Your search keyword '"Huang, Heng-Li"' showing total 15 results

1. Biomechanical Effects of Bone Atrophy, Implant Design, and Vertical or Tilted of Posterior Implant on All-on-Four Concept Implantation: Finite Element Analysis

Author

Huang, Heng-Li, Lin, Ting-Wei, Tsai, Hui-Ling, Wu, Yu-Ling, and Wu, Aaron Yu-Jen

Published

2022

2. Optimal positions of clear aligner attachments to achieve lower canine tipping and bodily movement using finite element analysis.

Author

Chen, Pin-Yu, Huang, Heng-Li, Yu, Jian-Hong, and Hsu, Jui-Ting

Subjects

ORTHODONTIC appliances, FINITE element method, TEETH, MANDIBLE, ROTATIONAL motion

Abstract

Clear aligners are popular orthodontic tools because of their relatively aesthetic appearance and convenience of use. Nevertheless, bodily tooth movements still present challenges. This study evaluated various configurations of attachments placed on the mandibular canine in terms of the efficiency of canine bodily movement and correction of tipping. A finite element model of the mandible was constructed to investigate the effects of various attachment configurations on the overall bodily movement and undesirable tipping of a mandibular canine. Canine movements were categorized into four types, namely tipping and bodily movements in the mesial and distal directions. The size and shape of the attachments were fixed, but their placement and orientation were varied. Five and seven attachment configurations were evaluated for their influence on tipping and bodily movements, respectively. Attachment configuration significantly influenced mandibular canine tipping. The mesial occlusal–distal cervical and mesial occlusal–mesial cervical configurations had notable effects on mesial tipping, and the mesial occlusal–mesial cervical configuration excelled in distal tipping by increasing strain by 33.1%. The mesial occlusal–mesial cervical attachment configuration consistently had superior efficiency in facilitating both mesial and distal bodily movements of the canine. The mesial occlusal–mesial cervical attachment configuration excelled in all four types of canine movement. Irrespective of the attachment configuration, canines tend to move overall with slight tipping due to skeletal resistance and their center of rotation. The attachment configuration is crucial to the success of clear aligner treatment and must be carefully considered in clinical practice. [ABSTRACT FROM AUTHOR]

Published

2024

3. Biomechanical analysis of occlusal modes on the periodontal ligament while orthodontic force applied

Author

Tsai, Ming-Tzu, Huang, Heng-Li, Yang, Shih-Guang, Su, Kuo-Chih, Fuh, Lih-Jyh, and Hsu, Jui-Ting

Published

2021

4. Effects of diameters of implant and abutment screw on stress distribution within dental implant and alveolar bone: A three-dimensional finite element analysis.

Author

Shen, Yen-Wen, Huang, Heng-Li, Hsu, Jui-Ting, and Fuh, Lih-Jyh

Subjects

ALVEOLAR process, FINITE element method, STRESS concentration, DENTAL implants, CANCELLOUS bone, COMPACT bone

Abstract

Few studies have investigated the effects of abutment screw diameter in the stress of dental implants and alveolar bones under occlusal forces. In this study, we investigated how variations in implant diameter, abutment screw diameter, and bone condition affect stresses in the abutment screw, implant, and surrounding bone. Three-dimensional finite element (FE) models were fabricated for dental implants with external hex-type abutments measuring 4 and 5 mm in diameter. The models also included abutment screws measuring 2.0 and 2.5 mm in diameter. Each implant model was integrated with the mandibular bone comprising the cortical bone and four types of cancellous bone. In total, 12 finite element models were generated, subjected to three different occlusal forces, and analyzed using FE software to investigate the stress distribution of dental implant and alveolar bone. Wider implants demonstrated lower stresses in implant and bone compared with standard-diameter implants. The quality of cancellous bone has a minimal impact on the stress values of the implant, abutment screw, and cortical bone. Regardless of occlusal arrangement or quality of cancellous bone, a consistent pattern emerged: larger abutment screw diameters led to increased stress levels on the screws, while the stress levels in both cortical and cancellous bone showed comparatively minor fluctuations. Wider implants tend to have better stress distribution than standard-diameter implants. The potential advantage of augmenting the abutment screw diameter is unfavorable. It may result in elevated stresses in the implant system. [ABSTRACT FROM AUTHOR]

Published

2024

5. Biomechanical Evaluation of Bone Atrophy and Implant Length in Four Implants Supporting Mandibular Full-Arch-Fixed Dentures.

Author

Huang, Heng-Li, Tsai, Hui-Ling, Wu, Yu-Ling, Hsu, Jui-Ting, and Wu, Aaron Yu-Jen

Subjects

*OVERLAY dentures, *DENTURES, *ATROPHY, *FINITE element method, *ALVEOLAR process, *CANCELLOUS bone, *STRAINS & stresses (Mechanics)

Abstract

Residual alveolar ridge resorption often occurs after tooth extraction, which causes issues requiring further prothesis rehabilitation. A treatment concept referred to as all-on-four, involving fixed dentures supported with four implants, was recently developed. The current study aimed to determine the effect of changing bone atrophy and implant length in all-on-four treatments on stress and strain in the surrounding bone of the implant. A three-dimensional finite element method was used in this research. The stress analysis was conducted with von Mises stress values. Two types of synthetic jawbone models with mild and moderate atrophy were used. Furthermore, two different implant lengths with a similar implant design and diameter were selected, and they were classified into eight models. Then, the bone model was assessed via a computed tomography (CT) scan and was transformed into a virtual model in Geomagic and SolidWorks with implant rebuilding. After modifying bone atrophy, the von Mises stresses in the surrounding bone of the implant were as follows: mild type 2 < mild type 3 < moderate type 3 < moderate type 4. The bone quantity change rate increased more than when bone conditions were limited. Compared with changes in implant lengths, the stresses in the peri-implant surrounding bone were generally higher in the 9 mm implant length group than in the 11.5 mm group. However, the results did not significantly differ. In conclusion, the von Mises stress and strain increased in the models with moderate atrophy and low-density trabecular bone. Hence, bone atrophy and its presurgical diagnosis in long-term implant prognosis are crucial. [ABSTRACT FROM AUTHOR]

Published

2022

6. Biomechanical effect of implant design on four implants supporting mandibular full-arch fixed dentures: In vitro test and finite element analysis.

Author

Wu, Aaron Yu-Jen, Hsu, Jui-Ting, Fuh, Lih-Jyh, and Huang, Heng-Li

Subjects

FINITE element method, OSSEOINTEGRATED dental implants, DENTURES, STRAIN gages, COMPACT bone, MANDIBLE surgery, IN vitro studies, DENTAL implants, PHYSIOLOGIC strain, IMPACT of Event Scale, DENTISTRY, KINEMATICS

Abstract

Background/purpose: Impact of the implant shape on the biomechanical performance of all-on-four treatment of dental implant is still unclear. This study evaluated the all-on-four treatment with four osseointegrated implants in terms of the biomechanical effects of implant design and loading position on the implant and surrounding bone by using both in vitro strain gauge tests and three-dimensional (3D) finite element (FE) analyses.Methods: Both in vitro and 3D FE models were constructed with placing NobelSpeedy and NobelActive implants as well as a titanium framework in an edentulous jawbone based on the concept of all-on-four treatment. Three types of loads were applied: at the central incisor area (loading position 1) and at the molar regions with (loading position 2) and without (loading position 3) the denture cantilever. For the in vitro tests, the principal bone strains were recorded by rosette strain gauges and statistically evaluated using Wilcoxon's rank-sum test. The 3D FE simulations analyzed the peak von-Mises stresses in the implant and surrounding cortical bone.Results: The peak stress and strain in the surrounding bone were typically 36-62% (3D FE analysis) and 47-57% (in vitro test) (p < 0.001)higher for loading position 3 than for loading positions 1 and 2. Between those two implant designs, the bone strains and bone stresses did not differ significantly.Conclusion: For all-on-four treatment with four osseointegrated dental implants, altering the implant design does not appear to affect the biomechanical performance of the entire treatment, especially in terms of the stresses and strains in the surrounding bone. [ABSTRACT FROM AUTHOR]

Published

2020

7. Biomechanical evaluation of one-piece and two-piece small-diameter dental implants: In-vitro experimental and three-dimensional finite element analyses.

Author

Wu, Aaron Yu-Jen, Hsu, Jui-Ting, Chee, Winston, Lin, Yun-Te, Fuh, Lih-Jyh, and Huang, Heng-Li

Subjects

DENTAL implants, FINITE element method, STRAIN gages, JAWS, IN vitro studies, ANATOMY

Abstract

Background/purpose: Small-diameter dental implants are associated with a higher risk of implant failure. This study used both three-dimensional finite-element (FE) simulations and in-vitro experimental tests to analyze the stresses and strains in both the implant and the surrounding bone when using one-piece (NobelDirect) and two-piece (NobelReplace) small-diameter implants, with the aim of understanding the underlying biomechanical mechanisms.Methods: Six experimental artificial jawbone models and two FE models were prepared for one-piece and two-piece 3.5-mm diameter implants. Rosette strain gauges were used for in-vitro tests, with peak values of the principal bone strain recorded with a data acquisition system. Implant stability as quantified by Periotest values (PTV) were also recorded for both types of implants. Experimental data were analyzed statistically using Wilcoxon's rank-sum test. In FE simulations, the peak value and distribution of von-Mises stresses in the implant and bone were selected for evaluation.Results: In in-vitro tests, the peak bone strain was 42% lower for two-piece implants than for one-piece implants. The PTV was slightly lower for one-piece implants (PTV = -6) than for two-piece implants (PTV = -5). In FE simulations, the stresses in the bone and implant were about 23% higher and 12% lower, respectively, for one-piece implants than those for two-piece implants.Conclusion: Due to the higher peri-implant bone stresses and strains, one-piece implants (NobelDirect) might be not suitable for use as small-diameter implants. [ABSTRACT FROM AUTHOR]

Published

2016

8. Biomechanical analysis of a temporomandibular joint condylar prosthesis during various clenching tasks.

Author

Huang, Heng-Li, Su, Kuo-Chih, Fuh, Lih-Jyh, Chen, Michael Y.C., Wu, Jay, Tsai, Ming-Tzu, and Hsu, Jui-Ting

Subjects

TEMPOROMANDIBULAR disorders, PROSTHETICS, BIOMECHANICS, COMPACT bone, CANCELLOUS bone, THREE-dimensional modeling, FINITE element method, THERAPEUTICS

Abstract

The objective of this study was to evaluate the effect of clenching tasks on the stress and stability of a temporomandibular joint (TMJ) condylar prosthesis, as well as on the stress and strain in the whole mandible and bone surrounding three screws. Three-dimensional finite element models of the mandible and a TMJ condylar prosthesis using three screws were established. Six static clenching tasks were simulated in this study: incisal clench (INC), intercuspal position (ICP), right unilateral molar clench (RMOL), left unilateral molar clench (LMOL), right group function (RGF), and left group function (LGF). Based on the simulation of the six clenching tasks, none of the inserted screws or the TMJ condylar prosthesis were broken. In addition, the stability of the TMJ condylar prosthesis was sufficiently high for bone ongrowth. For the whole mandibular bone, the maximum von Mises stress and von Mises strain observed in the cortical bone and cancellous bone were yielded by the ICP and RMOL, respectively. For the bone surrounding the inserted screws, the maximum von Mises stress and von Mises strain in both the cortical bone and cancellous bone were yielded by the LMOL. Clenching tasks had significant effects on the stress distribution of the TMJ condylar prosthesis, as well as on the stress and strain distribution of the whole mandible and the bone surrounding the inserted screws. [ABSTRACT FROM AUTHOR]

Published

2015

9. Biomechanical effects of the implant material and implant-abutment interface in immediately loaded small-diameter implants.

Author

Wu, Aaron, Huang, Heng-Li, Hsu, Jui-Ting, and Chee, Winston

Subjects

*BIOMECHANICS, *DENTAL implants, *DENTAL abutments, *IMMEDIATE loading (Dentistry), *TORQUE, *TITANIUM alloys, *OSSEOINTEGRATION, *FINITE element method

Abstract

Objective: Small-diameter implants have been available since the 1990s, but few studies have analyzed their mechanical properties. This study evaluated the effects of the implant material and the implant-abutment connection designs on the primary stability and the marginal bone strain of small-diameter implant subject to immediate loading. Materials and methods: Insertion torque value (ITV), implant stability quotient (ISQ), and Periotest value (PTV) of three implant systems with four parameters (titanium, titanium alloy, internal and external hexagon connections) were measured after placing implants into artificial type 2 jaw-bone models. Specimens were tested under both vertical and oblique static loads at 190 N. Peak values of the principal bone strain were recorded and analyzed statistically by the Kruskal-Wallis test and multiple-comparisons Bonferroni test. Results: PTV and ISQ were higher for the NIOSM311 (internal-hex and Ti alloy) and FOSM311 (external-hex and pure Ti) implants, respectively, than for the NOSM311 (external-hex and Ti alloy) implant. Under vertical loading the peak value of peri-implant bone strains did not differ significantly among these three implant systems. However, the peak bone strains were at least 32 % lower for the NIOSM311 and FOSM311 implants than for the NOSM311 implant under lateral loading. Conclusions: The implant material and the implant-abutment connection design significantly influence the peri-implant bone strain of immediately loaded small-diameter implants, but barely affect their primary stability. Clinical Relevance: A commercially pure titanium implant with an internal connection has the potential to reduce the risk of implant failure of small-diameter implant related to biomechanical complications. [ABSTRACT FROM AUTHOR]

Published

2014

10. A new method to evaluate the elastic modulus of cortical bone by using a combined computed tomography and finite element approach

Author

Huang, Heng-Li, Tsai, Ming-Tzu, Lin, Dan-Jae, Chien, Chi-Sheng, and Hsu, Jui-Ting

Subjects

*ELASTICITY, *TOMOGRAPHY, *BONE density, *THREE-dimensional imaging, *ESTIMATION theory, *SIMULATION methods & models, *MECHANICAL loads, *BONE mechanics, *FINITE element method

Abstract

Abstract: This study attempted to estimate the elastic modulus of cortical specimens directly from the computed tomography (CT) number (CT). Cubic specimens of fresh bovine femora were tested under compressive loading. The corresponding three-dimensional mesh models of these specimens were established with the aid of CT images. The elastic modulus of each element was determined using the following transfer formula: E=A×(CT)B. The A and B were determined by matching the simulation results with the experimental force–displacement curves. An optimization approach was used to match the entire specimen sets between simulations and experiments. The results indicated that the elastic modulus of cortical bone can be effectively estimated using a power relationship (E=1.26×10−3×(CT)1.93) directly from the CT number. This procedure eliminates the need to determine the bone density, and therefore reduces the computational time required to define mechanical properties in finite element methods. [Copyright &y& Elsevier]

Published

2010

11. Biocompatibility and Microstructure-Based Stress Analyses of TiNbZrTa Composite Films.

Author

Lai, Bo-Wei, Chang, Yin-Yu, Shieh, Tzong-Ming, and Huang, Heng-Li

Subjects

STRAINS & stresses (Mechanics), COMPUTER-aided design software, SURFACE preparation, FINITE element method, CELL morphology, FIBRONECTINS

Abstract

Background: the clinical application of orthopedic or dental implants improves the quality of the lives of patients. However, the long-term use of implants may lead to implant loosening and related complications. The purpose of this study is to deposit titanium (Ti)-niobium (Nb)-zirconium (Zr)-tantalum (Ta) alloys on the surface of Ti-6Al-4V to increase structural strength and biocompatibility for the possible future application of implants. Materials and methods: Ti, Nb, Zr, and Ta served as the materials for the surface modification of the titanium alloy. TiNbZr and TiNbZrTa coatings were produced using cathodic arc evaporation, and a small amount of nitrogen was added to produce TiNbZrTa(N) film. Annealing and oxidation were then conducted to produce TiNbZrTa-O and TiNbZrTa(N)-O coatings. In this study, biological tests and finite element analyses of those five alloy films, as well as uncoated Ti-6Al-4V, were performed. Human osteosarcoma cells (MG-63) and mouse fibroblast cells (L-929) were used to analyze cytotoxicity, cell viability, and cell morphology, and the bone differentiation of MG-63 was evaluated in an alkaline phosphatase experiment. Furthermore, for measuring the gene expression level of L-929, reverse transcription quantitative real-time polymerase chain reaction (RT-qPCR) was conducted. The three-dimensional (3D) computational models of the coated and uncoated sample films were constructed using images of transmission electron microscopy and computer-aided design software and, then, the stress distributions of all models were evaluated by finite element analysis. Result: the cytotoxicity test revealed that the surface treatment had no significant cytotoxic effects on MG-63 and L-929 cells. According to the results of the cell viability of L-929, more cell activity was observed in the surface-treated experimental group than in the control group; for MG-63, the cell viability of the coated samples was similar to that of the uncoated samples. In the cell morphology analysis, both MG-63 and L-929 exhibited attached filopodia and lamellipodia, verifying that the cells were well attached. The alkaline phosphatase experiment demonstrated that the surface treatment did not affect the characteristics of early osteogenic differentiation, whereas RT-qPCR analysis showed that surface treatment can promote better performance of L-929 cells in collagen, type I, α1, and fibronectin 1. Finally, the results of the finite element analysis revealed that the coated TiNb interlayer can effectively reduce the stress concentration inside the layered coatings. Conclusions: TiNbZrTa series films deposited using cathodic arc evaporation had excellent biocompatibility with titanium alloys, particularly in regard to soft tissue cells, which exhibited an active performance. The finite element analysis verified that the TiNb interlayer can reduce the stress concentration inside TiNbZrTa series films, increasing their suitability for application in biomedical implants in the future. [ABSTRACT FROM AUTHOR]

Published

2022

12. Effects of splinted prosthesis supported a wide implant or two implants: a three-dimensional finite element analysis.

Author

Huang, Heng‐Li, Huang, Jehn‐Shyun, Ko, Ching‐Chang, Hsu, Jui‐Ting, Chang, Chih‐Han, and Chen, Michael Y. C.

Subjects

*PROSTHETICS, *DENTAL implants, *FINITE element method, *MASTICATION disorders, *DENTISTRY, *ARTIFICIAL implants

Abstract

Three-dimensional finite element (FE) models of splinted prosthetic crowns were studied and stress analyses were evaluated with different types of implant support, including standard, wide or two implant(s) for partial, posterior edentulous restorations. The FE models were constructed based on a cadaver mandible containing the 2nd premolar and the 1st molar. The crowns of these two teeth were modeled as connected and disconnected to mimic the splinted and non-splinted designs, respectively. One standard implant was placed at the premolar region, while three types of implant support, one at a time (the standard implant, wide implant and two implants), were used to support the molar crown. A 100 N oblique load was applied to the buccal cusp on each crown. The FE simulation was validated experimentally via strain gauge measurement. The experimental data were well correlated with the FE predictions ( r2=0.97). When compared with the standard implant used in the molar area, the wide implant and two implants reduced the peak stress in crestal bone by 29–37% for both splinted and non-splinted cases. Inserting the standard implant into both the premolar and molar area, the bone stresses were identical for splinted and non-splinted designs. However, splinting the adjacent crowns has shown to decrease the bone stresses at the premolar region by 25%, while the wide implant or two implants were placed at the molar region. The biomechanical advantages of using the wide implant or two implants are almost identical. The benefit of load sharing by the splinted crowns is notable only when the implants on the premolar and molar regions have different supporting ability. [ABSTRACT FROM AUTHOR]

Published

2005

13. Corrigendum to "Biomechanical effect of implant design on four implants supporting mandibular full-arch fixed dentures: in vitro test and finite element analysis" [Journal of the Formosan Medical Association 119 (2020) 1514-1523].

Author

Yu-Jen Wu, Aaron, Hsu, Jui-Ting, Fuh, Lih-Jyh, and Huang, Heng-Li

Subjects

FINITE element method, MEDICAL societies, DENTURES

Published

2021

14. The number of screws, bone quality, and friction coefficient affect acetabular cup stability

Author

Hsu, Jui-Ting, Chang, Chih-Han, Huang, Heng-Li, Zobitz, Mark E., Chen, Weng-Pin, Lai, Kuo-An, and An, Kai-Nan

Subjects

*FINITE element method, *BONES, *NUMERICAL analysis, *BIOMEDICAL engineering

Abstract

Abstract: One of the major causes of loosening of cementless acetabular cup implants is insufficient initial stability. This study used three-dimensional finite element models of the pelvis and acetabular components to investigate the effects of the number of screws, bone quality, and friction coefficient of the acetabular cup on the initial stability under normal walking. A commercially available hemispherical acetabular cup with five screw holes was used as the default model. The stiffness of the pelvis and the friction coefficient of the cup were systematically varied, within a realistic range, to assess the initial stability of the acetabular cup. The simulations showed that the inserted screws provide only a localized reduction in the relative micromotion between the cup and pelvis therefore inserting several screw closed together might not be useful. Changes in the pelvic stiffness have a non-linear effect on the initial stability of acetabular cup and the subchondral bone provides good support for fixation of the cementless cup. The friction coefficient of the acetabular cup plays a limited role, comparing with the factor of bone quality, in resisting relative micromotion in the cup–pelvis interface. [Copyright &y& Elsevier]

Published

2007

15. The relation between micromotion and screw fixation in acetabular cup

Author

Hsu, Jui-Ting, Lai, Kuo-An, Chen, Qingshan, Zobitz, Mark E., Huang, Heng-Li, An, Kai-Nan, and Chang, Chih-Han

Subjects

*FASTENERS, *HARDWARE, *ANATOMY, *FINITE element method

Abstract

Abstract: One of the major causes inducing loosening in the cementless acetabular cup implanting is its insufficient initial stability. In this study, three-dimensional finite element models of the pelvis and acetabular components were developed to investigate the relationship between relative micromotion, initial stability, and screw fixation under six daily activity loadings. A commercial available hemispheric cup with five screw holes was used as the target acetabular cup. The simulation results showed that if screws were placed closed together, when the screw number increased from 1 to 5, the peak micromotion decreased less than 14%, from 126.5 to 108.8μm, while the stable region, micromotion less than 28μm, enlarged only by 40%, from 46.1% to 64.7%. However, if the screw could be placed near the cup rim, a single rim screw, 202.1μm micromotion, could provide better stability than that of four dome screws, 209.6μm micromotion, placed closed together. To conclude, multiple cup screws should be placed near cup rim and as separate as possible to enlarge the stable region and reduce the peak micromotion between cup and acetabulum. [Copyright &y& Elsevier]

Published

2006