Root canal's instrumentation is an essential step of root canal treatment procedure since it determines the efficacy of all subsequent procedures.1 This treatment phase is associated with root canal disinfection and canal tapering shape, with maintenance of the foramen position without any deviations from the original path of the canal.2 These shaping goals have been set as major objectives by various preparation techniques, and instruments that were introduced for canal instrumentation3 of this concept is difficult to reach in curved canal where procedural errors are very common to take place.4 Stainless steel files induce great lateral forces in curved canals due to its stiffness that lead to alter the canal morphology.5 Flexible NITI endodontic files did improve the root canal preparation by their ability to shape the narrow and curved root canals without producing any aberrations6 besides creating more centered canal preparations than stainless steel hand files.7 Evaluating the performance of endodontics files was always correlated to their ability to shape the curved root canals and their capability to preserve the original anatomy of them.8–10 Although many evaluating parameters were reported in the literature when shaping ability of instrument was evaluated, yet transportation is the most frequently used. Such evaluations are important to clinicians and researchers; their consideration is valued in the selection of a particular rotary NiTi instrument.11

BT-Race (FKG, La Chaux-de-Fonds, Switzerland) is a newly introduced endodontic file system. It mainly consists of three sequences of files. BT1(10/.06), BT2(35/.00), and BT3(35/.04), but BT4(40/.04) and BT5(50/.04) are also available. BT-Race is sterile and for a single use, to avoid patient cross-contamination, reduce both cyclical fatigue and torsion stress on instruments and, reduce the possibility of breakage.12 Single used files are frequently used to prepare multiple canals in a single furcated tooth; these files perform a significant amount of work.

Literature has limited information about the shaping ability of BT-Race instruments; only one study was available,13 which revealed that BT-Race has a respectable ability to maintain root canal curvature.13

The aim of this in vitro study is to evaluate repeated use of BT-Race file to resemble multi-rooted canals; for this, the research questions raised are: Does the new rotary files systems BT-Race induce root canal transportation and how does repetitive use1–6 affect the ability of BT-Race file to induce root canal transportation?

A total of thirty-six curved root canals in clear resin blocks (Dentsply-Maillefer) were used for this study. Each was mounted with an angle of apical curvature of 60° and was of 16-mm canal length. The blocks were given numbers from one to thirty-six (B1–B36) and then assembled into six groups (G1–G6). Each group consisted of six blocks. Six kits of the BT-Race file system were also given numbers from one to six (F.S.1.–F.S.6). Each kit was used to prepare the corresponding number of the block's group where each file was used six times each, one time in each block within each group.

In all canals, working length (WL) was set up to the level of the apical foramen using a #10 hand K-file (Dentsply Maillefer, Ballaigues, Switzerland) and glide path was established using a #10 hand K-file (Dentsply Maillefer, Ballaigues, Switzerland). The canals were then instrumented by BT-Race files using crown-down technique, driven by the Rooter Endodontic motor (FKG, La-Chaux De Fonds, Switzerland); the rotational speed was set at the recommended rotation of 800rpm and 1.5N/cm torque. Preparation was performed by the same operator, using the files in a gentle in-and-out motion until the full working length was reached. The instrumentation sequence was as follows: BT1 (size 10, 0.06 taper); BT2 (size 35, 0.00 taper); and BT3 (size 35, 0.04 taper). Between the uses of each rotary instrument in order to keep the glide path open, all canals were frequently irrigated with 99% ethyl alcohol using a 30-G side-vented needle and repeatedly recapitulated with K-file ISO 10.

All blocks were photographed before and after preparation using macroscopic magnifier (Leica Microsystems) with a total of 6× magnification with an image analysis program (Leica Application Suite© 2008 Leica Microsystems, Switzerland. Ltd.). Then both images for each block were overlapped accurately using Paint Shop Pro 9 (JascSoftware® U.S.A.). They were then transferred as one image to the SolidWorks program (SolidWorks 2014 ×64 Edition) and a drawing model was generated (Fig. 1).

Fig. 1.

Model transferred onto the Solidwork software (SolidWorks 2014 ×64 Edition).

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The possibility of canal transportation was assessed at four locations along the canal walls on both sides of the simulated canal (outer and inner); those sites were selected to signify the apical, middle, and coronal levels. The measurements of 1mm and 3mm were used to demonstrate the apical level, 5mm indicated the middle level, and 7mm specified the coronal level.

Transportation of the canal's center was determined by subtracting the amount of resin removed at the outer wall (convex) from that removed at the inner wall (concave) divided by two. A positive result means that transportation occurs mainly on the inner surface of the canal curvature and negative value indicates that transportation occurs mainly on the outer surface of the canal curvature.

SPSS software V.22 was used for data analysis, and multivariate statistical analysis (GLM – General Linear Model) was applied to compare the transportation between the six groups when time of uses and the transportation in the four locations in the canals were considered. The statistical Greenhouse–Geisser was considered toward the rejection of covariance homogeneity after application of Mauchly's test. The Bonferroni correction was used for multiple comparisons analysis with a significance level of 0.05.

One file fractured; BT2 number 4 was broken during the sixth time attempting to prepare block number thirty-four.

Means and standard deviations of canal center transportations are shown in (Table 1). When all locations were considered, there were no statistically significant differences in transportation between the six groups of files (F=0.453; p=0.808). BT-Race rotary NiTi instruments showed transportation in both canal sides. However, there was more transportation toward the inside of the curve in the coronal and middle levels (−values), rather than further toward the outside of the curve at the apical level (+values) (Table 2).

On the other hand there were statistically significant differences in this measure between the locations when all groups about number of uses (F=22.358; p<0.0005) –were considered (Table 1).

No statistically significant differences were found in transportation in the interactive influence of the locations and the number of uses of the files (F=0.746, p=0.691) – (Fig. 2).

Fig. 2.

Measures of transportation induced by BT files considering locations and number of usage.

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In average, the transportation was greater and statistically significant at 5mm from the apex than other locations (p<0.05). The major mean difference of transportation was found between 5mm from the apex and 1mm (0.052mm; p<0.0005). The second largest transportation was found at 7mm from the apex. In this case, the largest mean difference occurred when compared the location at 1mm from the apex (0.025mm; p<0.03) – (Table 3).

The purpose of this study was to determine the shaping ability of BT-Race endodontic file systems by measuring canal transportation in simulated root canals in resin blocks. The reliability of resin blocks as an experimental model for assessment of instruments and preparation techniques has been established.14,15 Although literature has reported that caution should be taken in justification of the results, since there are differences between resin and dentin materials,16 clinical relevance can be transmitted as result of their outcomes.17,18

In this study, transportation of the canal at the apical level of the simulated canals was analyzed in a two-dimensional plan using Solidwork software. A previous study found that highest acceptable amount of canal transportation occurred apically; this measurement is reached up to 0.15mm and should not be greater than 0.30mm.1 Measurements outside of this range are responsible for number of adverse effects on the apical seal.19 Our study demonstrated that the amount of the canal transportation induced by BT-Race was less than both figures mentioned (Table 1; Fig. 2).

Till date, only one study by Burklein et al. evaluated the shaping ability of BT-Race.13 The inspected locations, as well as the methodologies, are different. Burklein et al. study, showed that the transportation at 0.5mm was 0.12±0.08; our study showed that at 1mm, it was 0.032±0.020. Burklein et al. study compared the BT-Race with Mtwo, PTU, and PTN systems, and showed no significant differences between all four instruments regarding canal transportation. Ours showed no statistically significant difference between the files themselves.

Due to the lack of studies conducted on the BT-Race, results were compared with the published data of the predecessor systems. Despite the fact that different methodologies were used, the outcomes were similar. Saber et al.20 measured the transportation induced by iRaCe (FKG, La Chaux-de-Fonds, Switzerland) at the apical region, and found it to be (0.06±0.01); this study's data showed (0.032±0.020) as the value of the transportation at the center of the canal. The other Race study showed transportation at apical level of 3mm (0.10±0.10) and at middle level of 6mm (0.15±0.13)21; this study's results are well within the ranges shown by BT-Race files at 3mm (0.038±0.022) and at 5mm (0.085±0.038), and almost equal to Nabavizadeh et al.22 that revealed 0.034 at 1mm, and 0.010 at 5mm for BioRace.

In this study's results, the amount of canal transportations was generally small; the reason for the small amount of transportation induced by BT-Race can be explained by the file flexibility. Previous studies found that a lesser amount of transportation takes place with more flexible files.23 It was also specified that the centered canal preparation depends on the file design, its flexibility, or the instrumentation technique.24 The file sequences and BT tip of the BT-Race instrument allow adequate apical preparation sizes, ensure that the original canal shape is maintained, and keep the files centered in the canal.12,25 These reasons could be another cause of the small amount of observed transportation.

This study's data showed also that the direction of transportation was in the apical area toward the outside curvature, a finding supported by the previous reports, which also confirmed the same inclination; this was explained as a result of file's superelasticity, which was allowing the instrument to follow the canal curvature.9,26,27

Evaluating the changes of the amount of root canal transportation upon reusing the file six times was chosen to mimic the clinical situation of treating one or two molars within the same patient. Single patient NiTi use is the world's endodontic golden standard, specifically for the cross-contamination reason and breakage of instruments as a result of metal fatigue. It is crucial to study instruments in non-clinical reuse circumstances to decide their most extreme capacities and performance. Our result exhibited no statistical difference between amount of canal transportation when the file was used six times. Up to the present time, no study evaluated how several clinical uses of BT-Race instruments would effect root canal transportation; however, one study examined the effects of multiple clinical uses of Protaper universal file on the incidence of root canal transportation.28 This study reported significant diversity in the amount of transportation between the numbers of file uses. The variances between the instruments’ design made the comparison impossible.

BT-Race file system has a “non-screw-in design” that introduces them into the root canal with low magnitude of positive force and torque, and allows them to be removed smoothly from the canal with low magnitude of negative force and torque, This could be seen in (Figs. 3–5) as provided from the FKG based on our request. This ability can be added to the reason why BT-Race instruments can be used frequently without significant changes in amount of transportation.

Fig. 3.

Effect of torque. Positive and negative forces on B1.

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Fig. 4.

Effect of torque. Positive and negative forces on B2.

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Fig. 5.

Effect of torque. Positive and negative forces on B3.

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It is important to note that the instruments do maintain their cutting efficiency throughout the experiment; transportation decreases were not due to decreases in blade cutting ability. Our study showed that the files were able to maintain their cutting efficiency even after 6 times usage, since they could remove the resin materials on both the inner and outer sides of the tested simulated canals.

The single use BT-Race file is ideal for use in one case only; the manufacture claims that it is ideal for molars with 4/5 canals.12 In our study, a fracture happened after the instrument was used six times; this could be due to significant amount of work done above the recommendation by the manufacturer (more than 5). In addition, the inherent resistance of the resin material used in the block may cause unwinding of the instrument flutes and, consequently, fracture of the files.29–31 Burklin et al. also reported one BT-Race file fractured (BT2)13 and deduced that to the cylindrical design of the instrument that makes it prone to fracture. The electro-polished surface feature of the file is responsible for decreasing the effects of torsional and cyclic fatigue,25 which could explain its resistance to fracture. Despite the limitations of this study, a small amount of transportation was induced by BT-Race file; repetitive use1–6 did not affect the ability of BT-Race to maintain the shaping ability of curved root canal as there were no statistically difference between the amount of transportation and the number of uses. A standard protocol for testing the shaping ability of NiTi rotary instruments is required to confirm consistency of methodology and to obtain comparable results when assessing the transportation of new instruments and techniques.

Under the condition of this study, BT-Race files (FKG, La Chaux-de-Fonds, Switzerland) respect the original canal curvature well. It can be used to prepare multi-rooted teeth with minimal amount of transportation.

The authors have no conflicts of interest to declare.