Mechanical responses of the periodontal ligament based on an exponential hyperelastic model: a combined experimental and finite element method

Huang, Hainan; Tang, Wencheng; Yan, Bin; Wu, Bin; Cao, Dan

doi:10.1080/10255842.2015.1006207

Cited by 35 publications

(12 citation statements)

References 40 publications

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“…The upper strain of 2.4% was baseless, and whether the strain of 2.4% may be related to root resorption would require further studies, although it was related to the tooth movement rate. In addition, the PDL was assumed to be an inaccurate linear elastic material in their simulation, which also affected the accuracy of their results (Huang et al, 2016; Anneke et al, 2017). On the other hand, Liao et al (2016) just considered the PDL stress but ignored the strain, and as a result, the optimal forces of the canine distal translation and tipping were 35-100 and 14-50 g, respectively, as defined by local hydrostatic pressure, and 76-266 and 37-135 g as defined by volumeaveraged hydrostatic stress.…”

Section: Discussionmentioning

confidence: 99%

A biomechanical case study on the optimal orthodontic force on the maxillary canine tooth based on finite element analysis

Liu

Peng

et al. 2018

J. Zhejiang Univ. Sci. B

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Excessive forces may cause root resorption and insufficient forces would introduce no effect in orthodontics. The objective of this study was to investigate the optimal orthodontic forces on a maxillary canine, using hydrostatic stress and logarithmic strain of the periodontal ligament (PDL) as indicators. Finite element models of a maxillary canine and surrounding tissues were developed. Distal translation/tipping forces, labial translation/tipping forces, and extrusion forces ranging from 0 to 300 g (100 g=0.98 N) were applied to the canine, as well as the force moment around the canine long axis ranging from 0 to 300 g·mm. The stress/strain of the PDL was quantified by nonlinear finite element analysis, and an absolute stress range between 0.47 kPa (capillary pressure) and 12.8 kPa (80% of human systolic blood pressure) was considered to be optimal, whereas an absolute strain exceeding 0.24% (80% of peak strain during canine maximal moving velocity) was considered optimal strain. The stress/strain distributions within the PDL were acquired for various canine movements, and the optimal orthodontic forces were calculated. As a result the optimal tipping forces (40-44 g for distal-direction and 28-32 g for labial-direction) were smaller than the translation forces (130-137 g for distal-direction and 110-124 g for labial-direction). In addition, the optimal forces for labial-direction motion (110-124 g for translation and 28-32 g for tipping) were smaller than those for distal-direction motion (130-137 g for translation and 40-44 g for tipping). Compared with previous results, the force interval was smaller than before and was therefore more conducive to the guidance of clinical treatment. The finite element analysis results provide new insights into orthodontic biomechanics and could help to optimize orthodontic treatment plans.

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Section: Discussionmentioning

confidence: 99%

A biomechanical case study on the optimal orthodontic force on the maxillary canine tooth based on finite element analysis

Liu

Peng

et al. 2018

J. Zhejiang Univ. Sci. B

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“…where l i are the deviatoric principal stretches obtained from the principal stretches, J 1I is the elastic volume strain, and m i , a i and D i are the parameters used in such a hyperelastic model [35]. The hyperelastic constitutive model was also proposed to fit PDL's viscoelastic behaviour [34], and has been adopted widely in dental biomechanics [11,36]. Its accuracy had also been validated [34] by correlating with the previous in vitro studies on PDLs of human cadavers [37] as well as other mathematical models [37,38].…”

Section: Finite-element Modelling and Simulationmentioning

confidence: 99%

In vivo effects of different orthodontic loading on root resorption and correlation with mechanobiological stimulus in periodontal ligament

Zhong

Chen

Weinkamer

et al. 2019

J. R. Soc. Interface.

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Orthodontic root resorption is a common side effect of orthodontic therapy. It has been shown that high hydrostatic pressure in the periodontal ligament (PDL) generated by orthodontic forces will trigger recruitment of odontoclasts, leaving resorption craters on root surfaces. The patterns of resorption craters are the traces of odontoclast activity. This study aimed to investigate resorptive patterns by: (i) quantifying spatial root resorption under two different levels of in vivo orthodontic loadings using microCT imaging techniques and (ii) correlating the spatial distribution pattern of resorption craters with the induced mechanobiological stimulus field in PDL through nonlinear finite-element analysis (FEA) in silico. Results indicated that the heavy force led to a larger total resorption volume than the light force, mainly by presenting greater individual crater volumes ( p , 0.001) than increasing crater numbers, suggesting that increased mechano-stimulus predominantly boosted cellular resorption activity rather than recruiting more odontoclasts. Furthermore, buccal-cervical and lingual-apical regions in both groups were found to have significantly larger resorption volumes than other regions ( p , 0.005). These clinical observations are complemented by the FEA results, suggesting that root resorption was more likely to occur when the volume average compressive hydrostatic pressure exceeded the capillary blood pressure (4.7 kPa).

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“…However, for simplicity, and utility on finite element analysis, many authors have capitulated to the assumption and focused on finding the most suitable elastic modulus values of periodontal ligament as a homogenous, isotropic, and linear elastic material 3 , 6 , 16 , 24 , 25 . However, recent authors have regarded the periodontal ligament as a non-linear, hyperelastic material, and have found variable elastic modulus values for periodontal ligament 13 . The influence of periodontal ligament as a non-linear hyperelastic material should be considered in further studies.…”

Section: Discussionmentioning

confidence: 99%

3-D finite element analysis of the effects of post location and loading location on stress distribution in root canals of the mandibular 1st molar

Yoon

Lee

et al. 2018

J. Appl. Oral Sci.

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Objective The purpose of this study was to evaluate, by using finite element analysis, the influence of post location and occlusal loading location on the stress distribution pattern inside the root canals of the mandibular 1st molar.Material and Methods Three different 3-D models of the mandibular 1st molar were established: no post (NP) – a model of endodontic and prosthodontic treatments; mesiobuccal post (MP) – a model of endodontic and prosthodontic treatments with a post in the mesiobuccal canal; and distal post (DP) – a model of endodontic and prosthodontic treatments with a post in the distal canal. A vertical force of 300 N, perpendicular to the occlusal plane, was applied to one of five 1 mm2 areas on the occlusal surface; mesial marginal ridge, distal marginal ridge, mesiobuccal cusp, distobuccal cusp, and central fossa. Finite element analysis was used to calculate the equivalent von Mises stresses on each root canal.Results The DP model showed similar maximum stress values to the NP model, while the MP model showed markedly greater maximum stress values. The post procedure increased stress concentration inside the canals, although this was significantly affected by the site of the force.Conclusions In the mandibular 1st molar, the distal canal is the better place to insert the post than the mesiobuccal canal. However, if insertion into the mesiobuccal canal is unavoidable, there should be consideration on the occlusal contact, making central fossa and distal marginal ridge the main functioning areas.

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Mechanical responses of the periodontal ligament based on an exponential hyperelastic model: a combined experimental and finite element method

Cited by 35 publications

References 40 publications

A biomechanical case study on the optimal orthodontic force on the maxillary canine tooth based on finite element analysis

A biomechanical case study on the optimal orthodontic force on the maxillary canine tooth based on finite element analysis

In vivo effects of different orthodontic loading on root resorption and correlation with mechanobiological stimulus in periodontal ligament

3-D finite element analysis of the effects of post location and loading location on stress distribution in root canals of the mandibular 1st molar

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