Introduction: Deformity correction requires detailed operative planning and implementation. Software engineering innovations including virtual surgical planning (VSP) platforms facilitate preoperative spinopelvic parameter assessment and consideration of various operative plans theoretically capable of achieving the desired corrections. UNiD software uses calibrated radiographs and AI-integrated predictive model to simulate postoperative spinopelvic parameters based on corrective techniques and anticipated compensatory changes. Patient-specific spinal rods can be manufactured based on the generated plan providing intraoperative validation of correction.
Methods: We conducted a retrospective analysis of 146 patients who underwent long-segment thoracolumbar fusions with pelvic fixation and a minimum of 1-year follow-up for deformity correction. Patients were dichotomized: UNiD (61 patients), control (85 patients). Comparative analysis was performed assessing UNiD software accuracy and compare outcomes to our historical control prior to implementing UNiD. Equivalence analysis was performed using 5˚ and 1.5cm limits.
Results: Amongst UNiD patients, achieved spinopelvic parameters at 3-months were equivalent to the simulated plan: LL, PT, PI, SS, PI-LL mismatch, SVA, T1PA, TK, and L4-S1 lordosis. At 1-year, there was a significant improvement in all PROMs (p < 0.001). UNiD demonstrated a significant increase in L4-S1 lordosis (37.4˚ vs. 28.7˚,p=0.001) and decrease in T1PA (17.3˚ vs. 23.5˚,p=0.001) versus control. Achieved SVA, LL, and PI-LL mismatch in control group were not equivalent to improvements seen in UNID. UNiD demonstrated a significant increase in achievement of SVA < 5cm (73.8% vs. 55.3%,p=0.026) and T1PA < 20˚ (70.5% vs. 28.2%,p=0.001). Rod fracture rate was significantly higher in control (8.2% vs. 0.0%,p=0.042). On 1-year follow-up radiograph, there was no significant difference in PJK (p=0.278) or PJF (p=0.294).
Conclusion : UNiD accurately predicted spinal alignment achieved at 3-months and was associated with improved 1-year PROMs. UNiD software in conjunction with patient-specific rods may facilitate achievement of deformity correction goals with an improved safety profile at least up to 1-year due to decreased rod fractures. Further research is necessary to demonstrate long-term durability and delineate potential impact of VSP and patient-specific instrumentation particularly with continual software and engineering innovations.
.jpg)
