Analysis of fracture, force, and temperature in orthogonal elliptical vibration-assisted bone cutting

Abstract

Bone is a natural composite and its cutting is a common procedure in orthopedic surgery. The processing damage, cutting force, and cutting heat strongly influence postoperative recovery. In this study, a orthogonal elliptical vibration-assisted (EVA) bone cutting system is developed based on semi-brittle behaviors of bone to experimentally investigate fracture, cutting force, roughness and temperature rise. To prevent large-scale fractures during bone cutting, an extended finite element method model incorporating detailed microstructure and material properties of bone is created to understand the crack-propagation mechanism. Both the simulation and the experiments demonstrate that the elliptical vibration could effectively control the direction of crack propagation. The experimental results also demonstrate that the cutting force and surface roughness decreases with an increase in the vibration frequency or amplitude, whereas temperature rise increases with the vibration frequency. These findings prove that the EVA could allow for low-trauma bone cutting in orthopedic surgery.