Department of Neurological Surgery and.
Head and Neck Research Lab, Cleveland Clinic;
J Neurosurg Spine. 2015 Aug;23(2):170-7. doi: 10.3171/2014.12.SPINE131112. Epub 2015 May 15.
OBJECT The degenerative process of the spinal column results in instability followed by a progressive loss of segmental motion. Segmental degeneration is associated with intervertebral disc and facet changes, which can be quantified. Correlating this degeneration with clinical segmental motion has not been investigated in the thoracic spine. The authors sought to determine if imaging-determined degeneration would correlate with native range of motion (ROM) or the change in ROM after decompressive procedures, potentially guiding clinical decision making in the setting of spine trauma or following decompressive procedures in the thoracic spine. METHODS Multidirectional flexibility tests with image analysis were performed on thoracic cadaveric spines with intact ib cage. Specimens consisted of 19 fresh frozen human cadaveric spines, spanning C-7 to L-1. ROM was obtained for each specimen in axial rotation (AR), flexion-extension (FE), and lateral bending (LB) in the intact state and following laminectomy, unilateral facetectomy, and unilateral costotransversectomy performed at either T4-5 (in 9 specimens) or T8-9 (in 10 specimens). Image grading of segmental degeneration was performed utilizing 3D CT reconstructions. Imaging scores were obtained for disc space degeneration, which quantified osteophytes, narrowing, and endplate sclerosis, all contributing to the Lane disc summary score. Facet degeneration was quantified using the Weishaupt facet summary score, which included the scoring of facet osteophytes, narrowing, hypertrophy, subchondral erosions, and cysts. RESULTS The native ROM of specimens from T-1 to T-12 (n = 19) negatively correlated with age in AR (Pearson's r coefficient = -0.42, p = 0.070) and FE (r = -0.42, p = 0.076). When regional ROM (across 4 adjacent segments) was considered, the presence of disc osteophytes negatively correlated with FE (r = -0.69, p = 0.012), LB (r = -0.82, p = 0.001), and disc narrowing trended toward significance in AR (r = -0.49, p = 0.107). Facet characteristics, scored using multiple variables, showed minimal correlation to native ROM (r range from -0.45 to +0.19); however, facet degeneration scores at the surgical level revealed strong negative correlations with regional thoracic stability following decompressive procedures in AR and LB (Weishaupt facet summary score: r = -0.52 and r = -0.71; p = 0.084 and p = 0.010, respectively). Disc degeneration was not correlated (Lane disc summary score: r = -0.06, p = 0.861). CONCLUSIONS Advanced age was the most important determinant of decreasing native thoracic ROM, whereas imaging characteristics (T1-12) did not correlate with the native ROM of thoracic specimens with intact rib cages. Advanced facet degeneration at the surgical level did correlate to specimen stability following decompressive procedures, and is likely indicative of the terminal stages of segmental degeneration.
脊柱退行性变导致不稳定,随后节段运动逐渐丧失。节段性退变与椎间盘和小关节变化有关,这些变化可以量化。在胸段脊柱中,尚未研究与临床节段运动相关的退行性变。作者试图确定影像学确定的退行性变是否与固有运动范围(ROM)或减压手术后的 ROM 变化相关,这可能有助于指导脊柱创伤或减压手术后的胸段脊柱的临床决策。
对具有完整肋骨笼的胸段尸体脊柱进行多方向柔韧性测试和图像分析。标本包括 19 个新鲜冷冻的人体尸体脊柱,范围从 C-7 到 L-1。在完整状态下以及在 T4-5(9 个标本)或 T8-9(10 个标本)进行椎板切除术、单侧小关节切除术和单侧肋横突切除术之后,获得每个标本在轴向旋转(AR)、屈伸(FE)和侧屈(LB)的 ROM。利用 3D CT 重建对节段性退变进行图像分级。利用 Lane 椎间盘综合评分量化椎间盘间隙退变,该评分量化了骨赘、狭窄和终板硬化,所有这些都导致了 Lane 椎间盘综合评分。利用 Weishaupt 小关节综合评分量化小关节退变,该评分包括小关节骨赘、狭窄、肥大、软骨下侵蚀和囊肿的评分。
T-1 至 T-12 节段标本的固有 ROM(n = 19)与 AR(Pearson r 系数=-0.42,p = 0.070)和 FE(r = -0.42,p = 0.076)的年龄呈负相关。当考虑到区域 ROM(跨越 4 个相邻节段)时,椎间盘骨赘的存在与 FE(r = -0.69,p = 0.012)、LB(r = -0.82,p = 0.001)呈负相关,椎间盘狭窄在 AR 中呈趋势与显著性相关(r = -0.49,p = 0.107)。使用多个变量评分的小关节特征与固有 ROM 相关性最小(r 范围为-0.45 至+0.19);然而,减压手术后在 AR 和 LB 中,手术水平的小关节退变评分与胸段稳定性呈强烈负相关(Weishaupt 小关节综合评分:r = -0.52 和 r = -0.71;p = 0.084 和 p = 0.010)。椎间盘退变与固有 ROM 不相关(Lane 椎间盘综合评分:r = -0.06,p = 0.861)。
年龄是影响胸段固有 ROM 降低的最重要因素,而影像学特征(T1-12)与具有完整肋骨笼的胸段标本的固有 ROM 不相关。手术水平的高级小关节退变与减压手术后的标本稳定性相关,这可能表明节段退变已进入晚期。
