Your search keyword '"biomechanical behavior"' showing total 3 results

1. Investigation of the effects of graded models on the biomechanical behavior of a bone-dental implant system under osteoporotic conditions.

Author

Ying Li, Zhong Shuang Liu, Xiao Ming Bai, and Bin Zhang

Subjects

*BONE mechanics, *DENTAL implants, *OSTEOPOROSIS, *METALS in medicine, *MEDICAL research, *FINITE element method

Abstract

Objective: To investigate the effects of graded models on the biomechanical behavior of a bone-implant system under osteoporotic conditions. Methodology: A finite element model (FEM) of the jawbone segments with a titanium implant is used. Two types of models (a graded model and a non-graded model) are established. The graded model is established based on the graded variation of the elastic modulus of the cortical bone and the non-graded model is defined by homogeneous cortical bone. The vertical and oblique loads are adopted. The max von Mises stresses and the max displacements of the cortical bone are evaluated. Results: Comparing the two types of models, the difference in the maximum von Mises stresses of the cortical bone is more than 20%. The values of the maximum displacements in the graded models are considerably less than in the non-graded models. Conclusions: These results indicate the significance of taking into account the actual graded properties of the cortical bone so that the biomechanical behavior of the bone-implant system can be analyzed accurately. [ABSTRACT FROM AUTHOR]

Published

2013

2. Investigation of the effects of graded models on the biomechanical behavior of a bone-dental implant system under osteoporotic conditions

Author

Zhang B, Shuang Liu Z, Li Y, and Ming Bai X

Subjects

Biomechanical behavior, business.industry, medicine.medical_treatment, Cortical bone, Finite element analysis, Oblique case, General Medicine, Graded model, Finite element method, medicine.anatomical_structure, Homogeneous, medicine, von Mises yield criterion, Original Article, Implant, Composite material, Dental implant, business, Elastic modulus

Abstract

Objective: To investigate the effects of graded models on the biomechanical behavior of a bone-implant system under osteoporotic conditions. Methodology : A finite element model (FEM) of the jawbone segments with a titanium implant is used. Two types of models (a graded model and a non-graded model) are established. The graded model is established based on the graded variation of the elastic modulus of the cortical bone and the non-graded model is defined by homogeneous cortical bone. The vertical and oblique loads are adopted. The max von Mises stresses and the max displacements of the cortical bone are evaluated. Results: Comparing the two types of models, the difference in the maximum von Mises stresses of the cortical bone is more than 20%. The values of the maximum displacements in the graded models are considerably less than in the non-graded models. Conclusions: These results indicate the significance of taking into account the actual graded properties of the cortical bone so that the biomechanical behavior of the bone-implant system can be analyzed accurately.

Published

2013

3. Investigation of the effects of graded models on the biomechanical behavior of a bone-dental implant system under osteoporotic conditions.

Author

Li Y, Shuang Liu Z, Ming Bai X, and Zhang B

Abstract

Objective: To investigate the effects of graded models on the biomechanical behavior of a bone-implant system under osteoporotic conditions. Methodology : A finite element model (FEM) of the jawbone segments with a titanium implant is used. Two types of models (a graded model and a non-graded model) are established. The graded model is established based on the graded variation of the elastic modulus of the cortical bone and the non-graded model is defined by homogeneous cortical bone. The vertical and oblique loads are adopted. The max von Mises stresses and the max displacements of the cortical bone are evaluated., Results: Comparing the two types of models, the difference in the maximum von Mises stresses of the cortical bone is more than 20%. The values of the maximum displacements in the graded models are considerably less than in the non-graded models., Conclusions: These results indicate the significance of taking into account the actual graded properties of the cortical bone so that the biomechanical behavior of the bone-implant system can be analyzed accurately.

Published

2013