservative, like the 

remineralization treatment, while others are more aggressive, like bleaching (9,10). Resin infiltration has 

been intensively investigated as far as more dental tissue-preserving strategy to halt and manage smooth 

surface or proximal lesions. The goal of this concept is the obstructing of the high porosity of an early 

enamel lesion using low-viscosity resins. This method genuinely adheres to the concepts of noninvasive 

dentistry, which aid in the detection of incipient lesions using diagnostic instruments as well as the lim-

ited invasive intervention of the cavitated lesions (11). 

     Furthermore, the resin-filled microporosities cannot evaporate, resulting in immediate aesthetic 

enhancement (12). On the other hand, microabrasion was reported by Roberson et al. in 2002 as a con-

servative option for the reduction or eradication of the superficial discolorations. It has a wide range of 

uses, including the elimination of the surface non-carious enamel irregularities and nowadays it had been 

proposed as a method for removing the demineralized white lesions (13). 

     A paste containing hydrochloric acid and pumice is applied to the affected tooth surfaces to uni-

formly remove up to 0.2 μm of enamel surface using a combination of chemical erosion and mechanical 

abrasion. Microabrasion produces a glossy, glass-like enamel surface that may refract and reflect light in 

a number of ways (14,15). Any remaining underlying enamel stains may be concealed by these optical 

qualities, Saliva hydration of the teeth improves these favorable optical properties (10). 

     Microhardness testing of the demineralized and the treated lesions at various depths of enamel and 

dentine is an effective approach for obtaining indirect information about the changes concerning the 

mineral content in dental hard tissues. Furthermore, no available Iraqi study had been found concerning 

the evaluation of the effect of the resin infiltration and the microabrasion of the artificial white spot le-

sions at various depths. Therefore, this study aimed to assess the surface qualities of the artificially in-

duced white spot lesions after treatment with the resin infiltration and microabrasion in terms of the 

surface microhardness at various depth. The null hypothesis suggests that there is no significant differ-

ence in microhardness of Resin infiltration and Opalustre microabrasion material at various depths of 

demineralization. 

Materials and Methods  

Samples  

     A total of 48 sound premolars were extracted, for orthodontic demand, from patients aged 12-20 

years old (16,17). They were obtained from different private and public dental clinics in Baghdad city. Teeth 

with hypoplasia, crack, incipient carious lesions/white spots and filling were excluded after being 

checked by 10X magnifying lens. In order to eliminate the debris and soft tissues, all the teeth were 

washed and polished using non fluoridated type of pumice slurry (PD, Switzerland), the collected teeth 

were stored for one week in a 0.05 % thymol solution (an antimicrobial solution that inhibits bacterial 

growth). Then, the teeth soaked in deionized distilled water (DDW) until they were subjected to any in-

tervention (18). 

Sample preparation  

     In order to prepare flat surface for Vicker’s microhardness testing, the buccal surface of each tooth 

was polished with Sof-Lex Disks (3M ESPE, USA) in a progressive manner (beginning with the coarse, 

then medium and fine, ending with the superfine) using contra-angle slow-speed hand-piece. 



         J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022                                                           Al-Mamoori and Al Haidar 
 

 

46 

 

     Then a circular opening of 6mm in diameter was standardized on the buccal surface of every tooth 

with a ruler. An imaginary line was drawn on the tip of the buccal cusp to the cervical line, as well as ad-

ditional line among the mesial and distal tooth surfaces at their most prominent curvature, to determine 

the middle area of the buccal surface. Then, a 6mm adhesive tape circle was cut and put on the buccal 

surface of the tooth. After that, the tooth was painted with an acid resistant nail varnish after that adhe-

sive tape was removed, leaving a circular window on the buccal surface of the tooth, following the de-

mineralization, the specimens were properly washed in deionized distilled water (DDW) once more (19).   

WSLs formation  

     Two hundred ml of demineralizing solution was prepared (2.2 mM potassium dihydrogen phos-

phate (KH2PO4), 2.2 mM calcium chloride (CaCl2), and 50 mM acetic acid) for a whole day (20).  

     All of the teeth were immersed in an artificial caries solution for a whole day with pH of 5 at 37°C, 

the solution was changed daily until the frosty white appearance was achieved. The extent of the white 

spot lesion was assessed on daily basis with a DIAGNOdent pen. If the extent of the lesion was not suffi-

cient, the teeth were immersed again in the artificial caries solution (21). 

     The readings of the induced WSLs in the shallow enamel were ranged between 6 and 14, which as-

sembled in about a week. While the readings of deep enamel lesion were ranged from 15 to 20 and they 

took about 10 days to be yield. A duration period of about 15 days was needed to induce WSLs in the 

shallow dentine by which their readings were ranged between 21and 29 (22). 

Treatment groups after WSLs formation 

     The main three groups were allocated randomly into two groups, each group of 8 teeth, according 

to the type of treatment, which was either one of the following: 

1- Resin infiltration group: Icon resin (Icon etch; DMG, Hamburg, Germany). The application of the 

material was done according to the manufacturer instruction as follows: Icon-etch (15%HCl gel) applied 

first for 2 min, followed by water rinsing and air-drying for 30s. The second step was by application of 

Icon-dry (ethanol) for 30s then air-drying, third was application of Icon- infiltrant for 3 min., with light 

curing of the infiltrant for 40 s, and then treated sample teeth stored in DDW. 

2- Opalustre Microabrasion group: Opalustre was used (Opalustre Enamel Microabrasion Slurry, Ul-

tradent, South Jordan, Utah, USA). In which also applied according to manufacture instruction, Abrasive 

material was applied on the surface of the teeth with mechanical friction performed by a rubber cup at 

500 r/min speed, lasting 30 to 40 seconds, followed by Water rinsing and air drying. 

Microhardness Testing 

     The Vicker’s microhardness test (400 Series, Wilson Wolpert, Germany) was measured for each 

tooth of the total sample at the baseline, after white spot lesion formation and after treatment with each 

material with a diamond indenter made with a 300 g load. Three indentations (500 μm apart) were ap-

plied on the buccal surfaces, with a dwell time of 15 seconds. Indentation was noticed in digital readings, 

and an average was obtained(24). 

Statistical analysis 

     The data collected was subjected to the statistical package for social science (SPSS, version 21, Chi-

cago, Illinois, USA). Descriptive statistics as minimum, maximum, mean, standard deviation (SD) was 

used. The inferential statistics were Shapiro Wilk Levene test and General linear model, the Least Signif-

icant Difference (LSD) and Bonferroni post hoc test. The level of significance was set at 0.05. Partial eta 

square Effect size was: small (0.01-0.059), medium (0.06-0.139), Large >=0.14. 

Results 



         J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022                                                           Al-Mamoori and Al Haidar 
 

 

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     Microhardness is normally distributed among phases, layers and materials using Shapiro Wilk at 

p>0.05. At the three different depth groups, the surface microhardness was measured at the baseline, after 

demineralization and after treatment with the Icon and the Opalustre, (Table 1). The surface microhard-

ness was decreased dramatically after demineralization then it raised again after treatment. There was a 

significant difference in the microhardness of all the depths of WSL at the different phases of the study.   

Table 1: Descriptive and statistical test of Microhardness unit (VHN) among phases and groups by layers. 

      

     While there was a decrease in the hardness in all depth layers after demineralization, a noticeable 

increase was found after treatment with each of the materials. However, when comparing the effect size 

between the two materials (icon and the opalustre), it was slightly higher for the icon material than it was 

for the opalustre, which mean that the resin infiltration was the better in improving the microhardness of 

teeth after demineralization than the microabrasion. 

     Pairwise comparison in Table2 shows a statistical significant difference between each phase of the 

study in all the depth layers and for both of the materials except in outer enamel layer in opalustre ma-

terial between baseline and after treatment, the result was not significant. 

 

Discussion 

     Dental caries prevention techniques primarily attempt to arrest caries and to remineralize the af-

fected dental surface in its early phases. In fact, using preventive materials to treat the initial decay and 

white lesions on the enamels will slow or avoid the cavity growth and maintain the tooth structure. Initial 

enamel lesions can be treated and their acidity resistance can be increased with specially devised treat-

Layers Phases 

Material 

Resin infiltration Opalustre microabrasion 

Minimum Maximum Mean ±SD Minimum Maximum Mean ±SD 

outer 

Enamel 

Base line 257.320 487.210 362.534 70.181 220.700 438.200 344.786 79.370 

Demin. 188.570 280.040 232.499 32.086 126.500 299.700 233.058 58.228 

After treatment 227.600 378.600 315.663 53.721 201.300 393.700 319.428 76.692    

Statistics 
F 25.820 20.711 

P value 0.00000* 0.00000* 

Inner 

Enamel 

Base line 235.060 428.100 344.924 64.885 272.700 473.500 336.810 61.475 

Demin. 125.700 238.300 187.476 32.001 143.600 239.700 187.995 28.312 

After treatment 217.400 398.500 298.858 70.708 236.400 361.500 284.416 39.563 

Statistics 
F 38.810 33.851 

P value 0.00000* 0.00000* 

Outer 

Dentine 

Base line 275.600 407.280 339.549 52.426 242.470 453.160 348.296 60.608 

Demin. 128.700 238.300 174.161 32.798 156.280 210.900 179.724 17.978 

After treatment 256.220 360.760 299.648 40.197 205.680 349.600 279.584 50.466 

Statistics 
F 44.695 43.619 

P value 0.00000* 0.00000* 

*=significant at p≤0.05. 



         J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022                                                           Al-Mamoori and Al Haidar 
 

 

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ment regimens (25). Incipient lesions have reduced microhardness than that of the sound and caries-free 

enamel surface. The process of chemical dissolving of enamel rods weakens the enamel and generates 

voids, resulting in a loss in microhardness after demineralization (26,27). 

     Table 2: Multiple comparisons of microhardness unit (VHN) between different study phases according 

to lesion depth and study materials. 

    *=significant at p≤0.05, ^ not significant. 

Microhardness tests are commonly utilized to assess the tooth hardness. This procedure is simple, rapid, 

and only takes a small part of the sample buccal surface to test. In 2003, Gutierrez-Salazar and 

Reyes-Gasga proposed in tooth hardness studies the Vicker indenter is more useful than the Knoop’s, so 

the Vickers hardness test was chosen in this study (28). 

     In this study the specimen surfaces were impressed with a diamond indenter made with a 300 g 

load, three indentations (500 μm apart) for 15 seconds (29,30). 

The microhardness of the samples treated with resin infiltration was increased. This could be explained 

as that because of the low viscosity, resin fills the pores between the remaining crystals in the porous le-

sion, forming a diffusion barrier not only on the surface, but also even within the lesion body, causing the 

demineralized tissues to reharden and enhance the mechanical strength. The results of this investigation 

agreed with those of Torres et al. (26) and Paris et al. (31), who found that resin infiltration improves the mi-

Pairwise Comparisons 

Measure:   VH 

Material Layer (I) study phase (J) study phase Mean Difference (I-J) p- value 

Resin infiltration 

outer Enamel 
Base line 

Demineralization. 130.035 0.00000 * 

After treatment 46.871 0.00032 * 

Demineralization. After treatment -83.164 0.00000 * 

Inner Enamel 
Base line 

Demineralization. 157.448 0.00000 * 

After treatment 46.066 0.00040 * 

Demineralization. After treatment -111.381 0.00000* 

Outer Dentine 
Base line 

Demineralization. 165.388 0.00000* 

After treatment 39.901 0.00221* 

Demineralization. After treatment -125.486 0.00000* 

Opalustre micro-

abrasion 
 

outer Enamel 
Base line 

Demin. 111.729 0.00000* 

After treatment 25.359 0.07673 ^ 

Demin. After treatment -86.370 0.00000* 

Inner Enamel 
Base line 

Demin. 148.815 0.00000* 

After treatment 52.394 0.00006* 

Demin. After treatment -96.421 0.00000* 

Outer Dentine 
Base line 

Demin. 168.573 0.00000* 

After treatment 68.713 0.00000* 

Demin. After treatment -99.860 0.00000* 

b. Adjustment for multiple comparisons: Bonferroni. 



         J. Bagh. Coll. Dent. Vol. 34, No. 1. 2022                                                           Al-Mamoori and Al Haidar 
 

 

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crohardness of the carious lesions when compared to the untreated artificial lesions following demineral-

ization, 

     Microhardness was significantly increased when microabrasion techniques were used, indicating 

that this micro-invasive treatment method was beneficial for the management of incipient caries lesions. 

Although there were insufficient researches on the outcome of the microabrasion on enamel hardness, the 

procedure has previously demonstrated an increase in enamel microhardness following a microabrasion 

process, like the finding of vitro research by Yazkan's (32).  Hardness improvement can be explained ac-

cording to the theory indicating that the acid compound changes the prismatic structure of enamel, caus-

ing a compacting effect so therefore increasing the hardness of the teeth (33,34). 

     In this study, when comparing the mean difference between the Icon and the opalustre materials, it 

was found that the mean difference of resin infiltration in the outer enamel between the demineralization 

and after treatment phases was lower than in opalustre material. However, the mean difference of Icon in 

inner enamel and outer dentine was higher than in opalustre, which mean according to this result the 

Icon material had a better performance in increasing the microhardness. 

Conclusion 

     As of when the depth of the WSL increased the microhardness value decrease accordingly. Both 

resin infiltration and microabrasion were effective in treating WSL and improving the microhardness 

values of the teeth at different depth of demineralization. 

Conflict of interest: None. 

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  ( المختبر في دراسة  (االصطناعية البيضاء البقع آلفات  الدقيقة الصالدة على الدقيق والكشط  الراتنج العنوان: تأثير 

 2 اسيل حيدر الحيدر,  1ريم مجيد المعموري الباحثون: 
 المستخلص: 

  والبكتريا  الجرثومية  الصفيحة  تراكم  بسبب  تظهر  قد   متعددة  اسبابها.  السليم  السطح  أسفل  المعادن  منزوعة  البقع  هذه  وتكون  االسنان  في  التسوس  ظهور  عالمات  اول  من  هي  البيضاء  البقعالخلفية:  

 للبقع المختلفة االعماق في  الدقيق والقشط الراتنج  مادة بين الصالدة ومقارنة اختبار هو الدراسة من الهدف .الفم نظافة سوء من يعانون الذين الصغار والمراهقين األطفال لدى تطورت التي

 .البيضاء
 باستخدام البيضاء البقع لعمق تبعا اساسية مجاميع ثالث الى االسنان تقسيم تم ثم المعادن ازالة محلول باستخدام البشرية الضواحك من سن 48 على البيضاء البقع تكوين تمالعمل: المواد وطرق 

 (. الدقيق اوالقشط الراتنج مادة) العالج نوع حسب مجموعتين الى مجموعة كل تقسيم تم ثم.  diagnodent ال قلم
 .الدقيق والقشط الراتنج بمادة معالجتها بعد  االسنان صالدة في زيادة هناك كان حين في االسنان صالدة قلت البيضاء البقع عمق زاد  كلما ان االستنتاج يمكنناالنتائج: