颈椎高速低幅手法治疗前后的颈椎节段运动学。

Intervertebral kinematics of the cervical spine before, during, and after high-velocity low-amplitude manipulation.

机构信息

Department of Orthopedic Surgery, University of Pittsburgh, 3820 South Water St, Pittsburgh, PA 15203, USA.

出版信息

Spine J. 2018 Dec;18(12):2333-2342. doi: 10.1016/j.spinee.2018.07.026. Epub 2018 Aug 22.

BACKGROUND CONTEXT

Neck pain is one of the most commonly reported symptoms in primary care settings, and a major contributor to health-care costs. Cervical manipulation is a common and clinically effective intervention for neck pain. However, the in vivo biomechanics of manipulation are unknown due to previous challenges with accurately measuring intervertebral kinematics in vivo during the manipulation.

PURPOSE

The objectives were to characterize manual forces and facet joint gapping during cervical spine manipulation and to assess changes in clinical and functional outcomes after manipulation. It was hypothesized that patient-reported pain would decrease and intervertebral range of motion (ROM) would increase after manipulation.

STUDY DESIGN/SETTING: Laboratory-based prospective observational study.

PATIENT SAMPLE

12 patients with acute mechanical neck pain (4 men and 8 women; average age 40 ± 15 years).

OUTCOME MEASURES

Amount and rate of cervical facet joint gapping during manipulation, amount and rate of force applied during manipulation, change in active intervertebral ROM from before to after manipulation, and numeric pain rating scale (NPRS) to measure change in pain after manipulation.

METHODS

Initially, all participants completed a NPRS (0-10). Participants then performed full ROM flexion-extension, rotation, and lateral bending while seated within a custom biplane radiography system. Synchronized biplane radiographs were collected at 30 images/s for 3 seconds during each movement trial. Next, synchronized, 2.0-milliseconds duration pulsed biplane radiographs were collected at 160 images/s for 0.8 seconds during the manipulation. The manipulation was performed by a licensed chiropractor using an articular pillar push technique. For the final five participants, two pressure sensors placed on the thumb of the chiropractor (Novel pliance system) recorded pressure at 160 Hz. After manipulation, all participants repeated the full ROM movement testing and once again completed the NPRS. A validated volumetric model-based tracking process that matched subject-specific bone models (from computed tomography) to the biplane radiographs was used to track bone motion with submillimeter accuracy. Facet joint gapping was calculated as the average distance between adjacent articular facet surfaces. Pre- to postmanipulation changes were assessed using the Wilcoxon signed-rank test.

RESULTS

The facet gap increased 0.9 ± 0.40 mm during manipulation. The average rate of facet gapping was 6.2 ± 3.9 mm/s. The peak force and rate of force application during manipulation were 65 ± 4 N and 440 ± 58 N/s. Pain score improved from 3.7 ± 1.2 before manipulation to 2.0 ± 1.4 after manipulation (p <. 001). Intervertebral ROM increased after manipulation by 1.2° (p = .006), 2.1° (p = .01), and 3.9° (p = .003) at the C4/C5, C5/C6, and C6/C7 motion segments, respectively, during flexion-extension; by 1.5° (p = .028), 1.9° (p = .005), and 1.3° (p = .050) at the C3/C4, C4/C5, and C5/C6 motion segments, respectively, during rotation; and by 1.3° (p = .034) and 1.1° (p = .050) at the C4/C5 and C5/C6 motion segments, respectively, during lateral bending. Global head ROM relative to the torso increased after manipulation by 8º (p = .023), 10º (p = .002), and 13º (p = .019) during lateral bending, axial rotation and flexion-extension, respectively, after manipulation.

CONCLUSIONS

This study is the first to measure facet gapping during cervical manipulation on live humans. The results demonstrate that target and adjacent motion segments undergo facet joint gapping during manipulation and that intervertebral ROM is increased in all three planes of motion after manipulation. The results suggest that clinical and functional improvement after manipulation may occur as a result of small increases in intervertebral ROM across multiple motion segments. This study demonstrates the feasibility of characterizing in real time the manual inputs and biological responses that comprise cervical manipulation, including clinician-applied force, facet gapping, and increased intervertebral ROM. This provides a basis for future clinical trials to identify the mechanisms behind manipulation and to optimize the mechanical factors that reliably and sufficiently impact the key mechanisms behind manipulation.

背景

颈部疼痛是基层医疗机构最常见的症状之一，也是医疗保健费用的主要原因之一。颈椎推拿是治疗颈部疼痛的一种常见且临床有效的干预措施。然而，由于以前在推拿过程中难以准确测量椎间运动学，因此推拿的体内生物力学尚不清楚。

目的

本研究旨在描述颈椎推拿过程中的手动力和小关节间隙，并评估推拿后临床和功能结果的变化。假设推拿后患者报告的疼痛会减轻，椎间活动范围（ROM）会增加。

研究设计/设置：基于实验室的前瞻性观察性研究。

患者样本

12 例急性机械性颈部疼痛患者（4 名男性和 8 名女性；平均年龄 40±15 岁）。

测量指标

推拿过程中小关节间隙的大小和速度，推拿过程中应用力的大小和速度，推拿前后主动椎间 ROM 的变化，以及推拿后测量疼痛变化的数字疼痛评分量表（NPRS）。

方法

首先，所有参与者完成 NPRS（0-10）。然后，参与者在定制的双平面放射系统中坐在座位上进行全 ROM 屈伸、旋转和侧弯运动。在每个运动试验中，以 30 幅/秒的速度同步采集双平面射线照片 3 秒。接下来，在 0.8 秒内以 2.0 毫秒持续时间的脉冲双平面射线照片以 160 幅/秒的速度同步采集。推拿由持牌脊医使用关节柱推技术进行。对于最后五名参与者，脊医拇指上的两个压力传感器（Novel pliance 系统）以 160 Hz 的频率记录压力。推拿后，所有参与者再次重复全 ROM 运动测试，并再次完成 NPRS。使用基于容积模型的跟踪过程，该过程使用与双平面射线照片匹配的特定于主体的骨骼模型（来自计算机断层扫描）以亚毫米精度跟踪骨骼运动。小关节间隙的计算方法是相邻关节面之间的平均距离。使用 Wilcoxon 符号秩检验评估前后变化。

结果

推拿过程中关节间隙增加了 0.9±0.40mm。平均关节间隙增大速度为 6.2±3.9mm/s。推拿过程中的峰值力和力应用速率分别为 65±4N 和 440±58N/s。疼痛评分从推拿前的 3.7±1.2 改善至推拿后的 2.0±1.4（p<0.001）。推拿后椎间 ROM 增加，屈伸运动节段 C4/C5、C5/C6 和 C6/C7 分别增加 1.2°（p=0.006）、2.1°（p=0.01）和 3.9°（p=0.003）；旋转运动节段 C3/C4、C4/C5 和 C5/C6 分别增加 1.5°（p=0.028）、1.9°（p=0.005）和 1.3°（p=0.050）；侧弯运动节段 C4/C5 和 C5/C6 分别增加 1.3°（p=0.034）和 1.1°（p=0.050）。推拿后，相对于躯干，头部整体 ROM 在侧弯、轴向旋转和屈伸运动中分别增加 8°（p=0.023）、10°（p=0.002）和 13°（p=0.019）。

结论

本研究首次在活体人类中测量颈椎推拿过程中的小关节间隙。结果表明，在推拿过程中目标和相邻运动节段会发生小关节间隙，推拿后所有三个运动平面的椎间 ROM 均增加。这些结果表明，推拿后临床和功能的改善可能是由于多个运动节段椎间 ROM 的微小增加所致。本研究证明了实时描述颈椎推拿的手动输入和生物反应的可行性，包括临床医生施加的力、小关节间隙和增加的椎间 ROM。这为未来的临床试验提供了基础，可以确定推拿的机制，并优化可靠且充分影响推拿关键机制的机械因素。