Live bone inherently responds to applied mechanical stimulus by altering its internal tissue composition and ultimately biomechanical properties, structure and function. The final formation may structurally appear inf...Live bone inherently responds to applied mechanical stimulus by altering its internal tissue composition and ultimately biomechanical properties, structure and function. The final formation may structurally appear inferior by design but complete by function. To understand the loading response, this paper numerically investigated structural remodeling of mature sheep femur using evolutionary structural optimization method (ESO). Femur images from Computed Tomography scanner were used to determine the elastic modulus variation and subsequently construct finite element model of the femur with stiffest elasticity measured. Major muscle forces on dominant phases of healthy sheep gait were imposed on the femur under static mode. ESO was applied to progressively alter the remodeling of numerically simulated femur from its initial to final design by iteratively removing elements with low strain energy density (SED). The computations were repeated with two different mesh sizes to test the convergence. The elements within the medullary canal had low SEDs and therefore were removed during the optimization. The SEDs in the remaining elements varied with angle around the circumference of the shaft. Those elements with low SED were inefficient in supporting the load and thus fundamentally explained how bone remodels itself with less stiff inferior tissue to meet load demand. This was in line with the Wolff’s law of transformation of bone. Tissue growth and remodeling process was found to shape the sheep femur to a mechanically optimized structure and this was initiated by SED in macro-scale according to traditional principle of Wolff’s law.展开更多
Daily 20-mg and once-weekly 56.5-mg teriparatide(parathyroid hormone 1–34) treatment regimens increase bone mineral density(BMD) and prevent fractures, but changes in bone turnover markers differ between the two ...Daily 20-mg and once-weekly 56.5-mg teriparatide(parathyroid hormone 1–34) treatment regimens increase bone mineral density(BMD) and prevent fractures, but changes in bone turnover markers differ between the two regimens. The aim of the present study was to explain changes in bone turnover markers using once-weekly teriparatide with a simulation model. Temporary increases in bone formation markers and subsequent decreases were observed during once-weekly teriparatide treatment for 72 weeks. These observations support the hypothesis that repeated weekly teriparatide administration stimulates bone remodeling, replacing old bone with new bone and leading to a reduction in the active remodeling surface. A simulation model was developed based on the iterative remodeling cycle that occurs on residual old bone. An increase in bone formation and a subsequent decrease were observed in the preliminary simulation. For each fitted time point, the predicted value was compared to the absolute values of the bone formation and resorption markers and lumbar BMD. The simulation model strongly matched actual changes in bone turnover markers and BMD. This simulation model indicates increased bone formation marker levels in the early stage and a subsequent decrease. It is therefore concluded that remodeling-based bone formation persisted during the entire treatment period with once-weekly teriparatide.展开更多
In this review,a brief presentation is first given to the hierarchical structure and mechanical behavior of bone.Then,the recent advancements in nanoscale characterization of bone ultrastructure and ingredients are di...In this review,a brief presentation is first given to the hierarchical structure and mechanical behavior of bone.Then,the recent advancements in nanoscale characterization of bone ultrastructure and ingredients are discussed based on an extensive quantity of references in the literature.Moreover,computational and analytical bone mechanics at ultrastructure levels are critically reviewed with the growing body of knowledge in the field.The computational and analytical models are summarized in several categories for ease of understanding bone nanomechanics and their applicability/limitations.This review is expected to provide a well-informed foundation for the researchers interested in interrogating the complex biomechanical response of bone at its nanoscale hierarchy.展开更多
The failure of bone injury repair surgery is mostly due to the stress shielding effect caused by the difference of elastic modulus between the implant prosthesis and human bone,result-ing in a great damage to patients...The failure of bone injury repair surgery is mostly due to the stress shielding effect caused by the difference of elastic modulus between the implant prosthesis and human bone,result-ing in a great damage to patients.To solve this problem,in this study,the influencing factors of the elastic modulus of implant prosthesis were investigated,the relationship between the elastic modulus of the implanted prosthesis and the influencing factors was analyzed,and then a design method of the implant prosthesis to reduce the stress shielding effect by adjusting the unit module to control the elastic modulus was established.This method was used for the biomechanical simula-tion to simulate the displacement and stress distribution between the implant prosthesis and the surrounding bone tissue,and then the reliability of the method was verified.The implant prosthe-sis with an elastic modulus consistent with that of the experimental dog bone was made by this method,and used for the animal experiments.The effects of implant prosthesis with different mod-ulus on the growth of surrounding bone tissue were observed,and at the same time,the reliability of the implant design method and the results of biomechanical simulation were verified.It is con-firmed that this method can effectively reduce the stress concentration of implant prosthesis by more than 15.4%and increase the growth of bone tissue by more than 21%.展开更多
文摘Live bone inherently responds to applied mechanical stimulus by altering its internal tissue composition and ultimately biomechanical properties, structure and function. The final formation may structurally appear inferior by design but complete by function. To understand the loading response, this paper numerically investigated structural remodeling of mature sheep femur using evolutionary structural optimization method (ESO). Femur images from Computed Tomography scanner were used to determine the elastic modulus variation and subsequently construct finite element model of the femur with stiffest elasticity measured. Major muscle forces on dominant phases of healthy sheep gait were imposed on the femur under static mode. ESO was applied to progressively alter the remodeling of numerically simulated femur from its initial to final design by iteratively removing elements with low strain energy density (SED). The computations were repeated with two different mesh sizes to test the convergence. The elements within the medullary canal had low SEDs and therefore were removed during the optimization. The SEDs in the remaining elements varied with angle around the circumference of the shaft. Those elements with low SED were inefficient in supporting the load and thus fundamentally explained how bone remodels itself with less stiff inferior tissue to meet load demand. This was in line with the Wolff’s law of transformation of bone. Tissue growth and remodeling process was found to shape the sheep femur to a mechanically optimized structure and this was initiated by SED in macro-scale according to traditional principle of Wolff’s law.
文摘Daily 20-mg and once-weekly 56.5-mg teriparatide(parathyroid hormone 1–34) treatment regimens increase bone mineral density(BMD) and prevent fractures, but changes in bone turnover markers differ between the two regimens. The aim of the present study was to explain changes in bone turnover markers using once-weekly teriparatide with a simulation model. Temporary increases in bone formation markers and subsequent decreases were observed during once-weekly teriparatide treatment for 72 weeks. These observations support the hypothesis that repeated weekly teriparatide administration stimulates bone remodeling, replacing old bone with new bone and leading to a reduction in the active remodeling surface. A simulation model was developed based on the iterative remodeling cycle that occurs on residual old bone. An increase in bone formation and a subsequent decrease were observed in the preliminary simulation. For each fitted time point, the predicted value was compared to the absolute values of the bone formation and resorption markers and lumbar BMD. The simulation model strongly matched actual changes in bone turnover markers and BMD. This simulation model indicates increased bone formation marker levels in the early stage and a subsequent decrease. It is therefore concluded that remodeling-based bone formation persisted during the entire treatment period with once-weekly teriparatide.
基金Some work reported in this publication was partially supported by grants from the National Science Foundation(CMMI-1538448,CMMI-1266390)National Institutes of Health(AG027780 and AR055955),Office of the Vice President for Research of the University of Texas at San Antonio.
文摘In this review,a brief presentation is first given to the hierarchical structure and mechanical behavior of bone.Then,the recent advancements in nanoscale characterization of bone ultrastructure and ingredients are discussed based on an extensive quantity of references in the literature.Moreover,computational and analytical bone mechanics at ultrastructure levels are critically reviewed with the growing body of knowledge in the field.The computational and analytical models are summarized in several categories for ease of understanding bone nanomechanics and their applicability/limitations.This review is expected to provide a well-informed foundation for the researchers interested in interrogating the complex biomechanical response of bone at its nanoscale hierarchy.
基金supported by the 13th Five-Year Plan Science and Technology Research Project of Jilin Province Department of Education(JJKH20200066KJ)the Jilin Province Science and Technology Department Project(20200708126YY).
文摘The failure of bone injury repair surgery is mostly due to the stress shielding effect caused by the difference of elastic modulus between the implant prosthesis and human bone,result-ing in a great damage to patients.To solve this problem,in this study,the influencing factors of the elastic modulus of implant prosthesis were investigated,the relationship between the elastic modulus of the implanted prosthesis and the influencing factors was analyzed,and then a design method of the implant prosthesis to reduce the stress shielding effect by adjusting the unit module to control the elastic modulus was established.This method was used for the biomechanical simula-tion to simulate the displacement and stress distribution between the implant prosthesis and the surrounding bone tissue,and then the reliability of the method was verified.The implant prosthe-sis with an elastic modulus consistent with that of the experimental dog bone was made by this method,and used for the animal experiments.The effects of implant prosthesis with different mod-ulus on the growth of surrounding bone tissue were observed,and at the same time,the reliability of the implant design method and the results of biomechanical simulation were verified.It is con-firmed that this method can effectively reduce the stress concentration of implant prosthesis by more than 15.4%and increase the growth of bone tissue by more than 21%.