Faculty of Dentistry, McGill University, Montreal, Québec, Canada.
Am J Orthod Dentofacial Orthop. 2011 Sep;140(3):356-65. doi: 10.1016/j.ajodo.2010.05.024.
The purpose of this investigation was to characterize the placement pattern and factors influencing the primary stability of mini-implants in human cadavers. The factors studied were mini-implant length, placement depth, bone density, and bone type.
Sixty standard mini-implants (6, 8, and 10 mm; 20 of each size) were placed into the maxillas and mandibles of 5 fresh human cadavers. Computed tomography imaging was used to measure the placement pattern, bone density, and thickness surrounding each device. The mini-implants were subsequently subjected to increasing tensile forces (pull-out force) until failure, and the maximum mechanical anchorage force of each was recorded with a dynamometer. A statistical model was realized by using MATLAB version 7.5.0 with Statistics Toolbox 7 (MathWorks, Natick, Mass) including the maximum anchorage force, mini-implant length, bone type, placement depth, and density surrounding each section of the mini-implant.
Placement depth was strongly dependent on mini-implant length: 15% of the 6-mm implants failed to anchor their parallel sections into cortical bone, but 95% of the 10-mm mini-implant parallel sections penetrated beyond the buccal cortical bone; all 20 tips of the 6-mm mini-implants (100%) reached cancellous bone, whereas 75% of the 10-mm implants penetrated both cortical plates, reaching the lingual cortical bone. Longer mini-implants were associated with greater incidences of sinus and bicortical perforations. The correlation coefficients between the initial maximum mechanical anchorage force and the studied factors were as follows: bone density and placement depth combined (r = 0.65, P <0.001), mini-implant length (r = 0.45, P = 0.004), bone density (r = 0.42, P = 0.007), and placement depth (r = 0.29, P = 0.06).
During mini-implant length selection, the clinician should consider the important trade-off between anchorage and risk of placement complications or damage to the tissues. Longer mini-implants enable more anchorage; however, they are associated with a higher risk of damage to neighboring structures. Placement depth and bone density at the site of mini-implant placement are the best predictors of primary stability.
本研究的目的是描述微型种植体在人体尸体中的初始稳定性的放置模式和影响因素。研究的因素包括微型种植体的长度、放置深度、骨密度和骨类型。
将 60 个标准微型种植体(6、8 和 10mm;每种尺寸 20 个)放置在 5 个新鲜人体尸体的上颌骨和下颌骨中。使用计算机断层扫描成像测量每个设备周围的放置模式、骨密度和厚度。随后,微型种植体承受逐渐增加的拉伸力(拔出力),直至失效,并使用测力计记录每个微型种植体的最大机械锚固力。使用 MATLAB 版本 7.5.0 和 Statistics Toolbox 7(MathWorks,Natick,Mass)实现了一个统计模型,其中包括最大锚固力、微型种植体长度、骨类型、放置深度和微型种植体各部分周围的密度。
放置深度强烈依赖于微型种植体的长度:15%的 6mm 种植体未能将其平行部分锚固到皮质骨中,但 95%的 10mm 微型种植体平行部分穿透颊侧皮质骨;20 个 6mm 微型种植体的尖端(100%)均到达松质骨,而 75%的 10mm 种植体穿透两皮质板,到达舌侧皮质骨。较长的微型种植体与更多的窦和双皮质穿孔的发生率相关。初始最大机械锚固力与研究因素之间的相关系数如下:骨密度和放置深度的组合(r=0.65,P<0.001)、微型种植体长度(r=0.45,P=0.004)、骨密度(r=0.42,P=0.007)和放置深度(r=0.29,P=0.06)。
在选择微型种植体长度时,临床医生应考虑锚固和放置并发症风险或对组织损伤之间的重要权衡。较长的微型种植体可以提供更多的锚固力;但是,它们与相邻结构损伤的风险较高相关。微型种植体放置部位的放置深度和骨密度是初始稳定性的最佳预测指标。
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