{"title":"Comparison of Load Distribution in Subperiosteal Implants and Mini Plates in Orthognathic Surgery.","authors":"Metin Berk Kasapoglu, Zeynep Afra Akbiyik Az","doi":"10.7150/ijms.111111","DOIUrl":null,"url":null,"abstract":"<p><p><b>Background:</b> Orthognathic surgery is important for correcting craniofacial deformities and restoring occlusion. However, in edentulous patients with severe maxillary atrophy, traditional fixation methods, such as mini plates, may not provide sufficient stability and support for prosthetic rehabilitation. Advances in additive manufacturing have enabled the development of patient-specific subperiosteal implants, offering improved biomechanical performance and more favourable load distribution. <b>Methods:</b> This study utilized finite element analysis to compare the biomechanical performance of traditional mini plates and customized subperiosteal implants in maxillary orthognathic surgery. Computed tomography data were used to construct patient-specific models, and a Le Fort I osteotomy with a 9-mm maxillary advancement was simulated. Displacement and stress distribution were analysed under vertical and oblique loading conditions, focusing on critical regions such as osteotomy sites and screw interfaces. <b>Results:</b> Subperiosteal implants exhibited superior biomechanical performance, with significantly lower displacement (0.58 mm) compared to mini plates (4.50 mm). Stress levels in mini plates frequently exceeded the yield strength of grade IV titanium, whereas subperiosteal implants remained within the elastic limit of Ti6Al4V. Additionally, screw stresses were reduced by 38-42% in the subperiosteal implant group, thereby reducing the risk of mechanical failure. <b>Conclusions:</b> Customized subperiosteal implants provided enhanced stability, reduced stress concentrations, and improved load distribution compared to traditional mini plates. These findings highlight their potential as a transformative solution in orthognathic surgery, particularly for edentulous patients with severe maxillary atrophy. Future research should focus on long-term clinical outcomes and cost-effectiveness to further establish their role in maxillofacial reconstruction.</p>","PeriodicalId":14031,"journal":{"name":"International Journal of Medical Sciences","volume":"22 10","pages":"2257-2268"},"PeriodicalIF":3.2000,"publicationDate":"2025-04-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC12080587/pdf/","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"International Journal of Medical Sciences","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.7150/ijms.111111","RegionNum":3,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"2025/1/1 0:00:00","PubModel":"eCollection","JCR":"Q1","JCRName":"MEDICINE, GENERAL & INTERNAL","Score":null,"Total":0}
引用次数: 0
Abstract
Background: Orthognathic surgery is important for correcting craniofacial deformities and restoring occlusion. However, in edentulous patients with severe maxillary atrophy, traditional fixation methods, such as mini plates, may not provide sufficient stability and support for prosthetic rehabilitation. Advances in additive manufacturing have enabled the development of patient-specific subperiosteal implants, offering improved biomechanical performance and more favourable load distribution. Methods: This study utilized finite element analysis to compare the biomechanical performance of traditional mini plates and customized subperiosteal implants in maxillary orthognathic surgery. Computed tomography data were used to construct patient-specific models, and a Le Fort I osteotomy with a 9-mm maxillary advancement was simulated. Displacement and stress distribution were analysed under vertical and oblique loading conditions, focusing on critical regions such as osteotomy sites and screw interfaces. Results: Subperiosteal implants exhibited superior biomechanical performance, with significantly lower displacement (0.58 mm) compared to mini plates (4.50 mm). Stress levels in mini plates frequently exceeded the yield strength of grade IV titanium, whereas subperiosteal implants remained within the elastic limit of Ti6Al4V. Additionally, screw stresses were reduced by 38-42% in the subperiosteal implant group, thereby reducing the risk of mechanical failure. Conclusions: Customized subperiosteal implants provided enhanced stability, reduced stress concentrations, and improved load distribution compared to traditional mini plates. These findings highlight their potential as a transformative solution in orthognathic surgery, particularly for edentulous patients with severe maxillary atrophy. Future research should focus on long-term clinical outcomes and cost-effectiveness to further establish their role in maxillofacial reconstruction.
背景:正颌手术是矫正颅面畸形和恢复咬合的重要手段。然而,对于上颌严重萎缩的无牙患者,传统的固定方法,如微型钢板,可能不能为假肢康复提供足够的稳定性和支持。增材制造的进步使患者特异性骨膜下植入物的发展成为可能,提供了更好的生物力学性能和更有利的负载分布。方法:采用有限元方法比较传统微型钢板与定制骨膜下种植体在上颌正颌手术中的生物力学性能。计算机断层扫描数据用于构建患者特异性模型,并模拟Le Fort I型截骨术与上颌前移9mm。以截骨部位和螺钉界面等关键区域为重点,分析了垂直和斜向加载条件下的位移和应力分布。结果:骨膜下植入物表现出优越的生物力学性能,与微型钢板(4.50 mm)相比,其位移(0.58 mm)显著降低。微型钢板的应力水平经常超过IV级钛的屈服强度,而骨膜下植入物保持在Ti6Al4V的弹性极限内。此外,骨膜下种植体组的螺钉应力降低了38-42%,从而降低了机械故障的风险。结论:与传统的微型钢板相比,定制的骨膜下植入物提供了更高的稳定性,减少了应力集中,改善了负荷分布。这些发现突出了它们作为正颌手术的变革性解决方案的潜力,特别是对于患有严重上颌萎缩的无牙患者。未来的研究应着眼于长期临床效果和成本效益,以进一步确立其在颌面重建中的作用。
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