Identification of dynamic load for prosthetic structures

Zhang, Dequan; Han, Xu; Zhang, Zhongpu; Liu, Jie; Jiang, Chao; Yoda, Nobuhiro; Meng, Xianghua; Li, Qing

doi:10.1002/cnm.2889

Cited by 7 publications

(3 citation statements)

References 60 publications

(125 reference statements)

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“…The authors also clarified that the load on the implant at gum chewing was basically larger than that at maximum voluntary clenching (MVC). Other studies [ 38 , 39 ] reported that the load magnitude was affected by food texture, and the load magnitude during chewing was larger than that during MVC. The data were subsequently used for advanced experimental and numerical purposes, such as finite element analysis (FEA), and the effect of peri-implant bone resorption on the stress distribution in implant body was investigated [ 40 ].…”

Section: Resultsmentioning

confidence: 97%

In vivo measurement of three-dimensional load exerted on dental implants: a literature review

et al. 2022

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Background For biomechanical consideration of dental implants, an understanding of the three-dimensional (3D) load exerted on the implant is essential, but little information is available on the in vivo load, including the measuring devices. Purpose This review aimed to evaluate studies that used specific load-measuring devices that could be mounted on an implant to measure the functional load in vivo. Materials and methods An electronic search utilizing the internet research databases PubMed, Google Scholar, and Scopus was performed. The articles were chosen by two authors based on the inclusion and exclusion criteria. Results In all, 132 studies were selected from the database search, and 16 were selected from a manual search. Twenty-three studies were finally included in this review after a complete full-text evaluation. Eleven studies were related to the force measurements using the strain gauges, and 12 were related to the piezoelectric force transducer. The principles of the two types of devices were completely different, but the devices produced comparable outcomes. The dynamics of the load magnitude and direction on the implant during function were clarified, although the number of participants in each study was small. Conclusions The load exerted on the implant during function was precisely measured in vivo using specific measuring devices, such as strain gauges or piezoelectric force transducers. The in vivo load data enable us to determine the actual biomechanical status in more detail, which might be useful for optimization of the implant prosthetic design and development of related materials. Due to the limited data and difficulty of in vivo measurements, the development of a new, simpler force measurement device and method might be necessary.

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Section: Resultsmentioning

confidence: 97%

In vivo measurement of three-dimensional load exerted on dental implants: a literature review

et al. 2022

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“…To meet the aforementioned requirements, several bite force sensor systems have been developed. (9,10) The sensor must be sufficiently thin not to interfere with occlusion to measure bite force in the maximal intercuspal position, which is the best-fit position of the opposing teeth. Furthermore, a wearable measurement system is required to monitor bruxism during sleep.…”

Section: Introductionmentioning

confidence: 99%

Novel Self-powered Flexible Thin Bite Force Sensor with Electret and Dielectric Elastomer

Ichikawa¹,

Hijikata²

2022

Sensors and Materials

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Monitoring the bite force is valuable in the treatment of bruxism, an unconscious oral habit. Conventional bite force sensors used in clinical practice are unsuitable for wearable bite force measurement systems because of their size and measurement principles. In this study, a selfpowered bite force sensor composed of an electret and a dielectric elastomer is proposed to realize a mouthguard-type wearable bite force measurement system. A theoretical model of the sensor was constructed to compensate for the nonlinearity between the applied bite force and sensor output voltage. A fabricated large-scale prototype sensor and theoretical model accurately estimated an applied force of up to 50 N. The proposed sensor is expected to realize a selfpowered bite force monitoring system by making it thin and embedding it in a mouthguard.

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“…Compared with the measurement method in vitro, theoretical calculation represented by finite element method (FEM) with the advantages of controllable experimental conditions, low cost, and short experimental cycle is more and more popular in recent decades. [21][22][23][24] Various methods for orthodontic force simulation which applied external force loads to teeth or appliances can be found in literature. Liao et al 1 applied distally directed tipping and bodily forces to human maxillary to investigate optimal orthodontic force.…”

Section: Introductionmentioning

confidence: 99%

Simulation of orthodontic force of archwire applied to full dentition using virtual bracket displacement method

Zhang

Gan

Zhao

et al. 2019

Numer Methods Biomed Eng

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Objective Orthodontic force simulation of tooth provides important guidance for clinical orthodontic treatment. However, previous studies did not involve the simulation of orthodontic force of archwire applied to full dentition. This study aimed to develop a method to simulate orthodontic force of tooth produced by loading a continuous archwire to full dentition using finite element method. Method A three‐dimensional tooth‐periodontal ligament‐bone complex model of mandible was reconstructed from computed tomography images, and models of brackets and archwire were built. The simulation was completed through two steps. First, node displacements of archwire before and after loading were estimated through moving virtual brackets to drive archwire deformation. Second, the obtained node displacements were loaded to implement the loading of archwire, and orthodontic force was calculated. An orthodontic force tester (OFT) was used to measure orthodontic force in vitro for the validation. Results After the simulation convergence, archwire was successfully loaded to brackets, and orthodontic force of teeth was obtained. Compared with the measured orthodontic force using the OFT, the absolute difference of the simulation results ranged from 0.5 to 22.7 cN for force component and ranged from 2.2 to 80.0 cN•mm for moment component, respectively. The relative difference of the simulation results ranged from 2.5% to 11.0% for force component, and ranged from 0.6% to 14.7% for moment component, respectively. Conclusions The developed orthodontic force simulation method based on virtual bracket displacement can be used to simulate orthodontic force provided by the archwire applied to full dentition.

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Identification of dynamic load for prosthetic structures

Cited by 7 publications

References 60 publications

In vivo measurement of three-dimensional load exerted on dental implants: a literature review

In vivo measurement of three-dimensional load exerted on dental implants: a literature review

Novel Self-powered Flexible Thin Bite Force Sensor with Electret and Dielectric Elastomer

Simulation of orthodontic force of archwire applied to full dentition using virtual bracket displacement method

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