A comparison of the shaping ability of reciprocating NiTi instruments in simulated curved canals

Effective cleaning and shaping the root canal system is the primary objective of root canal instrumentation. The root canal should be cleaned and shaped to allow three-dimensional obturation. The ideal prepared root canal should have a continuously tapering funnel shape that preserves the original anatomy with the smallest diameter at the end point and the largest at the orifice providing adequate canal shape to fill the canal.1, 2

Shaping the canal is the most time-consuming and difficult factor of root canal therapy. Many techniques, devices, and instruments such as stainless steel hand instruments or nickel-titanium rotary instruments have been introduced to produce the appropriate root canal preparation.

The use of stainless steel hand files is time consuming and tiring, and it produces a high level of procedural errors.3 Since Walia et al. introduced nickel-titanium (NiTi) alloy called Nitinol,4 NiTi files in clinical practice has benefited the efficacy of endodontic practice by accuracy, speed, quality and risk reduction compared with the previously used manual stainless steel files because of their greater flexibility, better resistance to torsional fracture and the shape memory effect.5-8 The use of nickel-titanium instruments have reduced operator fatigue and enhances the success rate of root canal treatment in comparison with stainless steel hand instruments.9, 10 As a result, there are several engine-driven systems available in dental market that use NiTi instruments of varying designs and dimensions now.

The use of balanced forces technique, the use of clockwise and anticlockwise movements in the preparation of root canals, was introduced in 1985.11 This technique allows maintenance of the original canal shape in curved root canal during preparation.12

The concept of reciprocating motion based on balanced force technique was introduced by Yared, who utilized the single F2 ProTaper instrument (Tulsa Dentsply, Tulsa, OK, USA) in reciprocating motion to shape root canals.13 This was shown to be as effective as the full ProTaper system in cleaning around root canals and extruding similar amounts of apical debris. Recently, two different reciprocating systems were introduced: Reciproc (VDW, Munich, Germany) and WaveOne (Dentsply Maillefer, Ballaigues, Switzerland). Both instruments have been designed for use in reciprocation (Figure 1).

Figure 1
New reciprocating systems. (a) Reciproc file (R25, R40, R50) and Silver Reciproc reciprocating engine (VDW, Munich, Germany); (b) WaveOne file (small, primary, large) and WaveOne motor (Dentsply Maillefer, Ballaigues, Switzerland).

• Click for larger image

These new systems suggest that the instrument designs can complete shaping the root canal with single file instrumentation. Thus, only one instrument is required to prepare a root canal. The Reciproc manufacturer suggests that only one of the three files is required to prepare a root canal: R25 (tip size 25 with a taper of 0.08 over the first apical millimeters), R40 (tip size 40 with a taper of 0.06 over the first apical millimeters), or R50 (tip size 50 with a taper of 0.05 over the first apical millimeters). According to WaveOne manufacturer, WaveOne single file is enough to fully shape the root canal. WaveOne NiTi files are available in three sizes: small (tip size 21 with a taper of 0.06), primary (tip size 25 with a taper of 0.08) and large (tip size 40 with a taper of 0.08).

Although successful therapy depends on many parameters, one of the most important factors in any root canal treatment is canal preparation. This is essential because preparation determines the efficacy of mechanical debridement and ideal canal geometries for adequate obturation.14 To date few investigations into the shaping ability of reciprocating files have been carried out. The purpose of the present study was to compare the shaping ability of new Reciproc and WaveOne instruments compared with ProTaper, Profile and hand instruments during the preparation of simulated root canals in resin blocks.

Successful endodontic therapy is dependent upon the dentist's ability to clean and shape the root canal safely and effectively. This study attempted to compare the efficiency and shaping ability of the new single-file systems Reciproc and WaveOne with the established ProTaper and Profile instruments. Reciproc and WaveOne are commercially available instruments designed specifically to be used in reciprocating motion.

Generally, to evaluate the shaping abilities of different instruments, two experimental models have been used; simulated root canals in resin blocks and root canals in extracted human teeth. Although the use of real teeth provides conditions that are close to the clinical situation, it has large variations in the root canal morphology.17 Resin blocks are able to standardize the conditions in terms of diameter, length and angle of curvature of the original canal shape and allow direct comparison of the shaping ability of different instruments.16 However, the simulated canals in resin blocks do not represent the action of the instruments in the root canals of natural teeth. One of the drawbacks of using rotary instruments in resin block is heat generation, which may soften the resin material, leading to binding of cutting blades, and separation of the instrument.5.18 However, provided that the conditions are the same for either instruments or techniques tested, a comparison or the resultant shape of the canal using simulated canals in resin blocks may be a valid substitute for natural teeth.19

Measurements were determined at the certain distinct points. In previous studies, measurements were made at a total of nine positions; width at the end-point, width of the zip (when present) at its widest point, width of the elbow (when present) at its narrowest point, width at the apex of the curve of the original canal. width at the wide zone (when present) coronal to the elbow corresponding to the 'danger zone', width at the beginning of the curve, width at a narrowing of the canal (when present) coronal to the curve, width at a point half-way between the curve and the orifice, and width at the orifice and modification of the this method was used.20, 21 In the present study, measuring points could be defined using the method described by Schäfer et al.16 By this method, we were able to maintain certain distance from the apical foramen and remove any subjective factors that might influence in deciding the measuring point.

When comparing the shaping abilities of different preparation systems of different root canal instruments, it is important to have similar apical preparation diameter.22, 23 In this investigation, the final apical diameter in all groups was a size 25. For single-file systems, the Reciproc R25 file and the WaveOne primary reciprocating file were selected. These instruments had the same tip size of 25. This were performed in accordance with the recommendation of the manufacturers as these sizes are designated for narrow and curved canals when a hand instruments do not passively reach the full working length.

Whereas ProTaper, Profile and hand instruments have various apical sizes with gradual increase, Reciproc and WaveOne have omitted the conventional increments and offer apical widths of apical size 25 and 40. And the risk of transportation always increases in curved canals and with the increase of file size. Wider apical preparation might result in some canal straightening and undesirable weakening of the tooth structure, whereas minimal enlargement may leave tissue remnants and infected dentin behind.24 Thus, the Reciproc R25 file, the WaveOne primary reciprocating file, ProTaper F2, Profile #25 .06 and #25 K file were selected for this study.

The main parameters were used to evaluate the shaping ability while protecting the curvature of the canal and maintaining a good centering ability. Substantial curvature in the root canals lead to increased difficulty in root canal preparation.15, 20 Several studies have determined the curvature of the root canals.15, 25-27 To describe the severity of curved canals, Schneider initially put forward the concept of the angle of root canal curvature. The degree of canal curvature was defined as the angle between the long axis of the canal and a line from the point of initial curvature to the apical foramen.15 To describe the canal curvature, Schneider method which is the first and still most common method was used in this study. This method has limitation in that the radius of curvature is not considered as an important second parameter.25 But it is still a simple and generally accepted method for measuring root canal curvatures.

Statistical analysis using paired t-test revealed that in the mean resin removal, there were differences at all levels except the apical third (1 - 3 mm level) of Reciproc and WaveOne group; 2, 4 mm level of ProTaper; 5 mm level of Profile and 9, 10 mm level of K file group. This indicated that in the groups of Reciproc and WaveOne, the instrument had a tendency to maintain the centering in the apical 1 - 3 mm of the canal (Table 1).

These instruments should be used cautiously to avoid excessive removal at the inner curve, leading to danger zones and straightening of the canal. According to the results of the present study, in all groups the resin was removed more from the outer side of the curvature in the apical 1 - 3 mm except at the apical 3 mm level of Reciproc group, indicating a slight outer widening of the canal. ProTaper instruments removed more resin on the inner side of the curvature in comparison with the outer side of the curvature.21 This study found that stainless steel instrument led to more preparation at the middle level (curved region) than NiTi instruments. This result indicates that NiTi instruments decreased the risk of strip perforation in the curved canals. Stainless steel hand file has a high frequency of preparation errors probably as a result of the inherent stiffness of the metal. In most circumstances, the use of stainless steel files in narrow curved canals is difficult and limits apical enlargement thus hindering obturation.16, 28

The inner/outer ratio is closed to 1 at apical 5, 6 mm level using Profile and apical 3 mm using Reciproc and WaveOne. This demonstrates that better compliance with original canal shape was obtained. A possible difference between the instruments can be the reciprocating movement. Previous studies have assessed ProTaper instruments when used in a reciprocating working motion regarding preparation of curved root canals.13, 29, 30 To overcome the root curvature, 'balanced forced technique' was proposed by Roane et al. in 1985.11 Reciprocal action is the specially designed to work in a similar manner but in a reverse balanced force motion. A large rotating angle in the counter clockwise motion determines the instrument advances in the canal and engages dentin to cut it, whereas a smaller angle in the clockwise motion allows the file to be immediately disengaged and safely progress along the canal path, while reducing the effect of a screwing effect and file breakage. These angles are specific for the different instruments. According to manufacturer, Reciproc is 150° counter clockwise then 30° clockwise rotation, while WaveOne is 170° counter clockwise then 50° clockwise rotation. These differences could have influenced the results of this study.

The straightening of curved root canals is one of major problems during root canal preparation. In order to reduce canal aberrations, new NiTi instruments have been developed. In 2007, a new NiTi M-Wire (Dentsply Tulsa Dental Specialties, Tulsa, OK, USA) technology was produced in an advanced thermal treatment process. The manufacturer states that M-wire is used to produce instruments with greater resistance to cyclic fatigue and greater flexibility than traditional NiTi alloy.31, 32 Reciproc and WaveOne are manufactured with M-wire NiTi alloy. The mean straightening ranged between 2.94 when using ProTaper and 3.74 when using WaveOne. Although there is no statistical significance, Reciproc and WaveOne tend to be less straightened and K-file tends to be more straightened than other instruments. There was no statistical significance in the difference of working length loss within the groups. These findings are consistent with the observation of other investigators who observed the minimal decrease in working distance occurring with rotary NiTi instruments,5, 17 but the authors of these studies doubted the clinical significance of the findings.

In present study, the shaping ability of different instruments including single file system was investigated by the amount of resin removed, straightening of the canal, and change of the working length. Because reciprocating movement uses pecking motion, the force applied to the apical portion can cause side-effects such as microcracks. Other important parameters are still needed to understand reciprocation and their influence on the shaping ability of these instruments.

Within the limitation of this present study, NiTi instruments are superior to stainless-steel K file in their shaping ability. Reciproc and WaveOne instruments maintained the original canal curvature in curved canals better than ProTaper and Profile, which tend to transport towards the outer canal wall of the curve in the apical part of the canal. Thus, both single-file systems showed relatively good shaping ability and can be suitable for shaping of curved canal with only one instrument.