Assessment of the Accuracy of Patient Specific Plates for Correction of Maxillary Cant in Facial Asymmetry

Overview

The goal of this clinical trial is to learn how accurate patient-specific plates (PSPs) are for correcting a tilted upper jaw (maxillary cant) in people with facial asymmetry. The main questions it aims to answer are: * How closely does the actual surgery match the virtual surgical plan? * How satisfied are participants with how they look after surgery? Researchers will compare the surgery results using PSPs to the original 3D virtual plan to see how well they match. Participants will: * Have a CT scan and 3D virtual surgery planning * Get custom-made plates designed to fit their upper jaw * Undergo surgery to correct the tilt of the upper jaw * Be followed for up to 6 months to check healing and results

This prospective clinical trial aims to evaluate the accuracy and efficacy of patient-specific plates (PSPs) created through virtual surgical planning (VSP) for the correction of maxillary cant in patients with facial asymmetry. Facial asymmetry, particularly in the upper third of the face, often presents with occlusal canting that poses both aesthetic and functional challenges. Traditional orthognathic techniques, such as LeFort I osteotomy with standard fixation hardware, often rely heavily on surgeon experience, potentially compromising consistency and precision. Virtual Surgical Planning and 3D-Printed PSPs introduce a paradigm shift by enabling surgeons to simulate the osteotomy and repositioning process in a digital environment. This planning facilitates the design and fabrication of custom titanium plates and cutting guides precisely tailored to the patient's skeletal anatomy. This trial investigates whether these individualized devices can achieve closer adherence to the preoperative virtual plan, thus improving surgical accuracy and outcomes. A sample of eight clinical cases will be included, all diagnosed with maxillary cant and facial asymmetry and meeting defined inclusion/exclusion criteria. The intervention involves a multi-step process: CT Imaging and Data Acquisition: High-resolution scans of each patient's craniofacial skeleton are obtained in DICOM format. 3D Modeling and Segmentation: Specialized software (Mimics, ProPlan, 3-Matic) is used to segment anatomical structures and perform virtual surgical planning. Design of PSPs and Surgical Guides: Custom plates and cutting guides are generated based on the planned osteotomy and repositioning. 3D Printing and Manufacturing: Plates are fabricated from titanium using milling techniques, while guides are printed with biocompatible resin. Surgical Execution: The LeFort I osteotomy, combined with BSSO when indicated, is performed using the guides to ensure precise bone cuts and the PSPs for fixation in the planned position. The primary outcome is the degree of congruence between preoperative virtual plans and postoperative outcomes, assessed through 3D superimposition of CT images at multiple timepoints (1 week, 1 month, 3 months, and 6 months). Secondary outcomes include aesthetic evaluation and patient satisfaction. Postoperative care involves standardized antibiotic, analgesic, and steroid regimens, with structured follow-up. Accuracy is quantified in millimeters using reproducible anatomical landmarks. Data will be analyzed using appropriate parametric or nonparametric tests, depending on distribution. This study addresses a critical gap in the literature by focusing specifically on the role of PSPs in correcting maxillary cant-a feature of asymmetry often overlooked in prior research. The results are expected to contribute evidence-based insights into improving surgical precision, enhancing patient-specific outcomes, and possibly minimizing intraoperative time and postoperative complications.