| [1] Vadivelu S, Stewart TJ, Qu Y, et al. NG2+ progenitors derived from embryonic stem cells penetrate glial scar and promote axonal outgrowth into white matter after spinal cord injury. Stem Cells Transl Med. 2015;4(4):401-411.
[2] Lukovic D, Valdés-Sanchez L, Sanchez-Vera I, et al. Brief report: astrogliosis promotes functional recovery of completely transected spinal cord following transplantation of hESC-derived oligodendrocyte and motoneuron progenitors. Stem Cells. 2014; 32(2):594-599.
[3] Xue F, Wu EJ, Zhang PX, et al. Biodegradable chitin conduit tubulation combined with bone marrow mesenchymal stem cell transplantation for treatment of spinal cord injury by reducing glial scar and cavity formation. Neural Regen Res. 2015;10(1):104-111.
[4] Yin YM, Lu Y, Zhang LX, et al. Bone marrow stromal cells transplantation combined with ultrashortwave therapy promotes functional recovery on spinal cord injury in rats. Synapse. 201569 (3): 139-147.
[5] Miao X, Wu X, Shi W. Umbilical cord mesenchymal stem cells in neurological disorders: A clinical study. Indian J Biochem Biophys. 2015;52(2):140-146.
[6] Cheng H, Liu X, Hua R, et al. Clinical observation of umbilical cord mesenchymal stem cell transplantation in treatment for sequelae of thoracolumbar spinal cord injury. J Transl Med. 2014;12:253.
[7] 周继辉, 姚猛, 王岩松,等. 新型脊髓纳米组织工程支架的组织相容性[J]. 中国组织工程研究, 2013,17(21):3854-3861.
[8] Wang Y, Yao M, Zhou J, et al. The promotion of neural progenitor cells proliferation by aligned and randomly oriented collagen nanofibers through ?1 integrin/MAPK signaling pathway. Biomaterials. 2011;32(28):6737-6744.
[9] Yin Y, Huang P, Han Z, et al. Collagen Nanofibers Facilitated Presynaptic Maturation in Differentiated Neurons from Spinal-Cord-Derived Neural Stem Cells through MAPK/ERK1/ 2-Synapsin I Signaling Pathway. Biomacromolecules. 2014;15(7): 2449-2460.
[10] Lazebnik M, Singh M, Glatt P, et al. Biomimetic method for combining the nucleus pulposus and annulus fibrosus for intervertebral disc tissue engineering.J Tissue Eng Regen Med. 2011; 5(8): e179-e187.
[11] Vadala G, Sowa G, Hubert M,et al. Mesenchymal stem cells injection in degenerated intervertebral disc: cell leakage may induce osteophyte formation.J Tissue Eng Regen Med. 2012;6(5):348-355.
[12] Mizuno H, Roy AK, Vacanti CA, et al. Tissue-engineered composites of anulusfibrosus and nucleus pulposus for intervertebral disc replacement. Spine. 2004;29(12):1290-1297.
[13] 徐宏光,赵其纯,姜宗元,等.一氧化氮在腰椎间盘退变中的作用[J].颈腰痛杂志,2001,22(1):21-23.
[14] 徐宏光,丁国正,陈小虎,等.血管内皮生长因子165 重组质粒pcDNA/ V促兔椎体终板血管生成的实验观察[J].中华医学杂志,2012, 92(7): 491-495.
[15] 胡春江,徐宏光.磷酸化p38MAPK及ANK在终板软骨细胞退变模型中表达的变化[J].皖南医学院学报,2011,30(2):112-114.
[16] 徐宏光,彭红心,程加峰,等.人颈椎椎体终板软骨细胞退变模型的建立及其意义[J].中华医学杂志,2011,91(41):2912-2916.
[17] 徐宏光,章平治,宋俊兴,等.循环机械压力诱导下兔椎间盘退变器官模型的建立及意义[J].中国骨与关节外科2014,7(1):45-51.
[18] Xu HG, Zhang XH, Wang H, et al. Intermittent cyclic mechanical tension-induced calcification and downregulation of ankh gene expression of end plate chondrocytes. Spine (Phila Pa 1976). 2012;37:1192e7.
[19] Xu HG, Yu YF, Zheng Q, et al. Autophagy protects end plate chondrocytes from intermittent cyclic mechanical tension induced calcification.Bone.2014;66:232-239.
[20] Xu HG,Zheng Q,Song JX,et al. Intermittent cyclic mechanical tension promotes endplate cartilage degeneration via canonical Wnt signaling pathway and E-cadherin/β-catenin complex cross-talk. Osteoarthritis Cartilage. 2015; pii: S1063-4584(15) 01262-5.
[21] 鞠浩,张建勋,安刚,等.机器人辅助脊柱微创手术系统设计与实现[J].南开大学学报(自然科学版),2008,41(4):31-35.
[22] 宋银灏,安刚,张建勋,等.脊柱微创手术机器人运动控制系统的设计.计算机工程与应用,2010,46(14):58-61.
[23] 张春霖,杨通宝,朱红鹤,等.比较两种前段膨胀椎间融合器在椎间盘镜下治疗腰椎不稳症的生物力学特点[J].中国组织工程研究, 2012, 16(9):1639-1642 .
[24] 李莹,曾昭峰,张春霖,等.可膨胀桥拱式椎间融合器的生物学特性[J].中国组织工程研究, 2014,18(22):3593-3596.
[25] Wang Y, Xie J, Yang Z, et al. Computed tomography assessment of lateral pedicle wall perforation by free hand subaxial cervical pedicle screw placement. Arch Orthop Trauma Surg. 2013; 133(7):901-909.
[26] 解京明,张漾杰,鲁宁,等.下颈椎经椎弓根螺钉内固定相关解剖学观察[J].脊柱外科杂志,2006,4(6):354-358.
[27] 杨振东,解京明,王迎松,等.下颈椎椎弓根螺钉技术外侧壁穿破相关因素分析[J].中华创伤杂志,2011,8(8):123-126.
[28] 王迎松,杨振东,解京明,等.下颈椎椎弓根螺钉并发症分析[J].中华创伤杂志,2010,26(7):141-146.
[29] Vaccaro AR, Oner C, Kepler CK, et al. AOSpine thoracolumbar spine injury classification system. Fracture description, neurological staus, and key modifiers. Spine. 2013;38(23):2028-2037.
[30] Gepstein R, Werner D, Shabat S, et al. Percutaneous posterior lumbar interbody fusion using the B-twin expandable spinal spacer. Minim Invasive Neurosurg. 2005;48(6):330-333.
[31] 陈远武,张德仁,肖礼祖,等.局麻下经皮应用膨胀式腰椎间隙融合术治疗腰椎退变性疾病的临床研究[J].脊柱外科杂志,2006,12(6): 343-346.
[32] Morgenstern R, Morgenstern C. Percutaneous Transforaminal Lumbar Interbody Fusion (pTLIF) with a Posterolateral Approach for the Treatment of Denegerative Disk Disease: Feasibility and Preliminary Results. Int J Spine Surg. 2015;9:41.
[33] MacCollin M, Chiocca EA, Evans DG, et al. Diagnostic criteria for schwannomatosis. Neurology. 2005; 64: 1838-1845.
[34] Baser ME, Friedman JM, Evans DG. Increasing the specificity of diagnostic criteria for schwannomatosis. Neurology. 2006; 66: 730-732.
[35] Jacoby LB, Jones D, Davis K, et al. Molecular analysis of the NF2 tumor-suppressor gene in schwannomatosis. Am J Hum Genet. 1997; 61: 1293-1302.
[36] Hulsebos TJ, Plomp AS, Wolterman RA, et al. Germline mutation of INI1/SMARCB1 in familial schwannomatosis. Am J Hum Genet. 2007; 80: 805-810.
[37] Piotrowski A, Xie J, Liu YF, et al. Germline loss-of-function mutations in LZTR1 predispose to an inherited disorder of multiple schwannomas. Nat Genet. 2014; 46: 182-187.
[38] Smith MJ, Isidor B, Beetz C, et al. Mutations in LZTR1 add to the complex heterogeneity of schwannomatosis. Neurology. 2015; 84:141-147.
[39] 王辉,马雷,丁文元,等.改良PVCR治疗胸腰段先天性契形椎引起脊柱后凸畸形的疗效分析[J] .中华解剖与临床杂志,2014,19(4): 275-279.
[40] 王辉,马雷,张迪,等.后方单侧截骨入路椎体大部分切除固定矫形术治疗陈旧性胸腰段椎体压缩骨折伴后凸畸形[J]. 中华创伤骨科杂志, 2015, 17(6): 492-496.
[41] Wang H, Ma L, Yang DL, et al. Comparison of clinical and radiological improvement between the modified trephine and high-speed drill as main osteotomy instrusment in pedicle subtraction osteotomy. Medicine. 2015. |
