Differences in lumbar spine and lower extremity kinematics in people with and without low back pain during a step-up task: a cross-sectional study

A power analysis was conducted based on data from a pilot study of group differences in kinematics during a walking and a pickup task (partial n² = 0.338) [24, 25]. We determined that a minimum of 15 subjects was needed to detect a group by region interaction effect with 80% power. For the current study, 37 subjects between the ages of 18 and 65 participated. Nineteen subjects had LBP, and 18 subjects had no history of LBP (controls). The subjects with LBP were recruited from 2 outpatient physical therapy clinics, where they were seeking treatment for their LBP. The controls were recruited from physicians’ offices and the surrounding community. Subjects with LBP reported a primary complaint of LBP that limited activities of daily living for at least 3 consecutive days. Exclusion criteria included a history of serious spinal or other medical conditions, physical or mental disabilities, pregnancy, persons who are unable to provide their own legal informed consent, and a BMI > 30 kg/m². The body mass index criterion was selected because subcutaneous tissue may influence the accuracy of skin marker placement and tracking. Subject recruitment and testing occurred from January 2011 – May 2013. The Human Subjects Research Committee at Nazareth College in Rochester, NY, approved the protocol and the subjects provided informed consent before participating.

To measure the level of pain, disability, and fear avoidance, each subject with LBP completed a Numeric Rating Scale for Pain (NRS), LBP symptom questionnaire, Oswestry Disability Index (ODI), and Fear-Avoidance Beliefs Questionnaire (FABQ) prior to participation [26‐29].

A 9-camera, 3-dimensional optical motion capture system (Vicon Inc., Denver, CO) was used to capture data using a frame rate of 100 Hz as subjects performed the step-up task. Fifty-seven retro-reflective markers were placed on pre-determined anatomical landmarks of the lumbar spine, pelvis and extremities (Fig. 1). The landmarks were located, and then markers were placed on all subjects by the same licensed physical therapist, who had 10 years experience with motion capture testing. The lumbar spine model has been described in detail in previous publications, and was tested for and demonstrated acceptable reliability and validity for measuring regional lumbar spine kinematics [10, 25, 30]. The upper lumbar segment was defined by markers 4 cm lateral to L1 and on the spinous process of L3. The lower lumbar segment was defined by markers 4 cm lateral to L4 and on the spinous process of L5. Markers on the PSIS, ASIS, and iliac crest bilaterally defined the pelvis. For the thigh segment, markers were placed on the superior, inferior and posterior thigh. For the lower leg segment, markers were placed on the fibular head, superior, inferior and posterior lower leg and the tibial tuberosity. Markers on the feet were placed on the third metatarsal head, fifth metatarsal tuberosity, and calcaneus. Markers were placed bilaterally on the medial and lateral femoral condyles and medial and lateral malleoli for calibration, but were removed for the movement trials.

Prior to conducting each step-up trial, a static calibration trial was captured to calculate knee and ankle joint centers and a dynamic trial was captured to calculate functional hip joint centers. For the step-up trial, each subject was instructed to step-up onto a single rectangular step, 24 cm tall, placed ~13 cm from the great toe (Fig. 1). A higher than normal (15–20 cm) step height was used to challenge the subject and to accentuate any movement impairments. The subject was instructed to step-up with the right foot, followed by the left, and then remain on the step. The test movement was repeated three times leading with the right foot, and then three times leading with the left foot. Subjects were allowed to move at a self-selected speed, with no additional instructions. Each subject rated their LBP on the 11-point NRS (0 = no pain, 10 = worst imaginable pain) before and after performing the step-up task; change in pain behavior on the NRS was recorded.

The marker data was post-processed, without knowledge of group membership, using Nexus software (Vicon, Inc., Denver, CO) to correct unlabeled trajectories and fill gaps using the gap filling function in Nexus. Data was exported from Nexus and then imported to Visual 3D (C-Motion, Inc., Germantown, MD) where marker data were filtered using a second-order Woltring filter (GCVSPL) [31] (2 × 10⁻⁴ MSE variance; optimization mode, 3) and the custom spine model was applied [10, 32]. Based on the parameters used for the GCVSPL filter, and the 100 Hz sampling frequency, the equivalent cutoff frequency parameter for a 2nd order low-pass Butterworth filter would be approximately 4.2 Hz (3.4 Hz with adjustment for dual pass) [33]. https://​isbweb.​org/​software/​sigproc.​html] Functional joint centers were calculated for the hip from the dynamic trial and anatomic joint centers were calculated for the knee and ankle from the static calibration trial [34]. The upper lumbar, lower lumbar, hip, knee and ankle segment angles were derived in the sagittal, coronal, and axial planes from the start to end of the movement task. The start of the task was identified when the movement of the T1 marker exceeded 5% of its maximum linear velocity in any direction. The end of the task was identified when the calcaneus marker on the trailing limb reached a linear velocity of zero in the vertical direction, and both feet were on the step. Movement time was calculated and maximum and minimum segment angles were identified between the start and end of the movement task. Angle excursion for each segment was calculated as the difference between the maximum and minimum segment angle in each of the three planes of motion for each trial. Angle excursion measures from each trial then were averaged across the three right step-up trials and then across the three left step-up trials.

The data were analyzed using SPSS version 21.0 using an alpha level of 0.05. Group differences in subject characteristics and movement time were evaluated using t-tests for ratio scale data and chi-square tests for categorical data.

All lumbar spine and lower extremity kinematic measures were examined for normality and the presence of outliers. For each measure, standardized skewness and standardized kurtosis were calculated to assess normality, as these would best highlight departures from normality beyond what is tolerated in the generally robust analysis of variance (ANOVA) [35]. Kinematic measures with standardized skewness or kurtosis values outside the accepted range for normality (±2) were transformed using the log natural transformation (base-e logarithm) for analysis to ensure that any non-normality issues did not threaten statistical findings.

Separate group X region mixed design ANOVAs were conducted for the lumbar spine (2 groups × 2 regions) and lower extremities (2 groups × 3 regions) and for each plane of motion (sagittal, coronal, axial). Group (LBP, control) served as a between subject factor and region (lumbar spine: upper, lower; lower extremity: hip, knee, ankle) served as the repeated measures factor. Preliminary analysis including a repeated measures factor of side revealed no effect of step-up side, so measures were averaged for the right and left step-up tasks in subsequent analyses. Because group differences were of primary interest in the current study, significant interactions were followed up with simple nested comparisons comparing the two groups to further examine the source of the significant interactions. Data were back transformed to report in graphical form and to report confidence intervals.

Standardized skewness and kurtosis values indicated departures from normality for skewness for coronal plane excursion of the knee (standardized skewness = 2.75), sagittal plane (standardized skewness = 2.20) and axial plane (standardized skewness = 3.13) excursion of the lower lumbar region. ANOVA models are generally robust to violations of normality, however to ensure the reliability of test-statistics, data were log transformed prior to conducting analyses [35]. This resolved non-normality as reflected by standardized skewness and kurtosis values for all measures falling within ±2.

Results for group differences in lumbar spine kinematics are presented in Fig. 2 and results of statistical tests are presented in Table 3. In the sagittal plane, there was a significant group by region interaction (P = 0.016) and a significant main effect of group (P = 0.027). There was no significant main effect of region (P = 0.287). Follow up nested comparisons revealed that subjects in the LBP group displayed less sagittal plane movement in the lower lumbar spine than the control group (mean diff: −5.1°; 95% CI: -7.9° − −2.2°; P = 0.001), but there was no group difference in upper lumbar spine motion in the sagittal plane (mean diff: −0.9°; 95% CI: -3.6° − 1.8°; P = 0.603). In the coronal and axial planes respectively, there were no significant main effects of group (P = 0.418, P = 0.555) or group by region interactions (P = 0.169, P = 0.767).

Results for group differences in lower extremity kinematics are presented in Fig. 3 and results of statistical tests are presented in Table 3. In the sagittal plane, there was a significant group by region interaction effect (P = 0.008) and a significant main effect for region (P = 0.001). There was no significant main effect of group (P = 0.957). Follow up nested comparisons revealed no significant group differences in lower extremity kinematics at the hip (mean diff: −1.8°; 95% CI: -4.6° − 1.0°; P = 0.190), knee (mean diff: −2.7°; 95% CI: -6.6° − 1.3°; P = 0.165), or ankle (mean diff: 1.9°; 95% CI: -0.3° − 4.0°; P = 0.102) in the sagittal plane. In the coronal plane, there was a significant group by region interaction effect (P = 0.004) and a significant main effect of group (P = 0.001) and region (P = 0.001). Follow up nested comparisons revealed that the LBP group displayed significantly more coronal plane movement at the knee joint than the control group (mean diff = 4.9°, 95% CI: 2.0°-7.8°, P = 0.001), but there were no group differences in coronal plane movement at the hip (mean diff: 0.3°; 95% CI: -0.6° − 1.2°; P = 0.543) or ankle joint (mean diff: 0.7°; 95% CI: -0.6° − 2.4°; P = 0.176). In the axial plane, there was a significant main effect of group (P = 0.002) and region (P = 0.020), but no significant group by region interaction effect (P = 0.621). Subjects in the LBP group displayed more axial plane lower extremity movement than controls.

There are several limitations to the current study. First, because this is a cross-sectional study, we were unable to determine whether lumbar spine kinematics in the LBP group contributed to the LBP problem or occurred as a result of the LBP problem. However, subjects were recruited from a physical therapy clinical population and therefore the findings can be generalized to patients in this setting. Second, there is the potential for error in measuring spine movement with surface marker measures because of skin movement. Alternatively, surface marker measures are currently the only available method to objectively measure both lumbar spine and lower extremity kinematics during complex functional tasks. Last, some studies have shown that people with LBP have differences in movement variability, but the kinematic variables used in the current study were segment excursions and we did not measure movement variability.