计算机导航对人工髋关节股骨柄假体置入的精确性验证

目的 分析计算机导航对人工髋关节股骨柄假体三维空间位移变化跟踪显示的精确性.方法 于导航计算机中建立柄假体三维虚拟像,并进行虚拟像与实物间匹配对应.在虚拟空间中,确立三维方向刎度值,并以此为基准进行计算机导航跟踪下的假体位移变量测定,与真实位移输出值比较而验证精确度.结果 导航监测柄假体的平行位移,监测值与真实值间差异(1.01±0.47)mm;对于角位移的监测,差异1.09°±0.62°.两次独立操作所得结果筹异无统计学意义(t=0.238,P>0.05).结论 在不同的平行/角位移设定输出下,计算机导航均可精确监测,可有效引导股骨柄假体置入.     

计算机导航对人工髋关节股骨柄假体置入的精确性验证

Objective To evaluate the accuracy of surgical navigation for localization and orientation of the femoral stem component in total hip arthroplasty, nethods In the hypothesized space, 3-D images of femoral stem were reconstructed. The coronal, sagittal and horizontal axes and scale divisions were established to calculate the displacement and rotation of the stem. Matching between the stem and its 3-D images was performed while the stem was moved in various distances and angles on the digital motion-platform. Then the actual change in the position of the implant and the caleulative data obtained from the navigation system were compared to evaluate the accuracy. Results The mean difference in displacement between the measurements and the actual changes was (1.01 ±0.47) mm, and the mean difference in the measured and actual angles was 1.09°±0.62°. The duplicate test found no significant difference (t = 0.238, P > 0.05). Conclusion Precise placement of the stem in the desired location and orientation can be achieved by the navigation system in the total hip arthroplasty.     

计算机导航对人工髋关节股骨柄假体置入的精确性验证

Objective To evaluate the accuracy of surgical navigation for localization and orientation of the femoral stem component in total hip arthroplasty, nethods In the hypothesized space, 3-D images of femoral stem were reconstructed. The coronal, sagittal and horizontal axes and scale divisions were established to calculate the displacement and rotation of the stem. Matching between the stem and its 3-D images was performed while the stem was moved in various distances and angles on the digital motion-platform. Then the actual change in the position of the implant and the caleulative data obtained from the navigation system were compared to evaluate the accuracy. Results The mean difference in displacement between the measurements and the actual changes was (1.01 ±0.47) mm, and the mean difference in the measured and actual angles was 1.09°±0.62°. The duplicate test found no significant difference (t = 0.238, P > 0.05). Conclusion Precise placement of the stem in the desired location and orientation can be achieved by the navigation system in the total hip arthroplasty.     

计算机导航对人工髋关节股骨柄假体置入的精确性验证

Objective To evaluate the accuracy of surgical navigation for localization and orientation of the femoral stem component in total hip arthroplasty, nethods In the hypothesized space, 3-D images of femoral stem were reconstructed. The coronal, sagittal and horizontal axes and scale divisions were established to calculate the displacement and rotation of the stem. Matching between the stem and its 3-D images was performed while the stem was moved in various distances and angles on the digital motion-platform. Then the actual change in the position of the implant and the caleulative data obtained from the navigation system were compared to evaluate the accuracy. Results The mean difference in displacement between the measurements and the actual changes was (1.01 ±0.47) mm, and the mean difference in the measured and actual angles was 1.09°±0.62°. The duplicate test found no significant difference (t = 0.238, P > 0.05). Conclusion Precise placement of the stem in the desired location and orientation can be achieved by the navigation system in the total hip arthroplasty.     

计算机导航对人工髋关节股骨柄假体置入的精确性验证

Objective To evaluate the accuracy of surgical navigation for localization and orientation of the femoral stem component in total hip arthroplasty, nethods In the hypothesized space, 3-D images of femoral stem were reconstructed. The coronal, sagittal and horizontal axes and scale divisions were established to calculate the displacement and rotation of the stem. Matching between the stem and its 3-D images was performed while the stem was moved in various distances and angles on the digital motion-platform. Then the actual change in the position of the implant and the caleulative data obtained from the navigation system were compared to evaluate the accuracy. Results The mean difference in displacement between the measurements and the actual changes was (1.01 ±0.47) mm, and the mean difference in the measured and actual angles was 1.09°±0.62°. The duplicate test found no significant difference (t = 0.238, P > 0.05). Conclusion Precise placement of the stem in the desired location and orientation can be achieved by the navigation system in the total hip arthroplasty.     

计算机导航对人工髋关节股骨柄假体置入的精确性验证

Objective To evaluate the accuracy of surgical navigation for localization and orientation of the femoral stem component in total hip arthroplasty, nethods In the hypothesized space, 3-D images of femoral stem were reconstructed. The coronal, sagittal and horizontal axes and scale divisions were established to calculate the displacement and rotation of the stem. Matching between the stem and its 3-D images was performed while the stem was moved in various distances and angles on the digital motion-platform. Then the actual change in the position of the implant and the caleulative data obtained from the navigation system were compared to evaluate the accuracy. Results The mean difference in displacement between the measurements and the actual changes was (1.01 ±0.47) mm, and the mean difference in the measured and actual angles was 1.09°±0.62°. The duplicate test found no significant difference (t = 0.238, P > 0.05). Conclusion Precise placement of the stem in the desired location and orientation can be achieved by the navigation system in the total hip arthroplasty.     

计算机导航对人工髋关节股骨柄假体置入的精确性验证

Objective To evaluate the accuracy of surgical navigation for localization and orientation of the femoral stem component in total hip arthroplasty, nethods In the hypothesized space, 3-D images of femoral stem were reconstructed. The coronal, sagittal and horizontal axes and scale divisions were established to calculate the displacement and rotation of the stem. Matching between the stem and its 3-D images was performed while the stem was moved in various distances and angles on the digital motion-platform. Then the actual change in the position of the implant and the caleulative data obtained from the navigation system were compared to evaluate the accuracy. Results The mean difference in displacement between the measurements and the actual changes was (1.01 ±0.47) mm, and the mean difference in the measured and actual angles was 1.09°±0.62°. The duplicate test found no significant difference (t = 0.238, P > 0.05). Conclusion Precise placement of the stem in the desired location and orientation can be achieved by the navigation system in the total hip arthroplasty.     

计算机导航对人工髋关节股骨柄假体置入的精确性验证

Objective To evaluate the accuracy of surgical navigation for localization and orientation of the femoral stem component in total hip arthroplasty, nethods In the hypothesized space, 3-D images of femoral stem were reconstructed. The coronal, sagittal and horizontal axes and scale divisions were established to calculate the displacement and rotation of the stem. Matching between the stem and its 3-D images was performed while the stem was moved in various distances and angles on the digital motion-platform. Then the actual change in the position of the implant and the caleulative data obtained from the navigation system were compared to evaluate the accuracy. Results The mean difference in displacement between the measurements and the actual changes was (1.01 ±0.47) mm, and the mean difference in the measured and actual angles was 1.09°±0.62°. The duplicate test found no significant difference (t = 0.238, P > 0.05). Conclusion Precise placement of the stem in the desired location and orientation can be achieved by the navigation system in the total hip arthroplasty.     

计算机导航对人工髋关节股骨柄假体置入的精确性验证

Objective To evaluate the accuracy of surgical navigation for localization and orientation of the femoral stem component in total hip arthroplasty, nethods In the hypothesized space, 3-D images of femoral stem were reconstructed. The coronal, sagittal and horizontal axes and scale divisions were established to calculate the displacement and rotation of the stem. Matching between the stem and its 3-D images was performed while the stem was moved in various distances and angles on the digital motion-platform. Then the actual change in the position of the implant and the caleulative data obtained from the navigation system were compared to evaluate the accuracy. Results The mean difference in displacement between the measurements and the actual changes was (1.01 ±0.47) mm, and the mean difference in the measured and actual angles was 1.09°±0.62°. The duplicate test found no significant difference (t = 0.238, P > 0.05). Conclusion Precise placement of the stem in the desired location and orientation can be achieved by the navigation system in the total hip arthroplasty.     

国产股骨柄假体在前路髋关节置换中的应用

目的 评价BE2柄在植入后早期的稳定性(下沉、偏移)、并发症及功能评分的结果,以及初步评价BE2股骨柄假体植入后早期的临床效果.方法 收集2018年9月至2019年12月于哈医大一院骨科采用BE2股骨柄假体进行初次髋关节置换术的病例资料,全部病例均为微创前路关节置换(DAMIS).本组包括89例(110髋),男50例(...     

计算机导航系统辅助下全髋关节表面置换的初步经验

目的 初步评估计算机辅助下行全髋关节表面置换的手术方法及假体植入的精确性.方法 对40例患者分成导航组(20例)和对照组(20例),分别采用计算机导航系统辅助和标准常规技术完成全髋关节表面置换术.比较两组手术时间、术中失血量、Harris髋关节评分(HHS),以及髋臼杯外展角和前倾角的偏移度及股骨假体柄干角和前倾角的偏移度.结果 手术时间导航组较对照组长38.7min(P＜0.05),术中平均出血量导航组较对照组多109.4 ml(P＜0.05).随访平均14.5个月,HHS评分两组比较差异无统计学意义(P＞0.05).对照组髋臼杯外展角偏移度(7.3°±4.3°)大于导航组(1.9°±1.3°)(P＜0.05),对照组髋臼杯前倾角偏移度(3.9°±2.3°)大于导航组(2.4°±1.5°)(P＜0.05).导航组股骨假体柄干角偏移度(1.5°±1.0°)小于对照组(11.3°±1.3°)(P＜0.05),导航组股骨假体前倾角偏移度(1.8°±2.3°)小于对照组(6.5°±5.3°)(P＜0.05).结论 计算机导航系统辅助下行全髋关节表面置换术可以提高假体植入的精确性,避免股骨颈皮质骨切迹,降低股骨颈骨折的风险.