J Bagh College Dentistry Vol. 29(3), September 2017 Comparison among Restorative Dentistry 9 Comparison among pulp capping materials in: calcium ion release, pH change, solubility and water sorption(An in vitro study) Dr. Nagham A. AL-Hyali, B.D.S., M.Sc.(1) ABSTRACT Background: Calcium hydroxide and calcium-silicate materials used as direct pulp capping materials. The aims of this in vitro study is to compare among these materials in, the calcium ion release and pH change in soaking water after immersion of materials’ specimens in deionized water. Also Solubility and water sorption of materials’ specimens measured after soaking time. Calcium-silicate materials used were Biodentine, TheraCal and MTA Plus. Materials and methods: Four materials used in this study; Urbical lining (as control group), Biodentine, TheraCal and MTA Plus. Ten discs fabricated from each tested material, by using plastic moulds of 9 mm diameter and 1 mm thickness. Each specimen was immersed in 10 ml of deionized water and stored at 37ºC using incubator for 3 hr, 24hr, 14 days and 30 days as a sequence. The amount of calcium ion (Ca+2) released in soaking water was measured in each tube using atomic absorption spectrophotometer. Also pH analysis for soaking water measured by using pH meter. For solubility and water sorption measurement, the specimen (n=10) weighed with precision weighing scale before immersion in deionzed water to determine the initial Weight (W1) and immediately after weighing immersed in 10 mL of deionized water at 37 °C for 1 week using an incubator, then removed and weighing again (W2). The samples blotted dry using filter paper and dehydrated in an oven at 37 °C for 24 hr and weighed again (W3). Then percentage of solubility and water sorption were determined. The obtained data were analysed using one-way ANOVA and Tukey tests at 0.05 significant levels. Results: Statistical analysis showed highly significant differences (P<0. 05) among tested materials and in all tests (Ca+2 release, pH change, solubility and water sorption). Biodentine showed higher calcium ion released at four soaking time, with non significant difference with TheraCal and highly significant difference with MTA Plus and control group at 24 hr. immersion time; While MTA Plus showed non significant difference with control group at 24 hr. Less amount of calcium released was in control group. All tested materials induced alkalization of the soaking water that decreased with time. Means of solubility and water sorption showed that MTA Plus and biodentine had higher solubility in comparison with control group, while TheraCal showed less solubility than control group. The results of water sorption showed that less sorption percentage occurred in control group in comparison with other groups. Conclusion: calcium-silicate materials released more Ca+2 with time than calcium hydroxide. TheraCal showed less solubility and higher water sorption in comparison with control group. Biodentine and MTA Plus showed higher solubility and water sorption in comparison with TheraCal and control group. Keywards: calcium-silicate materials, calcium hydroxide, solubility, calcium ion and pH. (J Bagh Coll Dentistry 2017; 29(3):9-16) INTRODUCTION The procedure of pulp capping relies primarily on the ability of pulpal tissue to heal. Various factors affect this process including age, periodontal condition and stage of root formation. Procedural factors such as: size of exposure, its nature (traumatic, mechanical or carious) and microbial contamination of the site have also been described as determinants of the success of pulp capping. However, the importance of these factors has been challenged. Wide arrays of materials have been used for pulp capping, but calcium hydroxide remains the standard (1). For many decades' calcium hydroxide has been the standard material for maintaining pulp vitality, used in a direct and indirect pulp capping, because it's capable of stimulating the formation of tertiary dentin by the pulp, which seals exposures by newly formed hard tissue (2).Nevertheless, calcium hydroxide has some drawbacks such as poor bonding to dentin, material resorption and (1) Lecturer, Conservative Department, College of Dentistry, Baghdad University. mechanical prevent microleakage in term, because instability, so thatit does not of the porosities (tunnel defects) of the newly formed hard tissue, which may act as a portal of entry for microorganisms. These may cause secondary inflammation of the pulp tissue and thought to be responsible for failed maintenance of tooth vitality. In addition, the high pH (approximately 12.5-12.8) of calcium hydroxide suspensions causes liquefaction necrosis at the surface of the pulp tissue (3, 4). The bioactivity of pulp capping agents was often associated with ability to release hydroxyl and calcium ion (Ca+2) (4). Hydroxyl ion (OH-) provides an antimicrobial effect by formation alkaline media (higher pH) that create an adverse environment for bacterial survival and proliferation (5,6), and causes pulpal necrosis that triggers tissue repair and prompts the release of proteoglycans, metalloproteinases and growth factors from the mineralized dentine matrix. OH- ion can signal pulpal undifferentiated cells to migrate to the injury site, proliferate and differentiate into odontoblasts like cells to secrete organic extracellular matrix and initiate mineralization (7). Ca+2ion is also necessary for J Bagh College Dentistry Vol. 29(3), September 2017 Comparison among Restorative Dentistry 10 differentiation and mineralization of pulp cells (8) by reducing capillary permeability and in turn reducing, the serum flow and the levels of inhibitory pyrophosphates that causes mineralization (9). In addition, the eluted Ca+2 ion increases the proliferation of human dental pulp cells in dose dependent manner (10,11) and activates pyrophosphatase which helps to maintain dentine mineralization and the formation of a dentine bridge (12). Bioactive materials have been used in every field of dentistry and medicine. These materials are broadly used in the field of conservative dentistry and available in different form and composition that acts directly on vital tissue inducing its healing and repair induction of various growth factors and different cells. Bioactive materials (Calcium silicate– containing materials), including Mineral Trioxide Aggregate (MTA), Biodentine and TheraCal LC are new material that have numerous applications, such as direct pulp capping. Interestingly, calcium hydroxide are formed during their setting reaction, which impart with antibacterial and regenerative properties. For this reason, bioactive materials and calcium hydroxide are thought to share a similar mechanism of action (13). However, studies showed less inflammation, better dentin bridging, hydroxyl apatite formation, and minimal cytotoxicity with bioactive materials (14, 15). Water sorption and solubility are important physical properties of pulp capping material because degradation of the cement and lining materials, leads to debonding of the restoration and recurrent decay (16). However, most of tests are static solubility tests, unrelated to the conditions found in the oral environment and applied only to short-term solubility, while some investigators studied the solubility in dynamic state (different pH) (17,18). The aim of this in vitro study is first to compare between calcium hydroxide and calcium- silicate containing dental materials in: calcium ion released in deionized water, solubility, water sorption and whether their pH alters with time. MATERIALS AND METHODS Four types of pulp capping materials (Table 1) used in this study (four groups), the powder / liquid ratio and mixing of the components of each material was carried according to manufacturer instructions as follow: Control group (Calcium hydroxide group): Urbical lining consist of two pastes mixed in a 1:1 weight proportion. MTA Plus group: Mineral Trioxide Aggregate material consist of powder and liquid, manipulated by mixing of 3 parts of powder with 1 part of liquid to obtain putty like consistency, setting time for MTA about 55 min (19). Biodentine group: Biodentine consist of powder and liquid. The powder was mixed with 5 drops of liquid in a capsule using a triturator (YDM, HANGZHOU YIN YA new materials CO. LTD, China) for 30 seconds, setting time about 12 to 15 minutes (20). TheraCal group: TheraCal its light curing material, in this study cured by light emitted diode LED (LATTE, China) with light intensity 700mW/cm2. Duration of light curing about 20 seconds for each layer which should not exceed 1mm in depth (21). Specimens’ construction Fabrication of ten disc-shaped specimens from each tested material (Table 1), by using plastic moulds of 9 mm diameter and 1 mm thickness. Preweighed dental floss was embedded in the discs during fabrication to assist in handling of the samples. For fabrication of each specimen, the mould filled with the tested material which mixed according to manufacturers’ instructions, in a room with climate-controlled conditions (50±10% humidity and 23±2ºC), then the filled mould was covered with a polyester strip and a glass plate (Figure 1), maintained under pressure until complete setting of chemical set materials, while light cure TheraCal LC did not need pressure (22, 23). After construction of specimens, each specimen immersed in separated plastic tube containing 10 ml of deionized water for 3hr, 24hr, 14 days and 30 days as a sequence. At each immersion time, the soaking water subjected to the following testing: pH analysis and testing of calcium ions released. Solubility and water sorption percentage were measured for each material after immersion time 7 days. Testing of Solubility and Water Sorption The American Dental Association’s specification #8 (zinc phosphate cement solubility) was adopted with a few small modifications to design the methodology used in this study, the solubility tests used deionized water rather than oral fluids for immersion of specimens (4, 23). The sample (n=10 for each tested materials) weighed with precision weighing scale (Professional Digital Table Top Scale, China) (figure1), before immersion in water to determine the initial Weight (W1) and immediately weighing after immersed vertically by using dental floss, in 10 mL of deionized water in individually plastic tube at 37 °C for 1 week in an incubator (Memmert, Germany), then saturated sample removed and weighing again (W2). The samples then blotted dry using filter paper, dehydrated in J Bagh College Dentistry Vol. 29(3), September 2017 Comparison among Restorative Dentistry 11 an oven at 37 °C for 24 hr, and weighed again (W3). The loss of material (solubility) was obtained from the difference between the initial and the final drying mass (W1- W3) of each disc, discounting the mass of the dental floss. Each weight (in µg/mm3) measurement was repeated three times. The percentage of solubility and water sorption were determined as follows (15, 24): % Solubility= [(W1– W3)/ W3] 100% %Water Sorption= [(W2– W3)/ W3]100% W1: The initial weight of sample W2: Sample saturated with water W3: The final weight of sample after dehydration Testing of calcium ions release and pH analysis Each disc-shaped specimen was immersed in 10 ml of deionized water and stored at 37ºC using incubator (Memmert, Germany) for 3 hr, 24hr, 14 days and 30 days. The specimens removed from tube after tested times and amount of calcium ions released in soaking water was measured (in ppm) in each tube using atomic absorption spectrophotometer (25) (ICE 3300, Thermo Scientific, USA) and pH of each solution measured using pH meter (HANNA instruments, PH microprocessor PH meter and HI 1332 PH probe, China). Statistical analysis was performed with SPSS software package (version 20.0). Data of each test collected and analyzed using analysis of variance test (One-Way ANOVA) and Tukey test to find any significance difference between the groups. Mean difference is significant at the 0.05 level. Table (1): Types of materials used in the study, types of activation, manufacturer and batch number. Materials Composition Activation Manufacturer and Batch # Urbical lining (Calcium hydroxide) Base paste: Ester glycol salicylate, Zinc oxide, Calcium phosphate, Calcium tungstate Pigments Catalyst paste: Calcium hydroxide 26%, N-ethyl toluene sulphonamide, Zinc oxide, Titanium dioxide, Zinc stearate, Calcium wolframate, salicylate. Chemical Promedica, dental material GmbH, Domagkstra, Neumunster, Germany. Batch#: 2441 MTA Plus (Mineral Trioxide Aggregate) Powder: tricalcium silicate (CaO)3 · SiO2dicalcium silicate (CaO)2 · SiO2tricalcium aluminate (CaO)3· Al2O3bismuth oxide Bi2O3, gypsum CaSO4 ·2 H2O liquid: distilled water H2O Chemical PPH CERKAMED company, Kwiat Kow Skiego, StalowaWola, Polska Batch #: 1809141 BiodentineTM Powder: tricalcium silicate Ca3SiO5 (>70%) dicalcium silicate Ca2SiO4 (<15%) zirconium oxide ZrO2 (5%) calcium carbonate CaCO3 (>10%) as filler Iron oxides (<1%) liquid water H2O, calcium chloride CaCl2 (>15%) as accelerator, hydro soluble polymer (polycarboxylate), water reducing agent Chemical Septodont, Saint Maurdes, Fosses, France. Batch#: B14835 TheraCal LC Paste: 45%wt mineral material (type III Portland cement), 10%wt radiopaque component, 5%wt hydrophilic thickening agent (fumed silica), 45%metacrylic resin Physical (Light) BISCO, Irving Park Rd. Schaumburg, U.S.A. Batch #: 1500000915 J Bagh College Dentistry Vol. 29(3), September 2017 Comparison among Restorative Dentistry 12 Figure 1: Some of equipment and instruments used in this study RESULTS Table 2 summarizes Ca+2 ion released means and standard deviations for tested materials, the results showed that all tested materials released Ca+2 ion in soaking time and the released decreased with time, with the exception of biodentine at 30 days, the mount released more than at 14 days. All calcium silicate-containing materials released more Ca+2 ion than Ca(OH)2 material (Table 2), except MTA Plus at 14 and 30 days. One Way ANOVA showed highly significant differences among the groups in alkalization effect on soaking water. All materials induced alkalization of the soaking water that decreased with time (Table 2). One Way ANOVA and Tukey test showed highly significant differences among the groups in Ca+2 ion released (Table 4). Higher solubility occurred in MTA Plus followed by Biodentine, Urbical and less percentage occurred with TheraCal (Table 3). The results of water sorption test, showed highly significant differences among the groups with higher percentage of sorption occurred in MTA Plus group followed by, Biodentine, TheraCal and less percentage occurred with Urbical (Table 3, 5). DISCUSSION The ability to release calcium and hydroxyl ions is a key factor for successful pulp capping therapy because of calcium’s action on pulp cell differentiation and hard tissue mineralization (26). The therapeutic effect of calcium hydroxide materials is due to its ability to break down into calcium and hydroxyl ions. Hydroxyl ion show an affinity to various biologically active substances such as microbes causes endodontic diseases (27). Their antimicrobial activity is formation of potent alkaline medium leading to the destruction of lipids, which are the main component of bacterial cell membrane and causing structural damage to bacterial proteins and nucleic acids (28). Chemically, calcium hydroxideis classified as a strong base with high pH. Although some studies have confirmed its efficacy against endodontic bacteria, other studies have questioned its effectiveness (29). In this study calcium hydroxide compared with calcium silicate materials including, MTA Plus, Biodentine and TheraCal in calcium ion release, because these materials formed calcium hydroxide during their setting reaction (30). Mineral Trioxide Aggregate introduced by Torabinejad in 1993 (31). It's a bioactive material has a common characteristic of apatite formation (19). This is a material of choice for vital pulp therapy, apexification, apexogenesis, correcting procedural errors as well as for root-end filling material in apicoectomy procedures (13). The exact mechanism of dentinal bridge formation when MTA is used is not known completely. However, it was found that when MTA was used as a pulp capping agent it induces cytologic and functional changes within pulpal cells, resulting in formation of fibro dentine and reparative dentin at the surface of mechanically exposed dental pulp, its causes proliferation, migration and differentiation of odontoblast-like cells that produce a collagen matrix. This formed mineralized matrix by osteodentin initially and then by tertiary dentin formation (19). Biodentine with Active Biosilicate Technology announced by dental material manufacturer Septodent in September of 2010, and made available in January of 2011. Biodentine is a calcium silicate based material having similar properties of dentin and has a positive effect on vital pulp cells stimulating tertiary dentin formation (32), used for the treatment of root perforation or for the pulpal floor, internal and external resorption, apexification, retrograde root canal obturation, pulpotomy and also for temporary sealing of cavities and cervical filling (33). Septodent claimed that Biodentine is not mutagenic (34) and can resist microleakage in comparison with MTA (35). TheraCal It is a light cured resin modified calcium silicate filled liner used for insulating and protecting dentin-pulp complex in a direct and indirect pulp capping, and as a protective base/liner under composites, amalgams, cements and other base materials (21). TheraCal has the ability to form hydroxyl apatite when immersed in a phosphate-containing solution (36) with lowest cytopathic effects (14).In this in vitro study, calcium silicate groups showed highly significant differences in comparison with control group (p<0.001). Biodentine demonstrated higher alkalinizing capability and calcium ion than other groups at all soaking time (3 h, 24 h, 14 days and 30 days), the J Bagh College Dentistry Vol. 29(3), September 2017 Comparison among Restorative Dentistry 13 Ca+2 ions and pH of soaking waterdecrease with time and pH range from (11.06-9.17) with highly significant differences among subgroups of biodentine. These results agreed with Gandolfi M. et al., 2013(15) and Gandolfi M. et al., 2014 (37). Tukey test revealed highly significant differences among subgroups of materials, except between control and MTA Plus groups, and between biodentine and TheraCal groups at 24 hr. immersion time, the results were non-significant differences. The high Ca+2 ion released of biodentine can be correlated with the presence of calcium silicate component and calcium chloride (15). MTA Plus similar to Biodentine in composition, the results showed higher Ca+2release and higher pH (11.65-8.21) in comparison with TheraCal and control group. The calcium ion release and alkalizing decrease with time. These results agreed with Gandolfi M. et al., 2013 (15) and Gandolfi M. et al., 2014 (37), but disagree with Gandolfi M.G. et al., 2012 (21) who showed that TheraCal release moreCa+2 ions in comparison with Dycal and ProRoot MTA. Calcium silicate materials leached large amounts of Ca+2 and OH- ions (high pH) because, the hydration reaction of the calcium silicate particles triggers the dissolution of their surface with the formation of a calcium silicate hydrate gel and Ca(OH)2, together with the release of Ca +2 and OH- (15), which impart them with antibacterial and regenerative properties (13, 38). Bioactive materials were used in contact with periapical bone tissue or with vital pulp. For this reason, they should possess specific bio-properties like biocompatibility, bio-interactivity (release of biologically relevant ions), and bioactivity (apatite-forming ability) in order to promote the activity of mineralizing cells and the formation of new periapical bone or reparative dentine (15). All tested materials caused alkaline soaking water and alkalinity decreased with time. The elevated pH of calcium hydroxide and calcium silicate materials activated alkaline phosphatise which was hydrolytic enzyme that acted by liberation of inorganic phosphate from the esters of phosphate, it’s important for process of mineralization (38, 39). The best pH for activation of this enzyme ranged from (8.6 to 10.3) (40, 41). This enzyme can separate the phosphoric esters, freeing phosphate ions, which once free react with Ca+2 ion from the blood stream to form a precipitate calcium phosphate in the organic matrix. This precipitate is the molecular unit of hydroxyl apatite (15). Ion release depends on the nature of the mineral particles and on the network structure of the cement responsible for water sorption and solubility as well as the permeability of the material to water diffusion (porosity) (37). Calcium release and pH were measuredin deionized water rather than simulated body fluid in order to standardize the test conditions and hence allow a comparison of the data with other future studies (15). Solubility test found that calcium hydroxide had less solubility (6.45%) than Biodentine and MTA Plus, but more solubility than TheraCal, with highly significant differences among the groups. While water sorption of control group was less than other groups.Biodentine showed less solubility (13.05%) and water sorption (16.3%) in comparison with MTA Plus (solubility (19.35%) and water sorption (26.48%), correlated with the restricted amount of dispersing water- reducer super plasticizing mixing fluid likely based on polycarboxylic ether. These results in agreement with Gandolfi et al, 2014 (37), but disagree with Gandolfi etal., 2013 (15) who found that biodentine had lower watersorption than ProRoot MTA while the solubility values for ProRoot MTA lower than Biodentine. Biodentine and MTA Plus were prepared by mixing the mineral powder with water-based liquid using very different liquid/powder weight proportions for each material. The liquid susceptible to evaporation in the drying procedure needed for the solubility test to obtain the final dry mass. The hydration of calcium silicate cements proceeds by converting liquid into structural and constrained water. This process occurs mainly in the first few days, moreover the leaching of water-soluble components causes' weight loss. This means that the reduction of the original weight obtained in the dry mass will not be entirely due to the solubility of the material, because much of the weight loss is caused by evaporation of the mixing free water during the final drying of the samples. All this must be taken in consideration when collecting the data of solubility (15).It was reported in previous studies that long–time storage of dental cements in water affected the mechanical properties of the cements (42, 43). Cattani-Lorente et al (44) found that deterioration of the physical properties of the cements after long–term storage in an aqueous environment could be related to the water absorption of these materials. Part of absorbed water acted as a plasticizer, inducing a decrease in strength. Weakening resulted from erosion and plasticizing effect of water. In the present study, TheraCal showed low solubility (3.59%) and less water sorption (11.53%) compared with the other materials, these related to the presence of a light- curable resin and the ability to release a moderate but constant amount of Ca+2 ions. As a conclusion J Bagh College Dentistry Vol. 29(3), September 2017 Comparison among Restorative Dentistry 14 of this study the reveal that, biodentine is superior to calcium hydroxide and other calcium silicate materials in Ca+2ions released, while TheraCal is better insolubility and water sorption. Further studies are needed to compare the results of this in vitro study with future in vivo study. REFERENCES 1.Camp JH, Barrett EJ, Pulver F. endodontic treatment for the primary and young permanent dentition. 8th edi. St. Louis: USA Mosby; 2002. p. 797–844. 2.Foreman Pc and Barnes F. A review of calcium hydroxide. Int Endo J 1990; 23:283-297. 3.Simon S, Cooper P, Smith A, Picard B, Ifi CN, Berdal A. Evaluation of a new laboratory model for pulp healing: preliminary study. Int Endod J 2008; 41: 781-790. 4.Fulzele P, Baliga S, Thosar N, Pradhan D. Evaluation of calcium ion, hydroxyl ion release and pH levels in various calcium hydroxides based intra canal medicaments: An in vitro study. Contemp Clin Dent. 2011; 2(4):291-5. 5.Estrela C, Sydney GB, Bammann LL, Felippe O. Mechanism of action of calcium and hydroxyl ions of calcium hydroxide on tissue and bacteria. Braz. Dent. J. 1995; 6: 85–90. 6.Modena KC, Casas-Apayco LC, Atta MT, Costa CA, HeblingJ, Sipert CR, Navarro MF, Santos CF. Cytotoxicity and biocompatibility of direct and indirect pulp capping materials. J. Appl. Oral Sci. 2009 Nov-Dec; 17(6):544-54. 7.Bakland LK and Andreasen JO. Will mineral trioxide aggregate replace calcium hydroxide in treating pulpal and periodontal healing complications subsequent to dental trauma? A review. Dental Traumatology 2012; 28: 25–32. 8.Schröder U. Effects of calcium hydroxide-containing pulp-capping agents on pulp cell migration, proliferation, and differentiation. J Dent Res. 1985; 64: 541–548. 9.Chandra BS and Krishna VG. Vital pulp therapy, pulpotomy and apexification in: Grossman’s Endodontic Practice. 12th ed. New Delhi: Wolters Kluwer; 2010. p. 315. 10.Takita, T, Hayashi M, Takeichi O, Ogiso B, Suzuki N,Otsuka K, Ito K. Effect of mineral trioxide aggregate on proliferation of cultured human dental pulp cells. Int Endod J 2006; 39: 415–422. 11.Clapham DE. Calcium signalling Cell.1995; 80: 259– 268. 12.Estrela C and Holland R. Calcium hydroxide study based on scientific evidences. J Appl Oral Sci 2003; 11: 269–282. 13.Roberts HW, Toth JM, Berzins DW, Charlton DG. Mineraltrioxide aggregates material use in endodontic treatment: A review of the literature. Dental Materials 2008; 24(2):149-64. 14.Hebling J, Lessa FC, Nogueira I, Carvalho RM, Costa CA. Cytotoxicity of resin-based light-cured liners. Am J Dent. 2009 Jun; 22(3):137-42. 15.Gandolfi M, Siboni F, Polimeni A, Bossù M, Riccitiello F,Rengo S, Prati C. In Vitro Screening of the Apatite-Forming Ability, Biointeractivity and Physical Properties of a Tricalcium Silicate Material for Endodontics and Restorative Dentistry. Dent J 2013; 1: 41-60. 16.Piwowarczy kA, Lauer HC, Sorensen JA. Microleakage of various cementing agents for full cast crowns. Dent Mater 2005; 21 (5):445-53. 17.Yanikoglu N and Dymus YZ. Evaluation of the solubility of dental cements in artificial saliva of different pH values. Den Mat J 2007; 26(1): 62-67. 18.Hajmiragha H, Nokor S, Alikhasi M, Nikzad S, Dorriz H. Solubility of three lutting cements in dynamic artificial saliva. J. of Dentistry Tehran 2008; 5(3): 95-98. 19.Parirokh M and Torabinejad M. Mineral trioxide aggregate: a comprehensive literature Review-Part III: Clinical applications, drawbacks, and mechanism of action. J Endod 2010; 36:400-13. 20.Till Dammaschke. Case Studies Septodont Collection Focus on Biodentine No.1 - March 2012 Focus on Biodentine a new bioactive cement for direct pulp capping reproduced with kind permission of Deutscher Ärzte- Verlag. 21.Gandolfi MG, Siboni F, Prati C. Chemical-physical properties of TheraCal, a novel light-curable MTA-like material for pulp capping. Int. Endod J 2012; 45: 571-9. 22.Driscoll CF, Woolsey GD, Reddy TG, Craig RG. Solubility of zinc oxide eugenol and calcium hydroxide cements in simulated dentinal fluid. J Oral Rehabil. 1989; 16(5):451-5. 23.Francisconi LF, Freitas, scaffa PM, Mondelli RF. Water sorption and solubility of different calcium hydroxide cements. J Appl. Oral Sci. 2009; 17(5):427-31. 24.Kazanji NM and Watkinson AC. Soft lining materials: their absorption of and solubility in artificial saliva. Br Dent J 1988; 165: 91. 25.Kuga MC, Campos E, Viscardi PH, Carrilho P. Hydrogenions and calcium releasing of MTA Fillapex® and MTA-based formulations. RSBO 2011 Jul-Sep; 8(3):271-6. 26.Koubi G, Colon P, Franquin JC, Hartmann A, Richard G,Faure MO, Lambert G. Clinical evaluation of the performance and safety of a new dentine substitute, Biodentine, in the restoration of posterior teeth - a prospective study. Clin. Oral Investing2013 Jan; 17(1):243-9. 27.Siqueira JF and Lopes HP. Mechanisms of antimicrobial activity of calcium hydroxide: A critical review. Int Endod J 1999; 32: 361–9. 28.Tamburic SD, Vuleta GM, Ognjanovic JM. In vitro release of calcium and hydroxyl ions from two types of calcium hydroxide preparations. Int Endod J 1993;26: 125–30. 29.Mohammadi Z and Dummer PM. Properties and applications of calcium hydroxide in endodontic and dental traumatology. Intern End J 2011; 44: 697–730. 30.Koubi G. A Chemical study of a new Ca3SiO5 – based material induced as dentine substitute. Abstract in Clin Oral Invest, Sevillia 2009. 31.Lee SJ, Monsef M, Torabinejad M. Sealing ability of a mineral trioxide aggregate for repair of lateral root perforations. J Endod 1993; 19: 541–4. 32.Santos AD, Moraes JC, Araujo EB, Yukimitu K, ValerioFilho WV. Physio-chemical properties of MTA and a novel experimental cement. Int Endod J 2005; 38: 443-7. 33.Dammaschke T, Leidinger J, Schäfer E. Long-term evaluation of direct pulp capping-treatment outcomes over an average period of 6.1 years. Clin.Oral Investig.2010; 14: 559-67. 34.Laurent P, Camps J, De MM, Dejou J, About I. Induction of specific cell responses to a Ca3SiO5 - based posterior restorative material. Dent. Mater. 2008; 24 (11): 1486-1494. J Bagh College Dentistry Vol. 29(3), September 2017 Comparison among Restorative Dentistry 15 35.Tran V, Pran V, Colon P. Microleakage of new restorative calcium (Biodentine) oral presentation, mentioned in "Biodentine publications and communication 2005-2010, by Septodent. Dec. 2012: 64. 36.Gandolf MG, Siboni F, Taddei, Modena P, Prati C. Apatite-forming Ability of TheraCal Pulp-Capping Material. J Dent Res 90 (Spec Iss A): abstract number 2520, 2011 (www.dental research.org). 37.Gandolfi M, Siboni F, Botero T, Riccitiello F, Prati C. Calcium silicate and calcium hydroxide materials for pulp capping: bio interactivity, porosity, solubility and bioactivity of current formulations. J. Appl. Bio mater Funct Mater. 2014:1-18. 38.Gandolfi M, Biol D, Siboni F, Prati C. Ion Release, Porosity, Solubility, and Bioactivity of MTA Plus Tricalcium Silicate. Endo. J. October 2014: 1-6. 39.Granstrom and GandLinde A. A biochemical study of alkaline phosphatase in isolated rat incisor odontoblast. Arch Oral Biol. 1972; 17:1213–24. 40.Binnie WH and Mitchell DF. Induced calcification in the sub dermal tissues of the rat.J Dent Res 1973; 52: 1087–91. 41.Tronstad L, Andreassen JO, Haselgreen G, Kristerson L,Riis I. pH changes in dental tissues after root canal filling with calcium hydroxide. J Endod1981; 7: 17–21. 42.Yoruc H.A.B. and Karaaslan A. Effect of water storage on the mechanical properties of zinc polycarboxylate cements. Digest J. of Nano materials and Bio structures 2007; 2(2): 243-52. 43.Tuna SH and, Keyf F. Water sorption and solubility of provisional and permanent luting cement. Hacettepe Dishekimligi Fakultesi Dergisi 2006; 30(3): 19-24. 44.Cattani-lorente MA, Dupuis V, Payan J, Moya F, Meyer JM. Effect of water on the physical properties resin modified glass ionomer cements. Dent Mat 1999; 15: 71- 79. Table (2): Descriptive statistic for pH analysis and Calcium ions released with one-way ANOVA test among the subgroups of each group. Groups (n=10) Times pH analysis Calcium ions released Mean S.D. F-Test p- value Sig. Mean S.D. F-Test p-value Sig. Control 3 hr. 10.25 0.18 138.246 0.000 HS 33.94 3.81 83.257 0.000 HS 24 hr. 10.43 0.08 26.42 3.94 14 days 9.57 0.03 15.77 2.15 30 days 9.74 0.06 14.21 2.63 Biodentine 3 hr. 11.06 0.27 97.984 0.000 HS 92.73 2.10 2218.629 0.000 HS 24 hr. 11.63 0.25 35.19 1.47 14 days 9.41 0.60 28.67 1.56 30 days 9.17 0.30 34.03 2.71 MTA 3 hr. 11.65 0.26 296.100 0.000 HS 46.48 2.91 609.521 0.000 HS 24 hr. 11.42 0.16 26.23 1.22 14 days 8.37 0.46 11.43 1.16 30 days 8.21 0.403 8.82 1.12 TheraCal 3 hr. 10.60 0.87 29.379 0.000 HS 63.28 2.57 815.388 0.000 HS 24 hr. 8.87 0.43 36.67 2.81 14 days 8.67 0.33 22.91 2.10 30 days 7.97 0.49 17.82 1.18 P > 0.05: Non significant (NS), P < 0. 05: Significant (S), P≤ 0.01: Highly differences (HS) Table (3): Descriptive statistic of Solubility and Water sorption tests, and comparison among the groups using one-way ANOVA. Groups (n=10) Solubility test Water sorption test Descriptive statistic Comparison Descriptive statistic Comparison Mean S.D. F-Test p- value Mean S.D. F-Test p- value Control 6.45 0.36 966.503 0.000 HS 6.03 0.44 1922.701 0.000 HS Biodentine 13.05 0.88 16.301 0.87 MTA 19.35 0.93 26.48 0.38 TheraCal 3.59 0.51 11.53 0.66 J Bagh College Dentistry Vol. 29(3), September 2017 Comparison among Restorative Dentistry 16 Table (4): Tukey test and one-way ANOVA for comparison among the tested materials in calcium ions released (in ppm) at each immersion time. Tukey test One-way ANOVA Times Comparison among the groups Mean difference p-value Sig. F-Test p-value Sig. 3hr Control Biodentine -58.79 0.000 HS 759.147 0.000 HS MTA -12.54 0.000 HS TheraCal -29.34 0.000 HS Biodentine MTA 46.25 0.000 HS TheraCal 29.45 0.000 HS MTA TheraCal -16.80 0.000 HS 24hr Control Biodentine -8.77 0.000 HS 45.944 0.000 HS MTA 0.19 0.998 NS TheraCal -10.25 0.000 HS Biodentine MTA 8.96 0.000 HS TheraCal -1.48 0.587 NS MTA TheraCal -10.44 0.000 HS 14 days Control Biodentine -12.90 0.000 HS 181.010 0.000 HS MTA 4.34 0.000 HS TheraCal -7.14 0.000 HS Biodentine MTA 17.24 0.000 HS TheraCal 5.76 0.000 HS MTA TheraCal -11.48 0.000 HS 30 days Control Biodentine -19.82 0.000 HS 277.150 0.000 HS MTA 5.39 0.000 HS TheraCal -3.61 0.002 HS Biodentine MTA 25.21 0.000 HS TheraCal 16.21 0.000 HS MTA TheraCal -9.00 0.000 HS Table (5): Tukey test for comparison among the tested materials in Solubility and Water sorption. Tukeytest comparison among the Groups For solubility For water sorption Mean difference p-value Sig. Mean difference p-value Sig. Control Biodentine -6.59 0.000 HS -10.26 0.000 HS MTA -12.89 0.000 HS -20.45 0.000 HS TheraCal 2.86 0.000 HS -5.50 0.000 HS Biodentine MTA -6.30 0.000 HS -10.18 0.000 HS TheraCal 9.46 0.000 HS 4.76 0.000 HS MTA TheraCal 15.76 0.000 HS 14.95 0.000 HS الخالصة المقدمة: قامت هذه الدراسة من اجل المقارنة بين هيدروكسيد الكالسيوم وسيليكات الكالسيوم في تحرير ايونات الكالسيوم وتغيير درجة حموضة الماء وقياس ذوبان وامتصاص الماء. من كل نوع عيناتوثريكال.عشرة )مجموعة السيطرة( , بايودنتين, ام تي اي بالس الكالسيوم هذا البحث هي: هيدوكسيدمستعملة في المواد ال المواد والطريقة المستعملة في البحث: 02عة, سا 42ساعات, 7درجة سليليزية باستعمال الحاضنة لمدة 73مل من الماء منزوع األيونات ويتم حفظها في درجة حرارة 01ثم تغمر فيتصنع باستعمال قوالب بالستيكية هاز قياس الحامضية. بعد يوم. كمية ايونات الكالسيوم المحررة في ماء الغمر تقاس باستعمال مطياف االمتصاص الذري. أيضا درجة حموضة ماء الغمر تقاس باستعمال ج 71يوم و ( Tukey test)واختبار الفرق المعنوي (ANOVA) ال اختبار تحليل التباينتحلل البيانات الناتجة إحصائيا باستعم. ذلك تخضع العينات لنسبة درجة الذوبان ونسبة امتصاص الماء اظهر اختبار . فيمانسبة في تحرير أيونات الكالسيوم وفي جميع األوقات أعلىبين المواد وفي جميع االختبارات. أظهر بايودنتين ظهر التحليل اإلحصائي وجود فروقا معنويةأ النتائج: االم تي اي بالس كانا أعلى ذوبان بالمقارنة مع مجموعة السيطرة، وأظهرت ن البايودنتين وأبة الماء مع الوقت. وأظهرت نتائج الذوبان وامتصاص الماء حموضة الماء نقصان قلوي .نتائج امتصاص الماء بان أقل نسبة امتصاص وقعت في مجموعة السيطرة بالمقارنة مع المجموعات األخرى وبان من بقية المواد وامتصاص قل نسبة ذسيليكات الكالسيوم تحرر ايونات كالسيوم أكثر وتقل الكمية مع الوقت. أما بالنسبة لقلوية الماء فإنها تقل مع الوقت. الثريكال لديه أ االستنتاج : .ومجموعة السيطرة نسبة ذوبان وامتصاص من الثريكال أعلىاقل من مجموعة السيطرة. البايودنتين واالم تي اي بالس اظهرا