Image anatomy of percutaneous retrograde screw fixation of acetabular posterior column

YU Ke-Quan; GAO Shi-Chang; CHEN Jian-Fei; WU Min

doi:10.16098/j.issn.0529-1356.2020.01.014

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Acta Anatomica Sinica ›› 2020, Vol. 51 ›› Issue (1) : 78-85. DOI: 10.16098/j.issn.0529-1356.2020.01.014

Anatomy

Image anatomy of percutaneous retrograde screw fixation of acetabular posterior column

YU Ke-quan¹ GAO Shi-chang^1* CHEN Jian-fei¹ WU Min²

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Abstract

Objective To investigate the position, direction and fixation range of retrograde screw of the posterior column of acetabulum based on CT data. Methods Totally 100 cases (50 males, 50 females) of normal adult pelvic CT data were collected from the First Affilated Hospital of Chongqing Medical University. The pelvis was reconstructed by Mimics 17.0 software and imported into Geomagic Studio 2015 software. The virtual screw was placed in the posterior column from the ischial tuberosity to the iliac fossa, the maximum diameter, the entrance point, the exit point，the direction, safe fixation inclination angles of the screw were measured. The range of the screw fixing，the best fluoroscopic views and the easy-to-penetrate site of the screw in the posterior column were assessed. Results The safe corridor the posterior column of the acetabulum was similar to the “triangular prism” shape. The entrance point was located on the midline of the medial edge and lateral edge of the ischial tuberosity, which were (12.99±1.99) mm in male and (13.26±2.58) mm in female from farthest end of the ischial tuberosity. There were no stitistical significant differences between male and female(P>0.05). The exit points was located at the iliac fossa, which were (23.65±2.42)mm in male and (24.94±2.39) mm in female to the ipsilateral anterior sacroiliac joint line,and (19.33±2.60)mm in male and (17.63±2.00) mm in female to the arcus marginalis. The maximum diameters of screw were (17.21±1.41) mm in male and (15.54±1.51) mm in female. The angles between screw and coronal plane were (15.00±4.92)° in male and (12.94±4.72)° in female; the angles between screw and sagittal plane were (10.52±3.04)° in male and (7.72±2.99)° in female. The abore data had statistially significant differences between male and female (P<0.05). Percutaneous retrograde screw could fix the acetabular posterior column fracture that below the 4.0 cm proximal the horizontal plane of the femoral head center. The easy-to-penetrate sites were the junction of the acetabular posterior wall and the sciatic branch，the middle part of the acetabulum, and below 1.0 cm of the highest point of greater sciatic notch. The tangential position of three lateral faces of the “triangular prism” were ilium oblique position 10°, the ilium oblique position 60°, and obturator oblique position 60°. Conclusion The entrance point of the retrograde screw is located on the midline of the ischial tuberosity, which is 1.3 cm from farthest end of the ischial tuberosity and the direction is forward inclination about 15°, external inclination about 10°. The acetabular posterior column fracture that below 4.0 cm proximal plane to the femoral head center can be fixed by the retrograde screw.

Key words

Acetabular Posterior Column / Retrograde screw / Image anatomy / Human

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YU Ke-quan GAO Shi-chang CHEN Jian-fei WU Min. Image anatomy of percutaneous retrograde screw fixation of acetabular posterior column[J]. Acta Anatomica Sinica. 2020, 51(1): 78-85 https://doi.org/10.16098/j.issn.0529-1356.2020.01.014

References

［1］ Wright RD Jr, Hamilton DA Jr, Moghadamian ES, et al. Use of the obturator-outlet oblique view to guide percutaneous retrograde posterior column screw placement［J］. J Orthop Trauma, 2013, 27(6): e141-143.

［2］ Lin YC, Chen CH, Huang HT, et al. Percutaneous antegrade screwing for anterior column fracture of acetabulum with fluoroscopic-based computerized navigation［J］. Arch Orthop Trauma Surg, 2008, 128(2): 223-226.

［3］ Zheng Q, Liao ShH, Shi ShY, et al. The optimal computer aided design for lag screw internal fixation in the posterior column of the acetabulum［J］. Acta Anatomica Sinica, 2008, 39(2):238-242. (in Chinese)

郑琦, 廖胜辉, 石仕元, 等. 优化髋臼后柱螺钉内固定的计算机辅助设计［J］. 解剖学报, 2008,39(2):238-242.

［4］ Chen W, Zhang Z, Lu Y, et al. Fluoroscopic views for safe insertion of lag screws into the posterior column of the acetabulum［J］. BMC Musculoskelet Disord, 2014, 15:-303.

［5］ Azzam K, Siebler J, Bergmann K, et al. Percutaneous retrograde posterior column acetabular fixation: is the sciatic nerve safe? A cadaveric study［J］. J Orthop Trauma, 2014, 28(1): 37-40.

［6］ Zhang P, Tang J, Dong Y, et al. A new navigational apparatus for fixation of acetabular posterior column fractures with percutaneous retrograde lagscrew: design and application［J］. Medicine (Baltimore), 2018,97(36): e12134.

［7］ Mouhsine E, Garofalo R, Borens O, et al. Percutaneous retrograde screwing for stabilisation of acetabular fractures［J］. Injury, 2005,36(11): 1330-1336.

［8］ Lai JQ, Cao ShL, Wang YR, et al. Anatomy and radiology of the back zone of acetabular posterior column ［J］. Chinese Journal of Orthopaedic Trauma， 2015，17(5): 369-373. (in Chinese)

赖剑强, 曹生鲁, 汪祎然, 等. 髋臼后柱后区的解剖学和影像学研究［J］. 中华创伤骨科杂志，2015，17(5): 369-373.

［9］ Feng X, Sheng Z, Qiang L, et al. Definition of a safe zone for antegrade lag screw fixation of fracture of posterior column of the acetabulum by 3D technology［J］. Injury, 2016, 47(3): 702-706.

［10］Wang QX, Zhang YZ, Pan JSh, et al. Applied anatomy of retrograde lag screw internal fixation in the posterior column of the acetabulum［J］. Chinese Journal of Clinical Anatomy, 2006,24(1):38-40. (in Chinese)

王庆贤, 张英泽, 潘进社,等. 逆行髋臼后柱拉力螺钉内固定的应用解剖学［J］. 中国临床解剖学杂志, 2006, 24(1): 38-40.

［11］Yi C, Burns S, Hak DJ. Intraoperative fluoroscopic evaluation of screw placement during pelvic and acetabular surgery［J］. J Orthop Trauma, 2013, 28(1): 48-56.

［12］Mu WD, Wang XQ, Jia TH, et al. Quantitative anatomic basis of antegrade lag screw placement in posterior column of acetabulum［J］. Arch Orthop Trauma Surg, 2009, 129(11): 1531-1537.

［13］Mosheiff R, Khoury A, Weil Y, et al. First generation computerized fluoroscopic navigation in percutaneous pelvic surgery［J］. J Orthop Trauma,2004,18(2): 106-111.

［14］Xu P, Wang H, Liu ZY, et al. An evaluation of three-dimensional image-guided technologies in percutaneous pelvic and acetabular lag screw placement［J］. J Surg Res, 2013,185(1): 338-346.

［15］Wong JSY, Lau JCH, Chui KH, et al. Three-dimensional-guided navigation percutaneous screw fixation of fragility fractures of the pelvis［J］. J Orthop Surg (Hong Kong), 2019,27(1):2309499019833897.

［16］Schaefer TK, Spross C, Stoffel KK, et al. Biomechanical properties of a posterior fully threaded positioning screw for cannulated screw fixation of displaced neck of femur fractures［J］. Injury, 2015,46(11):2130-2133.

［17］Dragoni M, Heiner AD, Costa S, et al. Biomechanical study of 16-mm threaded, 32-mm threaded, and fully threaded SCFE screw fixation［J］. J Pediatr Orthop, 2012,32(1):70-74.