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后交叉韧带重建中三个胫骨隧道位置的生物力学比较:三维有限元分析

Biomechanical comparison of three tibial tunnel positions for PCL reconstruction: a 3D finite element analysis.

作者信息

Tian Siman, Zheng Yi, Long Yubin, Niu Yingzhen, Li Zhikuan, Dong Jiangtao

机构信息

Department of Joint Surgery, Hebei Medical University Third Hospital, Shijiazhuang, China.

Institute of Orthopedics, Hebei Medical University Third Hospital, Shijiazhuang, China.

出版信息

BMC Musculoskelet Disord. 2025 May 6;26(1):446. doi: 10.1186/s12891-025-08716-7.

DOI:10.1186/s12891-025-08716-7
PMID:40329272
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12054236/
Abstract

PURPOSE

To compare the biomechanical properties of the graft during PCL reconstruction by three-dimensional finite element analysis of the PCL trans-tibial reconstruction technique with three different tibial bony channel exit positioning points, to determine which method of positioning is better able to avoid wear and tear between the graft and bony channel, and to reduce the failure rate of the PCL reconstruction.

METHODS

This is a study limited to computational simulation and based on data from a single anatomical model. Thirty-year-old male volunteers were selected. A three-dimensional knee joint model consisting of the distal femur, the proximal tibiofibula and the posterior cruciate ligament was established based on CT scanning and three-dimensional reconstruction of the left knee joint. According to the different positioning points of the tibial tunnel exit, the PCL model of tibial side PCL anatomical region center point reconstruction, the PCL model of Fanelli suggested point (i.e., 10 mm below and 5 mm lateral to the PCL anatomical point) reconstruction, and the PCL model of tibial side posterior posterior joint capsule distal anticompromise and posterior mediastinum reference positioning point (i.e., 5 mm above the posterior capsule distal retropubic, 5 mm medial to the posterior mediastinum) reconstruction were established (respectively designated as Model 1, Model 2, and Model 3). The diameter of the entire graft was set uniformly at 7 mm. With the knee flexed at 90° and the midpoint of the line connecting the medial and lateral apexes of the tibial intercondylar ridge as the reference point, a standardized backward thrust displacement of 5 mm was applied to simulate a posterior knee drawer test with all proximal femoral degrees of freedom constrained. The model overall Mises stress, tibial plateau Mises stress, PCL Mises stress, PCL contact Cpress stress, PCL contact stress and PCL contact effective area were measured.

RESULTS

Simulated posterior drawer tests demonstrated that Model 3 exhibited a substantial reduction in PCL contact Cpress stress (22.57 MPa) compared to Model 1 (32.93 MPa) and Model 2 (29.86 MPa). Additionally, the ratio of contact force (277.48 N) to effective graft-tibial contact area (50.19 mm²), representing the contact force per unit area, was also the lowest in Model 3 compared to Model 1 (213.88 N/17.65 mm²) and Model 2 (470.77 N/63.75 mm²). These findings indicate that Model 3 significantly reduced frictional loads between the graft and tibia, highlighting its biomechanical optimization potential. Further analysis revealed that Model 3 also displayed the lowest tibial plateau Mises stress (48.80 MPa). However, its PCL tensile stress (69.71 MPa) was significantly higher than that of Model 1 (41.03 MPa) and Model 2 (40.90 MPa), suggesting that while Model 3 minimizes friction dependency, it primarily transfers loads through graft tension.

CONCLUSION

Compared with the anatomic regional center point and Fanelli point reconstruction PCL, the grafts of the soft tissue reference tibial localization reconstruction PCL method were subjected to greater tensile forces, but they had significantly lower friction with the tibia and were able to reduce contact wear with the tibia. This can enhance long-term patient outcomes. Our study offers crucial biomechanical evidence for optimizing tunnel positioning in PCL reconstruction, propelling the advancement of surgical techniques.

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3949/12054236/7df2723f634e/12891_2025_8716_Fig7_HTML.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3949/12054236/a0885cb50b17/12891_2025_8716_Fig1_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3949/12054236/4d70ee29c5fe/12891_2025_8716_Fig2_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3949/12054236/e105eb518109/12891_2025_8716_Fig3_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3949/12054236/49690c380a24/12891_2025_8716_Fig4_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3949/12054236/49f806e5744b/12891_2025_8716_Fig5_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3949/12054236/3822b657630f/12891_2025_8716_Fig6_HTML.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3949/12054236/7df2723f634e/12891_2025_8716_Fig7_HTML.jpg
摘要

目的

通过对采用三种不同胫骨骨道出口定位点的PCL经胫骨重建技术进行三维有限元分析,比较PCL重建术中移植物的生物力学特性,确定哪种定位方法更能避免移植物与骨道之间的磨损,并降低PCL重建的失败率。

方法

本研究仅限于计算模拟,基于单个解剖模型的数据。选取30岁男性志愿者。基于左膝关节的CT扫描和三维重建,建立了一个由股骨远端、胫腓骨近端和后交叉韧带组成的三维膝关节模型。根据胫骨隧道出口的不同定位点,建立了胫骨侧PCL解剖区域中心点重建的PCL模型、Fanelli建议点(即PCL解剖点下方10 mm和外侧5 mm处)重建的PCL模型以及胫骨侧后关节囊远端反折和后纵隔参考定位点(即后囊远端耻骨后上方5 mm、后纵隔内侧5 mm处)重建的PCL模型(分别命名为模型1、模型2和模型3)。整个移植物的直径统一设定为7 mm。以膝关节屈曲90°、胫骨髁间嵴内外侧顶点连线中点为参考点,施加5 mm的标准化向后推力位移,模拟后抽屉试验,同时约束股骨近端的所有自由度。测量模型的整体米塞斯应力、胫骨平台米塞斯应力、PCL米塞斯应力、PCL接触Cpress应力、PCL接触应力和PCL接触有效面积。

结果

模拟后抽屉试验表明,与模型1(32.93 MPa)和模型2(29.86 MPa)相比,模型3的PCL接触Cpress应力显著降低(22.57 MPa)。此外,代表单位面积接触力的接触力(277.48 N)与移植物 - 胫骨有效接触面积(50.19 mm²)之比,在模型3中也低于模型1(213.88 N/17.65 mm²)和模型2(470.77 N/63.75 mm²)。这些结果表明,模型3显著降低了移植物与胫骨之间的摩擦负荷,突出了其生物力学优化潜力。进一步分析显示,模型3的胫骨平台米塞斯应力也最低(48.80 MPa)。然而,其PCL拉伸应力(69.71 MPa)显著高于模型1(41.03 MPa)和模型2(40.90 MPa),这表明虽然模型3最大限度地减少了摩擦依赖性,但它主要通过移植物张力传递负荷。

结论

与解剖区域中心点和Fanelli点重建PCL相比,软组织参考胫骨定位重建PCL方法的移植物承受更大的拉力,但与胫骨的摩擦力显著降低,能够减少与胫骨的接触磨损。这可以改善患者的长期预后。我们的研究为优化PCL重建中的隧道定位提供了关键的生物力学证据,推动了手术技术的进步。

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本文引用的文献

1
The tibial capsular reflection and septum in posterior compartment are safe and reliable soft-tissue landmark for tibial tunnel drilling in posterior cruciate ligament reconstruction.后交叉韧带重建中,胫骨关节囊反射和后室间隔是胫骨隧道钻取的安全可靠的软组织解剖标志。
Knee Surg Sports Traumatol Arthrosc. 2024 Jul;32(7):1682-1689. doi: 10.1002/ksa.12202. Epub 2024 Apr 23.
2
All-inside posterior cruciate ligament reconstruction - A systematic review of current practice.全关节镜下后交叉韧带重建——当前实践的系统评价
J Orthop. 2024 Apr 4;55:1-10. doi: 10.1016/j.jor.2024.03.041. eCollection 2024 Sep.
3
Rates of Subjective Failure After Both Isolated and Combined Posterior Cruciate Ligament Reconstruction: A Study From the Norwegian Knee Ligament Registry 2004-2021.
孤立后交叉韧带重建和联合后交叉韧带重建后主观失败率:2004-2021 年挪威膝关节韧带登记研究。
Am J Sports Med. 2024 May;52(6):1491-1497. doi: 10.1177/03635465241238461. Epub 2024 Mar 29.
4
A modified anatomical posterior cruciate ligament reconstruction technique using the posterior septum and posterior capsule as landmarks to position the low tibial tunnel.一种改良的解剖后交叉韧带重建技术,使用后隔室和后囊作为标志来定位胫骨隧道的低位。
BMC Musculoskelet Disord. 2024 Jan 18;25(1):73. doi: 10.1186/s12891-024-07176-9.
5
Morphometry of Posterior Cruciate Ligament in Knee joint - A Cadaveric Study.膝关节后交叉韧带的形态学研究-尸体研究。
Clin Ter. 2023 Nov-Dec;174(6):525-530. doi: 10.7417/CT.2023.5020.
6
Walking with a Posterior Cruciate Ligament Injury: A Musculoskeletal Model Study.后交叉韧带损伤后的行走:一项肌肉骨骼模型研究。
Bioengineering (Basel). 2023 Oct 11;10(10):1178. doi: 10.3390/bioengineering10101178.
7
Influence of the Tibial Tunnel Angle and Posterior Tibial Slope on "Killer Turn" during Posterior Cruciate Ligament Reconstruction: A Three-Dimensional Finite Element Analysis.胫骨隧道角度和胫骨后倾角对后交叉韧带重建术中“杀手弯”的影响:三维有限元分析
J Clin Med. 2023 Jan 19;12(3):805. doi: 10.3390/jcm12030805.
8
Biomechanical comparison of proximal, distal, and anatomic tibial tunnel for transtibial posterior cruciate ligament reconstruction.经胫骨后交叉韧带重建中近端、远端及解剖型胫骨隧道的生物力学比较
Proc Inst Mech Eng H. 2023 Jan;237(1):104-112. doi: 10.1177/09544119221135935. Epub 2022 Nov 25.
9
3D Killer Turn Angle in Transtibial Posterior Cruciate Ligament Reconstruction Is Determined by the Graft Turning Angle both in the Sagittal and Coronal Planes.3D 胫骨后交叉韧带重建中的“杀手转角”由矢状面和冠状面的移植物转角决定。
Orthop Surg. 2022 Sep;14(9):2298-2306. doi: 10.1111/os.13411. Epub 2022 Aug 3.
10
What Is the Maximum Tibial Tunnel Angle for Transtibial PCL Reconstruction? A Comparison Based on Virtual Radiographs, CT Images, and 3D Knee Models.胫骨隧道最大角度在经胫骨后交叉韧带重建中的应用:基于虚拟射线、CT 图像和 3D 膝关节模型的比较。
Clin Orthop Relat Res. 2022 May 1;480(5):918-928. doi: 10.1097/CORR.0000000000002111. Epub 2022 Jan 13.