http://orcid.org/0000-0002-3952-7681
Correction
17 Apr 2018: Astudillo-Rubio D, Delgado-Gaete A, Bellot-Arcís C, Montiel-Company JM, Pascual-Moscardó A, et al. (2018) Correction: Mechanical properties of provisional dental materials: A systematic review and meta-analysis. PLOS ONE 13(4): e0196264. https://doi.org/10.1371/journal.pone.0196264 View correction
Figures
Abstract
Provisional restorations represent an important phase during the rehabilitation process, knowledge of the mechanical properties of the available materials allows us to predict their clinical performance. At present, there is no systematic review, which supports the clinicians’ criteria, in the selection of a specific material over another for a particular clinical situation. The purpose of this systematic review and meta-analysis was to assess and compare the mechanical properties of dimethacrylates and monomethacrylates used in fabricating direct provisional restorations, in terms of flexural strength, fracture toughness and hardness. This review followed the PRISMA guidelines. The searches were conducted in PubMed, Embase, Web of Science, Scopus, the New York Academy of Medicine Grey Literature Report and were complemented by hand-searching, with no limitation of time or language up to January 10, 2017. Studies that assess and compare the mechanical properties of dimethacrylate- and monomethacrylate-based provisional restoration materials were selected. A quality assessment of full-text articles were performed according to modified ARRIVE and CONSORT criteria and modified Cochrane Collaboration’s tool for in vitro studies. Initially, 256 articles were identified. After removing the duplicates and applying the selection criteria, 24 articles were included in the qualitative synthesis and 7 were included in the quantitative synthesis (meta-analysis). It may be concluded that dimethacrylate-based provisional restorations presented better mechanical behavior than monomethacrylate-based ones in terms of flexural strength and hardness. Fracture toughness showed no significant differences. Within the monomethacrylate group, polymethylmethacrylate showed greater flexural strength than polyethylmethacrylate.
Citation: Astudillo-Rubio D, Delgado-Gaete A, Bellot-Arcís C, Montiel-Company JM, Pascual-Moscardó A, Almerich-Silla JM (2018) Mechanical properties of provisional dental materials: A systematic review and meta-analysis. PLoS ONE 13(2): e0193162. https://doi.org/10.1371/journal.pone.0193162
Editor: Ryan K. Roeder, University of Notre Dame, UNITED STATES
Received: January 31, 2018; Accepted: February 5, 2018; Published: February 28, 2018
Copyright: © 2018 Astudillo-Rubio 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 and its Supporting Information files.
Funding: The author(s) received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Provisional or interim restorations are commonly used in dentistry during the time between tooth preparation and placement of the definitive restoration [1]. In view of the strong demand for good aesthetic results, provisional restorations have become a valuable tool for esthetic and functional diagnosis in dentistry. Dentists can gain their patients’ confidence by handling this intermediate stage of treatment successfully, achieving the necessary predictability for a successful final restoration [2].
Fabrication of an ideal provisional restoration is crucial for gum health and to protect the pulp, for prosthetically-guided tissue healing to achieve an acceptable emergence profile, for minimizing the migration of dental abutments, and for assessing the prospective form and function of the definitive prosthesis [2,3].
Provisional restoration materials can be divided into two groups according to their chemical composition: those based on monomethacrylates or acrylic resins, which include polymethylmethacrylate (PMMA) and polyethyl/butyl methacrylate (PEMA); and those based on dimethacrylates or bis-acryl/composite resins such as bisphenol A-glycidyl dimethacrylate (Bis-GMA) and urethane dimethacrylate (UDMA; these resins are polymerized by light) [3]. The technology of provisional restoration materials has evolved in recent years, giving rise to improvements in the basic chemical composition that have made it possible to obtain commercial products which can be used with direct techniques, with good clinical and mechanical performance. This improves clinical practice, saves time and money and avoids sending to the laboratory for provisional restoration manufacture by indirect techniques [3].
Provisional restorations are subjected to chewing forces and require specific mechanical properties that allow them to survive the repeated functional forces of the oral environment, so in order to predict the behavior of a material, it is important to understand its mechanical properties. In clinical settings such as changes in the vertical dimension in full oral rehabilitation, long-span fixed prostheses, temporomandibular joint dysfunction therapies or patients who exhibit parafunctional habits, the mechanical properties of intermediate restorations play an important role in enabling the dentist to assess commercial products critically and choose the ideal material for a specific clinical situation [2].
Several in vitro studies have examined the mechanical properties of provisional restoration materials used with direct techniques. The aim of the present study is to compare and assess the available evidence through a systematic review and meta-analysis of the literature, seeking to answer the following research question: In provisional restorations executed using direct techniques, do the mechanical properties of dimethacrylate-based materials differ from those of monomethacrylate-based materials in terms of flexural strength, fracture toughness and hardness?
Materials and methods
This systematic review was conducted in accordance with the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) guidelines [4]. (S1 Table).
Search strategy
An exhaustive bibliographic search was conducted in MEDLINE-PubMed, Embase, Web of Science (Core Collection) and Scopus to identify relevant articles published up to 10 January 2017 with no limitations on the language or year of publication. Controlled vocabulary (MeSH terms in Pubmed and Emtree terms in Embase) and free-text terms in the titles and/or abstracts were used to define the search strategy in all the databases. The search strategies were implemented with keywords based on each section of the PICO question, separated by the Boolean operator OR, then all the sections were combined using the Boolean operator AND. The grey literature search was conducted in the New York Academy of Medicine Grey Literature Report. The electronic database searches were carried out by two of the authors (DAR and ADG), working separately. The keywords used were: MesH terms: “dental restoration, Temporary,” “tooth crown”, “denture, partial, Temporary”, “polymethyl methacrylate”, "bisphenol a-glycidyl methacrylate", “mechanical phenomena”, “mechanical processes”; Emtree terms: “tooth prosthesis”, “tooth crown”, “fixed partial denture”, “poly(methyl methacrylate)”, “mechanics”, “mechanical stress”, “hardness”. Free Terms: provisional dental restoration, interim dental restoration, temporary dental restoration, provisional crown, interim crown, temporary crown, provisional partial fixed prosthesis, PMMA, PEMA, bis-acryl, provisional resin, interim resin, mechanical properties, fracture toughness, flexural strength. (Table 1).
Eligibility criteria
Studies that analyzed and compared the mechanical properties of provisional restoration materials for use with direct techniques or in the dentist’s office, included both basic chemical composition groups (monomethacrylates and dimethacrylates) in the comparison, were included in the review.
The exclusion criteria covered articles that investigated provisional restoration materials for heat-curing or fabrication by indirect techniques, or compared the mechanical properties of different materials within a single chemical composition group, or studied provisional restorations placed on implants, provisional restorations in relation to endodontics or provisional cements. Case reports, case series, techniques for fabricating provisional restorations, literature reviews, abstracts, interviews, editorials and expert opinions were also excluded.
Screening and selection
The studies located in the searches were screened in duplicate, independently, by two researchers (DAR and ADG) in order to identify those with titles and abstracts that met the inclusion criteria. The articles on which both authors agreed were selected.
The full text of the articles selected on their titles and abstracts were read and the modified ARRIVE and CONSORT [5] criteria were applied to assess the methodological quality of the article as regards correct conduct and the structure of title, abstract, introduction, methods, results, discussion and conclusions (S2 Table). The references listed in all the articles selected after reading the full text were reviewed manually and checked against the inclusion criteria. Disagreements concerning their inclusion were resolved through discussion with the third author (APM).
Data extraction
A data extraction protocol was defined and assessed by two of the authors (DAR and ADG). The data were extracted independently from the full-text articles selected for inclusion, using a standardized form in electronic format (Office Excel 2011 software, Microsoft Corporation, Redmond, WA, USA). The authors classified the information on authors/year, study design, sample size, chemical composition, mechanical property studied, results, conclusions and risk of bias.
Assessment of risk of bias
The assessment of risk of bias in the in vitro studies included in this review was based on a previous study [6], and verified whether the mechanical properties were analyzed in accordance with the following parameters: (a) standardization of sampling procedures, (b) single operator, (c) description of sample size calculation, (d) blinding of test machine operator, and (e) calibration of sample size before applying the test, test design, and flexural strength, fracture toughness and hardness calculations in accordance with standards and specifications.
If the article reported clearly on the parameter it received a score of 0 for that specific parameter, if a particular parameter was reported but insufficiently or unclearly the score was 1, and if it was not possible to find this information the score was 2.
Articles that scored between 0 and 3 were classified as being at low risk of bias, those with scores of 4 to 7 as moderate-risk, and scores of 8 to 10 as high-risk.
The risk of bias of the in vitro studies included in the review was assessed independently, in duplicate, by two authors, and any disagreement on the evaluation was resolved by consensus.
To control for publication bias, the fail-safe number was used. This indicates the number of non-significant studies that would be required for the observed significance to disappear.
Data analysis
Given the considerable heterogeneity of the studies as regards research design, methods used, sample sizes, storage, and generation of materials, only studies that met certain criteria were included in the meta-analysis. For flexural strength, the criteria were: moderate or low risk of bias; compliance with ISO 10477:2004 or ADA 27, or specimens measuring 25 x 2 x 2 mm stored in a wet medium for between 24 hours and 14 days, and calibration of a universal testing machine with a crosshead speed of 0.75–1 mm/min; reporting the means and standard deviations for the different groups; and dimethacrylate group materials of a generation currently in use. For fracture toughness the criteria were: moderate or low risk of bias, compliance with ISO 13586:2000, or specimens geometry following the single-edge notched or compact tension methods, stored in a wet medium for between 24 hours and 14 days; reporting the means and standard deviations for the different groups; and dimethacrylate group materials of a generation currently in use. For the property of hardness, the criteria were analysis of Vickers or Knoop hardness in a wet medium, and reporting the mean values and standard deviations.
For the meta-analysis, the difference in means between the two groups in the studies included in this analysis was determined. The random effect model was considered when the heterogeneity was below 1. Heterogeneity was assessed by the Q test, for p < 0.1, as well as by the I2 test. For the combination of studies, a random effects method was used to calculate the differences in means. When three or more studies were included in the meta-analysis, a funnel plot and the fail-safe number were used to analyze publication bias. The meta-analysis was carried out with the random effects model of the Comprehensive Meta Analysis V3 software application.
Meta-analyses were conducted for flexural strength, fracture toughness and Knoop hardness alone, as the articles that studied Vickers hardness provided insufficient data and lacked the necessary information for a meta-analysis. Consequently, Vickers hardness was only included in the systematic review and descriptive analysis.
Results
Search and selection
The PRISMA statement flowchart summarizing the selection process is shown in Fig 1. The search returned 256 studies. Of these, 89 duplicates were excluded. Another 118 studies were excluded because they did not meet the eligibility criteria. The remaining 49 studies were selected for examination of the full text, which resulted in excluding 17 articles which did not meet the inclusion criteria. Subsequently, 8 of the remaining 32 articles were excluded after modified ARRIVE and CONSORT criteria were applied. Of the remaining 24 studies included in the systematic review, 15 studied flexural strength, 3 studied fracture toughness, 2 studied hardness, 1 studied flexural strength and fracture toughness and 2 studied flexural strength and hardness. Only 1 studied all three properties together. (Table 2).
From Moher D, Liberati A, Tetzlaff J, Altman DG, The PRISMA Group (2009). Preferred Reporting Items for Systematic Reviews and Meta-Analyses: The PRISMA Statement. PLoS Med 6(7): e1000097. doi:10.1371/journal.pmed1000097.
*: 5 only studied monomethacrylates, 3 only studied dimethacrylates, 3 studied provisional restoration repair, 2 used thermoplastic polyester, 1 examined provisional cement, 1 assessed reinforcing monomethacrylate materials with fiberglass, and 2 were narrative literature reviews **: Incomplete description of materials, methods or details of the experimental procedure, difficult to replicate the test, not following standardized test procedures, not describing bias reduction strategies, no calculation of sample size, incomplete statistical analysis, no conflict of interests statement, Limited interpretation and comparison of results with the available literature.
For more information, visit www.prisma-statement.org.
Risk of bias
All of the 24 studies included in the systematic review presented moderate risk of bias. No high risk of bias was found in any of the articles included. (Fig 2 and Table 3).
From Aurelio IL, Marchionatti AM, Montagner AF, May LG, Soares FZ. Does air particle abrasion affect the flexural strength and phase transformation of Y-TZP? A systematic review and meta-analysis. [6].
The risks of bias most commonly found in the studies were: blinding of the testing machine operator, description of the sample size calculation, single operator of the machine and random assignment of specimens. The scores for blinding of the testing machine operator and description of the sample size calculation were generally low.
Meta-analyses
Seven studies met the best requirement features for quantitative analysis. Eight meta-analyses, including three global and five subgroup analyses, were performed on the flexural strength, fracture toughness and hardness data.
Flexural strength.
The dimethacrylates group showed significantly higher flexural strength than the monomethacrylates group, by an estimated 39.6 MPa (95% CI 23.4–55.8). The heterogeneity of the 7 studies included in the meta-analysis was high (Q = 377.1, heterogeneity p = 0.000, I2 = 98.4%). (Fig 3A).
Flexural strength. Dimethacrylate vs. monomethacrylate groups (Fig 3A), Flexural strength. Bis-acryl vs. PMMA (Fig 3B), Flexural strength. Bis-acryl vs. PEMA (Fig 3C), Flexural strength. PMMA vs. PEMA (Fig 3D).
The flexural strength of bis-acryl was estimated as significantly higher than that of PMMA, by 18.4 MPa (95% CI 4.3–32.5). The heterogeneity was high (Q = 41.2, heterogeneity p = 0.000, I2 = 92,7%) (Fig 3B).
On comparing bis-acryl with PEMA, the flexural strength of bis-acryl was significantly higher, by an estimated 44.9 MPa (95% CI 30.1–59.9). The heterogeneity was high (Q = 254.1, heterogeneity p = 0.000, I2 = 97.6%) (Fig 3C).
On comparing PMMA and PEMA, PMMA was not significantly different although the difference was estimated at 18.3 MPa (95% CI -0.33–38.1). The heterogeneity was high (Q = 121.1, heterogeneity p = 0.000, I2 = 97.5%) (Fig 3D).
Fracture toughness.
The random models analysis showed no significant difference between the dimethacrylate and monomethacrylate groups. The mean difference was estimated at 0.52 MPa.m1/2 in favor of dimethacrylate (95% CI 0.62–1.65). The heterogeneity of the studies included in the meta-analysis was high (Q = 132.7, heterogeneity p = 0.000, I2 = 99.2%) (Fig 4A).
Dimethacrylate vs. monomethacrylategroups (Fig 4A), Bis-acryl vs. PEMA (Fig 4B).
No significant differences were found on comparing bis-acryl and PEMA. The effect was estimated at 0.67 MPa.m1/2 in favor of bis-acryl (95% CI -0.16–1.50). The heterogeneity was high (Q = 69.6, heterogeneity p = 0.000, I2 = 98,6%) (Fig 4B).
Knoop hardness.
Dimethacrylates proved significantly superior to monomethacrylates, by 2.15 KHN (95% CI 0.24–4.06). The heterogeneity of the studies included in the meta-analysis was high (Q = 29.6, heterogeneity p = 0.000, I2 = 93.3%) (Fig 5A).
Dimethacrylate vs. monomethacrylate groups (Fig 5A), Bis-acryl vs. PMMA (Fig 5B).
Lastly, bis-acryl was not significantly superior to PMMA (1.44 KHN, 95% CI 0.95–1.93). The observed heterogeneity was high (Q = 23.2, heterogeneity p = 0.000, I2 = 95.7%) (Fig 5B).
As regards checking for publication bias impact, the following values were found through the classic fail-safe number: flexural strength comparison between the dimethacrylates group and the monomethacrylates group = 2941, between PMMA and bis-acryl = 125, between bis-acryl and PEMA = 3059, and between PMMA and PEMA = 178; fracture toughness comparison between the dimethacrylates group and the monomethacrylates group = 116, and between PEMA and bis-acryl = 185; Knoop hardness comparison between the dimethacrylates group and the monomethacrylates group = 45, and between PMMA and bis-acryl = 31.
Discussion
A number of in vitro studies have been conducted to assess the mechanical properties of provisional restoration materials used with direct techniques in dentistry. No randomized controlled clinical trials (RCT) or systematic reviews appear to exist to assist in selecting the ideal material for specific clinical situations, leaving the choice of material to criteria such as ease of handling and time taken in the office [7]. The present systematic review and meta-analysis is the first to analyze and combine published data from in vitro studies in order to assess their combined effect and answer the question of whether, in provisional restorations fabricated by direct techniques, the dimethacrylate and monomethacrylate groups differ significantly in their mechanical properties in terms of flexural strength, fracture toughness and hardness.
The overall results of this meta-analysis show that dimethacrylate-based materials exhibit better mechanical responses in terms of flexural strength and hardness than monomethacrylate-based materials. In general, the basic chemical composition of dimethacrylates gives them better mechanical behavior against applied stresses, as they have a rigid, cross-linked structure owing to the presence of highly viscous and voluminous multifunctional monomers (Bis-GMA or TEGDMA) that can cross-link with other polymeric chains. This cross-linking, combined with inorganic loading, makes these materials strong and easy to handle and to polish, resulting in a low exothermic temperature [7–11]. In contrast, monomethacrylates are polymers composed of monofunctional molecules with a linear structure and low molecular weight, the lack cross-linking leading to lower rigidity and mechanical resistance [7,8,12].
The present results match those of some other studies [8,12–15] which suggest that as well as the basic chemical composition of the dimethacrylate group, factors such as individual formulation, supplements added by the manufacturer and the degree of polymerization and of cross-linking of the matrix influence the mechanical performance of the material. For instance, replacement of the rigid monomers of the first-generation materials by the elastic monomers currently being used has improved the ability to withstand high forces, as they exhibit a small elastic deformation before breaking [8,16]. In addition, the present study has found that auto-polymerizing materials in the dimethacrylates group exhibit greater flexural strength and hardness than those which are polymerized by light, owing to the greater presence of filler particles [9,17]. Compared to auto-polymerizing dimethacrylates, dual-cure dimethacrylates present flexural strength advantages for up to 72 hours, owing to the large amount of initial polymerization caused by the reaction to photo-initiation. After that time, the values are similar[7,18,19].
In the monomethacrylates group, the present meta-analysis found that PMMA presented greater flexural strength than PEMA. PMMA was not significantly different although the difference was estimated at 18.3 MPa in favour to PMMA. In this group, it is also important to understand that mechanical behavior is influenced by the individual formulation of each comercial brand. Provisional restoration based on PMMA have many advantages, in terms of strength, aesthetics and colour stability, marginal fit, and they can be easily fabricated, polished and repaired. However, it has been reported to have some serious disadvantages like irritation of vital tissues, which could be due to leaching of the free monomer, high polymerization exotherm during setting, low wear resistance and high volumetric shrinkage, and should be used for the indirect technique of TCB fabrication, or as PMMA shells that are fabricated in the laboratory, which are then lined in the patient’s mouth with PEM/monomer system [10].
PEMA based provisional restoration are suitable for both direct and indirect techniques, due to their minimal polymerization exotherm, low shrinkage and better biocompatibility compared with PMMA. However, due to PEMA resins being mechanically weaker and with less colour stability than PMMA, their use is limited to making posterior interim prostheses, in short-term provisional treatment. Most provisional restoration based on PEMA contain either the monomer isobutyl methacrylate (IBMA) or n-butyl methacrylate (nBMA). The latter was introduced as a new provisional restorative material due to having low water uptake, low polymerization exothermic reaction and low irritation to the vital tissue. [10] The former commercial PEMA based provisional material with IBMA monomer (e.g. Trim, Bosworth) contains a plasticizer (di-butyl phthalate, DBP), to improve handling properties and reduce setting time. The phthalate is not chemically bonded to the plasma network, and phthalates are considered endocrine disruptors chemicals that cause estrogenic behavior and are possible carcinogens [10]. Therefore ingesting a small amount of these elements may cause considerable problems to the living system [16]. Moreover, the plasticizer reduces the glass transition temperature (Tg) of polymers by weakening the links between the polymer chains and increasing their movements, since the plasticizer slowly leached out of the material, and in turn contributed to more water being absorbed by the matrix to fill the spaces left by the leached material. Therefore, these materials have a lower flexural strength.[10].
Flexural strength and fracture toughness of provisional restorations in the monomethacrylates group decrese gradually in time. At the initial stages, the effect of water in monomer hydrolysis is low or nonexistent [13,18,20], allowing the material a certain degree of plastic deformation before breaking, known as ductile behavior. When the storage time is increased, however, this group of materials tends to absorb water, owing to its linear polymer network structure, the high polarity of its molecules and the air bubbles immersed in its structure as a result of manual mixing [7,8]. This water absorption leads to hydrolysis of the monomers, giving rise to a constant decrease in its mechanical properties [9,10,18,21].
In contrast, dimethacrylates have a rigid central structure that allows them to absorb only 0.8% by weight of water, it is due to the increase in the conversion of reactive double bonds by radicals and because the relaxation phenomena take place within the polymer network. In addition, the self-mixing cartridge system makes it possible to control the proportions of the components and avoid air entrapment [8]. However, thermocycling weakens the internal structure of the material, because the increasing water absorption, although this is less than in monomethacrylates, generates a reduction in the intermolecular forces between the chains of polymer. In addition, phenomena of hydrolysis of the silane layer surrounding the filler particles are observed, which promotes the propagation of cracks in the periphery of the filler particles.[22] These materials can withstand high forces before breaking, once the stress is greater than the proportional limit they fracture immediately rather than undergoing deformation. Consequently, they are described as rigid materials but brittle [9,10]. Other in vitro studies have assessed the mechanical effect that solutions which simulate foods have on the provisional restoration [12,22,23]. Heptane and 75% ethanol caused softening of the polymer matrix in both groups and degradation of the filler-matrix interface in the dimethacrylates group, but the dimethacrylates withstood breakdown by the solutions better than the monomethacrylates, owing to their cross-linked bi-functional monomers [12,22]. Only one study found that the solutions tested did not have a statistically significant effect on the flexural strength of the provisional restoration materials [23].
In the conventional direct technique, provisional restorations are in direct contact with saliva and intraoral moisture immediately after fabrication. This means that regardless of the basic chemical composition, the provisional restorations manually fabricated could suffer polymerization inhibition effects due to the oxygen, as the process of radical polymerization is still in progress, which affect long-term mechanical properties and color stability [21]. Nowadays, provisional restoration materials are available in blocks for machining by CAD/CAM systems. These blocks are fabricated under optimum polymerization conditions with no interference from water, giving adequate time for post-polymerization processes and relaxation phenomena, which means that the provisional restorations fabricated from blocks, whether monomethacrylate or dimethacrylate, have superior mechanical properties to those fabricated by conventional direct techniques from the moment the restoration is put in place [20,24,25].
The present meta-analysis also found that there was no significant difference between the dimethacrylates and monomethacrylates as regards their fracture toughness, in other words, their ability to stop cracks propagation. However, the way in which the cracks propagation are interrupt varies between the groups. In the dimethacrylate group, the presence of inorganic filler, the conversion of reactive double bonds during polymerization and relaxation phenomena within the polymer network, this renders the polymer network less sensitive to crack propagation. Although this ability is an advantage compared to the monomethacrylate group in the initial stages, it slowly diminishes owing to breakdown by water, which weakens the intermolecular forces in the polymer chain and hydrolyses the silane layer surrounding the filler particles, encouraging crack propagation at the edge of the filler particles as time passes [13,16,21,26,27]. In the monomethacrylate group, however, occurs a ductile fracture which differs from a brittle fracture in dimethacrylate group. Prior to fracturing, the specimen undergoes considerable plastic deformation, in this group the cracks are diverted by the plasticizing effect of water, which makes the fracture toughness acceptable only in the early stages [26], although it gradually diminishes over time because of water absorption by polymers which are not cross-linked, which weakens the material [21].
The structure of provisional restorations can be reinforced with fiberglass or polyethylene to improve their flexural strength and fracture toughness [27–29]. As regards flexural strength, reinforcement changes the fracture path: instead of catastrophic fractures (abutments and pontics), the fractures become partial and easy to repair (chipping on free surfaces), owing to the transfer of stresses from the weak polymer matrix to the fibers, which have high tensile resistance. As regards fracture toughness, the fibers bridge the crack and oppose its opening, exercising a closing force [29]. The reinforced specimens are as resistant as provisional restorations machined with CAD/CAM [25], and the stronger the reinforcing fiber’s adhesion to the polymer matrix, the greater the reinforcement effect, so silane-impregnated fiberglass provides greater reinforcement then plasma-impregnated polyethylene fibers [28,29]. Reinforcement by the addition of 1% by weight of polyhedral oligomeric silsesquioxane (POSS) to the formulation of the materials was also assessed. The results were not uniform and showed that the particular chemical composition of the provisional materials determines the ability of POSS to improve their mechanical properties [30].
The standards and specifications for in vitro testing of flexural strength employed in the studies included were ISO 4049:2000 [18], ISO 10477:2004 [13,26,27] and ANSI/ADA specification N° 27 [7,8,14,30]. Although their technical specifications are not very different from each other, ISO 10477:2004 considers criteria that are inherent to the process of provisionalization and the fabrication of provisional crowns and bridges; the optional addition to this standard is ANSI/ADA Standard No. 53 (ADA53-2013). There is no standard dental protocol for determining fracture toughness in polymeric materials [21]. The studies included in this review used ISO 13586 [21], ISO D256-97 [13], ASTM no. E 399–83 [26,28], and British Standard 5447[27]. The ISO 13586:2000 standard describes the assessment of fracture toughness in plastics assuming linear elastic fracture mechanics (LEFM), in which the plastic deformation zone remains concentrated around a small area at the point of the crack [21]. Two types of test were used to analyze hardness: Knoop and Vickers. The literature disagrees about which is the ideal test. Some authors [9,12,17,22] suggest that Knoop hardness tests allow elastic recovery of the material along the short axis, so determine the hardness values irrespective of the ductility of the test material. However, another study [13] suggests that Vickers hardness is a universal test, less sensitive to surface conditions, but more sensitive to measurement error.
Limitations
Currently there is no validated, clearly established criterion for assessing the methodological quality and risk of bias of in vitro studies. However, the modified ARRIVE and CONSORT criteria [5] and an adaptation of the Cochrane risk-of-bias tool domains for systematic reviews taken from a previous study were used in the present review [6].
The studies included in the systematic review presented moderate to high methodological quality and moderate risk of bias, but the meta-analysis showed high data heterogeneity (>90%). This confirms their differences in methodology, with a high number of variables such as lack of experimental test standardization and absence of sample size calculation, machine operator blinding and calibration of the universal testing machine, generating a wide range of flexural strength, fracture toughness and hardness values with high standard deviations between the studies included. For this reason, we recommend the standardization of the methodology of in vitro studies following the guidelines of Academy of Dental Materials guidance for mechanical properties[31].
The present review summarizes in vitro data. Although some studies show that the external validity of in vitro tests to predict the clinical performance of dental materials is limited [32,33], a systematic review, found that there is a moderately positive correlation between clinical and laboratory outcomes, besides, fracture toughness being mostly correlated with clinical fracture and flexural strength with clinical wear[34]. Well designed in vitro studies need to be taken into account, owing to their ability to clarify any initial queries before conducting clinical trials [6].
The successful performance of a provisional material is not based exclusively on its mechanical properties but also on its interaction with its immediate environment, so other factors such as marginal adaptation, color stability, and pulp and gum response need to be assessed. For this reason, clinical studies should be conducted to lend greater external validity to the present findings.
Conclusions
The available evidence after conducting this systematic review and meta-analysis indicates that dimethacrylate-based provisional restorations possess better mechanical behavior than monomethacrylate-based ones in terms of flexural strength and hardness, but there are no significant differences in fracture toughness. Among the monomethacrylates, PMMA shows greater flexural strength than PEMA.
In order to improve the quality of future studies, it would be advisable to conduct in vitro experimental testing with large samples, standardized specimen sizes, and blinded, calibrated testing machines in order to reduce the risk of bias.
Supporting information
S2 Table. Methodological characteristics of in-vitro studies based on arrive and consort modificated criteria.
https://doi.org/10.1371/journal.pone.0193162.s002
(DOCX)
Acknowledgments
The authors are grateful to Mary Georgina Hardinge for translating the manuscript into English.
References
- 1. Patras M, Naka O, Doukoudakis S, Pissiotis A. Management of provisional restorations’ deficiencies: A literature review. J Esthet Restor Dent. 2012;24: 26–38. pmid:22296692
- 2. Kadiyala KK, Badisa MK, Anne G, Anche SC, Chiramana S, Muvva SB, et al. Evaluation of Flexural Strength of Thermocycled Interim Resin Materials Used in Prosthetic Rehabilitation- An In-vitro Study. J Clin Diagn Res. 2016;10: ZC91–ZC95. pmid:27790588
- 3. Burns DR, Beck DA, Nelson SK, Committee on Research in Fixed Prosthodontics of the Academy of Fixed Prosthodontics. A review of selected dental literature on contemporary provisional fixed prosthodontic treatment: report of the Committee on Research in Fixed Prosthodontics of the Academy of Fixed Prosthodontics. J Prosthet Dent. 2003;90: 474–97. pmid:14586312
- 4. Urrútia G, Bonfill X. [PRISMA declaration: a proposal to improve the publication of systematic reviews and meta-analyses]. Med Clin (Barc). 2010;135: 507–11. pmid:20206945
- 5. Ramamoorthi M, Bakkar M, Jordan J, Tran SD. Osteogenic Potential of Dental Mesenchymal Stem Cells in Preclinical Studies: A Systematic Review Using Modified ARRIVE and CONSORT Guidelines [Internet]. Stem Cells International. 2015. p. 378368. pmid:26106427
- 6. Aurélio IL, Marchionatti AME, Montagner AF, May LG, Soares FZM. Does air particle abrasion affect the flexural strength and phase transformation of Y-TZP? A systematic review and meta-analysis. Dent Mater. 2016;32: 827–45. pmid:27083253
- 7. Nejatidanesh F, Momeni G, Savabi O. Flexural Strength of Interim Resin Materials for Fixed Prosthodontics. J Prosthodont. 2009;18: 507–511. pmid:19689710
- 8. Haselton DR, Diaz-Arnold AM, Vargas MA. Flexural strength of provisional crown and fixed partial denture resins. J Prosthet Dent. 2002;87: 225–8. Available: http://www.ncbi.nlm.nih.gov/pubmed/11854681 pmid:11854681
- 9. Jo LJ, Shenoy KK, Shetty S. Flexural strength and hardness of resins for interim fixed partial dentures. Indian J Dent Res. 2011;22: 71–6. pmid:21525681
- 10. Abdulmohsen B, Parker S, Braden M, Patel MP. A study to investigate and compare the physicomechanical properties of experimental and commercial temporary crown and bridge materials. Dent Mater. 2016;32: 200–10. pmid:26748979
- 11. Kim S-H, Watts DC. In vitro study of edge-strength of provisional polymer-based crown and fixed partial denture materials. Dent Mater. 2007;23: 1570–3. pmid:17706276
- 12. Yap A, Mah MKS, Lye CPW, Loh PL. Influence of dietary simulating solvents on the hardness of provisional restorative materials. Dent Mater. 2004;20: 370–376. pmid:15019452
- 13. Thompson GA, Luo Q. Contribution of postpolymerization conditioning and storage environments to the mechanical properties of three interim restorative materials. J Prosthet Dent. 2014;112: 638–48. pmid:24831742
- 14. Poonacha V, Poonacha S, Salagundi B, Rupesh PL, Raghavan R. In vitro comparison of flexural strength and elastic modulus of three provisional crown materials used in fixed prosthodontics. J Clin Exp Dent. 2013;5: e212–7. pmid:24455084
- 15. Zortuk M, Ozdemir E, Aguloglu S. Evaluating the fracture strength of three different provisional crowns. J Int Dent Med Res. 2010;3.
- 16. Lang R, Rosentritt M, Behr M, Handel G. Fracture resistance of PMMA and resin matrix composite-based interim FPD materials. Int J Prosthodont. 16: 381–4. Available: http://www.ncbi.nlm.nih.gov/pubmed/12956492 pmid:12956492
- 17. Diaz-Arnold AM, Dunne JT, Jones AH. Microhardness of provisional fixed prosthodontic materials. J Prosthet Dent. 1999;82: 525–8. Available: http://www.ncbi.nlm.nih.gov/pubmed/10559723 pmid:10559723
- 18. Balkenhol M, Mautner MC, Ferger P, Wöstmann B. Mechanical properties of provisional crown and bridge materials: chemical-curing versus dual-curing systems. J Dent. 2008;36: 15–20. pmid:18031919
- 19. Ireland MF, Dixon DL, Breeding LC, Ramp MH. In vitro mechanical property comparison of four resins used for fabrication of provisional fixed restorations. J Prosthet Dent. 1998;80: 158–62. Available: http://www.ncbi.nlm.nih.gov/pubmed/9710816 pmid:9710816
- 20. Alt V, Hannig M, Wöstmann B, Balkenhol M. Fracture strength of temporary fixed partial dentures: CAD/CAM versus directly fabricated restorations. Dent Mater. 2011;27: 339–47. pmid:21176946
- 21. Balkenhol M, Köhler H, Orbach K, Wöstmann B. Fracture toughness of cross-linked and non-cross-linked temporary crown and fixed partial denture materials. Dent Mater. 2009;25: 917–28. pmid:19249090
- 22. Akova T, Ozkomur A, Uysal H. Effect of food-simulating liquids on the mechanical properties of provisional restorative materials. Dent Mater. 2006;22: 1130–4. pmid:16386787
- 23. Yanikoğlu ND, Bayindir F, Kürklü D, Beşir B. Flexural Strength of Temporary Restorative Materials Stored in Different Solutions. Open J Stomatol. 2014;4: 291–298.
- 24. Rayyan MM, Aboushelib M, Sayed NM, Ibrahim A, Jimbo R. Comparison of interim restorations fabricated by CAD/CAM with those fabricated manually. J Prosthet Dent. 2015;114: 414–9. pmid:26001490
- 25. Peñate L, Basilio J, Roig M, Mercadé M. Comparative study of interim materials for direct fixed dental prostheses and their fabrication with CAD/CAM technique. J Prosthet Dent. 2015;114: 248–53. pmid:25935084
- 26. Gegauff AG, Wilkerson JJ. Fracture toughness testing of visible light- and chemical-initiated provisional restoration resins. Int J Prosthodont. 8: 62–8. Available: http://www.ncbi.nlm.nih.gov/pubmed/7710627 pmid:7710627
- 27. Kim S-H, Watts DC. Effect of glass-fiber reinforcement and water storage on fracture toughness (KIC) of polymer-based provisional crown and FPD materials. Int J Prosthodont. 17: 318–22. Available: http://www.ncbi.nlm.nih.gov/pubmed/15237879 pmid:15237879
- 28. Hamza TA, Rosenstiel SF, Elhosary MM, Ibraheem RM. The effect of fiber reinforcement on the fracture toughness and flexural strength of provisional restorative resins. J Prosthet Dent. 2004;91: 258–64. pmid:15060496
- 29. Samadzadeh A, Kugel G, Hurley E, Aboushala A. Fracture strengths of provisional restorations reinforced with plasma-treated woven polyethylene fiber. J Prosthet Dent. 1997;78: 447–50. Available: http://www.ncbi.nlm.nih.gov/pubmed/9399185 pmid:9399185
- 30. Hamza TA, Johnston WM, Schricker SR. Effect of polyhedral silsesquioxane (POSS) on the flexural strength and color of interim materials. J Prosthet Dent. 2014;112: 228–34. pmid:24680356
- 31. Ilie N, Hilton TJ, Heintze SD, Hickel R, Watts DC, Silikas N, et al. Academy of Dental Materials guidance—Resin composites: Part I—Mechanical properties. Dent Mater. The Academy of Dental Materials; 2017;33: 880–894. pmid:28577893
- 32. Rekow ED, Silva NRFA, Coelho PG, Zhang Y, Guess P, Thompson VP. Performance of dental ceramics: challenges for improvements. J Dent Res. 2011;90: 937–52. pmid:21224408
- 33. Kelly L, St Pierre-Hansen N. So many databases, such little clarity: Searching the literature for the topic aboriginal. Can Fam Physician. 2008;54: 1572–3. Available: http://www.ncbi.nlm.nih.gov/pubmed/19005131 pmid:19005131
- 34. Heintze SD, Ilie N, Hickel R, Reis A, Loguercio A, Rousson V. Laboratory mechanical parameters of composite resins and their relation to fractures and wear in clinical trials-A systematic review. Dent Mater. 2017;33: e101–e114. pmid:27993372