Automated Segmentation of Graft Material in 1-Stage Sinus Lift Based on Artificial Intelligence: A Retrospective Study.

Clinical implant dentistry and related research Pub Date : 2024-12-16 DOI:10.1111/cid.13426

Yue Xi, Xiaoxia Li, Zhikang Wang, Chuanji Shi, Xiaoru Qin, Qifeng Jiang, Guoli Yang

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Abstract

Objectives: Accurate assessment of postoperative bone graft material changes after the 1-stage sinus lift is crucial for evaluating long-term implant survival. However, traditional manual labeling and segmentation of cone-beam computed tomography (CBCT) images are often inaccurate and inefficient. This study aims to utilize artificial intelligence for automated segmentation of graft material in 1-stage sinus lift procedures to enhance accuracy and efficiency.

Materials and methods: Swin-UPerNet along with mainstream medical segmentation models, such as FCN, U-Net, DeepLabV3, SegFormer, and UPerNet, were trained using a dataset of 120 CBCT scans. The models were tested on 30 CBCT scans to evaluate model performance based on metrics including the 95% Hausdorff distance, Intersection over Union (IoU), and Dice similarity coefficient. Additionally, processing times were also compared between automated segmentation and manual methods.

Results: Swin-UPerNet outperformed other models in accuracy, achieving an accuracy rate of 0.84 and mean precision and IoU values of 0.8574 and 0.7373, respectively (p < 0.05). The time required for uploading and visualizing segmentation results with Swin-UPerNet significantly decreased to 19.28 s from the average manual segmentation times of 1390 s (p < 0.001).

Conclusions: Swin-UPerNet exhibited high accuracy and efficiency in identifying and segmenting the three-dimensional volume of bone graft material, indicating significant potential for evaluating the stability of bone graft material.

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基于人工智能的一期鼻窦提升中移植物材料自动分割的回顾性研究。

目的：准确评估一期鼻窦提升术后植骨材料的变化对评估种植体的长期存活至关重要。然而，传统的锥形束计算机断层扫描（CBCT）图像的人工标记和分割往往是不准确和低效的。本研究旨在利用人工智能在一期鼻窦提升手术中自动分割移植物材料，以提高准确性和效率。材料和方法：使用120个CBCT扫描数据集训练swwin -UPerNet以及主流医学分割模型，如FCN， U-Net, DeepLabV3， SegFormer和UPerNet。这些模型在30次CBCT扫描上进行了测试，以评估模型的性能，这些指标包括95% Hausdorff距离、Union交集（IoU）和Dice相似系数。此外，还比较了自动分割和人工分割的处理时间。结果：Swin-UPerNet在准确性上优于其他模型，准确率为0.84，平均精度和IoU值分别为0.8574和0.7373 (p)。结论：Swin-UPerNet在识别和分割植骨材料三维体积方面具有较高的准确性和效率，在评估植骨材料稳定性方面具有重要的潜力。

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Clinical implant dentistry and related research

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