Radiological lumbar instability may be related to LBP. Various diagnostic criteria have been proposed for lumbar instability [5, 6, 12–15]; however, the relationship between lumbar instability and LBP remains not investigated [1, 16, 17]. Some studies have measured radiological parameters of the lumbar spine in healthy volunteers [18–22], but they did not evaluate ADL impairment using ODI and RDQ. The literature revealed that benchmark measurements for lumbar instability are used dating back more than three decades, without validation with many healthy individuals [5, 6, 12–15].
To our best knowledge, this is the first study to collect and analyze systematic measurement data from dynamic lumbar radiographs of several healthy individuals. ODI and RDQ are widely used patient-oriented tools for assessing LBP-related ADL disabilities. In general, ODI of ≥ 20% and RDQ of ≥ 14 points are considered to indicate LBP-related impairment [8, 9]. Participants exceeding the aforementioned ODI and RDQ thresholds were excluded from this study to assess lumbar dynamics in individuals without LBP-related ADL impairments. Table 4 lists IROM and ΔST measurements reported in other studies. IROM in our cohort was smaller, whereas ΔST was comparable, to the previously reported values. The observed discrepancy in IROM compared with some earlier studies can be explained by the fact that participants were younger or were seated during dynamic radiography in the latter. Our study participants were older and were standing during the radiological examination. Conversely, ΔST is consistent between sitting and standing positions [23], which support the equivalence of ΔST between the present and previous studies. Dvorak et al. [22] revealed that passive lumbar flexion rather than active flexion may have caused a larger IROM than that observed in our cohort.
Table 4
Lumbosacral spine motion in normal individuals.
Authors | number of subjects | Sex | Age | Positioning during dynamic view | IROM (degrees: mean) | ΔST (mm: mean) |
L1–2 | L2–3 | L3–4 | L4–5 | L5–S | L1–2 | L2–3 | L3–4 | L4–5 | L5–S |
Clayson et al. (1962)18 | 26 | F | College Students | Sitting, active flexion / Standing, extension | 12.6 | 15.8 | 15.9 | 17.7 | 18.7 | NA | NA | NA | NA | NA |
Pearcy et al. (1984)19 | 11 | M | 25–36 | Standing, active flexion-extension | 13 | 14 | 13 | 16 | 14 | 4 | 3 | 3 | 3 | 2 |
Hayes et al. (1989)20 | 59 | M | 19–59 | Sitting, active flexion-extension | 7 | 9 | 10 | 13 | 14 | 1.9 | 2.4 | 2.5 | 3.0 | 1.3 |
Boden et al. (1990)21 | 40 | M | 19–43 | Standing, active flexion-extension | 8.2 | 7.7 | 7.7 | 9.4 | 9.4 | 1.4 | 1.3 | 1.2 | 1.2 | 1.0 |
Dvorak et al. (1991)22 | 41 | M/F | 22–50 | Standing, passive flexion-extension | 11.9 | 14.5 | 15.3 | 18.2 | 17 | 2.6 | 3.0 | 3.1 | 2.6 | 0.9 |
This Study | 420 | M/F | 24–83 | Standing, active flexion-extension | 4.3 | 5.4 | 4.9 | 5.0 | 5.9 | 2.2 | 2.7 | 2.4 | 2.2 | 0.9 |
IROM, intervertebral range of motion; ΔST, distance of sagittal translation; NA, not available. |
Nachemson’s criteria for lumbar instability, i.e., IROM of ≥ 10° and ΔST of ≥ 3 mm at L1–2 to L4–5, and IROM of ≥ 20° and ΔST of ≥ 4 mm at L5–S, have been widely adopted [5]. White et al. proposed a threshold IROM of 15° at L1–2 to L3–4, 20° at L4–5, and 25° at L5–S, with a ΔST of 4.5 mm at each level [6]. However, these criteria were not supported by data from a sufficient number of patients or healthy volunteers. The present study established standard values of IROM and ΔST that were measured and calculated from many healthy volunteers. The threshold values for IROM at L1–2 to L4–5 were 10.3°–12.4° in our cohort, which were higher than Nachemson’s cut-off value of 10° and did not exceed White’s cut-off value of 15° or 20°. The threshold values for ΔST at L1–2 to L4–5 were 5.4–5.5 mm, which exceeded Nachemson’s cut-off value of 3 mm and White’s cut-off value of 4.5 mm. Conversely, the threshold values for IROM and ΔST at L5–S were 13.9° and 3.3 mm, respectively, which do not exceed Nachemson’s (20° and 4 mm) and White’s cut-off values (25° and 4.5 mm). Therefore, the instability criteria advocated by Nachemson were not suitable except for L5–S level. The standard upper limits of IROM and ΔST need to be verified in subjects with lumbar spinal diseases before they can be used to define lumbar instability in pathological situations because we only included asymptomatic participants without lumbar movement restrictions.
Moreover, we evaluated the number of intervertebral segments exceeding the reference values of IROM and ΔST using IROM and ΔST scores according to Nachemson’s criteria. These scores indicate 25% of healthy participants meet the IROM criteria at any intervertebral level, and 7.6% had excessive angular motion at two or more levels. Conversely, 72% of participants met the criteria for abnormal ΔST at any level, and up to 41% deviated from Nachemson’s criteria at two or more levels [5].
Iguchi et al. revealed that ΔST has a greater influence on lumbar symptoms than IROM; however, asymptomatic individuals in our cohort demonstrated ΔST instability more frequently than IROM. This discrepancy is due to patient selection. Various symptoms were contained rather than low back pain because the patients presented in the former report had lumbar spinal canal stenosis [10].
Hayes et al. concluded that > 3 mm of dST is questionable as an indicator for fusion surgery because of lacking evidence. They also mentioned that the usage of dynamic radiographs of the lumbar spine for lumbar instability assessment is problematic. This opinion is in concordance with our result [20].
The relationship between LBP and radiological lumbar instability remains controversial. Our study could not evaluate the relationship between LBP and radiological lumbar instability as our cohort did not include participants with intermediate to severe LBP; therefore, additional studies of patients with severe LBP are necessary to clarify this association.
The inter-rater reliability of the intervertebral disk angle measured in our study was higher than that of sagittal translation. The lower reliability of sagittal translation measurements can be associated with the difficulty of controlling the obliquity of the X-ray beam and the influence of soft tissues surrounding the lumbar spine [24]. The posterior aspect of the vertebral body appears as two lines when the X-ray incidence angle is not parallel to the vertebral body, causing inaccurate sagittal translation measurement [25].
This study has several limitations. First, most of the volunteers were schoolteachers; therefore, the cohort was biased toward non-manual laborers in terms of sample selection. Second, the relationship between excessive mobility of the lumbar spine and LBP could not be evaluated because patients with severe LBP were excluded. Additionally, the degree of active flexion and extension depended on each participant as opposed to maximum passive motion. However, this study provides the first set of precise measurements for lumbar mobility in a large sample of participants who had less LBP-related disability according to ODI and RDQ.