versão impressa ISSN 1678-7757
J. Appl. Oral Sci. v.11 n.1 Bauru jan./mar. 2003
Análise morfológica da capacidade de limpeza promovida pela instrumentação rotatória, associada à soluções irrigantes, com limas de níquel-titânio em canais radiculares com achatamento mesio-distal
Melissa Andréia MarchesanI; Marcos Porto de ArrudaII; Yara T. Correa Silva-SousaIII; Paulo César SaquyIII; Jesus Djalma PecoraIV; Manoel D. Sousa-NetoIII
IDDS, MSc, Especialista em Endodontia pela Universidade de Ribeirão Preto
IIUndergraduate student from Faculty of Dentistry, University of Ribeirão Preto
IIIDDS, PhD, Faculty of Dentistry, University of Ribeirão Preto
IVDDS, PhD, Restorative Dentistry Department, School of Dentistry of Ribeirão Preto, USP, Brazil
Variations in the internal anatomy of root canals may interfere with the success of root canal because tissue remnants may remain in the isthmus, re-entrances and ramifications of flattened root canals making instrumentation more difficult. Successful root canal treatment depends fundamentally on shaping, cleaning, disinfection and obturation. This study verified the quality of cleaning of ProFile .04 rotary technique associated with different irrigating solutions: 0.5% sodium hypochlorite, calcium hydroxide + Tergentol and 2% chlorhexidine in canals with mesio-distal flattening. Twelve human mandibular central incisors were randomly divided into 3 groups and instrumented up to ProFile 0.4 #35 file after cervical preparation, and processed histologically. After optical microscopic evaluation, statistical analysis showed that the percentage of cleaning of the three irrigating solutions was statistically different. Two-by-two comparisons classified the irrigating solutions in increasing order of cleaning: calcium hydroxide + Tergentol < chlorhexidine < 0.5% sodium hypochlorite.
Uniterms: Dental pulp cavity, cleaning; Dental pulp cavity, rotary instrumentation; Flattened root canals.
As variações da anatomia interna de cada canal radicular podem interferir no sucesso da terapêutica endodôntica devido ao fato de que em canais radiculares achatados, pode persistir remanescentes teciduais em istmos, reentrâncias e ramificações dificultando a execução das técnicas de instrumentação. O sucesso do tratamento dos canais radiculares depende fundamentalmente do preparo da forma, limpeza, desinfecção e obturação. Poucos trabalhos avaliaram a limpeza dos canais radiculares após a instrumentação rotatória. O presente trabalho verificou a qualidade de limpeza dos canais radiculares, por meio da microscopia óptica, promovida pela técnica de instrumentação rotatória associada ao hipoclorito de sódio 0,5%, HCT20 e clorexidina, em canais achatados no sentido mésio-distal. Doze incisivos centrais inferiores humanos foram divididos aleatoriamente em três grupos para que fossem instrumentados com instrumetação rotatória (ProFile .04). A análise estatística evidenciou que os valores da porcentagem de limpeza para as diferentes soluções irrigantes foram estatisticamente diferentes entre si. Comparações duas a duas permitiram dispor as soluções irrigantes em ordem crescente de efetividade na limpeza, sendo: hipoclorito de sódio a 0,5% > clorexidina > HCT20.
Unitermos: Cavidade da polpa dentária, limpeza; Cavidade da polpa dentária, instrumentação rotatória; Canais radiculares achatados.
Variations in internal anatomy can interfere with root canal therapy because root canals are not cylindrical, they are flattened. Thus, tissue remnants can persist in isthmus, re-entrances and ramifications making instrumentation more difficult 22
The success of root canal treatment depends fundamentally on cleaning, shaping, disinfecting and sealing the root canal. Cleaning occurs simultaneously with biomechanical preparation, elimination of bacteria, their sub-products, degenerated pulp tissue and contaminated dentin creating a surgical space that permits proper sealing. This process occurs by the action of the instruments on the root canal walls, the chemical properties of the irrigating solutions and irrigation-aspiration.
Many methods are used to evaluate root canal cleanliness such as scanning electron microscope 4,11,16 microscope 22 specimen analysis before and after instrumentation 13 and recently computerized tomography 12,21. BARBIZAM et al. 2 observed by optic microscopic analysis of flattened root canals that instruments did not touch the polar areas during instrumentation. FARINIUK 10 analyzed circular root canals and found that the capacity of efficiently cleaning the root canal is not only based on instrumentation. Irrigation is of fundamental importance 1. Irrigation associated with instrumentation is necessary to remove debris for cleaning and disinfecting the root canal system.
Many auxiliary chemical solutions have been used; however, several are only registered in the literature and no longer used. Among all these solutions, sodium hypochlorite in different concentrations is most commonly used and accepted due to clarification, organic tissue dissolution, saponification, transformation of amines into chloramines, deodorizing and antibacterial effects 18,24.
However, recently other solutions have also been recommended for irrigation such as chlorhexidine and HCT20 (a calcium hydroxide solution). Chlorhexidine digluconate is a broad-spectrum antibacterial agent used in Periodontics to reduce plaque formation in periodontal diseases. It also links enamel or dentine hydroxyapatite to glycoproteins anionic acid groups, and is slowly released as its concentration decreases allowing prolonged action period3. Pure or associated calcium hydroxide solutions have also been used for root canal irrigation. These solutions neutralize bacterial sub-products such as lipopolysaccharides, they are biocompatible with pulp having the same effect as saline and distilled water 9 and have antiseptic properties. To improve these properties, 20% detergent was added to a calcium hydroxide solution creating HCT20 3. This association reduces surface tension and improves bacterial effect due to the increase of the diffusion rate in the bacterial cell.
Thus, this study evaluated histologically the cleaning capacity of rotary instrumentation associated with different irrigating solutions (0.5% sodium hypochlorite, chlorhexidine and HCT20) in mesio-distally flattened root canals.
MATERIAL AND METHODS
Twelve human mandibular central incisors with a mesio-distal flattened root and radiographically confirmed single root canal were obtained from laboratory stock. The teeth were stored in 0.1% thymol and maintained at 90C before use.
Conventional access was performed and a #10 K type file was introduced into the canal until it appeared at the apical foramen. The working length was established by subtracting 0.5 mm from this measurement. The teeth were randomly divided into 3 groups of 4 teeth each. All teeth were prepared according to Guerisoli et al. 14 using rotary instrumentation and ProFile .04 Ni-Ti files (Dentsply-Maillefer, Ballaigues, Switzerland) as follows: after initial enlargement with a stainless steel #15 file, an ascending sequential ProFile instrumentation (# 15 to #40) was performed to the working length.
In group 1, 2 ml of 0.5% sodium hypochlorite was used, between files, as an irrigating solution; in group 2, 2 ml of HCT20 was used between files and in group 3, 2 ml of chlorhexidine was used between files. Ten ml of distilled and deionized water was used for final irrigation in all groups to remove solution residue.
The apical third of each root was sectioned and removed for histological processing. The specimens were immersed in 10% buffered formalin and stored for 12 h in the same solution until histological processing. All specimens were then washed, decalcified in 10% glycoacetic acid and embedded in paraffin. Serial transverse cross-sections (5 mm) were stained with hematoxylin and eosin. The cross-sections were examined with an optic microscope (40x) coupled to a computer where the images were recorded. A grid was placed over these images to evaluate the total canal area and tile area with debris. The percentage of debris in the root canal after chemo-mechanical preparation was calculated and the non-parametric Kruskal-Wallis test was used for statistical analysis.
The results of percentage of cleaning of the root canal are shown in Table 1.
Due to the non-normality of the sample, the non-parametric Kruskal-Wallis test was applied and the irrigating solutions were placed in ascending order of cleaning efficiency. Sodium hypochlorite (0.5%) (Figure 1) was the most effective and HCT20 (Figure 2) was the least effective for cleaning the root canals. Chlorhexidine (Figure 3) showed an intermediate position.
Biomechanical preparation of the root canal is a basic requirement of root canal preparation. Its aim consists of cleaning the canal and its ramifications, removing most of the debris to create ideal conditions, which lead to healing and tissue regeneration.
Researchers have shown that chemical-mechanical preparation leave organic and inorganic debris in the root canals 5-8,20.
BARBIZAM et al. 2 demonstrated that rotary instrumentation with Ni-Ti files have a delimitated action area leaving polar areas of flattened root canals un-instrumented where the dentine canaliculli disposal favors microorganism maintenance.
Thus the use of an irrigating solution with specific chemical properties, among this organic tissue dissolution, and the association between instrumentation techniques to fulfill the lacune left by rotary instrumentation in this group of teeth is necessary.
This study evaluated the effect of different irrigating solutions associated to rotary instrumentation to clean the root canal. Due to the non-normality of the sample the Kruskal-Wallis test was performed between the groups. Sodium hypochlorite (0.5%) was the most effective and HCT20 was the least effective on cleaning the root canals. Chlorhexidine showed an intermediate position.
The best results were found for 0.5% sodium hypochlorite due to its dissolution activity as shown by: MOORER & WESSELINK 19, SPANÓ et al. 24. Which established important factors that interfere in this solution: a) quantity of solution related to organic tissue mass; b) contact surface; c) action time; d) solution volume; e) mechanical agitation f) solution temperature; and g) solution concentration. Thus, the higher these values the better the dissolution capacity of sodium hypochlorite necrotic or not organic tissue.
Sodium hypochlorite dissolution capacity liquefies the pulp and eases its removal from root canal interior. SPANÓ et al. 24 showed that the higher the concentration of sodium hypochlorite the faster the dissolution of the pulp tissue. Evidencing that in flattened root canals the use of an irrigating solution is necessary to dissolve pulp in the areas where the instrument does not touch.
The HCT20 solution showed the lower percentage of cleaning values. HASSELGREN et al. 15 demonstrated that calcium hydroxide dissolves organic tissue and that the effect of sodium hypochlorite is increased by previous calcium hydroxide treatment. In our study, even with the adding of detergent, which lowers superficial tension, there was no increase in the cleaning effect.
BARBOSA 3 showed that chlorhexidine does not present dissolution capacity however presents excellent antibacterial effect 17,23.
Based on the results obtained in this study we conclude that the use of an efficient irrigating solution during flattened root canal chemical-mechanical preparation is necessary to improve cleaning.
1) None of the tested solutions associated to rotary instrumentation lead to complete root canal cleaning;
2) 0.5% sodium hypochlorite presented the higher cleaning capacity followed by 2% chlorhexidine and HCT20.
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