Accuracy of Patient-Specific, 3D-Printed Laminofacetal Based Trajectory-Guide for Pedicle Screw Placement in Subaxial Cervical and Thoracic Spine

Background: Conventional methods of pedicle-screw placement have higher breach rates due to variations in pedicle trajectories. Objective: We studied the accuracy of patient-specific, three-dimensional (3D)-printed laminofacetal-based trajectory guide for pedicle-screw placement in the subaxial-cervical and thoracic spine. Materials and Methods: We enrolled 23 consecutive patients who underwent subaxial cervical and thoracic pedicle-screw instrumentation. They were divided into two groups: group A (cases without spinal deformity) and group B (cases with pre-existing spinal deformity). Patient-specific, 3D-printed laminofacetal-based trajectory guide for each instrumented level was designed. The accuracy of screw placement was assessed on postoperative computed tomography (CT) using the Gertzbein–Robbins grading. Results: A total of 194 pedicle screws (114 cervical and 80 thoracics) were placed using trajectory guides, of which 102 belonged to group B (34 cervical and 68 thoracics). Out of a total of 194 pedicle screws, 193 had clinically acceptable placement (grade A: 187; grade B: 6; and grade C: 1). In the cervical spine, 110 pedicle screws out of a total of 114 had grade A placement (grade B: 4). In the thoracic spine, 77 pedicle screws out of a total of 80 had grade A placement (grade B: 2; grade C: 1). Out of a total of 92 pedicle screws in group A, 90 had grade A placement, and the rest 2 had grade B breach. Similarly, 97 out of a total of 102 pedicle screws in group B were placed accurately, 4 had grade B and another had a grade C breach. Conclusions: Patient-specific, 3D-printed laminofacetal-based trajectory guide may help in accurate placement of subaxial cervical and thoracic pedicle screws. It may help reduce surgical time, blood loss, and radiation exposure.

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