# A Comparison of Generic and Subject‐Specific Finite Element Models of Distal Femur Fractures Treated With Locking Plates

**Authors:** Gareth Buhl, Pankaj Pankaj

PMC · DOI: 10.1002/cnm.70043 · 2025-05-19

## TL;DR

This study compares generic and personalized computer models of femur fractures treated with plates to see how much personalization affects results.

## Contribution

A novel modeling approach is introduced to assess the impact of subject-specificity in distal femur fracture simulations.

## Key findings

- Subject-specificity significantly affects bone strains at screw-bone interfaces.
- Plate stresses and far cortex motions are minimally influenced by subject-specific factors.
- The influence of subject-specificity decreases as healing progresses.

## Abstract

While the need for employing subject‐specific computational biomechanics models for treatment planning in orthopaedics is being increasingly voiced, it has not been clear when such specificity is essential and for which questions simpler models might be adequate. This study uses a novel modelling approach to generate finite element models to examine the influence of subject‐specificity in the treatment of distal femur fractures. Three subject‐specific finite element models are created from clinical CT scans, and the proposed approach is employed to impose identical fractures and locking plate treatments upon them. Additionally, the performance of the generic two‐material model based on a Sawbones fourth generation femur is also evaluated. Interfragmentary motions, plate stresses, and strains at the screw‐bone interface are examined due to a physiological loading at different stages of healing. The study finds that subject‐specificity has a major effect on strains in the bone at the screw‐bone interface. However, interfragmentary motions at the far cortex and plate stresses show minimal sensitivity to subject‐specific factors, while near‐cortical and shear interfragmentary motions are influenced by them. The influence of subject‐specificity decreases as healing progresses. These results indicate that while generic approaches may be sufficient to calculate global assembly responses, material heterogeneity and subject‐specific bone stock variations have a large impact on the interaction between the screws and bone. The study also shows that the proposed method, which enables manipulating bone geometry while retaining subject‐specific properties, can be used to evaluate the influence of subject‐specificity for other orthopaedic simulations.

This study examines the influence of subject‐specific parameters on locking‐plate treated distal femur fractures. A new approach is developed to impose identical injuries and treatments on subject‐specific models. The study finds that plate stress and far cortical interfragmentary motion are not influenced by subject−specificity, while the strain state in the bone at screw insertion sites is highly sensitive. These results, and the new modelling approach used, will help to improve the assessment of future treatments.

## Full-text entities

- **Diseases:** fractures (MESH:D050723), Distal Femur Fractures (MESH:D000092524)

## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12087712/full.md

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Source: https://tomesphere.com/paper/PMC12087712