Ye Jichao, Rider Sean M, Lafage Renaud, Gupta Sachin, Farooqi Ali S, Protopsaltis Themistocles S, Passias Peter G, Smith Justin S, Lafage Virginie, Kim Han-Jo, Klineberg Eric O, Kebaish Khaled M, Scheer Justin K, Mundis Gregory M, Soroceanu Alex, Bess Shay, Ames Christopher P, Shaffrey Christopher I, Gupta Munish C
1Department of Orthopaedic Surgery, Sun Yat-sen Memorial Hospital, Sun Yat-sen University, Guangzhou, Guangdong Province, China.
13Department of Orthopaedic Surgery, Washington University, St. Louis, Missouri; and.
J Neurosurg Spine. 2023 Mar 24;39(1):1-10. doi: 10.3171/2023.2.SPINE221295. Print 2023 Jul 1.
The objective of this study was to evaluate spinopelvic sagittal alignment and spinal compensatory changes in adult cervical kyphotic deformity.
A database composed of 13 US spine centers was retrospectively reviewed for adult patients who underwent cervical reconstruction with radiographic evidence of cervical kyphotic deformity: C2-7 sagittal vertical axis > 4 cm, chin-brow vertical angle > 25°, or cervical kyphosis (T1 slope [T1S] cervical lordosis [CL] > 15°) (n = 129). Sagittal parameters were evaluated preoperatively and in the early postoperative window (6 weeks to 6 months postoperatively) and compared with asymptomatic control patients. Adult cervical deformity patients were further stratified by degree of cervical kyphosis (severe kyphosis, C2-T3 Cobb angle ≤ -30°; moderate kyphosis, ≤ 0°; and minimal kyphosis, > 0°) and severity of sagittal malalignment (severe malalignment, sagittal vertical axis T3-S1 ≤ -60 mm; moderate malalignment, ≤ 20 mm; and minimal malalignment > 20 mm).
Compared with asymptomatic control patients, cervical deformity was associated with increased C0-2 lordosis (32.9° vs 23.6°), T1S (33.5° vs 28.0°), thoracolumbar junction kyphosis (T10-L2 Cobb angle -7.0° vs -1.7°), and pelvic tilt (PT) (19.7° vs 15.9°) (p < 0.01). Cervicothoracic kyphosis was correlated with C0-2 lordosis (R = -0.57, p < 0.01) and lumbar lordosis (LL) (R = -0.20, p = 0.03). Cervical reconstruction resulted in decreased C0-2 lordosis, increased T1S, and increased thoracic and thoracolumbar junction kyphosis (p < 0.01). Patients with severe cervical kyphosis (n = 34) had greater C0-2 lordosis (p < 0.01) and postoperative reduction of C0-2 lordosis (p = 0.02) but no difference in PT. Severe cervical kyphosis was also associated with a greater increase in thoracic and thoracolumbar junction kyphosis postoperatively (p = 0.01). Patients with severe sagittal malalignment (n = 52) had decreased PT (p = 0.01) and increased LL (p < 0.01), as well as a greater postoperative reduction in LL (p < 0.01).
Adult cervical deformity is associated with upper cervical hyperlordotic compensation and thoracic hypokyphosis. In the setting of increased kyphotic deformity and sagittal malalignment, thoracolumbar junction kyphosis and lumbar hyperlordosis develop to restore normal center of gravity. There was no consistent compensatory pelvic retroversion or anteversion among the adult cervical deformity patients in this cohort.
本研究的目的是评估成人颈椎后凸畸形患者的脊柱骨盆矢状位对线及脊柱代偿性变化。
回顾性分析由13个美国脊柱中心组成的数据库中接受颈椎重建且有颈椎后凸畸形影像学证据的成年患者:C2-7矢状垂直轴>4cm、颏眉垂直角>25°或颈椎后凸(T1斜率[T1S] -颈椎前凸[CL]>15°)(n = 129)。术前及术后早期(术后6周-6个月)评估矢状位参数,并与无症状对照患者进行比较。成年颈椎畸形患者根据颈椎后凸程度(严重后凸,C2-T3 Cobb角≤-30°;中度后凸,≤0°;轻度后凸,>0°)和矢状位排列不齐的严重程度(严重排列不齐,矢状垂直轴T3-S1≤-60mm;中度排列不齐,≤20mm;轻度排列不齐>20mm)进一步分层。
与无症状对照患者相比,颈椎畸形与C0-2前凸增加(32.9°对23.6°)、T1S(33.5°对28.0°)、胸腰段交界性后凸(T10-L2 Cobb角-7.0°对-1.7°)及骨盆倾斜(PT)增加(19.7°对15.9°)相关(p<0.01)。颈胸段后凸与C0-2前凸(R = -0.57,p<0.01)及腰椎前凸(LL)(R = -0.20,p = 0.03)相关。颈椎重建导致C0-2前凸减小、T1S增加及胸段和胸腰段交界性后凸增加(p<0.01)。严重颈椎后凸患者(n = 34)C0-2前凸更大(p<0.01)且术后C0-2前凸减小(p = 0.02),但PT无差异。严重颈椎后凸还与术后胸段和胸腰段交界性后凸更大增加相关(p = 0.01)。严重矢状位排列不齐患者(n = 52)PT减小(p = 0.01)、LL增加(p<0.01),且术后LL减小更明显(p<0.01)。
成人颈椎畸形与上位颈椎过度前凸代偿及胸段后凸减小相关。在颈椎后凸畸形和矢状位排列不齐增加的情况下,胸腰段交界性后凸和腰椎过度前凸发展以恢复正常重心。该队列中的成年颈椎畸形患者中没有一致的代偿性骨盆后倾或前倾。
