Background
Endodontic therapy is a commonly used approach for the treatment of pulpitis and periapical periodontitis. Endodontically treated teeth have been demonstrated to be more prone to crown or root fracture than vital teeth [
1,
2]. Vertical root fracture (VRF) is the most common and serious complication of the endodontically treated tooth, which typically leads to root resection and tooth extraction [
3]. Therefore, the prevention of VRF is desirable. Many attempts have been made to increase the strength of endodontically treated roots, such as placing posts inside the roots [
4,
5] and obturating dental materials in the root canals [
6‐
8]. In recent years, the effects of different obturating materials on the strength of endodontically treated roots have received substantial attention.
Gutta-percha with the resin-based sealer AH plus is regarded as the gold standard in current obturation systems. Although Gutta-percha has many excellent properties, including good biocompatibility, low cytotoxicity [
9], dimension stability and thermoplasticity, the ability of this material to strengthen roots that are treated endodontically remains unclear. Some studies [
2,
10‐
12] reported that Gutta-percha/AH plus significantly increased the VRF resistance of instrumented roots, whereas other studies reported no significant effect [
13‐
19]. Resilon, a root canal obturating material based on thermoplastic-filled polymer composites, has excellent sealing ability, antimicrobial activity, adhesive properties and retreatable properties [
20,
21] when used in combination with one of the dual-cure resin-based root canal sealers Epiphany or Realseal. However, whether the fracture resistance of root canals can be increased by filling with Resilon and whether roots obturated with Resilon have higher fracture resistance than do those filled with Gutta-percha remain unclear. The inconsistent results cannot provide clear guidance to clinicians in making appropriate clinical choices.
Therefore, it is imperative to conduct a meta-analysis to investigate and compare the strengthening effects of Gutta-percha and Resilon on prepared roots. For the purposes of the meta-analysis performed here, data from randomized controlled in vitro trials were compiled to evaluate and compare the effects of these two root canal filling materials on the VRF resistance of teeth after root canal therapy.
Discussion
VRF is often associated with the dehydration of dentin after endodontic therapy [
30], removal of the root structure during root canal instrumentation [
17,
19], loss of collagen cross-linking during root canal irrigation [
31‐
34] or excessive pressure during root canal obturation [
35]. At present, VRF has a high likelihood of occurring (up to 10.9%) after endodontic treatment [
36]. Its occurrence typically leads to endodontic treatment failure and tooth extraction [
37]. Therefore, it is important to seek an effective method to prevent VRF. Posts are typically used to reinforce endodontically treated roots [
38‐
40]. However, their efficacy is very controversial, as it is associates with several factors which can influence the distribution of stress on the root canals and the amount of remaining dentin [
41]. These factors include post type [
42], length, diameter, material, and design [
41], etc. If these factors are suitable, the posts might reinforce roots. If some of these factors are undesirable, the posts may play a negative role. Therefore, careful control of these factors must be taken when posts are used to reinforce endodontically treated teeth. Alternative methods to increase the VRF resistance of endodontically treated teeth have been investigated. Recently, obturating materials such as Gutta-percha and Resilon have been shown to influence the VRF resistance of root canals. However, there are different views in the literature with respect to whether these two materials can increase the postendodontic VRF resistance of roots and which one has a better reinforcement effect. These conflicting views make it difficult for clinicians to select the appropriate clinical approach. Therefore, a meta-analysis was performed to evaluate and compare the reinforcement efficacy of these two obturation systems on endodontically treated root canals. The results can offer guidance to clinicians in evidence-based decision making.
The results of this meta-analysis indicate that root canals filled with Resilon have higher fracture resistance than do prepared unfilled roots or roots filled with Gutta-percha/AH plus. These results can be attributed to the “monoblock” concept. According to Tay FR [
43], a monoblock is a gap-free, solid and mechanically homogeneous mass in the root canal space that consists of different bondable materials and interfaces, which can facilitate favorable root canal sealing and simultaneously reinforce the filled canal [
44,
45]. When Resilon is used to obturate a root canal, the Resilon core is bonded to the sealer (Epiphany or Realseal), and the resulting complex is bonded to the dentinal wall of the root canal [
46], forming a monoblock system [
47]. Resilon is a thermoplastic synthetic polymer composed of polyester with improved flexural strength. Compared with Gutta-percha, Resilon shows superior bonding potential when applied in combination with a resin-based sealer [
15]. Therefore, the Resilon system has a superior ability to reinforce instrumented roots than dose the Gutta-percha/AH plus obturation system.
This meta-analysis found no significant difference in VRF resistance between prepared unfilled roots and Gutta-percha/AH plus obturated roots. Gutta-percha/AH plus has been accepted as the standard obturating system in root canal treatment. However, although the adhesive strength between the AH-plus sealer and the dentine wall is favorable [
48], there is no chemical adhesion between Gutta-percha and AH-plus [
8]; therefore, no monoblock system is formed, and no reinforcement is provided to the roots [
49].
There was considerable heterogeneity among the included studies, which was primarily associated with methodological diversity. This diversity included differences in the type of tooth, root canal filling techniques and irrigation fluids, etc. The articles included in this meta-analysis involved different types of teeth, such as single-rooted straight maxillary anterior teeth, mandibular anterior teeth and mandibular premolars. Variation in root canal anatomies and root morphologies might affect fracture resistance of roots slightly [
50]. In addition, the investigators in the eligible studies used different obturation techniques, including a lateral compaction technique and a single cone technique. The lateral compaction technique does not produce a homogeneous mass because the core material and accessory cones always remain separated, and the excessive wedge force while compacting may lead to initial root cracks [
51], which might cause bias to the results of the studies with this technique and then affect the conclusion of our meta-analysis. Single cone techniques are often reliant upon sealers and may not densely obturate the canal in 3 dimensions [
52], which may affect the efficacy of the obturating materials in reinforcing the roots. Furthermore, the irrigation step may influence the bonding of the obturating materials to the dentinal surface of the root. In all of the included studies, the investigators used ethylene diamine tetraacetic acid (EDTA) and sodium hypochlorite (NaClO) to remove the smear layer. However, the final irrigations differed among the studies. According to Lertchirakarn et al. [
27], the high resistance of Resilon-obturated canals to fracture might be due to the clearance of the smear layer by EDTA after instrumentation which allowed the sealer to contact the canal wall and penetrate the dentinal tubules, resulting in increased root strength. In addition, it was reported that NaClO is not appropriate as the last irrigation to remove the smear layer because the residual solution may have adverse effects on the bonding strength of the primer to the dentine and may inhibit the curing of resin materials [
53]. In contrast, Varela et al. [
54] reported that the effect of NaClO on the polymerization of the sealer could be neglected. Due to these conflicting conclusions, the influence of final irrigation on the efficacy of the obturating materials in strengthening the roots remains unclear.
To our knowledge, this study presents the first meta-analysis performed to evaluate and compare the effects of Gutta-percha/AH plus and the Resilon system in reinforcing endodontically treated root canals. Strict inclusion and exclusion criteria were established. Only randomized controlled trials were included. Exhaustive searches of the relevant literature were performed. Fourteen studies were ultimately included. The risk of bias of these studies was strictly evaluated. Most of the included studies are well-designed research studies. A sensitivity analysis was used to explore the stability of results. The SMDs and 95% CIs did not change significantly when any one trial was removed. Therefore, our results are stable.
Although the meta-analysis was carefully conducted, some limitations remain. First, publication bias could not be evaluated because of the small number of trials included in the meta-analysis. Second, a medium risk of bias was found in some of the included studies. These studies scored especially poorly on the items including calculation of sample size and blinding of the examiner. Third, the meta-analysis is based on the findings of in vitro studies that were of low level of evidence. An in vitro approach is sometimes the only practical approach for medical or bio-medical research. However, in vitro studies have intrinsic limitations when attempting to accurately simulate biological, chemical or physical conditions in vivo [
55,
56]. Although fracture resistance testing can be used to evaluate the fracture resistance of root canals filled with different materials, factors such as the temperature cycling, the wet environment, the direction of masticatory force, the frequency of loading and the presence of periodontal membrane need to be considered because they may affect the fracture resistance of roots in vivo. Therefore, the results of in vitro studies cannot be validly extrapolated to the clinical context. Even so, mechanical testing methods can offer useful information to identify substrate variables [
57‐
60] and then provide guidance for application procedures [
61,
62]. Thus, a meta-analysis based on in vitro studies is helpful to clinical practice, especially in the absence of evidence based on well-designed clinical trials [
63‐
65]. Moreover, such a meta-analysis can suggest improvements and standardized methodologies for future studies [
66,
67].
In consideration of the above results and limitations, we suggest that future randomized controlled studies perform appropriate sample size calculations, randomization and blinding, and control potentially confounding factors. Moreover, well-designed randomized controlled clinical trials are needed to evaluate the incidence of VRF of endodontically treated teeth while using these two obturating materials.
Ms. MMT is a postgraduate student, College of Stomatology, Chongqing Medical University; a postgraduate student, Chongqing Key Laboratory of Oral Diseases and Biomedical Sciences; and a postgraduate student, Chongqing Municipal Key Laboratory of Oral Biomedical Engineering of Higher Education, Chongqing, China.
Dr. ZWC is a lecturer, College of Stomatology, Chongqing Medical University; a lecturer, Chongqing Key Laboratory of Oral Diseases and Biomedical Sciences; and a lecturer, Chongqing Municipal Key Laboratory of Oral Biomedical Engineering of Higher Education, Chongqing, China.
Ms. CJS is a postgraduate student, College of Stomatology, Chongqing Medical University; a postgraduate student, Chongqing Key Laboratory of Oral Diseases and Biomedical Sciences; and a postgraduate student, Chongqing Municipal Key Laboratory of Oral Biomedical Engineering of Higher Education, Chongqing, China.
Dr. BH is a lecturer, College of Stomatology, Chongqing Medical University; a lecturer, Chongqing Key Laboratory of Oral Diseases and Biomedical Sciences; and a lecturer, Chongqing Municipal Key Laboratory of Oral Biomedical Engineering of Higher Education, Chongqing, China.
Dr. XG is a lecturer, College of Stomatology, Chongqing Medical University; a lecturer, Chongqing Key Laboratory of Oral Diseases and Biomedical Sciences; and a lecturer, Chongqing Municipal Key Laboratory of Oral Biomedical Engineering of Higher Education, Chongqing, China.
Dr. YJC is a lecturer, College of Stomatology, Chongqing Medical University; a lecturer, Chongqing Key Laboratory of Oral Diseases and Biomedical Sciences; and a lecturer, Chongqing Municipal Key Laboratory of Oral Biomedical Engineering of Higher Education, Chongqing, China.
Dr. JLS is a professor, College of Stomatology, Chongqing Medical University; a professor, Chongqing Key Laboratory of Oral Diseases and Biomedical Sciences; and a professor, Chongqing Municipal Key Laboratory of Oral Biomedical Engineering of Higher Education, Chongqing, China.