Force-Controlled Biomechanical Simulation of Orthodontic Tooth Movement with Torque Archwires Using HOSEA (Hexapod for Orthodontic Simulation, Evaluation and Analysis)

This study aimed to investigate the dynamic behavior of different torque archwires for fixed orthodontic treatment using an automated, force-controlled biomechanical simulation system. A novel biomechanical simulation system (HOSEA) was used to simulate dynamic tooth movements and measure torque expression of four different archwire groups: 0.017 '' x 0.025 '' torque segmented archwires (TSA) with 30 degrees torque bending, 0.018 '' x 0.025 '' TSA with 45 degrees torque bending, 0.017 '' x 0.025 '' stainless steel (SS) archwires with 30 degrees torque bending and 0.018 '' x 0.025 '' SS with 30 degrees torque bending (n = 10/group) used with 0.022 '' self-ligating brackets. The Kruskal-Wallis test was used for statistical analysis (p < 0.050). The 0.018 '' x 0.025 '' SS archwires produced the highest initial rotational torque moment (M-y) of -9.835 Nmm. The reduction in rotational moment per degree (M-y/R-y) was significantly lower for TSA compared to SS archwires (p < 0.001). TSA 0.018 '' x 0.025 '' was the only group in which all archwires induced a min. 10 degrees rotation in the simulation. Collateral forces and moments, especially F-x, F-z and M-x, occurred during torque application. The measured forces and moments were within a suitable range for the application of palatal root torque to incisors for the 0.018 '' x 0.025 '' archwires. The 0.018 '' x 0.025 '' TSA reliably achieved at least 10 degrees incisal rotation without reactivation.