Patient-specific finite element analysis for assessing hip fracture risk in aging populations.
Chethan K NNadine Schmidt Genannt WaldschmidtJohn Valerian CordaB Satish ShenoySawan ShettyLaxmikant G KeniShyamasunder N BhatNishant NikamSenay MihcinPublished in: Biomedical physics & engineering express (2024)
The femur is one of the most important bone in the human body, as it supports the body's weight and helps with movement. The aging global population presents a significant challenge, leading to an increasing demand for artificial joints, particularly in knee and hip replacements, which are among the most prevalent surgical procedures worldwide. This study focuses on hip fractures, a common consequence of osteoporotic fractures in the elderly population. To accurately predict individual bone properties and assess fracture risk, patient-specific finite element models (FEM) were developed using CT data from healthy male individuals. The study employed ANSYS 2023 R2 software to estimate fracture loads under simulated single stance loading conditions, considering strain-based failure criteria. The FEM bone models underwent meticulous reconstruction, incorporating geometrical and mechanical properties crucial for fracture risk assessment. Results revealed an underestimation of the ultimate bearing capacity of bones, indicating potential fractures even during routine activities. The study explored variations in bone density, failure loads, and density/load ratios among different specimens, emphasizing the complexity of bone strength determination. Discussion of findings highlighted discrepancies between simulation results and previous studies, suggesting the need for optimization in modelling approaches. The strain-based yield criterion proved accurate in predicting fracture initiation but required adjustments for better load predictions. The study underscores the importance of refining density-elasticity relationships, investigating boundary conditions, and optimizing models through in vitro testing for enhanced clinical applicability in assessing hip fracture risk. In conclusion, this research contributes valuable insights into developing patient-specific FEM bone models for clinical hip fracture risk assessment, emphasizing the need for further refinement and optimization for accurate predictions and enhanced clinical utility.
Keyphrases
- hip fracture
- bone mineral density
- risk assessment
- computed tomography
- magnetic resonance imaging
- heavy metals
- clinical practice
- magnetic resonance
- machine learning
- physical activity
- mass spectrometry
- endothelial cells
- finite element
- artificial intelligence
- climate change
- pet ct
- total hip arthroplasty
- finite element analysis
- induced pluripotent stem cells
- virtual reality