Automated Computed Tomography Segmentation of the Pharyngeal Airway and Palate to Accelerate Tübingen Palatal Plate Fabrication in Pierre Robin Sequence.

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Abstract

Infants with Pierre Robin sequence frequently develop upper airway obstruction due to micrognathia and glossoptosis. The Tübingen palatal plate repositions the tongue base anteriorly to improve airway patency; however, conventional fabrication requires serial intraoral impressions and repeated nasoendoscopy, which prolongs airway compromise. Computed tomography (CT) enables single-session virtual spur design, yet manual pharyngeal airway and hard palate segmentation is labor-intensive, delaying treatment. The authors evaluated convolutional neural network-based automated segmentation to accelerate CT-guided Tübingen palatal plate fabrication using 74 low-dose head-and-neck CT scans (50 pre-contrast, 24 phonation) annotated retrospectively by 3 raters. Two-dimensional and 3-dimensional U-net models were trained with 5-fold cross-validation; ablation experiments compared cropping versus resizing; sagittal, coronal, versus axial planes; multiclass versus one-versus-rest strategies; and batch splitting. Primary outcome: dice similarity coefficient (DSC); secondary outcomes: inference time and contouring time saved. The 2-dimensional U-net achieved the best accuracy-efficiency balance, with mean DSC 0.8835 (palate 0.8741; airway 0.8928). Cropping improved sagittal DSC from 0.8584 to 0.8690. Multiclass and one-versus-rest DSC were comparable; semi-supervised pretraining conferred minimal benefit. Inference required <60 seconds on a single graphics processing unit, reducing manual contouring by approximately 25 minutes per patient and enabling same-day computer-aided design/computer-aided manufacturing printing. Automated CT segmentation eliminates a major clinical bottleneck, supporting faster, safer, and more personalized airway management for Pierre Robin sequence infants, and warrants prospective validation.

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