Biomechanical effect of mandibular advancement device with different protrusion positions for treatment of obstructive sleep apnoea on tooth and facial bone: A finite element study

Lee, Ji-Soo; Choi, Ho‐Young; Lee, Hyeonjong; Ahn, Su−Jin; Noh, Gunwoo

doi:10.1111/joor.12709

Cited by 28 publications

(20 citation statements)

References 37 publications

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“…Finite element (FE) analysis has been widely used to simulate different behaviors in dentofacial orthopedics and dental biomechanics (Ammar, Ngan, Crout, Mucino, & Mukdadi, ; Borcic et al, ; Cattaneo, Dalstra, & Melsen, ; Chang, Shin, & Baek, ; Field et al, ; Geramy & Morgano, ; Hsu, Chen, Chen, Huang, & Chang, ; Kibi et al, ; Lee, Choi, Lee, Ahn, & Noh, ; Liang, Rong, Lin, & Xud, ; Liu, Chang, Wong, & Liu, ; Rudolph, Willes, & Sameshima, ; Singh, Mogra, Shetty, Shetty, & Philip, ; Soares et al, ; Toms & Eberhardt, ; Vukicevic, Zelic, Jovicic, Djuric, & Filipovic, ; Yu, Baik, Sung, Kim, & Cho, ; Zhang, Cui, Lu, & Wang, ), because of many problematic issues in clinical testing, such as subject discomfort and limit of accessible areas. In the study conducted by Lee et al (), FE analysis was performed to investigate the mechanical effect of different protrusion positions of a mandibular advancement device (MAD) on teeth and facial bones, since the MAD‐induced stress and strain have not been measured directly from living structures. Ammar et al () used the FE jawbone model to simulate canine retraction with mini‐screw anchorage and compared stresses on the mini‐screw and fracture failure of tangential orthodontic forces.…”

Section: Introductionmentioning

confidence: 99%

An investigation into structural behaviors of skulls chewing food in different occlusal relationships using FEM

Lee

Chun

2019

Clinical & Exp Dental Res

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Objectives This study aims to investigate the effect of different occlusal relationships on skull structural and mechanical behaviors through simulation of chewing food. Methods Finite element (FE) skull models of occlusion for Class I, end‐on Class II, and full‐cusp Class II were generated. End‐on Class II and full‐cusp Class II were chosen as mild and severe Class II occlusions, respectively. A simplified food bolus was introduced between the upper and lower dentition of the right molars. Chewing food was simulated in the skulls by moving the mandible. An experiment was conducted to measure strains at selective locations and compared them to the analytical results for validation. Results In the early stages of mandibular movement, masticatory forces predicted from the skull models without food were lower than the skull models with food but increased drastically after occluding teeth full enough. As a result, the relationship between masticatory force and mandible movement shows that there is no significant difference between the skull models with food and without food in the range of human masticatory force, approximately 250 N. In all the cases of skulls including a food bolus, stress was similarly propagated from the mandible to the maxilla and concentrated in the same regions, including the mandibular notch and alveolar bone around the lower molars. Conclusion It is predicted that there is no significant difference of bite force–mandible movement relationships and stress distributions of skull and teeth, between end‐on Class II and full‐cusp Class II models. When simulating chewing activities on candy and carrot, it is also found that there is no difference of masticatory performance between Class II occlusions, from structural as well as mechanical perspectives.

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Section: Introductionmentioning

confidence: 99%

An investigation into structural behaviors of skulls chewing food in different occlusal relationships using FEM

Lee

Chun

2019

Clinical & Exp Dental Res

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“…In addition, the mandible moves antero-posteriorly when a MAD is applied, so the restorative force is directly transmitted to the anterior teeth. However, recent FEM studies [ 23 , 34 ] showed that load concentration induced by MADs was greater on the posterior teeth than on the anteriors; therefore, it is necessary to evaluate force distribution on the overall dentition as well as on the anterior teeth.…”

Section: Discussionmentioning

confidence: 99%

“…Our results also highlighted that attention should be paid to the transverse dimension of the posterior teeth during the long-term use of MADs, as well as the anteroposterior movements of the incisors. Previously, Lee et al [ 23 ] showed the highest force value in the mandibular second molar; therefore, it is likely to be inclined lingually. In contrast, in our study, the mandibular second molar indicated had the lowest force value.…”

Section: Discussionmentioning

confidence: 99%

“…The posterior restorative force produced from the relaxation of the mandibular muscles was represented by the restoring force of the spring. The posterior restorative force on the mandible is primarily caused by stretching of the two masticatory muscles, the deep masseter and posterior temporal muscle [ 23 ]. The spring tension stiffness values of these two muscles were 16.35 N/mm and 13 N/mm, respectively [ 24 ], and the force values generated by the MADs were approximately 100 gF for each millimeter of advancement [ 25 ].…”

Section: Methodsmentioning

confidence: 99%

“…An analysis of the force system applied to the dentition should precede the anticipation of the direction and extent of tooth movement after the use of MADs. Recently, Lee et al [ 23 ] analyzed the biomechanical effect of different protrusion positions of a MAD on the teeth and facial bones using finite element analysis (FEM). According to their results, both the incisors and mandibular molars, especially the buccal surface of second molars, were subjected to high stress, which caused lingual inclination of the molars.…”

Section: Introductionmentioning

confidence: 99%

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Force Distribution of a Novel Core-Reinforced Multilayered Mandibular Advancement Device

Ahn

Lee

et al. 2021

Sensors

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A mandibular advancement device (MAD) is a commonly used treatment modality for patients with mild-to-moderate obstructive sleep apnea. Although MADs have excellent therapeutic efficacy, dental side effects were observed with long-term use of MADs. The aim of this study was to analyze the force distribution on the entire dentition according to the materials and design of the MADs. Three types of MADs were applied: model 1 (single layer of polyethylene terephthalate glycol (PETG)), model 2 (double layer of PETG + thermoplastic polyurethane (TPU)), and model 3 (core-reinforced multilayer). In the maxilla, regardless of the model, the incisors showed the lowest force distribution. In most tooth positions, the force distribution was lower in models 2 and 3 than in model 1. In the mandible, the mandibular second molar showed a significantly lower force in all models. The mandibular incisors, canines, and molars showed the highest force values in model 1 and the lowest values in model 3. Depending on the material and design of the device, the biomechanical effect on the dentition varies, and the core-reinforced multilayered MAD can reduce the force delivered to the dentition more effectively than the conventional single- or double-layer devices.

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The biomechanical effects of bimaxillary osteotomies to the patients with mandibular retraction under incisal clenching

Luo,

Teng,

Chong

et al. 2024

Numer Methods Biomed Eng

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The purpose of this study is to investigate the biomechanical effect of bimaxillary osteotomies on patients with mandibular retraction. Mandibular retraction, as a typical maxillofacial deformity, and has great adverse effects on TMJ. Bimaxillary osteotomies are widely used to correct symptoms of mandibular retraction. It is necessary to understand the effect of surgery on temporomandibular disc (TMJ). Five patients with mandibular retraction and 10 asymptomatic subjects were involved in this study. Finite element models of preoperative, postoperative and control group were constructed based on the CT data. Nine sets of concentrated forces were used to simulate the muscle effect and contact method was used to simulate the interaction within the TMJs and dentitions. The results showed that bimaxillary osteotomies could effectively improve the maxillofacial morphology and alleviate the overload in TMJ. The facial asymmetry and right chewing side preference could cause imbalanced stress distributions in the TMJs and interfere the surgical treatment.

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Biomechanical effect of mandibular advancement device with different protrusion positions for treatment of obstructive sleep apnoea on tooth and facial bone: A finite element study

Abstract: Mandibular advancement at 70% of maximum protrusion induces risks of tooth root resorption and bone resorption. The mandibular second molars were subjected to the highest stresses. Stress on the teeth and facial bones was the lowest at 40% of maximum mandibular advancement.

Cited by 28 publications

References 37 publications

An investigation into structural behaviors of skulls chewing food in different occlusal relationships using FEM

An investigation into structural behaviors of skulls chewing food in different occlusal relationships using FEM

Force Distribution of a Novel Core-Reinforced Multilayered Mandibular Advancement Device

The biomechanical effects of bimaxillary osteotomies to the patients with mandibular retraction under incisal clenching

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