Figures
Abstract
Introduction
Experimental evaluation of endometric devices usually relies on visual, subjective detection of the apical constriction to determine the accuracy of measurements. The aim of the present study was to analyze the accuracy of measurements of Raypex 6 and EndoPilot using a novel, objective image-analysis system.
Methods
Onehundred and twenty teeth were randomized and allocated to three groups: After coronal flaring, either Raypex 6 or EndoPilot were used to determine the endodontic working length during instrumentation using manual files (RPM and EPM group respectively). In addition, EndoPilot was used for continuous, automatic measurement during rotating instrumentation (EPA group). If the working length had been reached according to endometric results, the files were fixed in place. Tooth and file were then embedded and prepared for analysis. Subsequently, the distance between the tip of the file and the apical constriction (DAC) or the apical foramen (DAF) was calculated using trigonometric analysis and the position of the file relative to AC and AF was analyzed.
Results
Both inter- and intra-examiner-reliability of the trigonometric analysis were nearly perfect (ICC = 0.999, p<0.001). DAC was not significantly different between groups (p>0.05, t-test). DAF was significantly decreased when EPA had been used compared to EPM (p<0.05, Exact-test). EPA resulted in files being positioned beyond AF significantly more often than the other two methods (p<0.01).
Citation: Christofzik D, Schwendicke F, Flörke C, Härtl A, Dörfer C, Größner-Schreiber B (2015) In Vitro Comparison of Raypex 6 and Endopilot Using a Novel, Computer-Aided Measurement System, for Determining the Working Length. PLoS ONE 10(8): e0134383. https://doi.org/10.1371/journal.pone.0134383
Editor: Susan R. Rittling, The Forsyth Institute, UNITED STATES
Received: May 7, 2015; Accepted: July 8, 2015; Published: August 3, 2015
Copyright: © 2015 Christofzik et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are within the paper.
Funding: The authors received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Introduction
The long-term success of endodontically treated teeth is determined by several factors like the presence, degree and extension of periapical inflammation or infection, a sufficient root filling as well as an adequate coronal seal [1, 2]. Longer average retention time of teeth increase endodontic treatment needs, and with rising life expectancy the number of performed root canal treatments per patient increases as well [3]. One of the most important factors for the long-term prognosis of a root filled tooth is the length of instrumentation and the position of the apical seal [4–7]. If the instrumentation remains shorter than desired (under preparation) in the case of necrotic pulp, bacteria remain and survive apically to the instrumented areas [8, 9]. Over preparation transports bacteria and infected tissue into the periapex, thereby compromising healing and regeneration of periapical tissues [10].
Radiographic measurement allows detection only the radiological apex [11], which is commonly found 1 mm beyond the apical constriction, with great variations from this rule [12, 13]. Thus, a solely radiographical determination of the working length is associated with a high risk of overpreparation [14]. In contrast, endometric measurements were shown to be a reliable, accurate method to estimate the length of the root canal [4, 15] and to determine the interval between the anatomical apex and the apical constriction [4, 16].
A major problem when experimentally assessing the accuracy of different endometric measurement systems is the identification of the apical constriction (AC): Often, a visual assessment using magnification aids was performed, which is prone to subjectivity and of limited reliability [4, 17, 18]. The present study introduces a newly designed image analysis software system, which allows reliable and objective identification of the AC. The system is used to compare two new endometric measurement devices, which use different measurement techniques. Both Raypex 6 (VDW, Munich, Germany) and EndoPilot (Schlumbohm, Brokstedt, Germany) allow manual assessment of the endodontic working length. In addition, EndoPilot allows continuous measurements during rotating instrumentation. Raypex 6 succeeds Raypex 5, which was shown to determine the working length with high reliability [17], whereas the EndoPilot uses a new detection method based on an impulse measuring system, thereby allowing increased measurement frequency and thus improving the accuracy for continuous measurements [19, 20]. The aim of this study was to compare the accuracy of manual and continuous endometric measurements in the assessment of the endodontic working length using an objective digital analysis system.
Materials and Methods
Specimen preparation
120 sound, caries-free, unrestored permanent teeth with complete root formation, which were extracted due to surgical or periodontal concerns with informed consent and under a protocol approved by the school’s IRB (Ethic committee of the Christian-Albrechts-University Kiel D444/10), were selected. Written consent was given, and only adult teeth were used. Teeth were cleaned and those with apical resorptions or vertical fractures excluded; specimens were stored in 0.08% thymol solution. Molars (n = 60) and single-rooted teeth (premolars and anteriors n = 60) were block-randomized and allocated to three experimental groups (Raypex, discrete measurement [RPM], EndoPilot manual, discrete measurement [EPM], EndoPilot automatic, continuous measurement [EPA], n = 40/group).
Pulpal access was prepared using water-cooled diamond-coated instruments (Brasseler, Lemgo, Germany), and the occlusal surface ground flat to allow reproducible length measurement. Root canal orifices were coronally enlarged using size 3 and 2 Gates-Glidden-burs (Brasseler GmbH, Lemgo, Germany). After irrigating the pulp chamber with 2ml of 3% NaOCl solution (25°C, 3 min), canals were initially explored until the apical third of the roots was entered using ISO 06 and 08 K-files (VDW, Munich, Germany).
Endometric measurement
To assess endometric measurements, an established measurement model was used [4, 18]. Teeth were mounted in a measurement chamber, which was then filled with 0.9% NaCl-solution, with roots being completely covered by the solution. For manual measurements, a size #10 K-file was used (VDW), while automatic measurements were performed using a #10 Mtwo file (VDW), with both files being used according to manufacturer’s instructions. Both endometric devices were calibrated and used according to manufacturer’s instructions.
For manual endometric measurement with Raypex 6 (RPM-group), the second green line on the displayed index was used to indicate a working length reaching the AC, while, similarly, a metric measurement result of 36 was used for manual measurements with EndoPilot (EPM-group). Since the EndoPilot allows continuous automatic measurement during rotating instrumentation, the auto-stop function was used for automatic measurements with EndoPilot (EPA-group). During all measurements, root canals were intermittently irrigated with a total of 2ml 3% NaOCl solution per canal.
If the AC had been reached according to the endometric measurement, files were fixed within the teeth using flowable resin (Tetric EvoFlow, Ivoclar Vivadent, Ellwangen, Germany). Teeth were then embedded in acrylic resin (Technovit 4071, Heraeus Kulzer, Wehrheim, Germany), ground and polished (ATM Saphir 360 E, ATM, Mammelzen, Germany) under microscopic observation (STEMI, Zeiss, Oberkochen, Germany) until the middle of the root canal (the maximum width) was exposed.
Evaluation
Digital images of cross-sections showing both the tip of the measurement file and the apical area were assessed using a microscope (Axiophot 2, Zeiss, Jena, Germany) interfaced with a digital imaging system (CFW 1312M, Scion, Frederick, USA) and a personal computer. The images were calibrated and scaled using AxioVision (Zeiss, Jena, Germany). The walls of the root canals were digitally marked (Adobe Photoshop CS5.1; Adobe, Munich Germany); the smallest distance between both walls was determined using an experimental software system (Fig 1).
The marked outline root canal is shown in red, the computer detected AC and its diameter (in μm) in yellow.
The diameter of the apical constriction and the apical foramen were measured. The distance (D) between the tip of the file and AC or the apical foramen (AF) was calculated using trigonometric analysis with the formula (Fig 2).
Using a similar approach, the mean distance between AC and AF was determined (Fig 2). The digital evaluation was independently performed by two dentists, and evaluation of 20 random images was additionally repeated after two weeks to allow calculation of inter- and intra-examiner reliability using intra-class-coefficients (ICC). Subsequently, it was analyzed if the tip of the file was positioned between AC and AF, before AC, or beyond AF, respectively.
Data were statistically contrasted using GraphPad Prism 6.0 (GraphPad Software, La Jolla, USA). To assess the influence of the endodontic measurement system on D, we performed one-way analyses of variance (ANOVA). To compare groups, independent samples t-test as well as Fisher’s Exact Test were used. Statistical significance was assumed if p<0.05.
Results
The computer-aided measurement was shown to be a consistently reliable method. Both intra- and inter-rater reliability were near perfect, with mean (95% CI) ICC being 0.999 (0.999/1.000, p<0.0001) for detection of both DAC and DAF.
Mean (SD) diameters of AC and AF were 0.27 (0.11) mm and 0.64 (0.22) mm, respectively. The mean (SD) distance between AC and AF was 0.36 (0.26) mm. There were no significant differences of these values between groups (p>0.05, ANOVA).
DAC was not significantly different among groups (p>0.05). DAF was significantly smaller for EPA compared with EPM (p<0.01), while RPM showed no difference compared to other groups (Table 1).
In addition, EPA showed the highest frequency of over instrumentation when compared with EPM and RPM (p<0.001), whereas instrumentation aided by RPM resulted in files being positioned between AF and AC in the majority of measurements.
Discussion
The study compared the accuracy of discrete endometric measurement of Raypex 6 and EndoPilot, and additionally evaluated the accuracy of continuous, automatic measurement of EndoPilot.
The precise determination of the working length is a crucial factor in root canal treatments [21], the endometric measurement provides the most accurate and reliable method [6] compared to tactile and radiographic determination.
A study conducted by Huang showed that endometric measurements rely on electro-physical rather than biological conditions of the surrounding tissues [22]. Thus, in vitro simulation of these conditions is suitable to experimentally assess different endometric devices [23, 24]. In addition, it was shown that endometric devices are most likely able to reliably determine the interval between AC and AF [6, 25], whereas the results of this and other studies show that most systems do not reach this aim yet [15].
In this study the analysis of both the apical anatomy and the relative position of the file using a digital system based on image analysis allowed an objective, reliable and precise evaluation of the accuracy of each measurement method. With the described analysis, both AC and AF can be determined without the need of subjective approximations [18]. In addition, the presented method dramatically decreased the detection limit of experimental analyses [26–28], from mm to μm [29].
Our results concerning the diameter of AC and AF and the distance between both are in accordance with previous studies [12, 13].
However, the two-dimensional assessment of a three dimensional system is a limitation of the present study: Since AC and AF are not planar entities, but rather stretch along a certain root canal length and diameter, such assessment may lead to misinterpretation of the accomplished measurements. Furthermore, a three-dimensional detection of this landmark using for instance a micro-CT might offer some advantages [30, 31], but would cause less accurate results than the two dimensional assessments [32, 33].
The results showed high accuracy for both devices, if they were used for manual determination of the working length. However, none of the devices seemed to offer significant advantages when compared to other commercial systems [17]. While less than 5% of the canals had been overprepared when endometric assessment was done manually-discrete, the automatic, continuous measurement led to significantly more overpreparation (24%). This might be due to the apically driven working mode of rotating instruments; a slow motion mode approach in proximity to AC might have some benefits. Further studies should assess other rotating endodontic systems with continuous automatic endometric measurements. In addition, future research may address how the rotating files themselves affect the manual-discrete measurement, and if continuous endometric assessment is more accurate without the auto-stop function.
Conclusions
This study found high accuracy for RPM and EPM, with no significant differences between the systems, whilst continuous automatic measurements were more often associated with over preparation than manual, discrete measurements. This might be associated with the auto-stop function used and should be further analyzed. The employed image-analysis-based assessment system has high reliability and is suitable for the comparison of endometric measurement devices in vitro.
Acknowledgments
The authors would like to thank VDW (München, Germany) and Schlumbohm (Brokstedt, Germany) for supplying the endometric measurement devices Raypex 6 and Endopilot, respectively. None of the authors have any confiict of interest related to this study.
Author Contributions
Conceived and designed the experiments: DC FS CF CD BGS. Performed the experiments: DC CF. Analyzed the data: DC CF AH. Contributed reagents/materials/analysis tools: DC CF AH. Wrote the paper: DC. Designed the software used in analysis: AH.
References
- 1. Ricucci D. Apical limit of root canal instrumentation and obturation, part 1. Literature review. Int Endod J. 1998;31(6):384–93. Epub 2004/11/24. pmid:15551606.
- 2. Ricucci D, Langeland K. Apical limit of root canal instrumentation and obturation, part 2. A histological study. Int Endod J. 1998;31(6):394–409. Epub 2004/11/24. pmid:15551607.
- 3. Eriksen HM. Endodontology—epidemiologic considerations. Endod Dent Traumatol. 1991;7(5):189–95. Epub 1991/10/01. pmid:1687387.
- 4. Ebrahim AK, Wadachi R, Suda H. In vitro evaluation of the accuracy of five different electronic apex locators for determining the working length of endodontically retreated teeth. Aust Endod J. 2007;33(1):7–12. Epub 2007/04/28. pmid:17461834.
- 5. Liang YH, Li G, Shemesh H, Wesselink PR, Wu MK. The association between complete absence of post-treatment periapical lesion and quality of root canal filling. Clin Oral Investig. 2012;16(6):1619–26. Epub 2012/01/10. pmid:22228024; PubMed Central PMCID: PMC3501171.
- 6. Schaeffer MA, White RR, Walton RE. Determining the optimal obturation length: a meta-analysis of literature. J Endod. 2005;31(4):271–4. Epub 2005/03/29. pmid:15793382.
- 7. Dunlap CA, Remeikis NA, BeGole EA, Rauschenberger CR. An in vivo evaluation of an electronic apex locator that uses the ratio method in vital and necrotic canals. J Endod. 1998;24(1):48–50. Epub 1998/03/06. pmid:9487868.
- 8. Ramachandran Nair PN. Light and electron microscopic studies of root canal flora and periapical lesions. J Endod. 1987;13(1):29–39. Epub 1987/01/01. pmid:3469299.
- 9. Chugal NM, Clive JM, Spangberg LS. Endodontic infection: some biologic and treatment factors associated with outcome. Oral Surg Oral Med Oral Pathol Oral Radiol Endod. 2003;96(1):81–90. Epub 2003/07/09. pmid:12847449.
- 10.
Hellwig E, Klimek J, Attin T. Einführung in die Zahnerhaltung: Prüfungswissen Kariologie, Endodontologie und Parodontologie: Deutscher Ärzteverlag; 2009.
- 11. Katz A, Tamse A, Kaufman AY. Tooth length determination: a review. Oral Surg Oral Med Oral Pathol. 1991;72(2):238–42. Epub 1991/08/01. pmid:1923402.
- 12. Green D. A stereomicroscopic study of the root apices of 400 maxillary and mandibular anterior teeth. Oral Surg Oral Med Oral Pathol. 1956;9(11):1224–32. Epub 1956/11/01. pmid:13370115.
- 13. Green D. Stereomicroscopic study of 700 root apices of maxillary and mandibular posterior teeth. Oral Surg Oral Med Oral Pathol. 1960;13:728–33. Epub 1960/06/01. pmid:13851474.
- 14. ElAyouti A, Weiger R, Lost C. Frequency of overinstrumentation with an acceptable radiographic working length. J Endod. 2001;27(1):49–52. Epub 2001/08/07. pmid:11487165.
- 15. Lauper R, Lutz F, Barbakow F. An in vivo comparison of gradient and absolute impedance electronic apex locators. J Endod. 1996;22(5):260–3. Epub 1996/05/01. pmid:8632140.
- 16. Mull JP, Manjunath V, Manjunath M. Comparison of accuracy of two electronic apex locators in the presence of various irrigants: An in vitro study. J Conserv Dent. 2012;15(2):178–82. Epub 2012/05/05. pmid:22557820; PubMed Central PMCID: PMC3339016.
- 17. Hoer D, Attin T. The accuracy of electronic working length determination. Int Endod J. 2004;37(2):125–31. pmid:14871179
- 18. Hör D, Krusy S, Attin T. Ex vivo comparison of two electronic apex locators with different scales and frequencies. Int Endod J. 2005;38(12):855–9. pmid:16343110
- 19. Schlumbohm G, inventorVerfahren zum Bestimmen der Position einer in einen Zahnwurzelkanal eingeführten Messelektrode. Germany2008.
- 20. Schlumbohm G, inventorVerfahren zum Antrieb eines auf einer Antriebseinheit angetriebenen medizinischen Instrumentes2012.
- 21. Bergenholtz G, Lekholm U, Milthon R, Engstrom B. Influence of apical overinstrumentation and overfilling on re-treated root canals. J Endod. 1979;5(10):310–4. Epub 1979/10/01. pmid:297752.
- 22. Huang L. An experimental study of the principle of electronic root canal measurement. J Endod. 1987;13(2):60–4. Epub 1987/02/01. pmid:3470425.
- 23. Kobayashi C, Suda H. New electronic canal measuring device based on the ratio method. J Endod. 1994;20(3):111–4. Epub 1994/03/01. pmid:7996080.
- 24.
Markula-Liegau A. In vitro Untersuchung zur Endometrie mit dem Messgerät Root ZX Zahnmed. Diss, Erlangen. 1996.
- 25. Somma F, Castagnola R, Lajolo C, Paterno Holtzman L, Marigo L. In vivo accuracy of three electronic root canal length measurement devices: Dentaport ZX, Raypex 5 and ProPex II. Int Endod J. 2012;45(6):552–6. Epub 2012/01/20. pmid:22257341.
- 26. Pagavino G, Pace R, Baccetti T. A SEM study of in vivo accuracy of the Root ZX electronic apex locator. J Endod. 1998;24(6):438–41. Epub 1998/08/07. pmid:9693591.
- 27. Plotino G, Grande NM, Brigante L, Lesti B, Somma F. Ex vivo accuracy of three electronic apex locators: Root ZX, Elements Diagnostic Unit and Apex Locator and ProPex. Int Endod J. 2006;39(5):408–14. Epub 2006/04/28. pmid:16640641.
- 28. Keller ME, Brown CE Jr., Newton CW. A clinical evaluation of the Endocater—an electronic apex locator. J Endod. 1991;17(6):271–4. Epub 1991/06/11. pmid:1940752.
- 29. Hoer D, Attin T. The accuracy of electronic working length determination. International endodontic journal. 2004;37(2):125–31. Epub 2004/02/12. pmid:14871179.
- 30. Moura-Netto C, Palo RM, Camargo CH, Pameijer CH, Bardauil MR. Micro-CT assessment of two different endodontic preparation systems. Braz Oral Res. 2013;27(1):26–30. Epub 2012/12/05. pmid:23207901.
- 31. Stavileci M, Hoxha V, Gorduysus O, Tatar I, Laperre K, Hostens J, et al. Effects of preparation techniques on root canal shaping assessed by micro-computed tomography. Med Sci Monit Basic Res. 2013;19:163–8. Epub 2013/06/14. pmid:23760162; PubMed Central PMCID: PMC3692384.
- 32. Klinke T, Daboul A, Maron J, Gredes T, Puls R, Jaghsi A, et al. Artifacts in magnetic resonance imaging and computed tomography caused by dental materials. PLoS One. 2012;7(2):e31766. Epub 2012/03/03. pmid:22384071; PubMed Central PMCID: PMC3285178.
- 33. Marending M, Schicht OO, Paque F. Initial apical fit of K-files versus LightSpeed LSX instruments assessed by micro-computed tomography. International endodontic journal. 2012;45(2):169–76. Epub 2011/10/14. pmid:21992481.