Evaluation of the Effect of Needle Position on Irrigant Flow in the C-shaped Root Canal Using a Computational Fluid Dynamics Model

Abstract

Introduction: The purpose of this study was to investigate the effect of the orientation of a side-vented needle on the irrigant flow pattern in a C-shaped root canal system using computational fluid dynamics and to evaluate the real-time replacement of irrigant in the lateral canal (LC).

Methods: A mandibular second molar with a complete C-shaped canal system was chosen for this study. The root canals were prepared and scanned, and then the images were exported to design software. A 30-G, side-vented irrigation needle was positioned with the open notch facing the lateral canal (case A) and rotated 90°, 180°, and 270° clockwise (cases B, C, and D, respectively). The flow pattern, irrigant replacement, velocity distribution, wall stress distribution, and apical pressure in the canal were analyzed.

Results: Most of the irrigant flowed to the canal outlet from the adjacent instrumented canal space with different trajectories in the 4 cases. The concentration of scalar immediately below the tip of the needle was exchanged quickly; the length of the cleared zone extended 3 mm beyond the tip of the needles. The depth of circulation in the LC in all cases increased during the first 0.2 seconds. After that, the exchange of irrigant reached a stable phase. Irrigant penetration in the LC was greatest in cases A and B (<1.1 mm). Apical pressure in case B was significantly lower than in other groups.

Conclusions: The scalar concentration can be used to evaluate the replacement of irrigant in the root canal over time. Orientation of the opening of the side-vented needle influences the flow pattern, velocity, apical wall pressure, and penetration into the LC.

Keywords: C-shaped root canal; computational fluid dynamics; lateral canal; real time; side-vented needle.