Abstract
BACKGROUND: Anterior cervical discectomy and fusion (ACDF) is a common surgical procedure for treating cervical spine diseases, but its anterior approach can lead to complications such as dysphagia and carotid artery injury due to the large incision. However, performing ACDF under a percutaneous endoscopic approach can effectively mitigate these issues. Considering the need for smaller-sized cages in endoscopic procedures, this study explores the feasibility of using small-sized cages for percutaneous endoscopic ACDF surgery. METHODS: The finite element method is used in this paper to construct cervical spine surgical models with three different sizes of cages implanted, studying the impact of size on cervical biomechanical performance. The dimensions of the cages remain constant in length and height, with a length of 14 mm and a height of 6 mm, and widths of 7 mm, 10 mm, and 14 mm, respectively. RESULTS: In a complete fusion state, the range of motion of the surgery level decreased, while adjacent segments showed a compensatory increase in range of motion. Intervertebral disc pressure increased in adjacent discs during flexion and extension. Facet joint pressure in the operated segments generally decreased across all conditions compared to the intact model, but in non-surgical segments exhibited varied compensatory increases under different conditions. Smaller cages led to increased von Mises stress on the cage and endplates, with stress distribution varying by motion condition. CONCLUSION: The results show that, using a 10 mm wide polyetheretherketone cage in complete fusion does not significantly affect postoperative vertebral stability or adjacent segment degeneration risk. Additionally, the risk of subsidence is relatively low, making it a suitable cage option for percutaneous endoscopic ACDF surgery.