Qi Zhong, Zidi Zhai, Zi'ang Wu, Yingyi Shen, Fang Qu, Yaqin Wu, Ziyuan Zhu, Chun Xu
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Implant stability quotient (ISQ), bone-to-implant contact (BIC), and bone volume fraction in 500 μm (BV/TV-500) and 1000 μm range (BV/TV-1000) were measured to evaluate the osseointegration performance of the implants. The implant thread design of 0.8-mm pitch, 0.2-mm depth, 0.15-mm TW, 10-degree CSA, and 10-degree ASA produced minimal σ<sub>vM</sub> for the maxillary posterior region (OPT-max). The thread design of 1.0-mm pitch, 0.3-mm depth, 0.2-mm TW, 0-degree CSA, and 20-degree ASA produced minimal σ<sub>vM</sub> for the mandibular posterior region (OPT-man). Optimized implants showed significantly improved ISQ value (p < 0.05) 4 weeks after implantation. The BV/TV-500 and BV/TV-1000 around the OPT-max, and the BIC and BV/TV-500 around the OPT-man implant were significantly higher than those around the originally designed implant, respectively (p < 0.05). The thread design significantly affects the stress in the peri-implant bone during and immediately after the implantation. 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引用次数: 0
摘要
优化商用牙种植体的螺纹设计,使种植体周围骨的应力分布达到理想状态。建立BLT®Φ4.1 × 10种植体(Institut Straumann AG)和牙槽骨模型。采用显式动力学有限元分析(EDFEA)计算种植体种植期间和种植后种植周皮质骨的动态von Mises应力(σvM)。通过正交试验设计确定了螺纹节距、螺纹深度、针尖宽度(TW)和冠/尖面角(CSA/ASA)的组合可产生最小的σvM。采用最佳的原始螺纹设计将植入物植入家兔胫骨。在500 μm (BV/TV-500)和1000 μm (BV/TV-1000)范围内测量种植体稳定性商(ISQ)、骨与种植体接触度(BIC)和骨体积分数,评价种植体的骨整合性能。0.8 mm节距、0.2 mm深度、0.15 mm TW、10°CSA和10°ASA的种植螺纹设计使上颌后牙区的σvM最小(OPT-max)。1.0 mm节距、0.3 mm深度、0.2 mm TW、0°CSA和20°ASA的螺纹设计使下颌后区(OPT-man)的σvM最小。优化后的植入物显著提高了ISQ值(p
Thread design optimization of a dental implant using explicit dynamics finite element analysis.
To optimize the thread design of a commercial dental implant for ideal stress distribution in the peri-implant bone. The models of the BLT® Φ4.1 × 10 implant (Institut Straumann AG) and the alveolar bone were created. Dynamic von Mises stress (σvM) in the peri-implant cortical bone during and immediately after implantation was calculated using explicit dynamics finite element analysis (EDFEA). The combination of thread pitch, depth, tip width (TW), and coronal/apical surface angle (CSA/ASA), which produced minimal σvM was determined as the optimal thread design by orthogonal experimental design. The implants with optimal and original thread designs were fabricated and implanted into rabbits' tibias. Implant stability quotient (ISQ), bone-to-implant contact (BIC), and bone volume fraction in 500 μm (BV/TV-500) and 1000 μm range (BV/TV-1000) were measured to evaluate the osseointegration performance of the implants. The implant thread design of 0.8-mm pitch, 0.2-mm depth, 0.15-mm TW, 10-degree CSA, and 10-degree ASA produced minimal σvM for the maxillary posterior region (OPT-max). The thread design of 1.0-mm pitch, 0.3-mm depth, 0.2-mm TW, 0-degree CSA, and 20-degree ASA produced minimal σvM for the mandibular posterior region (OPT-man). Optimized implants showed significantly improved ISQ value (p < 0.05) 4 weeks after implantation. The BV/TV-500 and BV/TV-1000 around the OPT-max, and the BIC and BV/TV-500 around the OPT-man implant were significantly higher than those around the originally designed implant, respectively (p < 0.05). The thread design significantly affects the stress in the peri-implant bone during and immediately after the implantation. The optimal thread design based on EDFEA promoted the osteogenesis around the implant.
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