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Cho: Evaluation of Global Sagittal Balance in Koreans Adults

Abstract

Objective

The global sagittal postural patterns as characterized by Roussouly classification have been previously described in various ethnicities, there were no studies investigated in Koreans. To analyze the distribution of the global sagittal postural patterns in Korean adults using Roussouly classification, the author prospectively studied.

Methods

252 asymptomatic Korean adults was recruited. Data was obtained by reviewing the films for each subject. Spinopelvic parameters were measured and sagittal postural patterns were then determined according to Roussouly classification. We compared the data across different ethnicities from our study and a previous study to further characterize Korean sagittal postures.

Results

The subject included 151 males and 101 females, with mean age of 33.2±8.2 years. The average descriptive results were as below: thoracic kyphosis 28.6±7.7°, lumbar lordosis 48.3±10.2°, sacral slope 37.8±5.8°, pelvic incidence 45.1±7.5°, pelvic tilt 9.4±6.7°, spinosacral angle 130.1±5.4°, and sagittal vertical axis 16.25±22.5 mm. 125 subjects among 252 (49.6%) belonged to Roussouly type 3 (namely neutral). There were also 58 (23%), 33 (13.1%), and 36 (14.3) subjects in type 1, 2, and 4 (namely non-neutral), respectively.

Conclusion

Enrolling 252 asymptomatic Korean adults, this prospective study found that 49.6% of asymptomatic Korean adults possessed a sagittal posture of Roussouly type 3. All radiologic parameters follows general concept of spinal sagittal balance pattern. Overall, this study might be a basis for further investigation of spinal sagittal balance.

INTRODUCTION

The human vertebral column consists of a three-dimensional structure such as sagittal, coronal, and axial plane, and the sagittal plane has various shapes depending on the individual4). The distinctions between normal and pathologic curvatures are less clear in the sagittal plane than the coronal plane1). Various sagittal planes are closely related to back pain and are important factors in the development of various spinal diseases. The spinal sagittal plane was studied relatively late compared to the coronal plane. Global spinal balance refers to the overall alignment of the spine—generally using center of C7 vertebral body as a reference point—with respect to another reference point on the sacrum or pelvis9). Clinically, global spinal balance is an important aspect of the evaluation of patients with spinal pathology and of surgical planning, to minimize complications such as adjacent segment disease, sagittal imbalance, pseudarthrosis, and progressive deformity9).
In 2004, Roussouly et al. introduced a four type classification through the prospective radiographic study of 160 asymptomatic Caucasian adults, they claimed that among 4 types, type 3 was considered as balanced neutral position and the other types as non-neutral12) (Fig. 1). The classification was mainly based on lumbar alignments and spinopelvic parameters such as sacral slope (SS), lumbar lordosis (LL), numbers of lumbar vertebrae in lordosis, inflection point (apex of lumbar lordosis) and lumbar tilt (Fig. 2). Among those parameters, location of apex of lumbar lordosis and sacral slope was considered most importantly. Roussouly et al.12) asserted that only 37.5% of asymptomatic Caucasian adults was type 3. Mac-Thiong et al.9) characterized the global sagittal balance in a larger cohort of asymptomatic Caucasian adults and emphasized the importance of the global sagittal balance such as surgical planning, evaluation of spinal pathology, postoperative adjacent segment changes, spinal instability, and spinal pseudoarthopathy.
As interests in sagittal balance is growing recently, many studies has been performed to reveal the global sagittal balance patterns of different ethnic groups5,9,17). In Asian population, Hu et al.5) published that 47.8% of the asymptomatic Chinese belonged to type 3 and whose average pelvic incidence (PI) value was 46.4±9.6°. There has been a lack of studies about the global sagittal postural patterns in asymptomatic Korean adults. Though some Korean authors studied each sagittal balance parameter without the analysis of the global sagittal patterns8). Therefore, for the purpose of analyze the global sagittal patterns of asymptomatic Korean adults, we performed this prospective imaging study and compared it with the previous studies of the global sagittal pattern of other ethnic group.

MATERIALS AND METHODS

Subjects

A total of 252 adult were enrolled in this study from January to December in 2015. Informed consent was obtained from each one and the Institutional Review Board in Ewha Mokdong Hospital approved the study. Inclusion criteria was normal adults who had visited Ewha Mokdong Hospital in order to the medical check-up in the range of 20 to 50 years old for 1 year from January to December in 2015. All subjects was living in metropolitan urban area. The subjects were mainly comprised of desk workers and housekeepers in occupation style.
252 asymptomatic Korean adults including 151 males and 101 females, with an average age of 33.2±8.2 years (ranging from 20 to 48 years old) was prospectively recruited (Table 1). At the time of enrollment, subjects were questioned about their medical history. The subjects who had any of the following conditions were excluded: 1) any history of spinal or orthopedic diseases or trauma, such as back, pelvic, and knee disease; and 2) any abnormal radiologic findings, such as kyphosis, scoliosis, spondylolisthesis, pelvic disease, compressed vertebral fracture beyond the normal range of variation.

Methods

Imaging methods

Standing posteroanterior and lateral view is taken with 36-inch-long cassette at Ewha Mokdong Hospital. For subsequent comparison with Caucasian and Chinese adults, this study adopted the radiographic protocol as in Roussouly et al.’s study12). The difference of imaging methods between Roussouly et al.’s study12) and this study was both arm and shoulder position. In this study, fists-on-clavicle position was performed for the avoidance of covering spinal column by arms and shoulders.
The subjects look forward and stands with elbow flexed. The hands are held in a relaxed state and the proximal wrist joint is placed in the center of the clavicle (fists-on-clavicle position). Because the posture of the lower limb affects the balance of the sagittal plane, it is important to maintain the standardized leg posture in the hip joint and knee joint extended state. The distance from the radiographic source to the film was maintained at 1.8 m and the edges of the films were squared with regard to the horizontal and vertical axes. All radiologic data were archived via Picture Archiving and Communication Systems (PACS; GE Healthcare, Milwaukee, WI, USA). Then the data were retrieved and measured through PACS using the PC-based measuring program.

Radiologic parameters

The sagittal spinopelvic parameters to measure included: 1) PI, the angle between the line from the center of the femoral head to the midpoint of the sacral endplate and a line perpendicular to the sacral endplate; 2) SS, the angle between the sacral endplate and a horizontal reference line; 3) pelvic tilt (PT), the angle between a line from the center of the femoral head to the midpoint of the sacral endplate and a vertical reference line drawn through the center of the femoral head; 4) spinosacral angle (SSA), the angle subtended by the upper sacral endplate and the line from the center of C7 vertebral body to the midpoint of upper sacral endplate; 5) LL, the angle subtended by the superior endplates of L1 and S1; 6) thoracic kyphosis (TK), the angle subtended by the superior endplate of T5 and inferior endplate of T12; and 7) sagittal vertical axis (SVA), the horizontal distance between C7 plumb-line and the posterosuperior corner of S1, positive if C7 plumb-line is behind the posterosuperior corner of S1, or otherwise negative (Fig. 2). All values were measured three times and the average numbers were acquired.
All subjects were categorized by Roussouly classification according to their pelvic and lumbar alignments (Fig. 1). We compared the data of groups and radiologic parameters, according to Roussouly’s classification, with those of other countries.

Statistical analysis

Statistical analyses were conducted with SPSS ver. 12.0 (SPSS Inc., Chicago, IL, USA). Descriptive statistics were provided in the form of mean±standard deviation and the confidence interval was set at 95%. Lilliefors test was used to examine whether the parameters were normally distributed. Two tailed unpaired student t-test were utilized to compare between different groups. Statistical significance was set at 0.05.

RESULTS

There was no significant difference in average age between men and women (p=0.887). No statistical differences was noted in LL, TK, and SS (p>0.05) (Table 1). There were significant differences in the values of PI, PT, SSA, and SVA between two genders (p<0.05). Those difference was attributed to relative pelvic retroversion due to female reproductive system.
In this study, 125 subjects among 252 (49.6%) belonged to Roussouly type 3 (namely neutral) (Table 2). There were also 58 (23%), 33 (13.1%), and 36 (14.3) subjects in type 1, 2, and 4 (namely non-neutral), respectively. In a male group, there were type 1 (36, 23.8%), type 2 (26, 17.2%), type 3 (70, 46.4%), and type 4 (19, 12.6%). Type 1 (22, 21.8%), type 2 (13, 12.9%), type 3 (49, 48.5%), and type 4 (16, 15.8%) were noted in a female group. Type 3 subjects were 46.4% of males and 55.4% of females (Table 2). No difference was revealed between males and females in the distribution of Roussouly types, or in comparison between the neutral group (type 3) and non-neutral (type 1, 2, and 4) (p=0.275) (Table 2).
All sagittal radiological parameters were significantly different among four Roussouly types except sacral slope (Tables 3 and 4). Lumbar lordosis and Pelvic incidence was increased from type 1 to 4 (LL: 47.8±9.3°, 37.8±5.5°, 53.5±6.7°, 67.5±5.6°; PI: 38.3±2.6°, 46.1±8.6°, 47.6±6.4°, 60.4±6.8°) Sagittal vertical axis were different among types (28.71±28.12, 12.15±32.4, 15.44±36.14, 1.05±8.99). Type 1 had the largest one and type 4 the smallest. There were also no statistical significance in spinosacral angle except between type 1, 2, 3, and 4 groups (p<0.05) (Tables 3 and 4).

DISCUSSION

The balance of the sagittal plane of the spine is essential for function as well as body shape, and the relation of the spine to pelvis is becoming increasingly important3). The spinopelvic alignment play an important role in maintaining an effective posture in normal and spinal diseases14). Sagittal alignment of the human spine and pelvis in standing and walking position is highly various in different individuals9). In simple overviews, the human spine has kyphosis in thoracic spine curve and lordosis in cervical and lumbar ones12). In historical review, Stagnara et al.13) classified the vertebral curves into normal, kyphotic, and lordotic according to their shape and degree, and Dubousset regarded the pelvis as the supporting segment between the vertebrae and the lower extremities. Evcik and Yucel2) claimed that there were statistical difference in thoracolumbar sagittal curve between patients who had chronic low back pain and controls who had acute back pain. The decrease of lumbar lordosis with an anterior shift of the sagittal vertical axis generates spinal symptoms and signs with spinal misalignment which is difficult to treat10). So, many authors have commented on the importance of preserving lumbar lordosis during lumbar spine fusion and avoidance of postoperative flat back6).
Not only regional spinal sagittal balance but also global spinal sagittal balance is crucial in every aspect of spinal treatment1). First of all, global spinal sagittal balance pattern would be the base of on-going studies in Korean. This prospective study focused on the groupings of the global sagittal postures of asymptomatic Korean adults in order to provide some references for future studies. For a comparison between the Korean and other ethnicities, we intentionally adopted a closely similar radiographic protocols as matched to those of Roussouly’s. The difference of imaging methods between Roussouly’s study and this study was both arm and shoulder position. In this study, fists-on-clavicle position was performed for the avoidance of covering spinal column by arms and shoulders. To show the difference in the distribution of the sagittal postural patterns between males and females, this study separated the subjects according to gender.
252 asymptomatic adult were enrolled, whose average PI value was 45.1±7.5° (Table 1), lower than that of Caucasian (51.7±55.0°), similar to Chinese’s one (43.3±5.1°)12,14). PI value has been known to constant value, a fixed anatomic relationship between the sacrum and the pelvis, irrespective of aging, which is pivotal value of spinal correction surgery16). This result might be related to the smaller average body size of Korean population than that of the Caucasian adults8,18). Our study found that regardless of spinal symptom, 49.6% of Korean adults possessed a neutral sagittal posture, namely Roussouly type 3, which was higher than 37.5% of Caucasian adults, as previous study, and which was no difference with Chinese, 47.8% as by Hu et al.5) and Roussouly et al.12). As we used similar imaging protocol employed by Roussouly et al.12), this difference between the two ethnics could not be attributed to imaging methods and measurements.
In this study, there were no differences of TK, LL, SS, PI, PT, SVA, and SSA values in gender as same as Caucasian study. But, in Chinese study in Asian ethnicity, females had higher SVA and SSA values than males and this was reflected by a higher proportion of Roussouly type 3 and type 4’s in female group than male. Average PT was 13.8±2.1°, type 4 had the smallest value than others. It means that the anterior flexion of pelvis to spine have lower PT for the compensation of posture because the value of PT and SS changes according to the position and posture of the spine and pelvis.
All the sagittal parameters except SS were significantly different between Roussouly types (Tables 3 and 4), and this is a reflection of the usefulness of Roussouly classification on sagittal postural alignments.
In general, Correlation between spinal parameter and pelvic parameter is important for spinal sagittal balance11). The most important correlation is between the PI as anatomical index and the SS as the positional index7,15). The second most important correlation is between the SS and the LL, and the LL and the TK have little correlation7,8). The PI is the sum of the SS and the PT. There is no change in the PI with the rotation of the pelvis. However, when the SS increases, the PT decreases, and when the SS increases, the PT increases3,4). As a whole, all radiologic parameter values of this study follow above the hypothesis. From type 1 to 4, the LL increase, more lordosis but no change occur at the TK. Regardless of type, the larger the SS, the smaller PT becomes a constant the PI. According to general spinal sagittal pattern, Lumbar parameters and pelvic parameters are changed for compensatory mechanism15). The decrease of lumbar lordosis and increase of thoracic kyphosis due to spinal degeneration is the main cause of sagittal imbalance. In type 1, 2, LL is lower than that of type 3, the PT is higher enough to compensate for lower lordosis. This is due to reduced LL followed by the facet degeneration, collapsed disc etc. In order to optimize the treatment of spinal sagittal imbalance and to avoid overlooking the severity of degenerative diseases, it is important to identify and understand the different patterns of these global spinal sagittal balance pattern. The sagittal balance is related to the pelvis and hip in addition to the spine, and the pelvic and spinal parameters show a close correlation with each other. Therefore, it is essential to measure the pelvic parameters as well as the spinal parameters. For this purpose, we should understand global sagittal balance of normal state as well as diseased state.
There were some limitations in our study. First, the recruitment bias seemed to be inevitable, enrolled subjects had not been evenly distributed for the representation of normal Korean adult. Second, radiologic imaging method was not same, so direct comparison among other ethnic group was not maintained. Third, more intense intraobserver and interobserver reliability was needed for the evaluation of measurement of parameters. Finally, as this was preliminary screening study, more careful designed future study for sagittal postural alignment are needed for clinical interpretations.

CONCLUSION

Registering 252 asymptomatic Korean adults, this prospective study found that 49.6% of asymptomatic Korean adults possessed a sagittal posture of Roussouly type 3. All radiologic parameters follows general concept of spinal sagittal balance pattern. Overall, this study might be a basis for further investigation of spinal sagittal balance.

Acknowledgements

The study protocol was approved by the institutional review board of Ewha Womans Mokdong Hospital (IRB No. 2016-08-023). Informed consent was confirmed by the IRB.

Fig. 1
Drawings of Roussouly types. Type 1: SS<35°, apex of lumbar lordosis (LL) at middle L5, the spine is hypolordotic and relatively normokyphotic; type 2: SS<35°, apex of LL at base L4, the spine is hypolordotic and hypokyphotic; type 3: 35°<SS<45°, apex of LL at middle L4, the spine is well balanced; type 4: SS>45°, apex of LL at base L3, the spine is hyperlordotic and hyperkyphotic. *Apex of lumbar lordosis (inflection point). SS: sacral slope.
jkns-60-5-560f1.gif
Fig. 2
Measurement of spinopelvic parameters. C7PL: C7 plumb-line, TK: thoracic kyphosis, LL: lumbar lordosis, SSA: spinosacral angle, SVA: sagittal vertical axis, SS: sacral slope, PT: pelvic tilt, PI: pelvic incidence.
jkns-60-5-560f2.gif
Table 1
Comparison of spinal sagittal parameters between males and females
Variable All Male Female p-value*
Age (years) 33.2±8.2 35.2±3.2 32.2±6.4 0.887
Thoracic kyphosis (°) 28.6±7.7 25.6±9.3 24.5±8.5 0.435
Lumbar lordosis (°) 48.3±10.2 40.4±9.7 51.3±11.2 0.021
Sacral slope (°) 37.8±5.8 36.4±7.2 38.7±9.2 0.456
Pelvic incidence (°) 45.1±7.5 45.1±9.0 48.5±9.8 0.059
Pelvic tilt (°) 9.4±6.7 8.6±7.9 10.3±2.3 0.077
Spinosacral angle (°) 130.1±5.4 129.0±8.7 131.8±3.4 0.068
Sagittal vertical axis (mm) 16.25±22.5 13.93±36.8 17.79±22.0 0.551

Values are presented as mean±standard deviation.

* Comparison in gender, Statistical significance at p<0.05, unpaired student t-test

Table 2
Distribution of Roussouly classification
All (n=252) Male (n=151) Female (n=101) p-value* p-value
Type 1 58 (23.0) 36 (23.8) 22 (21.8) 0.452
Type 2 33 (13.1) 26 (17.2) 13 (12.9) 0.102
Type 3 125 (49.6) 70 (46.4) 49 (48.5) 0.342 0.275
Type 4 36 (14.3) 19 (12.6) 16 (15.8) 0.215

Values are presented as number (%).

* p-value for the comparison distribution of Roussouly classification between male and female,

p-value for the comparison between neutral Roussouly type (type 3) and non-neutral ones (type 1, 2, and 4)

Table 3
Sagittal parameters according to types of Roussouly classification
Parameter Type 1 Type 2 Type 3 Type 4
Thoracic kyphosis (°) 23.1±4.4 17.4±8.7 27.8±9.9 24.6±7.4
Lumbar lordosis (°) 47.8±9.3 37.8±5.5 53.5±6.7 67.5±5.6
Sacral slope (°) 22.8±3.1 30.4±2.4 38.9±2.8 53.7±5.1
Pelvic incidence (°) 38.3±2.6 46.1±8.6 47.6±6.4 60.4±6.8
Pelvic tilt (°) 17.6±3.9 18.6±6.7 13.8±2.1 17.08±7.7
Spinosacral angle (°) 133.3±9.8 125.8±3.9 132.6±4.8 142.4±4.8
Sagittal vertical axis (mm) 28.71±28.1 12.15±32.4 15.44±36.1 1.05±9.0

Values are presented as mean±standard deviation

Table 4
p-values for the comparison of any two Roussouly types
Parameter Type 3 vs. type 1 Type 3 vs. type 2 Type 3 vs. type 4 Type 1 vs. type 2 Type 1 vs. type 4 Type 2 vs. type 4
Thoracic kyphosis (°) 0.356 0.000 0.750 0.001 0.147 0.000
Lumbar lordosis (°) 0.002 0.001 0.001 0.001 0.002 0.001
Pelvic incidence (°) 0.000 0.203 0.000 0.055 0.005 0.000
Pelvic tilt (°) 0.951 0.342 0.005 0.498 0.003 0.002
Spinosacral angle (°) 0.000 0.261 0.000 0.586 0.000 0.000
Sagittal vertical axis (mm) 0.269 0.458 0.875 0.459 0.006 0.478

Statistically significant at p<0.05

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