【 摘 要 】

Background

Laminar screws and lateral mass screws have been increasingly used in the treatment of cervical diseases. The purpose of this study is to determine the morphological characteristics of the posterior anatomical structures of the subaxial cervical vertebrae in a northeastern Chinese population.

Methods

Sixty-one consecutive patients underwent cervical spine computed tomography (CT). We analyzed a total of 610 axial images and 61 sagittal images. The following parameters were measured: lamina outer width (LOW), lamina inner width (LIW), lamina axis length (LAL), lamina transverse angle (LTA), lateral mass longitudinal diameter (LMLD), lateral mass transverse diameter (LMTD), sagittal spinous process length (SSPL), axial spinous process length (ASPL), spinal canal transverse diameter (SCTD), spinal canal longitudinal diameter (SCLD), osseous spinal canal area (OSCA), and Pavlov ratio (PR). The participants were classified into male and female groups and developmental canal stenosis (DCS; PR ≤0.75) and non-DCS (NDCS; PR >0.75) groups.

Results

Significant differences were observed among the different vertebral levels for almost all evaluated parameters, except for LTA and OSCA. Statistical differences were found between the right and left sides in all parameters, except for LIW and LOW. All linear parameters, except for SCLD and the angular parameter LTA, significantly differed between the sexes. Significant differences were found between the DCS and NDCS groups in terms of all parameters, except for SCTD.

Conclusions

Various measurements of the posterior structures of subaxial cervical vertebrae differed between the left and right sides, females and males, and the DCS and NDCS groups. Different techniques for lateral mass screw insertion should be used according to different vertebral level. Only C7 laminar may be able to safely accommodate a 2.5-mm translaminar screw. The study data can help doctors to make better surgical decisions and develop more appropriate implants for northeastern Chinese patients.

【 授权许可】

   
2015 Wang et al.; licensee BioMed Central.

【 预 览 】

附件列表

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【 图 表 】

【 参考文献 】

• [1]Abumi K, Shono Y, Taneichi H, Ito M, Kaneda K: Correction of cervical kyphosis using pedicle screw fixation systems. Spine (Phila Pa 1976) 1999, 24(22):2389-2396.
• [2]Hong JT, Sung JH, Son BC, Lee SW, Park CK: Significance of laminar screw fixation in the subaxial cervical spine. Spine (Phila Pa 1976) 2008, 33(16):1739-1743.
• [3]Ilgenfritz RM, Gandhi AA, Fredericks DC, Grosland NM, Smucker JD: Considerations for the use of C7 crossing laminar screws in subaxial and cervicothoracic instrumentation. Spine (Phila Pa 1976) 2013, 38(4):E199-E204.
• [4]Korres DS, Benetos IS, Tsailas PG: Lateral mass screw fixation for cervical spine trauma. Spine J 2006, 6(5):603.
• [5]Sciubba DM, Noggle JC, Vellimana AK, Conway JE, Kretzer RM, Long DM, et al.: Laminar screw fixation of the axis. J Neurosurg 2008, 8(4):327-334.
• [6]Senoglu M, Ozkan F, Celik M: Placement of C-7 intralaminar screws: a quantitative anatomical and morphometric evaluation. J Neurosurg Spine 2012, 16(5):509-512.
• [7]Kayalioglu G, Erturk M, Varol T, Cezayirli E: Morphometry of the cervical vertebral pedicles as a guide for transpedicular screw fixation. Neurol Med Chir (Tokyo) 2007, 47(3):102-107.
• [8]Yusof MI, Ming LK, Abdullah MS: Computed tomographic measurement of cervical pedicles for transpedicular fixation in a Malay population. J Orthop Surg (Hong Kong). 2007, 15(2):187-190.
• [9]Sieradzki JP, Karaikovic EE, Lautenschlager EP, Lazarus ML: Preoperative imaging of cervical pedicles: comparison of accuracy of oblique radiographs versus axial CT scans. Eur Spine J 2008, 17(9):1230-1236.
• [10]Abuzayed B, Tutunculer B, Kucukyuruk B, Tuzgen S: Anatomic basis of anterior and posterior instrumentation of the spine: morphometric study. Surg Radiol Anat 2010, 32(1):75-85.
• [11]Nakanishi K, Tanaka M, Sugimoto Y, Misawa H, Takigawa T, Fujiwara K, et al.: Application of laminar screws to posterior fusion of cervical spine: measurement of the cervical vertebral arch diameter with a navigation system. Spine (Phila Pa 1976) 2008, 33(6):620-623.
• [12]Alvin MD, Abdullah KG, Steinmetz MP, Lubelski D, Nowacki AS, Benzel EC, et al.: Translaminar screw fixation in the subaxial cervical spine: quantitative laminar analysis and feasibility of unilateral and bilateral translaminar virtual screw placement. Spine (Phila Pa 1976) 2012, 37(12):E745-E751.
• [13]Abumi K, Shono Y, Ito M, Taneichi H, Kotani Y, Kaneda K: Complications of pedicle screw fixation in reconstructive surgery of the cervical spine. Spine 2000, 25(8):962-969.
• [14]Kotil K, Akcetin MA, Savas Y: Neurovascular complications of cervical pedicle screw fixation. J Clin Neurosci 2012, 19(4):546-551.
• [15]Nakashima H, Yukawa Y, Imagama S, Kanemura T, Kamiya M, Yanase M, et al.: Complications of cervical pedicle screw fixation for nontraumatic lesions: a multicenter study of 84 patients. J Neurosurg Spine 2012, 16(3):238-247.
• [16]Neo M, Sakamoto T, Fujibayashi S, Nakamura T: The clinical risk of vertebral artery injury from cervical pedicle screws inserted in degenerative vertebrae. Spine 2005, 30(24):2800-2805.
• [17]Tan SH, Teo EC, Chua HC: Quantitative three-dimensional anatomy of cervical, thoracic and lumbar vertebrae of Chinese Singaporeans. Eur Spine J 2004, 13(2):137-146.
• [18]Cruz JJB, Larios AG, Sanchez AG, Silva EEV: Morphometric study of cervical vertebrae C3-C7 in a population from northeastern Mexico. Int J Morphol 2011, 29(2):325-330.
• [19]Xin-yu L, Kai Z, Laing-tai G, Yan-ping Z, Jian-min L: The anatomic and radiographic measurement of C2 lamina in Chinese population. Eur Spine J 2011, 20(12):2261-2266.
• [20]Patwardhan AR, Nemade PS, Bhosale SK, Srivastava SK: Computed tomography-based morphometric analysis of cervical pedicles in Indian population: a pilot study to assess feasibility of transpedicular screw fixation. J Postgrad Med 2012, 58(2):119-122.
• [21]Miyazaki M, Takita C, Yoshiiwa T, Itonaga I, Tsumura H: Morphological analysis of the cervical pedicles, lateral masses, and laminae in developmental canal stenosis. Spine 2010, 35(24):E1381-E1385.
• [22]Yusof MI, Ming LK, Abdullah MS, Yusof AH: Computerized tomographic measurement of the cervical pedicles diameter in a Malaysian population and the feasibility for transpedicular fixation. Spine (Phila Pa 1976) 2006, 31(8):E221-E224.
• [23]Harris BM, Hilibrand AS, Nien YH, Nachwalter R, Vaccaro A, Albert TJ, et al.: A comparison of three screw types for unicortical fixation in the lateral mass of the cervical spine. Spine (Phila Pa 1976) 2001, 26(22):2427-2431.
• [24]Roy-Camille R, Saillant G, Laville C, Benazet JP: Treatment of lower cervical spinal injuries—C3 to C7. Spine (Phila Pa 1976) 1992, 17(10 Suppl):S442-S446.
• [25]Levine AM, Mazel C, Roy-Camille R: Management of fracture separations of the articular mass using posterior cervical plating. Spine (Phila Pa 1976) 1992, 17(10 Suppl):S447-S454.
• [26]Jeanneret B, Magerl F, Ward EH, Ward JC: Posterior stabilization of the cervical spine with hook plates. Spine (Phila Pa 1976) 1991, 16(3 Suppl):S56-S63.
• [27]Anderson PA, Henley MB, Grady MS, Montesano PX, Winn HR: Posterior cervical arthrodesis with AO reconstruction plates and bone graft. Spine (Phila Pa 1976) 1991, 16(3 Suppl):S72-S79.
• [28]An HS, Gordin R, Renner K: Anatomic considerations for plate-screw fixation of the cervical spine. Spine (Phila Pa 1976) 1991, 16(10 Suppl):S548-S551.
• [29]Wu JC, Huang WC, Chen YC, Shih YH, Cheng H. Stabilization of subaxial cervical spines by lateral mass screw fixation with modified Magerl’s technique. Surg Neurol. 2008;70 Suppl 1:25–33. discussion S1: doi:S0090-3019(08)00179-.
• [30]Hockel K, Maier G, Rathgeb J, Merkle M, Roser F: Morphometric subaxial lateral mass evaluation allows for preoperative optimal screw trajectory planning. Eur Spine J 2014, 23(8):1705-1711.
• [31]Montesano PX, Juach EC, Anderson PA, Benson DR, Hanson PB: Biomechanics of cervical spine internal fixation. Spine (Phila Pa 1976) 1991, 16(3 Suppl):S10-S16.
• [32]Errico T, Uhl R, Cooper P, Casar R, McHenry T: Pullout strength comparison of two methods of orienting screw insertion in the lateral masses of the bovine cervical spine. J Spinal Disord 1992, 5(4):459-463.
• [33]Ji GY, Oh CH, Park SH, Kurniawan F, Lee J, Jeon JK, et al. Feasibility of translaminar screw placement in Korean population: morphometric analysis of cervical spine. Yonsei Med J. 2015;56(1):159–66. Doi: 201501159.
• [34]Abdullah KG, Steinmetz MP, Mroz TE: Morphometric and volumetric analysis of the lateral masses of the lower cervical spine. Spine (Phila Pa 1976) 2009, 34(14):1476-1479.
• [35]Panjabi MM, Duranceau J, Goel V, Oxland T, Takata K. Cervical human vertebrae. Quantitative three-dimensional anatomy of the middle and lower regions. Spine (Phila Pa 1976). 1991;16(8):86–9.
• [36]Stemper BD, Marawar SV, Yoganandan N, Shender BS, Rao RD: Quantitative anatomy of subaxial cervical lateral mass: an analysis of safe screw lengths for Roy-Camille and magerl techniques. Spine (Phila Pa 1976) 2008, 33(8):893-897.
• [37]Yusof MI, Shamsi SS: Translaminar screw fixation of the cervical spine in Asian population: feasibility and safety consideration based on computerized tomographic measurements. Surg Radiol Anat 2012, 34(3):203-207.