Abstract
In this study, we evaluated the physicochemical properties (PCP; radiopacity, flow, pH, and solubility) and the quality of root canal filling provided by an experimental industrialized paste (EP), with the same active ingredients as those of the Guedes Pinto paste, compared with the Vitapex® paste. PCP were analyzed according to the ANSI/ADA laboratory testing methods for endodontic filling and sealing materials. To analyze filling capacity, 120 artificial primary teeth (60 maxillary incisors [MIs] and 60 mandibulary molars [MMs]) were endodontically treated. The teeth were divided into eight groups based on the dental group (MIs or MMs), filling material (Vitapex® or EP), and insertion method (syringe or lentulo). The Image J® software was used to analyze the initial an final digital radiographies of each tooth, measuring and comparing root canal and void areas. The percentage of filling failure areas was obtained. Data were submitted to ANOVA and Tukey test of mean comparison. Regarding PCP, both pastes presented results according the ANSI/ADA standards. Flow capacity: Vitapex: 19.6 mm, EP: 25 mm (p < 0.01); radiopacity: Vitapex: 4.47 mmAl, EP: 6.06 mmAl (p < 0.01); pH after 28 days: Vitapex: 7.79, EP: 8.19 (p = 0.12); and solubility after 28 days: Vitapex: 2.68%, EP: 2.89% (p > 0.05). Regarding filling capacity analysis, EP demonstrated 12.5% of failure against 31.5% of Vitapex (p < 0.01). Compared to Vitapex, EP presented statistically significantly better results in flow, radiopacity, pH, and filling capacity. Molars presented more filling failures than incisors. The insertion method using a syringe and a thin tip was significantly better than that using Lentulo spiral carriers.
Tooth, Deciduous; Endodontics; Root Canal Obturation
Introduction
Endodontic treatment of primary teeth is a frequent clinical procedure in pediatric dentistry. The treatment is usually performed for dental caries (still considered a public health problem worldwide) or dental trauma, which is common in young children.1,2
Endodontic treatment success is often dependent on several factors, ranging from dental preoperatory conditions to the choice of final tooth restoration. Among these factors, the importance of the choice of endodontic filling material cannot be overlooked.
For treatment of primary teeth, endodontic filling materials must meet certain basic requirements, such as biocompatibility to peri-radicular tissues, slow resorption (to follow primary teeth physiological resorption), antimicrobial characteristics, and physicochemical properties, including radiopacity and flow.3,4,5,6 Moreover, the success of endodontic treatment of deciduous teeth depends on the quality of root canal filling, which is expected to present a complete fill of the root canal system without extrusion to the periapical tissues.7,8 Among different options used globally, Vitapex® (Neo International, Federal Way, USA), a premix of calcium hydroxide and iodoform, is considered the gold standard in filling materials for primary teeth, with considerable success rates. Among other features for being an excellent endodontic filling material, Vitapex® can induce bone formation. Using syringes with extremely thin plastic injection tips, the surgeon can easily dispose the paste into more apical portions of root canals, providing a compact seal and great filling.9,10,11However, the major concern for using Vitapex is that it is not commercialized in South America and other third-world countries.
In Brazil, the most commonly used root canal filling material for primary teeth is Guedes Pinto paste, which is composed of iodoform, prednisolone acetate, rifamycin sodium, and camphorated paramonochlorophenol (PMCC).12,13,14,15 Previous studies have demonstrated good antimicrobial and biocompatibility characteristics of the paste; clinical studies have also demonstrated positive results with the use of Guedes Pinto. Although the paste meets several requirements to be considered an appropriate endodontic filling material for primary teeth, limitations to its use include the need to be manipulated right before its use and difficulties related to its insertion in the root canal.13,16,17,18
To overcome these challenges, an experimental formulation based on the original formula of Guedes Pinto paste was developed (Registered Patent PI0802256-9, INPI 2018). The new formulation contains the same active components (iodoform, prednisolone acetate, rifamycin sodium, and PMCC) but with addition of new excipients. This experimental paste is presented in ready-to-use plastic syringes with thin plastic injection tips.
Considering the experimental nature of the product, strong scientific evidence must be built for its physicochemical properties and quality of root canal filling. Therefore, in this study, we conducted physicochemical tests for this experimental paste and compared the obtained results with those obtained following the use of Vitapex® paste.
Methodology
A previously trained operator conducted the study evaluating the physicochemical properties of flow, radiopacity, pH and solubility, and the quality of root canal filling of both pastes by using two different insertion techniques.
Vitapex® and the experimental paste were used in the present study. Both pastes were presented in identical ready-to-use plastic syringes with a considerably long and thin insertion point. To blind the pastes to the operator, these syringes were named paste A and paste B, respectively. The physicochemical properties were tested according to the American National Standards Institute/American Dental Association ANSI/ADA 57-2000 specification for endodontic sealing materials,19 which recommends that the trials must be performed at room temperature of 23°C ± 2°C.20
Flow
Each 0.5 mL of paste A and paste B were placed in the center of a glass plate. After 3 min, another glass plate was placed on the top of the first one, directly over the paste applying a total weight of 120 mg, resulting in compression. The set was let to remain stable for 10 min, after which the smallest and the largest diameters of each specimen were measured using a ruler graduated in millimeters. The mean of the diameters (in mm) was established for each paste. The test was repeated five times. The ANSI/ADA standards recommend the flow requirement not to be less than 17 mm.
Radiopacity
In total, 10 stainless steel ring molds (diameter: 10 ± 0.1 mm; height, 1 ± 0.1 mm) were used. The rings were placed over a thin glass plate and filled with either paste A or paste B. A small sheet of polyester film was placed over the rings to ensure the paste thickness of 1 mm. To classify the radiopacity, a 98% pure aluminum step wedge was used. After filling the molds, a digital x-ray device and a digital sensor (Diox and Fit,MicroImagem, Indaiatuba, Brazil) were used to obtain digital radiographs of each specimen next to the aluminum scale. The distance and radiation time were the same for each specimen (3 cm and 0.04 s, respectively).
The images were analyzed using the Image J® software (University of Madison, Madison, USA). The histogram value in gray scale corresponding to 7 mm of aluminum was considered as reference to calibrate the gray values. Three measurements were obtained for each specimen, using an area of 20 × 20 pixels for the image of the aluminum scale and for the image of the paste at three different spots inside the ring. The test was repeated ten times.
The mean gray value for each sample was calculated and converted to millimeters of aluminum (mmAl), by using the correspondent gray value to 7 mm in the aluminum scale. The ANSI/ADA standards recommend radiopacity not less than 3 mm of aluminum.
Filling capacity
A total of 120 artificial deciduous teeth (Denarte®/IM do Brazil, São Paulo, Brazil) were used in the study: 60 maxillary central incisors and 60 maxillary first molars. Manufactured using synthetic resins, the teeth have the external and internal anatomy of deciduous teeth, beholding an endodontic cavity filled with red wax that simulates the pulp tissue. The use of this artificial teeth was validated in a previous study.21 The teeth were distributed in four groups as follows: Group 1: 30 central incisors filled with the experimental paste; Group 2: 30 central incisors filled with the Vitapex paste; Group 3: 30 molars filled with the experimental paste; Group 4: 30 molars filled with the Vitapex paste.
Endodontic treatment
To analyze the existence of voids or obstructions in the canals, initial digital images of all the 120 teeth were obtained using digital radiographs. If case of an irregularity, the sample was replaced with a new one. The images were standardized by placing the teeth in an epoxy resin mold and using the same distance and radiation time for all teeth (3 cm and 0.04 s, respectively).
A trained operator completed all the 120 endodontic treatments, in accordance with an operatory protocol: endodontic access using a high-speed 1014HL round bur, complemented with Endo-Z bur (Dentsply Maillefer, Ballaigues, Switzerland). The working length was established by introducing a #10 K file into the root canal until the tip was visualized at the apical foramen. Thus, it was set as 14 mm to the incisors, 14 mm to the palatine root, and 13 mm to both vestibular roots of the molars. Endodontic preparation was performed using a manual crown-down technique with 2.5% sodium hypochlorite as an irrigant solution and light Endo-PTC as a lubricant (Farmácia Fórmula e Ação, São Paulo, Brazil). The apical preparation was set to a #35 K file for incisors. For molars, #30 K-Flex file on buccal canals and #40 K-Flex file for palatine canals. Final irrigation was performed using 2.5% sodium hypochlorite, followed by 17% EDTA-T (Farmácia Fórmula e Ação). Irrigation was performed using 30G Navitips (Ultradent, South Jordan, USA). Subsequently, the root canals were dried using the capillary tips (Ultradent) and paper points (Dentsply) before obturation.
Root canal filling
Paste A and paste B were filled in identical plastic syringes named PASTE A and PASTE B to blind the operator of the treatment. The teeth were divided into two subgroups on the basis of paste insertion method: syringe and tip or lentulo spiral carrier.
Syringe sub-groups: Vitapex insertion tip, which was used for both paste A and paste B, is thin and flexible, allowing for a good insertion into root canals. The operator introduced the tip carefully inside the root canal until 3 mm prior to the working length. Next, the material was placed inside the canal, removing the tip until the canal was fully filled. The excess material in the pulp chamber was then cleaned using a cotton pellet. A final digital radiograph was taken in the same conditions as those for the initial radiograph.
Lentulo spiral groups: Paste A and paste B were inserted in the same manner as were done in the syringe sub-groups. After canal filling, a #25 lentulo spiral carrier was placed 3 mm prior to the working length and activated for 3 s. Next, it was slowly removed. The excess material in the pulp chamber was then cleaned with a cotton pellet. A final digital radiograph was taken in the same conditions as those for the initial radiograph.
Digital radiography evaluation
The Image J® 1.53a software (Wayne Rasband, NIH, USA) was used for image analysis. Using the final radiograph, we measured the total area (mm2) of the root canal. Next, all area of voids or failure in the filling were individually measured. The percentage of failure areas were then calculated.
pH and solubility
After filling capacity test, 10 incisors from each paste group were randomly selected for pH and solubility tests. Pulp chambers were sealed with sticky wax and the teeth were weighed in a precision balance (Mettler Toledo LCC, Columbus, OH, USA). Next, they were individually immersed in a plastic tube containing 10 mL of deionized water. After time intervals of 30 min, 2 h, and 1, 7, 14, and 28 days, the teeth were removed, weighed, and immersed into a new plastic tube containing an equal volume of fresh deionized water. The pH in the solutions was analyzed using a pH meter (Mettler Toledo LCC).
Statistical analysis
The level of significance was set at 5%, and all the analyses were performed using the Stata 13.0 software (Stata Corp, College Station, TX, USA). Normal distribution was verified by using the Kolmogorov–Smirnov test (with Lilliefors correction). One-way ANOVA was used for physicochemical tests, complemented by Tukey post-hoc test. For statistical analysis of filling capacity, three-way ANOVA was used, complemented by Tukey ad-hoc test.
Results
Flow test
Both paste A and paste B presented results in line with the ADA standard no57 (not <17 mm). Experimental paste presented a significantly higher flow than Vitapex® paste (Table).
Radiopacity test
Both paste A and paste B presented values higher than the minimum stipulated to endodontic filling materials according to the ADA standard no5719, which is 3 mm Al. Experimental paste presented a significantly higher level of radiopacity than Vitapex® paste (Table).
pH
On comparing all time intervals, we found no significant differences for each of the paste. Comparing the pastes, the experimental paste presented a significantly higher pH than Vitapex® (Table).
Solubility
On comparing all time intervals, we found no significant differences for each of the paste. The final period values (28 days) are presented in Table.
Regarding filling capacity, the voids and failure percentages of all the groups are presented in Figure. On comparing the pastes for each variable (such as tooth type and the insertion method), the experimental paste presented a significantly lower percentage of failure than Vitapex (p < 0.01). Three-way ANOVA demonstrated no significant differences between the interaction of variables (paste X tooth X insertion method: p = 0.92).
Discussion
Endodontic treatment of deciduous teeth continues to be a highly relevant dental procedure in pediatric dentistry.22 The search for a perfect filling material encouraged us to investigate a new root canal filling material. Vitapex® paste is considered the gold standard in literature.23,24,25, 26,27,28 However, in Brazil, Vitapex is not commercialized and therefore Guedes-Pinto paste, also an iodoform-based preparation, is considered a good alternative. However, Guedes-Pinto paste has always been associated with handling difficulties for need of immediate manipulation.13 Therefore, a new ready-to-use formulation presented in injection syringes and composed of the same active components was idealized. In this study, we investigated the physicochemical characteristics and quality of root canal filling of this new formulation.
Both paste A and paste B presented radiopacity and flow values in accordance with the ADA standard of no57.19 Nevertheless, the experimental paste demonstrated significantly better results in radiopacity. Considering that iodoform is the component responsible for radiopacity in both pastes,29 we believe that the greater proportion of iodoform in the experimental paste may justify its superiority in radiopacity results. Iodoform constitutes 69.2% of the experimental paste’s formulation,14 whereas it constitutes only 40.4% of Vitapex® formulation, per manufacturer’s information (NeoDental Chemical Products Co, Tokyo, Japan). Although higher paste radiopacity has the advantage of allowing for better visualization in the radiograph, even in smaller amounts, it can mask some filling failure. To ensure this phenomenon does not occur in our sample, we performed an additional radiograph for each tooth in a proximal view and if any failure was presented only in this second view, the percentage was also recorded. In our study, none of the samples presented this condition.
Regarding flow capacity, we believe the difference between the percentages of liquid components of the pastes may have influenced the results. The experimental paste comprised PMCC as a liquid component of the composition and uses Rifocort in the proportion of 23.8%, which contains polyethylene glycol as vehicle. Vitapex® has a lower proportion of the vehicle (22%) and also the presence of calcium hydroxide, which is often used to decrease flow in many endodontic filling materials.3 Furthermore, the vehicle used in Vitapex is silicone oil. Oil vehicles offer aggregating properties and hinder solubilization.30 On the contrary, the polyethylene glycol vehicle used in the experimental paste is a viscous water-soluble vehicle with better dissociative properties, which may also justify its better results in flow capacity.31 Although both pastes met the ANSI/ADA recommendations, it is known that a higher flow paste would promote a higher filling capacity. This theory is in agreement with filling capacity results presented in our study. The pH and solubility of both pastes did not demonstrate significant differences at all time periods evaluated. The pH ranged between 7.6 and 8.4 and solubility at 28 days did not achieve 3% for both pastes.
The dental group of molars presented the highest percentage of failure in filling capacity. We believe that anatomical peculiarities of each dental group contributed greatly to this result. The internal anatomy of root canals may be considered a reflection of the external anatomy of the root. Thus, central incisor canals are generally straighter, and circular, presenting lesser difficulties during not only cleaning and shaping but also obturation. The opposite can be observed in the group of molars, whose root curvatures and flattening areas are reflected in narrower channels, para-apical exits, and other details that often complicate those steps of endodontic treatment.32,33,34
Certain details of the adopted methodology should be considered, such as the use of artificial primary teeth made of resin. Although these work models represent an advance in laboratory endodontics,13 they may not perfectly reproduce the natural teeth. In addition, the wax that fills the endodontic canal of the artificial primary teeth is difficult to remove and may have altered, in some cases, the establishment of working length and filling quality. Some artificial teeth also offered difficulties accessing the root apex, presenting lateral exits, obstructions, and voids in areas near the root canal.
While evaluating the quality of filling provided by the examined pastes, we must consider that this is an in vitro study, and in some aspects, this might have favored the results. For example, there were no clinical difficulties such as mouth opening limitations, need for psychological conditioning, or other possible complications that may often occur during pediatric treatment.
Vitapex® presented an inferior general result in filling quality when compared with the experimental paste. We observed higher failure rates with Vitapex® use in both the tested dental groups (incisors and molars) and insertion methods (syringe or lentulo). This finding could be attributed to the different formulation of the pastes and their physicochemical properties. Considering that the experimental paste presented better flow capacity than Vitapex, it seems that the experimental paste presented better filling quality. However, the obturation of all dental groups was performed in the same date and in sequence, which may have involved operator fatigue. Random distribution of teeth and type of material are indicated in the performance of other works to overcome this present limitation.
In contrast to our results, Asokan et al.,35 using computerized tomography, compared the percentage of the filled area volume provided by three endodontic pastes. Vitapex® paste presented superior results (95% filling of the total root canal volume), compared to an iodoform-based paste, Metapex (88%), and a zinc oxide-based paste (84%). Notably, these studies compared Vitapex® with zinc oxide-based pastes.19,31,36,37 In the present study, the comparison was stablished between Vitapex® and the experimental paste, which does not comprise zinc oxide or eugenol in its formulation, making it difficult to compare our results with those of earlier studies.
Conclusion
The results for both paste A and paste B were in accordance with the ADA standards. The experimental paste presented significant better flow, radiopacity, pH, and filling quality than Vitapex®. Molars presented more filling failures than incisors. The insertion method using syringe and a thin tip was significantly better than the use of Lentulo spiral carriers.
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Publication Dates
-
Publication in this collection
07 Aug 2020 -
Date of issue
2020
History
-
Received
20 Jan 2020 -
Accepted
28 May 2020 -
Reviewed
16 June 2020