Evaluation of Two Different Types of Mineral Trioxide Aggregate Cements as Direct Pulp Capping Agents in Human Teeth

Ballal, Nidambur Vasudev; Rao, Sheetal; Rao, Nirmala; Urala, Arun; Yoo, Jun-Sang; Al-Haj Husain, Nadin; Özcan, Mutlu

doi:10.3390/app112110455

Open AccessArticle

Evaluation of Two Different Types of Mineral Trioxide Aggregate Cements as Direct Pulp Capping Agents in Human Teeth

by

Nidambur Vasudev Ballal

^1,*

,

Sheetal Rao

¹,

Nirmala Rao

²,

Arun Urala

³,

Jun-Sang Yoo

⁴,

Nadin Al-Haj Husain

^5,6 and

Mutlu Özcan

⁶

¹

Department of Conservative Dentistry & Endodontics, Manipal College of Dental Sciences, Manipal Academy of Higher Education, Manipal 576104, India

²

Department of Oral Pathology & Microbiology, Manipal College of Dental Sciences, Manipal Academy of Higher Education, Manipal 576104, India

³

Department of Orthodontics and Dentofacial Orthopaedics, Manipal College of Dental Sciences, Manipal Academy of Higher Education, Manipal 576104, India

⁴

Department of Oral and Maxillofacial Surgery, Seoul National University School of Dentistry, Seoul 03080, Korea

⁵

Department of Reconstructive Dentistry and Gerodontology, School of Dental Medicine, University of Bern, 3012 Bern, Switzerland

⁶

Division of Dental Biomaterials, Clinic for Reconstructive Dentistry, Center of Dental Medicine, University of Zurich, 8001 Zurich, Switzerland

^*

Author to whom correspondence should be addressed.

Appl. Sci. 2021, 11(21), 10455; https://doi.org/10.3390/app112110455

Submission received: 23 September 2021 / Revised: 1 November 2021 / Accepted: 3 November 2021 / Published: 7 November 2021

(This article belongs to the Special Issue Clinical Applications for Dentistry and Oral Health)

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Abstract

:

Traumatic human dental injuries involving the pulp might necessitate direct capping procedures. This clinical study aimed to analyse the histological outcomes using two different direct capping materials. Twenty patients with bilateral premolars, scheduled for orthodontic extraction, were selected. The teeth were treated either using ProRoot MTA or RetroMTA. All patients were recalled after 30 and 60 days for teeth extraction. The histopathologically stained specimens were blindly evaluated using hard tissue bridge formation, inflammatory reaction and pulpal findings criteria. Data were evaluated statistically. Results: After 60 days, only the parameter for hard tissue bridge formation showed significant difference in the ProRoot MTA group (p = 0.010), while both direct capping materials performed similarly regarding inflammatory pulp reaction and pulpal findings. Although, during the first 30 days, RetroMTA presented better results in terms of continuity, morphology, hard tissue bridge localisation, and extension/general state of the inflammatory reaction, the continuity was better at 60 days when ProRoot MTA was applied. Treatment with RetroMTA healed the pulpal tissue faster compared with ProRoot MTA but it seemed to be rather a reparative process.

Keywords:

direct pulp capping; MTA; mineral trioxide aggregate cements; pulp; regeneration; repair

1. Introduction

Dental trauma is a significant problem in young people. It has been reported that most dental traumatic injuries involve anterior teeth [1]. These traumatic injuries can cause irreparable damage to the young permanent teeth, not only at the time of accident, but also during the post-treatment period. Maintaining the vitality of the dentin–pulp complex is a high priority in cases of traumatic pulp exposures, since vital functioning pulp is capable of initiating several defence mechanisms to protect the body from bacterial invasion. Once pulpal tissue is exposed to the oral environment, among many other processes, repair or regeneration might occur, which is achieved by encouraging the formation of a “dentin bridge”, using direct pulp capping (DPC) procedures. These involve the medical or addressing material application upon exposed tissue. Several prior studies indicated calcium hydroxide as gold standard for pulp capping [2,3,4]. However, performed studies have also reported disadvantages using calcium hydroxide such as dentin barrier tunnels, obliteration of the pulp chamber caused by extensive dentin formation, high oral fluid solubility, and a lack of degradation and adhesion after acid etching [5,6,7,8]. Mineral trioxide aggregate is one commonly used pulp capping agent, which was first evaluated by Pitt Ford et al. in monkey’s teeth, showing a superior performance of MTA compared with calcium hydroxide [9].

MTA has several advantages over calcium hydroxide, such as lower solubility, improved mechanical strength, better marginal adaptation, and sealing ability [10]. However, ProRoot MTA has disadvantages such as long setting time and causes discoloration of teeth [11,12]. Hence, several MTA-like materials have been developed with improved physical properties. Recently, RetroMTA (BioMTA, Seoul, Korea), consisting of a hydraulic calcium zirconia complex, was introduced for pulp capping, pulpotomy, perforation repair, and as a base material [13,14]. The complex is a mixture of calcium carbonate, aluminium oxide, silicone dioxide, and zirconium oxide.

In RetroMTA, similar components are present as in ProRoot MTA but less heavy metal contents than ProRoot MTA (Table 1).

Also, zirconium oxide has been added as an alternative radiopacifier to bismuth oxide to prevent discoloration [15]. It has been stated that RetroMTA has good biocompatibility, strong antibacterial effect, good sealing ability, fast setting (2.5 min) and no wash out. Chung C.J. et al. reported RetroMTA to have similar effects as ProRoot MTA on human pulp cells and can be used as pulp capping material. Only few clinial studies compared the efficacy of RetroMTA and ProRoot MTA as direct pulp capping material. Therefore, the aim of this clinical trial was to compare the efficacy of RetroMTA and ProRoot MTA in human dental pulp tissue healing when used as direct capping agent. The null hypothesis was there is no significant difference in hard tissue formation and inflammatory pulp response with RetroMTA and ProRoot MTA when evaluated after 30 or 60 days of application.

2. Materials and Methods

2.1. Inclusion and Exclusion Criteria

Twenty patients (ages 18–30) having contra lateral premolar teeth, scheduled for extraction because of orthodontic reasons were selected. A total of 40 teeth, 2 in each patient were selected. A split mouth design was used, where both MTA materials were applied in the same patient. Sample size was calculated with 95% confidence level and 80% power, according to existing literature [16]. Patients suffering from any systemic disease were excluded. The exclusion criteria were teeth with decay, restorations, trauma, periapical lesions, and periodontal pathologies. If teeth could not be isolated using a rubber dam and if patients were allergic to local anaesthesia, with systemic diseases, or when extraction is contraindicated, were also excluded. Informed consent of each patient was a prerequisite for participation in the study.

2.2. Clinical Procedure

Ethical clearance was approved from the institutional review board (IEC 859/2016). This study was registered in Clinical Trial Registry of India (CTRI/2017/10/010303) and carried out at the Department of Conservative Dentistry & Endodontics, Manipal College of Dental Sciences, Manipal, Karnataka, India. Following a detailed explanation of the experimental study purpose, clinical procedures, and possible risks, informed consent was obtained from each patient. Absence of decay, restorations, trauma, periapical lesions, and periodontal pathologies was assured throughout clinical and radiographical examination of all teeth. Teeth which could not be isolated under a rubber dam were excluded. The pulp sensibility of all the experimental teeth was tested using thermal (cold test, Endo-Frost, Coltene, Cuyahoga Falls, OH, USA) and electric stimuli (Parkell Electronics Division, Farmingdale, NY, USA). In each patient, local anaesthesia (Septodont, Saint-Maur-des-Fosses, France) was performed, followed by rubber dam isolation, and cleansing of the surrounding regions (clamp, dam, and tooth) using a 0.2% chlorhexidine gluconate solution. High speed diamond burs (Horico Dental, Berlin, Germany) under water coolant were used to prepare class I occlusal standardized cavities with an occlusal depth of 3 ± 0.2 mm, mesiodistal width of 4 ± 0.5 mm, and buccolingual width of 3 ± 0.2 mm. After exposure of the pulp in the cavity centre on the pulpal floor using a sterilized round bur under water cooling, haemostasis was obtained by application of gentle pressure using a saline solution moistened cotton pellet. The tooth was then randomly treated (coin toss method) with either ProRoot MTA (Dentsply Sirona) or RetroMTA (BioMTA). The same procedure was applied on the contra lateral premolar. Both MTA cements were prepared and applied according to manufacturer’s instructions. After application of the pulp capping material, a thin layer or resin-modified glass ionomer cement (Ionolux, VOCO GmbH, Cuxhaven, Germany) was placed over the tested capping materials as a liner and the access hole was restored using a universal resin composite (Filtek Z350 XT, 3M ESPE, St. Paul, MN, USA). All the procedures were carried out by a single operator, experienced in performing vital pulp therapy. All patients were recalled after 30 and 60 days for teeth extraction and histopathological analysis. In this period, if the patient experienced any pain in the restored test with the test agents, it was extracted immediately.

2.3. Tissue Processing for Microscopic Examination

A total of 10 teeth from each group were extracted after 30 days, and 10 further teeth were extracted after 60 days, for histopathological analysis. Presence and/or absence of post-operative tenderness to percussion, sensitivity, and pain were evaluation by questionnaires of the patients. Furthermore, Pulp sensibility tests were repeated according to the preoperatively performed ones at the time points 30 and 60 days. Oral surgeons extracted the teeth atraumatically, and orthodontists continued the orthodontic treatment. Following extraction, the apical 3 mm of the roots were sectioned to enable penetration of the 10% buffered formalin solution for 72 h. After blind coding for histomorphological processing and examination, the specimens were decalcified using 50% formic acid-sodium citrate for a 6 to 8 weeks period and prepared and embedded in paraffin. Between 10 and 12 sections, 4 or 5 6 micrometre sections were obtained by cutting using a microtome in a parallel direction to the vertical axis of the tooth. Sections were then mounted on glass slides, stained with haematoxylin-eosin, blindly evaluated by an experienced and calibrated oral and maxillofacial pathologist, according to the criteria in Table 2, Table 3 and Table 4. Each histomorphological event was evaluated with a 1–4 score system, with 1 being the best and 4 the worst result [17].

2.4. Statistical Analysis

Statistical analysis was performed with R Project for Statistical Computing 3.3.0 and Microsoft Excel 2013. The normality of the data distribution and the homogeneity of group variances were verified by the Kolmogorov–Smirnov test. Chi square test was performed for the comparison between the Proroot MTA and RetroMTA. p < 0.05 was considered as significant.

3. Results

All selected patients and treated teeth could be evaluated. The score percentages for each group in each criterion are shown after 30 days in Table 5, and after 60 days in Table 6.

Considering hard tissue bridge formation after 30 days, significant differences could be found when ProRoot and RetroMTA were compared. As for the parameters—continuity (p = 0.029), morphology (p = 0.023), and localisation (p < 0.001)—the RetroMTA performed significantly better compared with ProRoot MTA.

After 60 days, only continuity, the hard tissue bridge formation parameter, showed significant difference, in favour of the direct capping material ProRoot MTA (p = 0.010) (Figure 1).

The pulpal inflammatory response with the criteria (intensity, extension, and general state) no significance could be observed 30 days after the treatment for the parameter intensity (p = 1.00), while RetroMTA performed better in terms of extension (p = 0.007) and general state (p = 0.033).

Pulpal findings including the parameters (giant cells and particles) performed only significantly different for the parameter particles when both direct capping materials were compared after 30 days, in favour of RetroMTA (p = 0.048).

After 60 days, both direct capping materials Pro Root and RetroMTA performed similar regarding inflammatory response of the pulp and pulpal findings.

4. Discussion

This clinical study was conducted in teeth with a healthy uninflamed pulp using two different capping materials ProRoot MTA and RetroMTA, which are hydraulic biocompatible cements [18] with similar biological effects [19]. The null hypothesis was rejected for the parameters of hard tissue formation, inflammatory pulp response, and pulpal findings, except for intensity and giant cells number after 30 days, and for continuity after 60.

As for the hard tissue bridge, the RetroMTA results of this study showed better results regarding the parameters continuity, morphology, and localisation, while ProRoot MTA performed better regarding the parameter thickness. However, after 60 days, the only significant parameter was continuity, in favour of ProRoot MTA. The complete bridge formation is expected to take place 60–90 days after pulp capping [20,21].

The findings of this study are in accordance with one histological study, which evaluated direct pulp capping performance in dog’s teeth, where no significance could be found between the two test pulp capping materials RetroMTA and ProRoot MTA, where a hard tissue bridge was formed in direct contact to the vital pulp [18]. Kang et al. also sustained high success rate up to 1 year, with no significant differences between outcomes treated with ProRoot MTA (96.0%) and RetroMTA(96.0%) [22].

The dentine bridge, in the form of a calcified barrier, is usually considered a favourable response to capping therapy. In conjunction to vital signs, it supports that the pulp condition is healthy, leading to physiologic dentin deposition. Mass, E. et al. reported that a calcified barrier was found in almost 70% of teeth [23], compared with 55%–64% in previous studies [24,25].

The thickness of the dentine bridge in the 60 days sample of RetroMTA is less than 30 days. It is proof that the thickness of the dentinal bridge may vary depending on the location and angle of sectioning; therefore, it is more critical to evaluate the condition of pulp beside the bridge thickness, continuity, and quality, while assessing the success of the direct pulp capping material. The initiation is induced throughout initiation of reparative dentinogenesis in the case of MTA [26,27]. Pulp cells are aligned in proximity to crystals, built in a homogenous zone along the pulp–MTA interface. After MTA hardening, calcium oxide is formed, which can react with tissue fluids to produce calcium hydroxide [28]. After contact with pulp tissue, MTA presents some structures that are similar to calcite crystals, which attract fibronectin, which is generally responsible for cellular adhesion and differentiation [29]. Some studies found necrotic tissue next to the hard tissue bridge, which is assumed to be caused by MTA throughout coagulation in contact with pulp connective tissue [26]. The randomized controlled trial, conducted by Kang et al. [23], using three different MTA materials (ProRoot, Ortho, and RetroMTA), stated that the partial pulpotomy performed in permanent teeth showed favourable results, while clinical and radiographic results showed no difference after one year. In contradiction, one study found significantly worse results after 8 weeks using RetroMTA concerning pulp morphology and hard tissue bridge thickness compared to ProRoot. The hard tissue was described as a tubular reparative dentine. However, one study reported a lack of mineralized tissue and rather regular dentin with parallel tubules and rather amorphous and irregularly calcified tissue with lacunae of necrotic debris [23]. This finding may explain the changes after 60 days, and the less favourable performance of RetroMTA after 60 days. The quality of the hard tissue bridge relates to the pulpal health state after application of MTA and the pulp capping procedure [30,31].

For tooth survival, the pulp status and inflammatory response after pulp capping material application is more important compared to the thickness of the dentine bridge. The inflammatory response of the pulp with the criteria (intensity, extension, and general state) showed no significance between both tested cements after 60 days. RetroMTA is a hard-setting hydrophilic cement consisting of fine, hydrophilic particles that set in the presence of moisture and form a hard barrier. In contrast to Ca(OH)₂ suspension, calcium silicate cements are not resorbable; therefore, they provide long-term protection against the invasion of microorganisms [32,33]. The quality of the hard tissue influences the state of pulpal health after direct pulp capping [30,31]. Furthermore, the formation of a hard tissue bridge does not mean that the pulp tissue will be sealed completely, because the hard tissue is permeable initially [34]. The formation of a mineralized barrier after capping with RetroMTA was reported as unpredictable, as it was incomplete and showed channels, which can be supported by the findings of this study as initial better results after 30 days compared to ProRoot MTA disappear, while the values for ProRoot MTA remain stable. The inflammation intensity and extension of RetroMTA teeth increased, while the general state of the pulp decreased.

No significant difference regarding the presence of microorganisms was found after 60 days. This means that, although the MTA particles dissolved faster in the RetroMTA group, the bacteriostatic action of both MTAs, per se, was similar, and was enough to reduce the number of viable bacteria near the pulp exposure.

Study limitations were the healthy uninflamed teeth, which don’t present the response that occurs in a clinical setting of an inflamed pulp, as the pathological changes of inflammation, odontoblasts absence, and tertiary dentine formation are missing. As for the bacteria detection, low sensibility of the histochemical staining technique for the detection of bacteria makes their identification difficult, mainly when there is a small number of such microorganisms [35]. Moreover, bacteria are easily removed from dental tissue during histologic preparation [36,37]. Although the use of healthy teeth allows standardisation, the effects of ProMTA and RetroMTA should also be evaluated in a clinical setting using infected and inflamed teeth.

5. Conclusions

The results of the present study indicated that RetroMTA might be a valuable ProRoot MTA alternative, regarding the tested parameters pulpal findings, including inflammatory response and hard tissue bridge formation. Although, during the first 30 days period, RetroMTA presented better results in terms of continuity, localisation, and morphology of the formed hard tissue bridge and extension and inflammatory pulp response, the continuity improved after 60 days when ProRoot MTA was applied.

MTA seemed to heal the pulp tissue at a faster rate for RetroMTA compared to ProRoot MTA.

Author Contributions

Conceptualization, N.V.B., S.R., N.R., A.U., J.-S.Y. and M.Ö.; methodology, N.V.B., S.R., N.R., A.U., J.-S.Y. and M.Ö.; software, N.V.B., S.R., N.R., A.U. and J.-S.Y.; validation, N.V.B., S.R., N.R., A.U., J.-S.Y. and M.Ö.; formal analysis, N.V.B., S.R., N.R., A.U., J.-S.Y. and M.Ö.; investigation, N.V.B., S.R., N.R., A.U., J.-S.Y. and M.Ö.; resources, N.V.B., S.R., N.R., A.U., J.-S.Y. and M.Ö.; data curation, N.V.B., S.R., N.R., A.U. and J.-S.Y.; writing—original draft preparation, N.V.B., S.R., N.R., A.U., J.-S.Y., N.A.-H.H. and M.Ö.; writing—review and editing, N.V.B., S.R., N.R., A.U., J.-S.Y., N.A.-H.H. and M.Ö.; visualization, N.V.B., S.R., N.R., A.U., J.-S.Y., N.A.-H.H. and M.Ö.; supervision, N.V.B., S.R., N.R., A.U., J.-S.Y., N.A.-H.H. and M.Ö.; project administration, N.V.B., S.R., N.R., A.U., J.-S.Y., N.A.-H.H. and M.Ö.; funding acquisition, N.V.B., S.R., N.R., A.U., J.-S.Y. and M.Ö. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

The study was conducted according to the guidelines of the Declaration of Helsinki, and was approved by the Institutional Review Board (IEC 859/2016) of Manipal University (CTRI/2017/10/010303).

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Hard tissue bridge (arrow) and inflammatory cells (star) demonstrated in relation to ProRoot MTA and RetroMTA at 30 days and 60 days (haematoxylin and eosin, original magnification ×10).

Table 1. Composition of the experimental MTA cements used.

ProRoot MTA	RetroMTA
Tricalcium silicate	Calcium carbonate
Dicalcium silicate	Silicon dioxide Aluminium oxide Calcium Zirconium complex
Tricalcium aluminate
Tetracalcium aluminoferrite Calcium oxide Bismuth Oxide

Table 2. Evaluation parameters and scores used for hard tissue bridge formation (continuity, morphology, thickness of dental bridge, and localization).

Score	Continuity	Morphology	Thickness of Dental Bridge	Localization
1	Complete	Dentin or dentin associated with an irregular hard tissue	Up to 250 µm	Closure to the exposition area without invading the pulp space
2	Little communication of the capping material with the dental pulp	Only irregular hard tissue deposition	150–249 µm	Bridge invading pulp space next to the opposite dentin wall
3	Only lateral deposition of hard tissue on the walls of the cavity of pulp exposure	Only a slight layer of hard tissue deposition	1–149 µm	Bridge reached the opposite dentin wall
4	Absence of hard tissue bridge and absence of lateral deposition of hard tissue	No hard tissue deposition	Partial or absent bridge	No bridge or only hard tissue deposition on the walls of the exposition cavity site

Table 3. Scores used for the evaluation of the inflammatory response of pulp.

Score	Intensity of Inflammatory Reaction (Acute and Chronic)
1	Absent or very few inflammatory cells
2	Mild: average number less than 10 inflammatory cells
3	Moderate: average number 10–25 inflammatory cells
4	Severe: average number greater than 25 inflammatory cells
Score	Extension of The Inflammatory Reaction (Acute and Chronic)
1	Absent
2	Mild: inflammatory cells only next to dentin bridge or area of pulp exposition
3	Moderate: inflammatory cells are observed in part of coronal pulp
4	Severe: all coronal pulp is infiltrated or necrotic
Score	General State of The Pulp
1	No inflammatory reaction
2	With inflammatory reaction
3	Abscess
4	Necrosis

Table 4. Scores used for other pulpal findings.

Score	Giant Cells	Particles of Capping Materials
1	Absent	Absent
2	Mild	Mild
3	Moderate	Moderate
4	Pulp necrosis	Large number

Table 5. Percentage of scores (%) attributed to each group in each criterion of hard tissue bridge after 30 days for both cement types: ProRoot MTA and RetroMTA.

30 Days	ProRoot MTA				RetroMTA				X²	p
30 Days	1	2	3	4	1	2	3	4
Continuity	10	-	60	30	10	60	20	10	9.0	0.029
Morphology	20	-	60	20	80	-	10	10	7.503	0.023
Thickness	-	-	90	10	-	-	10	90		<0.001
Localisation	50	-	-	50	30	50	10	10	9.167	0.027
Intensity	90	10	-	-	100	-	-	-	-	1.0
Extension	20	80	-	-	80	20	-	-	7.2	0.007
General state	50	50	-	-	100	-	-	-	-	0.033
Giant cells	100	-	-	-	100	-	-	-	-	1
Particles	10	-	70	20	40	30	20	10	7.911	0.048

Table 6. Percentage of scores (%) attributed to each group in each criterion of hard tissue bridge after 60 days for both cement types: ProRoot MTA and RetroMTA.

60 Days	ProRoot MTA				RetroMTA				X²	p
60 Days	1	2	3	4	1	2	3	4
Continuity	10	-	60	30	20	-	20	60	11.33	0.01
Morphology	20	-	60	20	60	10	-	30	2.077	0.557
Thickness	-	-	90	10	-	-	10	90	1.25	0.264
Localisation	50	-	-	50	50	40	-	10	2.019	0.364
Intensity	90	10	-	-	50	20	30	-	3.533	0.171
Extension	20	80	-	-	60	30	10	-	1.143	0.565
General state	50	50	-	-	70	30	-	-	0.267	0.606
Giant cells	100	-	-	-	100	-	-	-	-	1
Particles	10	-	70	20	-	-	30	70	2.277	0.32

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Ballal, N.V.; Rao, S.; Rao, N.; Urala, A.; Yoo, J.-S.; Al-Haj Husain, N.; Özcan, M. Evaluation of Two Different Types of Mineral Trioxide Aggregate Cements as Direct Pulp Capping Agents in Human Teeth. Appl. Sci. 2021, 11, 10455. https://doi.org/10.3390/app112110455

AMA Style

Ballal NV, Rao S, Rao N, Urala A, Yoo J-S, Al-Haj Husain N, Özcan M. Evaluation of Two Different Types of Mineral Trioxide Aggregate Cements as Direct Pulp Capping Agents in Human Teeth. Applied Sciences. 2021; 11(21):10455. https://doi.org/10.3390/app112110455

Chicago/Turabian Style

Ballal, Nidambur Vasudev, Sheetal Rao, Nirmala Rao, Arun Urala, Jun-Sang Yoo, Nadin Al-Haj Husain, and Mutlu Özcan. 2021. "Evaluation of Two Different Types of Mineral Trioxide Aggregate Cements as Direct Pulp Capping Agents in Human Teeth" Applied Sciences 11, no. 21: 10455. https://doi.org/10.3390/app112110455

APA Style

Ballal, N. V., Rao, S., Rao, N., Urala, A., Yoo, J.-S., Al-Haj Husain, N., & Özcan, M. (2021). Evaluation of Two Different Types of Mineral Trioxide Aggregate Cements as Direct Pulp Capping Agents in Human Teeth. Applied Sciences, 11(21), 10455. https://doi.org/10.3390/app112110455

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Evaluation of Two Different Types of Mineral Trioxide Aggregate Cements as Direct Pulp Capping Agents in Human Teeth

Abstract

1. Introduction

2. Materials and Methods

2.1. Inclusion and Exclusion Criteria

2.2. Clinical Procedure

2.3. Tissue Processing for Microscopic Examination

2.4. Statistical Analysis

3. Results

4. Discussion

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Conflicts of Interest

References

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