Background:

DRJ

Dent Res J

Dental Research Journal

1735-3327 2008-0255

Medknow Publications Pvt Ltd

India

DRJ-12-144

Original Article

Histological assessment of pulpal responses to resin modified glass ionomer cements in human teeth

Eskandarizadeh

Ali

Parizi

Molook T

Goroohi

Hossein

Badrian

Hamid

Asadi

Abbas

Khalighinejad

Navid

Department of Restorative Dentistry and Oral and Dental Disease Research Center, Kerman, Iran Department of Oral and Maxillofacial Pathology and Oral and Dental Disease Research Center, Kerman, Iran Post-graduate Student of Endodontics, Yazd, Iran Post-graduate Student of Restorative Dentistry, Yazd Shahid Sadooghi University of Medical Sciences, Yazd, Iran Dentist, Iran Dentist, Iran

Address for correspondence:Molook Parizi, Department of Oral and Maxillofacial Pathology, Oral and Dental Disease Research Center, Kerman, Iran drtorabiparizi@yahoo.com

Mar–Apr 2015

12 2 144 149

2015

This is an open-access article distributed under the terms of the Creative Commons Attribution-Noncommercial-Share Alike 3.0 Unported, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Background:

The biocompatibility of resin-modified glass ionomers (RMGIs) as a lining material is still under question. The present study evaluated the response of the pulp-dentin complex following application of resin-modified glass-ionomer cement, calcium hydroxide and conventional glass-ionomer in deep cavities prepared in human teeth.

Materials and Methods:

In this controlled clinical trial, 30 deep class V buccal cavities (3 mm × 2 mm × 2 mm) were prepared in human premolars treatment planned to be extracted for orthodontic reasons and divided into 3 groups. Groups were lined by a RMGI (Vivaglass), conventional glass Ionomer (Ionocid) and calcium hydroxide respectively. The cavities were subsequently filled with amalgam. Each group was then divided into two sub-groups according to time intervals 5 and 30 days. The patients were referred to Kerman Dental School and in accordance with orthodontic treatment plan; premolars were extracted and then prepared for histological assessment. The sections were stained with hematoxylin and eosin and periodic acid Schiff techniques. All of the samples were examined using a number of criteria including odontoblastic changes, inflammatory cells response, reactionary dentin formation and presence of microorganisms. The data were analyzed by Kruskal-Wallis and Mann-Whitney tests. P < 0.05 was considered as significant.

Results:

There was no significant difference among odontoblastic changes, reactionary dentin, presence of bacteria and inflammatory cells response of the groups (P > 0.05).

Conclusion:

Ionocid and Vivaglass resin-modified glass ionomers can be used as lining materials in human teeth.

Biocompatibility calcium hydroxide glass ionomer pulp response tertiary dentin

</sec> <sec> <title>Introduction

Researches have shown that the placement of restorative materials will induce a response in the tooth dentin-pulpal complex to some degree. ¹Thus, the placement of a biocompatible liner on the cavity floor has been recommended to prevent harmful changes in dentin-pulp complex. ²

Calcium hydroxide cement (CHC) has long been the material of choice as a liner beneath amalgam restorations. ³, ⁴CHC is an alkaline dental material ⁵used as a liner under restorations, which acts as a stimuli blocker by filling small gaps by its crystal growth; ⁶however, concerns exist regarding the solubility of CHC, its lack of chemical or mechanical adhesiveness, its potential accelerated degradation during the adhesion bonding process ⁷and its inability to provide an effective long-term protection against microleakage. Therefore, scientists proposed glass-ionomer cements (GICs) as alternative lining materials to CHCs. ¹

In early 1970′s, Wilson and Kent ⁸introduced the first GIC, which was based on a single acid. At that time, its biocompatibility was not a big concern; however, with the addition of more acids to enhance certain characteristics and reduce setting time, GICs became more irritating ⁹and less biocompatible, despite their advantages such as fluoride release, non-shrinking setting reaction, chemical adhesion to tooth structure ¹⁰and linear coefficient of thermal expansion similar to tooth. ¹¹

Selection of a new material for clinical use must consider not only the mechanical and physical properties, but also biological compatibility. To evaluate the biocompatibility of dental materials, secondary animal tests and clinical human tests (usage tests) must be performed following initial in vitro tests. ²Since late 1980′s, when further development in the field of GIC led to the introduction of a hybrid generation of these materials, so called resin-modified glass-ionomer cements (RMGICs), ¹², ¹³these materials have passed various in vitro and animal tests, nominated for usage tests. Although studies show that RMGICs posses improved mechanical and physical properties and better adhesiveness than conventional glass-ionomers (GIs), ², ¹⁴their biological compatibility is still under question. Conducting a systematic review on in vivo human researches aiming at assessing the biocompatibility of RMGICs, Mickenautsch et al. ⁷did not come to a definite conclusion about the difference between pulpal reactions in resin-modified glass ionomer (RMGIs) and Dycal (CHC) and researchers have not made a definitive statement about this issue yet. This study was designed to comparatively investigate the biocompatibility of conventional GIC, RMGIC and Dycal to put a short step forward in a better understanding of dental materials.

Materials and methods

Ethical considerations

This study was approved by Ethical Committee of Dental School of Kerman University of Medical Sciences with registry number 85/17.

Tooth selection

In this controlled clinical trial, 30 non-carious, intact first premolars of 25 patients - 14 females and 11 males - aged between 14 and 30 referred to Kerman Dental School for tooth extraction for orthodontic treatment were included. The patients were informed about the procedures and potential risks of the study; written consents were obtained from the participants. The teeth were divided into six groups: V5, V30, I5, I30, D5 and D30.

Cavity preparation and filling

Prior to tooth extraction, the buccul surfaces of the teeth were cleansed using pumice powder and rubber cap. Each tooth was anaesthetized (2% Lidocaine with 1/100000 epinephrine, Darupakhsh, Tehran, Iran). Isolation was performed, using cotton rolls. Then Diamond fissure bur 245 (DiaTech LLC, Pforzheim, Germany) and high speed rotary instrument with water spray were used to prepare Class V cavities extended 3 mm mesiodistally, 2 mm occlusocervically with 2 mm depth, keeping the gingival floor in enamel, while 3-way syringe was washing the location. Each cavity was then vigorously rinsed and dried with a three-way syringe. After preparing the teeth for filling, the teeth in D5 and D30 groups were first treated with self-cure calcium hydroxide (Dycal, Dentsply, USA); equal amounts of Dycal tubes were mixed and placed on the axial wall of the cavity and left for 2.5-3.5 min to get rigid. Second, the teeth in I5 and I30 groups were treated with conventional GI cement(Ionocid-L30, Salami, Tehran, Iran). A scoop of powder was blended with a droplet of liquid and mixed for 10 s, was applied in the cavity and left for 2-3 min to get rigid. Third, the teeth in V5 and V30 groups were treated with RMGI (Vivaglass, Ivoclar, Germany); 0.25 g of powder was blended with 1 g of liquid and mixed for 20 s. One layer of RMGI was applied in cavity and dried with a stream of air. The RMGI was light cured (light cure unit, Degulux, Germany) with 400 mw/cm ²intensity for 20 s, according to manufacturer instructions. All of these procedures were performed according to manufacturers′ instructions. To prevent dentin sensitivity, two layers of varnish (Copalite, Teledyene Getz, Austria) were applied in the cavities and cavities were filled with lathecut high-copper amalgam (Cina, Faghihi Tehran, Iran), packed, cured and burnished following the conventional method.

Tooth extraction and histomorphological assay

After 5 days, V5, I5 and D5 teeth were anesthetized and extracted, while V30, I30 and D30 were extracted after 30 days with a minimum trauma. Roots of the teeth were cut-off in the middle by a diamond bur, accompanied by water spray. In order to survey pulpal reactions, histology slides were provided from each specimen. To do this, the specimens were first immersed in 10% formalin for 10 days, followed by a 3-day immersion in 5% phosphoric acid. Phosphoric acid was replaced every day. ⁷Then, the teeth were dehydrated, embedded in series of graded alcohol, finally ending up in Xylene. Then, the specimens were placed into melted paraffin. The melted paraffin was cooled, leaving a salad media for the sectioning of the tissue. After preparing 4 μm sections, the specimens were stained, using hematoxylin and eosin technique for routine histological evaluation and periodic acid Schiff staining for detecting microorganisms. At the final step, the slides were observed by means of light microscope (Zeiss, Germany) with ×40, ×100 and ×400 magnification Figure 1, Figure 2, Figure 3and Figure 4. Pulpal reactions were investigated and scored using the criteria illustrated in Table 1. Data were analyzed by Kruskal-Wallis and Mann-Whitney U statistical tests. P < 0.05 was considered as significant. Figure 1

Infl ammatory response in a specimen of Vivaglass group after 5 days (×10)

Figure 1

Figure 2

Tertiary dentin formation in a specimen of Dycal group after 30 days (×10)

Figure 2

Figure 3

Presence of microorganisms; periodic acid Schiff staining (×10)

Figure 3

Figure 4

Odontoblastic changes in a specimen of Ionocid group after 5 days (×10)

Figure 4

{Table 1}

Results

The results of this study are illustrated in Table 2. There was no significant difference among pulpal responses of the applied materials after 5 days (P = 0.32) and after 30 days (P = 0.81). Odontoblastic changes also showed no significant difference after 5 and 30 days (P = 0.07, P = 0.35 respectively). In terms of bacterial presence, no significant difference was seen among the groups both in 5 days and 30 days. No tertiary dentin (TD) formation occurred after 5 days and there was no difference in TD formation among the groups (P = 0.34).{Table 2}

Discussion

While some studies demonstrate that the RMGIs are less biocompatible than conventional GIs and calcium hydroxide ¹⁵, ¹⁶, ¹⁷the biocompatibility of these materials as cavity liners in human teeth is still under question. The results of this study showed that there is no significant difference between pulpal responses and TD formation of teeth lined with RMGIs and those lined with conventional GIs or calcium hydroxide.

Studies show that evaluating pulpal responses-inflammatory response, odontoblastic changes, presence of bacteria and TD formation-provides an appropriate index for choosing liner materials, as these criteria estimate the pulpal activity after restoration of teeth. ¹Mickenautsch et al. in their systematic review study, ⁷stated that the remaining dentin thickness does not significantly influence the histological pulpal responses. Thus, this criterion was not included in the present study.

In the present study, frequency of more intensive pulpal responses (odontoblastic changes and inflammatory response) of teeth lined with Vivaglass within 5 days were higher than 30 days. This is probably due to presence of residual monomers - such as hydroxyethyl methacrylate and triethylene glycol dimethacrylate - in the material within the first few days after cavity lining . ¹⁷This finding is in agreement with Mousavinasab et al. study stating that pulpal inflammatory reactions after 7 days are significantly higher than those of 30 and 60 days. ¹⁸

The results of the present study showed that moderate to severe inflammatory responses occur after 30 days in the absence of bacteria. These findings and the findings of similar studies ², ¹⁸emphasize the fact that although microorganisms and their products are considered to be the main etiological factor for dental pulpal inflammation, the restorative materials and liners can also trigger inflammatory responses. ¹⁹

There is another variable that influences the intensity of inflammatory responses. Murray et al. stated that time elapsed since material placement - as well as bacterial presence and type of material, affects inflammatory response, ¹⁹and that level of pulpal inflammation decreases over time. In the present study, the intensity of these responses has decreased over time, when Vivaglass was used.

Studies show that the components of RMGI may be released in wet environment. ¹⁷In the present study, Vivaglass did not cause severe pulpal inflammation. Probably an acid-base reaction in the cavity floor has prevented its components from being released. Furthermore, since no acid-etching was used in this study, the remaining smear layer did not allow the formation of a wet environment. ²

For both 5-day and 30-day time periods, mild and moderate-to-severe odontoblastic changes were higher when Vivaglass was used; nevertheless, the difference was not significant among the groups. This could be attributed to structural differences of deep and superficial dentin; first, number of dentinal tubules per square millimeter in the inner diameter of deep dentin is higher than superficial dentin; second, the inner diameter of deep dentin is larger than superficial dentin. As a result, the continuous out-ward dentin fluid movement interferes with monomer-to-polymer conversion and remaining monomers cause the rupture of odontoblasts. ²Other studies also reported more intensive odontoblastic changes for RMGI compared to Dycal; however, these studies also did not find a significant difference between pulpal reactions to these two materials. ², ¹⁸

In a study by Costa et al. presence of bacteria in walls of two teeth lined with RMGI was observed, giving no explanations for this observation. ²Furthermore, in the present study, two specimens showed bacterial presence. Since RMGIs provide proper seal, ²⁰inadequate isolation may be the main cause of bacterial presence and bacteria may have penetrated the cavity during restorative procedures rather than having leaked the cavities.

In the present study, no TD formation was detected after 5 days. Since all of the groups revealed TD formation after 30 days, it could be concluded that the elapsed time has had more significant effect than the type of material in TD formation. The results of the present study are in contrary with Murray et al.′s study. They reported that in terms of TD formation, the type of restorative material is more important than the time elapsed. This is because the time elapsed between treatment and histometric analysis of teeth in Murray et al.′s study was between 28 and 381 days. In fact, the specimens in that study had at least 28 days, which is the average time needed for TD formation, ²¹, ²²while in the present study 5 days was not enough time for TD formation. Also, Mousavinasab et al. did not find any TD formation after 7 days; however, they observed TD after 30 and 60 days in the specimens, regardless of the material used to line the cavities. ¹⁸

Murray et al. in their study demonstrated that TD formation in teeth lined with CHC occurs more than teeth lined with RMGI; ¹however, the present study and Mousavinasab et al.′s study showed that different materials do not cause significant difference in the TD formation. Formation of TD is followed by creating a dead tract in dentin and complete cessation in the formation of secondary dentin. ²³The contrast between these results may be due to the fact that RMGI in Mousavinasab et al. and our study was also able to create the dead tract in dentin. Yet we suggest that these materials be evaluated in carious teeth, too. We also suggest conducting similar studies with larger number of samples and longer time periods and with remaining dentin thickness measurement.

Conclusion

The results of this study showed that all of these materials were biocompatible when applied in deep cavities. Due to their improved properties and acceptable biocompatibility, RMGIs can be recommended to be used as lining materials.

Acknowlegments

We would like to express our sincere acknowledgment in the support and help of Research Department and Dental Material Research Center of Dental School of Kerman University of Medical Sciences.

Murray

About

Franquin

Remusat

Smith

Restorative pulpal and repair responses

J Am Dent Assoc 2001 132 482 91

Costa

Giro

do Nascimento

Teixeira

Hebling

Short-term evaluation of the pulpo-dentin complex response to a resin-modified glass-ionomer cement and a bonding agent applied in deep cavities

Dent Mater 2003 19 739 46

Weiner

Liners, bases, and cements: A solid foundation

Gen Dent 2002 50 442 6

Pinto

de Araújo

Franzon

Figueiredo

Henz

García-Godoy

Clinical and microbiological effect of calcium hydroxide protection in indirect pulp capping in primary teeth

Am J Dent 2006 19 382 6

Tam

Pulver

McComb

Smith

Physical properties of calcium hydroxide and glass-ionomer base and lining materials

Dent Mater 1989 5 145 9

Aoki

Takase

Ishikawa

Evaluation of lining materials and a new concept for lining: Alpha-TCP cement or visible light curing calcium hydroxide composition in composite resin restoration

Bull Tokyo Dent Coll 1991 32 171 81

Mickenautsch

Yengopal

Banerjee

Pulp response to resin-modified glass ionomer and calcium hydroxide cements in deep cavities: A quantitative systematic review

Dent Mater 2010 26 761 70

Wilson

Kent

The glass-ionomer cement, a new translucent dental filling material

J Appl Chem Biotechnol 1971 21 313

Stanley

Local and systemic responses to dental composites and glass ionomers

Adv Dent Res 1992 6 55 64

Mount

A Color Atlas of Glass Ionomer Cement.2 nd ed

London: Martin Dunitz; 4 A Color Atlas of Glass Ionomer Cement 2 nd ed London: Martin Dunitz; 1994 p 1-42

Huang

Chang

Cytotoxicity of resin-based restorative materials on human pulp cell cultures

Oral Surg Oral Med Oral Pathol Oral Radiol Endod 2002 94 361 5

Wilson

Resin-modified glass-ionomer cements

Int J Prosthodont 1990 3 425 9

Sidhu

Watson

Resin-modified glass ionomer materials.A status report for the American Journal of Dentistry

Am J Dent 1995 8 59 67

do Nascimento

Fontana

Teixeira

Costa

Biocompatibility of a resin-modified glass-ionomer cement applied as pulp capping in human teeth

Am J Dent 2000 13 28 34

Sasanaluckit

Albustany

Doherty

Williams

Biocompatibility of glass ionomer cements

Biomaterials 1993 14 906 16

Oliva

Della Ragione

Salerno

Riccio

Tartaro

Cozzolino

Biocompatibility studies on glass ionomer cements by primary cultures of human osteoblasts

Biomaterials 1996 17 1351 6

Geurtsen

Spahl

Leyhausen

Residual monomer/additive release and variability in cytotoxicity of light-curing glass-ionomer cements and compomers

J Dent Res 1998 77 2012 9

Mousavinasab

Namazikhah

Sarabi

Jajarm

Bidar

Ghavamnasiri

Histopathology study on pulp response to glass ionomers in human teeth

J Calif Dent Assoc 2008 36 51 5

Murray

Hafez

Smith

Cox

Bacterial microleakage and pulp inflammation associated with various restorative materials

Dent Mater 2002 18 470 8

Köprülü

Gürgan

Onen

Marginal seal of a resin-modified glass-ionomer restorative material: An investigation of placement techniques

Quintessence Int 1995 26 729 32

Murray

About

Lumley

Franquin

Remusat

Smith

Human odontoblast cell numbers after dental injury

J Dent 2000 28 277 85

Murray

About

Lumley

Smith

Franquin

Smith

Postoperative pulpal and repair responses

J Am Dent Assoc 2000 131 321 9

Garg

Textbook of Operative Dentistry.1 st ed

New Delhi: Jaypee Brothers Medical Pub Textbook of Operative Dentistry 1 st ed New Delhi: Jaypee Brothers Medical Pub; 2010 p 288