Verhaegen Jeroen C F, Innmann Moritz M, Merle Christian, Batista Nuno A, Phan Philippe, Grammatopoulos George
Division of Orthopaedic Surgery, The Ottawa Hospital, Ottawa, Ontario, Canada.
Department of Orthopaedic Surgery, University Hospital Antwerp, Edegem, Belgium.
Clin Orthop Relat Res. 2025 Sep 18. doi: 10.1097/CORR.0000000000003691.
Patients with stiff spines are at increased risk of instability after THA because of pelvic stiffness. Comprehensive study of patients with a stiff spine without hip arthritis could provide insight into native compensatory mechanisms and provide guidance on the mechanics to account for after arthroplasty.
QUESTIONS/PURPOSES: The primary aim of this study was to characterize static and dynamic compensatory mechanics that occur in the presence of either a stiff hip or stiff spine. The secondary study aims were to assess which spinopelvic imaging modalities would best uncouple compensation mechanisms and to test the effect of length of spinal fusion (that is, number of fused segments) on the existing compensatory mechanics.
This was a prospective, case-control study performed at two academic tertiary referral centers. The cohort studied included three groups: (1) the control group of asymptomatic volunteers without signs of hip osteoarthritis or history of spinal surgery (n = 52); (2) the hip group of patients with osteoarthritis treated with THA between 2018 and 2019 (n = 512), excluding those with age < 18 years (n = 2), BMI > 40 kg/m2 (n = 9), different diagnosis than osteoarthritis (n = 117), history of spinal or lower limb disease or surgery (n = 206), neurologic comorbidities (n = 17), absence of study consent (n = 20), or without spinopelvic radiographs (n = 17), in which the included patients (n = 124) were matched for age, sex, and BMI to the control group, resulting in the final hip group of 52 patients; and (3) the spine group were patients seen in clinic between 2023 and 2024 (n = 121), 1 year after spinal fusion, excluding those with BMI > 40 kg/m2 (n = 10), hip osteoarthritis or surgery (n = 16), neuromuscular disease (n = 1), spinal fusion not including lumbar spine (n = 1), or without spinopelvic radiographs (n = 41), leaving 52 patients. The whole cohort comprised 60% (93 of 156) females, and the mean ± SD age was 64 ± 11 years. All underwent standing, relaxed-, and deep-seated radiographs to determine static characteristics: lumbar lordosis, pelvic tilt, pelvic-femoral angle, and pelvic incidence. Dynamic characteristics included difference in pelvic tilt, lumbar lordosis, and pelvic-femoral angles between standing and relaxed- or deep-seated positions, thereby determining which imaging modality best uncoupled compensatory mechanisms. Correlation between the number of fused segments and spinopelvic parameters was assessed using Spearman correlation coefficient.
When standing, the spine group had a higher mean ± SD pelvic-femoral angle than the control (197° ± 7° versus 186° ± 10°, mean difference -11° [95% confidence interval (CI) -14° to -7°]; p < 0.001) and hip group (197° ± 7° versus 183° ± 11°, mean difference -14° [95% CI -18° to -10°]; p < 0.001) and a higher pelvic tilt compared with the control (20° ± 9° versus 15° ± 8°, mean difference -5° [95% CI -8° to -2°]; p = 0.003) and hip group (20° ± 9° versus 15° ± 7°, mean difference -5° [95% CI -9° to -2°]; p = 0.004). Dynamically, the spine group exhibited the least lumbar flexion (ΔLL) in both relaxed- (12° ± 11° versus 22° ± 12° versus 16° ± 12°; p = 0.002) and deep-seated transitions (25° ± 14° versus 43° ± 13° versus 43° ± 13°; p < 0.001). Between standing and deep-seated, change in pelvic tilt was greater in the spine group compared with the hip (20° ± 16° versus -6° ± 16°, mean difference -28° [95% CI -33° to -22°]; p < 0.001) and control group (20° ± 16° versus 4° ± 17°, mean difference -19° [95% CI -26° to -13°]; p < 0.001). Deep-seated, the spine group flexed the hip more than the hip group (109° ± 15° versus 70° ± 21°, mean difference -40° [95% CI -47° to -34°]; p < 0.001) and control group (109° ± 15° versus 85° ± 18°, mean difference -23° [95% CI -30° to -16°]; p < 0.001). Standing to deep-seated assessments better uncoupled compensatory mechanisms, as these detected differences between control and spine group (for instance, ∆LL standing/deep-seated 43° ± 13° versus 25° ± 14° [mean difference 19° (95% CI 14° to 25°); p < 0.001] versus ∆LL standing/relaxed-seated 16° ± 12° versus 12° ± 11° [mean difference 4° (95% CI 0° to 9°); p = 0.15]). The number of segments fused was associated with deep-seated lumbar lordosis (ρ = 0.55; p < 0.001) and pelvic tilt (ρ = -0.31; p = 0.02).
In this study, patients with a stiff spine have hyperextended hips when standing and hyperflexed hips in a deep-seated position and exhibit a fivefold greater change in pelvic tilt between these positions compared with controls. The greater pelvic tilt change may cause an acetabular cup to be brought in a functionally suboptimal orientation, leading to impingement or dislocation. Deep-seated radiographs can uncouple compensatory mechanisms and are recommended to better identify patients with spinal stiffness.
Level II, diagnostic study.
由于骨盆僵硬,脊柱僵硬的患者在全髋关节置换术后发生不稳定的风险增加。对无髋关节炎的脊柱僵硬患者进行全面研究,有助于深入了解天然的代偿机制,并为关节置换术后的力学分析提供指导。
问题/目的:本研究的主要目的是描述在存在僵硬髋关节或僵硬脊柱的情况下发生的静态和动态代偿力学。次要研究目的是评估哪种脊柱骨盆成像方式能最好地分离代偿机制,并测试脊柱融合长度(即融合节段数)对现有代偿力学的影响。
这是一项在两个学术三级转诊中心进行的前瞻性病例对照研究。研究队列包括三组:(1)无症状志愿者对照组,无髋骨关节炎体征或脊柱手术史(n = 52);(2)髋关节组,2018年至2019年间接受全髋关节置换术治疗的骨关节炎患者(n = 512),排除年龄<18岁(n = 2)、体重指数>40 kg/m²(n = 9)、诊断不同于骨关节炎(n = 117)、有脊柱或下肢疾病或手术史(n = 206)、有神经合并症(n = 17)、未签署研究同意书(n = 20)或无脊柱骨盆X线片(n = 17)的患者,其中纳入的患者(n = 124)在年龄、性别和体重指数方面与对照组匹配,最终髋关节组为52例患者;(3)脊柱组为2023年至2024年间在诊所就诊的患者(n = 121),脊柱融合术后1年,排除体重指数>40 kg/m²(n = 10)、髋骨关节炎或手术史(n = 16)、神经肌肉疾病(n = 1)、脊柱融合不包括腰椎(n = 1)或无脊柱骨盆X线片(n = 41)的患者,剩余52例患者。整个队列中女性占60%(156例中的93例),平均年龄±标准差为64±11岁。所有患者均接受站立位、放松位和深蹲位X线片检查,以确定静态特征:腰椎前凸、骨盆倾斜、骨盆股骨角和骨盆入射角。动态特征包括站立位与放松位或深蹲位之间骨盆倾斜、腰椎前凸和骨盆股骨角的差异,从而确定哪种成像方式能最好地分离代偿机制。使用Spearman相关系数评估融合节段数与脊柱骨盆参数之间的相关性。
站立时,脊柱组的平均±标准差骨盆股骨角高于对照组(197°±7°对186°±10°,平均差异-11°[95%置信区间(CI)-14°至-7°];p<0.001)和髋关节组(197°±7°对183°±11°,平均差异-14°[95%CI-18°至-10°];p<0.001),与对照组(20°±9°对15°±8°,平均差异-5°[95%CI-8°至-2°];p = 0.003)和髋关节组(20°±9°对15°±7°,平均差异-5°[95%CI-9°至-2°];p = 0.004)相比,骨盆倾斜度更高。在动态方面,脊柱组在放松位(12°±11°对22°±12°对16°±12°;p = 0.002)和深蹲位转换(25°±14°对43°±13°对43°±13°;p<0.001)时腰椎前屈最小。在站立位和深蹲位之间,脊柱组的骨盆倾斜度变化大于髋关节组(20°±16°对-6°±16°,平均差异-28°[95%CI-33°至-22°];p<0.001)和对照组(20°±16°对4°±17°,平均差异-19°[95%CI-26°至-13°];p<0.001)。在深蹲位时,脊柱组的髋关节屈曲度大于髋关节组(109°±15°对70°±21°,平均差异-40°[95%CI-47°至-34°];p<0.001)和对照组(109°±15°对85°±18°,平均差异-23°[95%CI-30°至-16°];p<0.001)。站立位到深蹲位的评估能更好地分离代偿机制,因为这些评估检测到了对照组和脊柱组之间的差异(例如,站立位/深蹲位时的腰椎前凸变化43°±13°对25°±14°[平均差异19°(95%CI 14°至25°);p<0.001],而站立位/放松位时的腰椎前凸变化16°±12°对12°±11°[平均差异4°(95%CI 0°至9°);p = 0.15])。融合节段数与深蹲位腰椎前凸(ρ = 0.55;p<0.001)和骨盆倾斜度(ρ = -0.31;p = 0.02)相关。
在本研究中,脊柱僵硬的患者站立时髋关节过伸,深蹲位时髋关节过度屈曲,与对照组相比,这两个位置之间的骨盆倾斜度变化大五倍。更大的骨盆倾斜度变化可能导致髋臼杯处于功能欠佳的方向,从而导致撞击或脱位。深蹲位X线片可以分离代偿机制,建议用于更好地识别脊柱僵硬患者。
II级,诊断性研究。
