Experimentally Determined Mechanical Properties of, and Models for, the Periodontal Ligament: Critical Review of Current Literature
- 1Department of Mechanical Engineering, Faculty of Engineering, University of Alberta, AB, Canada, T6G 2G8
- 2Room 5-8T Mechanical Engineering, Faculty of Engineering, University of Alberta, Edmonton, B, Canada, T6G 2G8
- 3Room 4-8H Mechanical Engineering, Faculty of Engineering, University of Alberta, Edmonton, B, Canada, T6G 2G8
- 4Department of Dentistry, Faculty of Medicine and Dentistry, University of Alberta, Edmonton, B, Canada, T6G 2N8
- Paul W. Major, major{at}ualberta.ca
Abstract
Introduction. This review is intended to highlight and discuss discrepancies in the literature of the periodontal ligament’s (PDL) mechanical properties and the various experimental approaches used to measure them. Methods. Searches were performed on biomechanical and orthodontic publications (in databases: Compendex, EMBASE, MEDLINE, PubMed, ScienceDirect, and Scopus). Results. The review revealed that significant variations exist, some on the order of six orders of magnitude, in the PDL’s elastic constants and mechanical properties. Possible explanations may be attributable to different experimental approaches and assumptions. Conclusions. The discrepancies highlight the need for further research into PDL properties under various clinical and experimental loading conditions. Better understanding of the PDL’s biomechanical behavior under physiologic and traumatic loading conditions might enhance the understanding of the PDL’s biologic reaction in health and disease. Providing a greater insight into the response of the PDL would be instrumental to orthodontists and engineers for designing more predictable, and therefore more efficacious, orthodontic appliances.
1. Introduction
Clinical orthodontic treatment is a lengthy, iterative, and possibly inefficient process [1]. Force systems in most orthodontic treatments are considered indeterminate and the magnitude of forces and moments are, in practice, largely unknown [2]. Furthermore, biologic response to orthodontic forces is not well understood. The physiological mechanism primarily responsible for tooth movement in response to a force is the periodontal ligament (PDL) [3]. Short-term tooth movement is regarded as primarily governed by PDL deformation because teeth are virtually rigid and are connected to an almost as rigid mandible by the PDL [4].
From a biomaterials perspective, the PDL is a complex, fiber-reinforced substance that responds to force in a viscoelastic and nonlinear manner [5]. The PDL consists of 53–74% collagen fibers and 1–2% blood vessels and nerve endings that are embedded into an amorphous muccopolysaccharide matrix [6, 7]. Fibrous collagen elements resist tensile forces and the highly hydrated viscous ground substance into which fibrous proteins are embedded forms the extracellular matrix. The ground substance is responsible for the PDL’s viscoelastic properties when subject to loading [8]. Also, the PDL’s cellular response to mechanical loading results in a metabolic response (remodeling of the ground substance and fibrous tissue) [7].
Orthodontic tooth movement is thought to require a minimum of four to eight hours [3] duration of force application and has been shown to be optimal when approximately continuous forces are applied [9–11]. The PDL’s response is characterized by instantaneous displacement, followed by a more gradual (creep) displacement that reaches a maximum after five hours [12], suggesting that fluid bound within the PDL may play an important role in the transmission, and damping of forces acting on teeth. PDL steady-state elastic response is usually attained about five hours after the teeth are loaded—when the flow of the PDL’s interstitial fluid through the surrounding alveolar bone causes the pressure within the PDL to decrease and the solid phase to carry the load alone [12]. Similar results were described in earlier experimental studies in which teeth were loaded laterally [13, 14], and teeth subjected to an intrusive [15–17], and/or an extrusive [18] load. Further, the tissue responds rigidly to rapid deformations (mastication) [19] while deforming elastoplastically when subjected to low-grade continuous forces (orthodontic movements) [20].
Biomechanical analyses of not only PDL stress-strain responses, but also viscoelastic responses such as hysteresis, creep, and stress-relaxation, help elucidate the tooth support function of the tissue [21]. Viscoelastic responses are principal causes of energy dissipation [22]. Without strain energy dissipation, excessive energy may cause tissue breakage [23–27]. Therefore, it seems highly probable that viscoelasticity is important for the tooth support function of the PDL, but little is known about the relation between the viscoelastic response and structure of the PDL [28].
Thus, the PDL’s mechanical properties are essential parameters for understanding the mechanical behavior of a tooth root and surrounding tissues [4]. These properties are important to orthodontic biomechanics, since its main focus is to understand how forces, which are applied to the tooth crown by means of elastic deformation of metal wires, are transferred to a tooth root and surrounding tissues.
Although much is known about the mechanical properties of teeth and alveolar bone, there is no similar definitive knowledge about the PDL [4]. Unfortunately, quantitative experimental data describing the complete behavior of the PDL are unavailable [29]. Determining stress levels in different areas of the PDL, which are the most important and least understood stress-strain levels in orthodontic biomechanics, may offer the best means of correlating the application of force on a tooth with the tooth’s response [3, 30].
The objective of this paper is to highlight and discuss the discrepancies that exist in published literature regarding experimentally determined mechanical properties of the PDL.
2. Materials and Methods
Articles were identified by searches of the following databases: Compendex, EMBASE, MEDLINE, PubMed, ScienceDirect, and Scopus, starting from the early 1900s through August 2010 in the English language (citations of publications in other languages were included, but these were sourced from English publications). We used the following search terms: “biomechanics,” “elasticity,” “finite element analysis,” “finite element method,” “mechanical properties,” “nonlinear elasticity,” “orthodontic tooth movement,” “periodontal ligament (PDL),” and “viscoelastic.”
3. Results
3.1. Mechanical Properties of the PDL
To date, there has been considerable research on the PDL given its crucial role in tooth movement and bone remodelling [31, 32]; much of which has been on determining PDL mechanical properties. Histological periodontal tissue changes during experimental tooth movement have been fervently investigated [33–35]. The PDL’s biological reaction is determined by stress-strain levels induced by mechanical forces applied to the tooth [36–40]. Young’s (elastic) modulus of the PDL appears to be the most important determinant for instantaneous tooth displacement [41]. However, lack of PDL’s mechanical properties consistency throughout the literature is a function of several, often interrelated, parameters. Difficulty lies in directly obtaining PDL data because tooth movement greatly depends on tooth size/shape [4] and, likely as with similar tissues, on strain rate [42].
3.2. Experimental Research and Results
Differences in PDL material properties and experimental approaches obviate the need for a consistent, standard protocol for testing and modeling the PDL. Elastic modulus was found to range from 0.01 to 1750 MPa, and Poisson’s ratio ranged from 0.28 to 0.49. Table 1 summarizes reported PDL material properties (does not include some studies that reference previously reported values)—highlighting the variability existing throughout the literature.
Experimental approaches for determining PDL material properties are summarized in Table 2. Diversity in experimental approaches is a cause of the wide dispersion of results when investigating PDL behavior, obviating the need for a standardized testing protocol. However, extracting small samples with a regular geometry from a complex biological structure is an arduous task.
The results show that regardless of the approach/methodology utilized (i.e., 2D-FEM, experimental, 3D-FEM, etc.), there is no conclusive correlation or relationship between the reported material parameters of the PDL and the experimental method that was used to obtain them. In fact, there exists such variability in these parameters that it may be a possibility that each individual PDL (i.e., from every single tooth) has its own distinct biomechanical behaviour—much like the uniqueness of a fingerprint. This could potentially be an area, not considered before, that calls for further work and investigation. It may be that a single, all-encompassing, PDL behavioural model is not the appropriate approach in understanding and predicting orthodontic tooth movement.
The results, similar to those found in Table 1, show that regardless of the methodology (i.e., in vivo or in vitro) numerous varying individual factors may impact the PDL’s biomechanical response. Thus, a similar conclusion presents itself—a single, all-encompassing, PDL behavioural model may not be the appropriate approach in understanding and predicting orthodontic tooth movement. In addition, for researchers performing further investigation into the PDL’s material properties, the results raise an awareness of what may influence their results.
4. Discussion
The discrepancy and inconsistency of elastic constants for the PDL was evident from the literature. These variations were due to a myriad of factors including experimental protocol inconsistencies. Experimental studies on tooth movement are difficult to interpret because the description of orthodontic forces is not uniform and is incomplete [72]. Pini et al. [73] indicated that the stress-strain curves from their experiments showed that the PDL is characterized by time-dependent, nonlinear mechanical behavior with the typical features of collagenous soft tissues.
When applying an orthodontic force to a tooth, the generally accepted concept is that bone resorption occurs on the PDL’s compressed side, and bone apposition occurs on the tensed side. A widening of the PDL space follows and then a tooth migration towards the compressed side [74]. The external stresses and strains the PDL is subjected to are integral stimuli for alveolar bone remodeling. However, Cattaneo et al. [68] showed that loading of the periodontium cannot be explained in simple terms of compression and tension along loading direction. It was observed that tension in the alveolar bone was far more predominant than compression. Furthermore, Meikle [75] indicated that firmly embedded in the orthodontic subconscious was the idea that pressure and tension sites were generated within the PDL, but he believed there were two major conceptual problems with this hypothesis; based on experimental evidence [76], it was unlikely that PDL principal fibers underwent significant tensile strain, or transferred forces directly to the alveolar bone. Conversely, he supported the idea that tooth movement experiments [77] seemed to corroborate the hypothesis that differential pressures can be generated within the periodontium.
Pietrzak et al. [6] indicated that reliable values of the PDL’s material properties were lacking, specifically noting the significant variance in Young’s modulus. They also pointed out the dearth of experimental evidence to justify the common assumption of PDL incompressibility, since it is extremely complicated and difficult to conduct accurate and reproducible experiments on thin, soft, and delicate PDL tissue.
Tanaka et al. [92] pointed out that some previous experiments [28, 90] examined the PDL’s viscoelastic behavior with quasistatic experimental setups. However, the quasistatic model is only an abstraction as it was found to work reasonably well for soft tissues, but even so, only for certain ranges of stresses, (rates of) strains, and frequencies of oscillations in which the formula (model) does not represent a specific tissue accurately [42]. A quasistatic viscoelastic response corresponds to stress relaxation and creep testing in terms of PDL experimentation. Damping is not modeled effectively and can be problematic when investigating the strain rate effect.
4.1. Factors Affecting Behavior
Considerable variation in PDL tissue response to tooth movement has been reported [99], and it results from differences in biomechanical signals and also to specific host differences, such as diurnal rhythms [100], occlusion [101], systemic metabolism [102], age [74, 103, 104], or normal variation in bony trabeculation. Since the PDL is viscoelastic [27, 73, 85, 105–108], its properties can vary with the mode of loading [109] and species type [96].
Iwasaki et al. [110] stated that the speed of orthodontic tooth movement was a function of environment, genotype, and genotype environment. Specific examples include:
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environment—orthodontic treatment, plaque, smoking status, drug use, disease, and diet;
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genotype—simple (single) or complex (multiple) gene interaction(s);
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genotype-environment—ageing, behavior, lifestyle, education, and socioeconomic status.
Various authors [16, 85, 86, 111–113] have demonstrated the nonlinearity and time dependence of the relationship between load and tooth displacement through in vivo experiments. Other studies [28, 66, 90] described the PDL as nonlinear and segmentspecific (viscoelastic properties could be assumed to differ locally and be dependent on the magnitude and frequency of the loads applied).
Genna et al. [93] pointed out that there was an effect associated with freezing collagen that must be accounted for in PDL models. Recently, Bergomi et al. [20] concluded that (i) the PDL showed pseudo-plastic viscous features for cyclic compressive loading, and (ii) these viscous features essentially resulted from interactions between the porous matrix and the unbound fluid content of the tissue.
4.2. Summary of Factors
A summary of the factors that may affect the mechanical properties of the PDL is shown in Table 3. However, a clear separation in the importance and a definitive measure of the degree of influence of these factors was absent from the literature.
Most experimental research focused on determining single-factor effects on the PDL (i.e., differences in tooth movement based on the size/shape of the tooth) and, thus, no inference or distinction can be stated with a reasonable degree of confidence on the combined effect of several factors.
The degree of importance or level of error of the factors could not be ascertained from the literature. Therefore, possible future research could be to examine the effect that various parameters/factors have on the PDL’s biomechanical properties and then quantitatively determine the degree of influence of each factor on the PDL’s response.
Considering the gamut of data and the sporadic nature of experimental results, taken together with the uniqueness of the PDL’s biomechanical properties, it can be concluded that the research focus should be placed on human PDL biomechanics and the impact of individual factors to the material properties. Future research should gravitate towards delineating the relative contributions of each individual factor in order to increase model accuracy and to tailor clinical treatment to be as patient specific as possible. In terms of modeling, it is believed that the most appropriate approach is to use a combined 3D FEM and experimental methodology in order to ensure a reasonably accurate fit. As a first step, the research should, however, focus on the development of a preliminary model that allows for a better phenomenological description of PDL behaviour under static, near clinical, orthodontic loading conditions.
5. Conclusion
The gamut of experimental approaches and simplistic/inaccurate assumptions highlight the need for continued research in ascertaining PDL properties under various and well-defined loading conditions, both clinical and experimental. These inconsistent properties underlying the PDL knowledge base are due, in part, to difficulties in examining this thin tissue and variations in experimentation approaches. It was shown that there were significant variations, some on the order of six orders of magnitude, of the elastic constants and mechanical properties of the PDL.
A better understanding of the PDL’s biomechanical behavior under physiologic and traumatic loading conditions might enhance the understanding of its biologic reaction in health and disease [114]. By providing a greater insight into human dental tissue response, we can help orthodontists improve people’s health, appearance, and self-confidence.
- © 2011 Ted S. Fill et al.