Physically based 3D finite element model of a single mineralized collagen microfibril

TL;DR

This study presents a detailed 3D finite element model of mineralized collagen microfibrils in human bone, incorporating structural details to analyze their mechanical behavior and structure-property relationships.

Contribution

The paper introduces a novel 3D finite element model that includes physical structural details of mineralized collagen microfibrils, enhancing understanding of their mechanical properties.

Findings

Model accurately predicts stress-strain behavior.

Mechanical properties depend on microfibril structure.

Results align with experimental data.

Abstract

Mineralized collagen microfibrils in human bone provide its mechanical properties (stiffness, elasticity, ductility, energy dissipation and strength). However, detailed 3D finite element models describing the mechanical behaviour of the mineralized collagen microfibrils are still lacking. In the current work, we developed a 3D finite element model of the mineralized collagen microfibril that incorporates the physical 3D structural details. The model components consist of five tropocollagen molecules, mineral hydroxyapatite and intermolecular cross-links joining primarily the ends of the tropocollagen molecules. Dimension, arrangement and mechanical behaviour of the constituents are based on previously published experimental and theoretical data. Tensile load was applied to the microfibril under different conditions (hydrated and dehydrated collagen) to investigate the relationship between the structure and the mechanical behaviour of the mineralized collagen microfibril (stress-strain curve and elastic modulus). The computational results match the experimental available data well, and provide insight into the role of the phases and morphology on the microfibril behaviour. Our predicted results show that the mechanical properties of collagen microfibrils arise due to their structure and properties. The proposed 3D finite element model of mineralized collagen microfibril contributes toward the investigation of the bottom-up structure-property relationships in human bone.