Is there a direct correlation between cervical sagittal alignment and spinopelvic sagittal alignment?: an observational study from asymptomatic Indian adults

Article information

Asian Spine J. 2025;.asj.2025.0145

Publication date (electronic) : 2025 September 2

doi : https://doi.org/10.31616/asj.2025.0145

Juan Esteban Muñoz Montoya

, Karthik Ramachandran

, Praveen R Iyer

, Ajoy Prasad Shetty

, Shanmuganathan Rajasekaran

Department of Spine Surgery, Ganga Hospital, Coimbatore, India

Corresponding author: Ajoy Prasad Shetty, Department of Spine Surgery, Ganga Medical Centre and Hospitals Pvt. Ltd, 313, Mettupalayam Road, Coimbatore, Tamil Nadu, 641043 India, Tel: +91-9344833797, Fax: +91-422-4383863, E-mail: ajoyshetty@gmail.com

Received 2025 March 9; Revised 2025 May 21; Accepted 2025 June 8.

Abstract

Study Design

Observational study.

Purpose

Cervical parameters play a vital role in maintaining global spinal sagittal alignment, but their correlation with spinopelvic parameters remains unclear. This study aimed to investigate potential direct correlations between cervical sagittal alignment and spinopelvic alignment in an asymptomatic population.

Overview of Literature

Previous studies have demonstrated a direct relationship between pelvic parameters, lumbar lordosis (LL), and thoracic kyphosis (TK), as well as a direct correlation between cervical lordosis (CL) and TK. However, the direct influence of pelvic parameters and LL on cervical parameters remains unclear, warranting further research.

Methods

This study involved 104 asymptomatic adults (females 62 [59.6%]) aged 18–50 years. Whole-spine standing lateral radiographs were obtained, and the pelvic, lumbar, thoracic, cervicothoracic, and cervical parameters were studied. Pearson’s correlation coefficient was used to assess correlations, with a significance threshold of p<0.05.

Results

The mean age of participants was 38.27±9.93 years. The pelvic incidence (PI) significantly correlated with C7 slope (r=−0.212, p=0.05). The pelvic tilt (PT) exhibited significant correlations with T1 slope−CL mismatch (r=−0.229, p=0.05) and C2 slope (r=−0.202, p=0.05). Furthermore, PI–LL mismatch showed a significant correlation with TIA (r=−0.197, p=0.05), T1 slope (r=−0.228, p=0.05), and C7 slope (r=−0.251, p=0.05).

Conclusions

This study reveals a significant correlation between cervical and spinopelvic parameters, emphasizing the interconnectedness of pelvic, lumbar, thoracic, and cervical spine parameters.

Keywords: Cervical sagittal parameters; Spinopelvic sagittal parameters; Pelvic incidence; Pelvic tilt; C7 slope

Introduction

The sagittal spinal balance, as defined by Dubousset [1], represents the interaction of the neuro-musculoskeletal components of the spine, pelvis, and lower extremities with gravity. This interaction enables the maintenance of a position that requires minimal energy expenditure, a concept often described as the “cone of economy” [1–3]. Achieving this balance necessitates a so-called “balance chain” comprising the feet, pelvis (pelvic vertebra), and skull (cephalic vertebra). This balance chain is a series of correlations that assess the spinopelvic relationship and regional sagittal alignment in an upright position [4–6].

Legaye et al. [5] and Legaye et al. [6] initially explored the relationship among various spinal and pelvic regions, establishing connections between the positional and morphological parameters of the hip, sacrum, and pelvis. Later, a study by Boulay et al. [7] involving 149 asymptomatic Caucasian adults reaffirmed the correlation among the pelvic parameters: pelvic incidence (PI) and sacral slope (SS) (r=0.7), as well as pelvic tilt (PT) (r=0.6). Gelb et al. [8] studied 100 asymptomatic middle-aged and older volunteers, analyzing the role of segmental spinal alignment in overall sagittal balance. They noted that despite advancing age, sagittal alignment was preserved due to the loss of distal lumbar lordosis without an increase in thoracic and thoracolumbar kyphosis [8].

Clément et al. [9] first described the importance of thoracic kyphosis (TK) as a harmonious curve in maintaining sagittal spinal balance. Recent findings indicate that TK comprises two unequal arches: a stable upper TK and a variable lower TK, with the apex typically at T8–T9, varying according to the Roussouly classification-based spinal morphotype. These considerations are crucial for analyzing sagittal compensation and planning corrections to mitigate the risk of mechanical complications [10,11].

Researchers are currently working to complete the correlation chain by investigating the influence of the cervical segment on the other spinal segments. Ames et al. [12] found correlations between pelvic and regional sagittal parameters, showing that high PI is associated with high lumbar lordosis (LL), which in turn relates to TK, and TK correlates with cervical lordosis (CL). However, they found no direct influence of PI on CL or vice versa [12]. Nunez-Pereira et al. [13] found no direct correlation between PI and cervical parameters in their study of 145 patients. Similarly, Muñoz Montoya et al. [14], in a study of 51 asymptomatic Hispanic adults, found no direct relationship between pelvic and cervical parameters, except for a weak correlation between the T1 slope and the PI–LL mismatch.

Recently, new cervical sagittal parameters, such as the C7 and C2 slopes, have emerged, but their role in sagittal alignment remains unclear. Therefore, the objective of this study was to investigate whether the previously described pelvic parameters directly influence both these new and conventional cervical parameters or if it is necessary to correlate the thoracic parameters.

Materials and Methods

Study design and population

This was an observational study of asymptomatic healthy volunteers aged between 18 and 50 years. The study was approved by the Institutional Review Board (IRB) of Ganga Medical Center and Hospital, Coimbatore (IRB no., 2020/01/02). Written informed consent was obtained from all participants before enrolment. The exclusion criteria included the presence of any spinal deformities, hip or lower limb discrepancies or diseases, recent trauma, chronic pain conditions, or musculoskeletal pathologies.

Radiographic evaluation and classification of types

Participants underwent standardized whole-spine radiographs in lateral and anteroposterior views while standing with arms crossed over their chests. Digital images were recorded on a picture archiving and communication system in digital imaging and communications in medicine format and then uploaded in the designated software program to measure the following sagittal alignment parameters (Table 1): (1) Pelvic parameters: PI, SS, PT. (2) Lumbar parameters: LL, PI–LL mismatch. (3) Thoracic parameters: TK: T1–T12; upper thoracic kyphosis (UTK): T1–T5; lower thoracic kyphosis (LTK): T5–T12. (4) Cervicothoracic parameters: thoracic inlet angle (TIA), T1 slope (T1S), neck tilt (NT), T1 slope–CL mismatch. (5) Cervical parameters: upper cervical parameters: C0–C2 angle, C1–C2 angle, C2 slope; lower cervical parameters: CL: C2–C7, C7 slope, cervical sagittal vertical axis (cSVA) (C2–C7). (6) Horizontal gaze parameter: McGregor slope (McGS).

Table 1

Definitions of various radiological parameters

Two spine surgery residents conducted measurements using the Surgimap program (Nemaris Inc., New York, NY, USA), which has demonstrated superior repeatability and reproducibility compared to manual radiologic measurements. The Surgimap’s specialized sagittal alignment tool was used for these assessments (Fig. 1). The user first outlined the femoral heads with two adjustable circles and then marked four segments corresponding to four key vertebral endplates (superior S1, superior L1, superior T1, and inferior C2). Once the landmarks were identified, the user adjusted the constrained spines to correctly overlay the cervical, thoracic, and lumbar curvatures. The software then automatically generated spino-pelvic parameters based on the demarcated landmarks and splines: direct parameters corresponded to angles drawn by the observer (PI, PT, SS, LL, C2C7, T1 slope, cSVA, PI–LL), while indirect parameters corresponded to angles estimated by the software based on the splines.

Fig. 1

Surgimap software used for measuring the various sagittal parameters. CL, cervical lordosis; cSVA, cervical sagittal vertical axis; PT, pelvic tilt; PI, pelvic incidence; SS, sacral slope; LL, lumbar lordosis.

Statistical analysis

Data analysis was conducted using IBM SPSS ver. 20.0 software (IBM Corp., Armonk, NY, USA), involving measures of central tendency for quantitative variables and proportions for qualitative variables. Differences between males and females were assessed using the independent t-test and Mann-Whitney U test for normally and non-normally distributed variables, respectively. Pearson’s correlation coefficient (r) was used to evaluate correlations, with strength of the correlations interpreted as very weak (0.0–0.1), weak (0.1–0.3), moderate (0.3–0.5), strong (0.5–0.7), very strong (0.7–0.9), and perfect (0.9–1.0). Intraclass correlation coefficients (ICCs) and their 95% confidence intervals (CIs) were calculated based on a mean rating (k=2), consistency, and two-way random effects for average measures to assess all sagittal parameters. ICC values were interpreted as poor (<0.50), moderate (0.50–0.74), good (0.75–0.90), and excellent (>0.90). The significance level was set at p<0.05.

Results

The study included 104 asymptomatic patients (62 female [59.6%]) with a mean age of 38.27±9.93 years. Table 2 presents the cervical and thoracic parameters expressed as mean, standard deviation, minimum, and maximum values. The mean values of various parameters were as follows: (1) Pelvic parameters: PI: 45.43°±9.717°, SS: 3.51°±7.968°. (2) Lumbar parameters: LL: −51.26°±12.456°. (3) Thoracic parameters: TK (T1–T12): 30.95°±10.928°, UTK (T1–T5): 11.133°±7.2546°. (4) Cervicothoracic parameters: TIA: 85.20°±10.646°, T1 slope: 26.26°±8.236°. (5) Cervical parameters: upper cervical parameters: C1–C2: −21.63°±11.381°, C2 slope: 2.31°±11.420°; lower cervical parameters: CL: C2–C7: −24.27°±14.902°, C7 slope: 23.0735°±8.34865°. (6) Horizontal gaze parameters: McGS: 2.118°±13.3506°. Age wise distribution of various important parameters has been mentioned in Supplement 1.

Table 2

Mean value of various parameters in the population

Intrarater and interrater reliability

The intrarater reliability was found to be excellent for all parameters (ICC, 0.96; 95% CI, 0.92–0.97). The interrater reliability between the two readers was also found to be excellent (ICC, 0.92; 95% CI, 0.86–0.95).

Correlation between pelvic and lumbar parameters

The correlations between pelvic and lumbar parameters are presented in Table 3. PI showed strong positive correlations with SS (r=0.602, p=0.000) and PT (r=0.613, p=0.000), and a moderate positive correlation with LL (r=−0.344, p=0.000). SS also showed a strong negative correlation with LL (r=−0.734, p=0.000). Conversely, PT showed a weak negative correlation with SS (r=−0.259, p=0.001) and a weak positive correlation with LL (r=0.312, p=0.001).

Table 3

Correlation between pelvic parameters and lumbar parameters

Correlation between lumbar and thoracic parameters

The correlations between lumbar and thoracic parameters are presented in Table 4. The pelvic parameters showed no direct correlation with the thoracic parameters. LL (L1–S1) showed a moderate negative correlation with TK (T1–T12) (r=−0.501, p=0.000) and LTK (T5–T12) (r=−0.499, p=0.000). Of note, LL (L1–L4) exhibited a moderate negative correlation with various thoracic segments (Table 4).

Table 4

Correlation between the lumbar parameters and thoracic parameters

Correlation between cervical and thoracic parameters

The correlation matrix in Table 5 shows the relationships between the cervical and thoracic segmental parameters. TK (T1–T12) strongly correlated with T1S (r=0.628, p=0.000) and C7 slope (r=0.575, p=0.000). TK (T1–T12) also exhibited a weak correlation with TIA (r=0.294, p=0.002) and a negative moderate correlation with CL (C2–C7) (r=−0.321, p=0.000). Of note, TIA was the only cervical sagittal alignment parameter to correlate with all thoracic segments; the other parameters were T1S, which correlated with the LTK (T5–T12) and TK (T1–T12). Similar results were observed with the C7 slope (Table 5).

Table 5

Correlation between the thoracic parameters and cervical parameters

Correlation between spinopelvic and cervical parameters

Table 6 shows the relationships between spinopelvic and cervical parameters. Key findings included a weak negative correlation between PI and C7 slope (r=−0.212, p=0.05) and a weak correlation of PT with T1 slope−CL mismatch (r=−0.229, p=0.05) and C2 slope (r=−0.202, p=0.05). Additionally, PI–LL mismatch showed very weak correlations with TIA (r=−0.197, p=0.05), T1 slope (r=−0.228, p=0.05), and C7 slope (r=−0.251, p=0.05). No correlation were observed between other spinopelvic and cervical parameters (Table 6).

Table 6

Correlation between cervical and spinopelvic alignment in the asymptomatic Indian population

Discussion

The cervical spine can be divided into upper and lower cervical regions with distinct functions and responses to bodily changes. The primary roles of the cervical spine are maintaining horizontal gaze and supporting the weight of the head [12,15,16]. Recent studies have highlighted the distinction between cervical sagittal alignment and malalignment, significantly affecting patients’ quality of life [16,17]. This understanding stems from establishing normal values and efforts to standardize cervical sagittal alignment measurements, essential for planning cervical spine surgeries [18].

The PI–LL mismatch is a widely used parameter in the context of adult spinal deformity. It serves as a key objective for correcting the deformity, significantly impacting the patient’s quality of life. It is measured using a formula that categorizes results as either less than 10° or greater than 10°, illustrating the relationship between PI and LL, in addition to PT and SS [19]. While the influence of this parameter on cervical alignment is largely unknown, our study revealed a weak correlation between pelvic and cervical parameters. Specifically, we found connections between PI and the C7 slope, PT and T1 slope, CL mismatch, and C2 slope. Additionally, a weak inverse correlation was observed between PI–LL mismatch and TIA, T1S, and C7 slope. These findings align with Muñoz Montoya et al. [14], who also reported a relationship between PI–LL mismatch and T1S.

Lee et al. [20] in 2012 introduced several parameters like TIA, NT, and T1S, advancing the study of cervical sagittal alignment. These parameters have facilitated research into direct and indirect correlations between the cervical, thoracic, lumbar, and pelvic regions [20]. Current and previous research suggest a minimal or weak direct influence of pelvic parameters on cervical sagittal alignment, which does not follow the expected correlation chain [21].

The results of our study are consistent with those of Nunez-Pereira et al. [13], Lee et al. [22], and Shao et al. [23], who found very weak correlations between CL and LL (r=0.1, p<0.01), as well as between C0–C2 and sacral slope (SS) (r=−0.1, p<0.05) in asymptomatic healthy volunteers. Similarly, the study by Alijani and Rasoulian [21] among the Iranian population found a weak correlation between the C1–C2 angle and LL (r=0.1, p=0.01) in symptomatic individuals. Additionally, CL (C2–C7) showed weak correlations with PI (r=0.1, p=0.04) and PT (r=0.12, p=0.003) [21]. Our study also found weak negative correlations between PI and C7 slope, PT and T1 slope−CL mismatch, and PT and C2 slope (r=−0.202, p=0.05). Additionally, PI–LL mismatch showed weak correlations with TIA, T1S, and C7 slope. These findings highlight the importance of evaluating global spinal sagittal alignment as a whole, considering correlations between different regions, rather than in isolation or only among non-contiguous segments (Supplement 2A, B).

The chain of correlations indicates that increased CL leads to increased T1S, leading to an increase in TK and LL, all related to PI [24]. However, studies on cervical alignment, including pelvic and thoracolumbar alignment, showed no direct correlation between LL and CL, emphasizing the complex interconnections between cervical, thoracic, lumbar, and pelvic regions [25,26]. LL and PI directly influence TK, which in turn indirectly affects cervical sagittal alignment [22,27]. This suggests an interdependence among cervical parameters. However, the impact of LL and pelvic parameters on the cervical spine remains unclear [22,28].

The concept of the C7 slope, introduced by Le Hue et al. [18], is the foundation for understanding global cervical alignment. It is defined as the angle of the C7 vertebra, with values categorized as either less than or greater than 20° [18]. Another study utilized a T1S value greater than 26° as a threshold. However, due to difficulties in visualizing T1, the C7 slope is a more practical surrogate variable for studying cervical sagittal alignment [29]. The study by Nunez-Pereira et al. [13] identified the C7 slope as a crucial link between pelvic, spinal, and cervical parameters, showing it is an important indicator of global sagittal balance. Furthermore, their study underscored the direct relationship between the thoracolumbar and cervical spine. Notably, an altered C7 slope on cervical X-ray may signal potential global sagittal imbalance, warranting a full spinal evaluation, which can inform and refine the surgical plan [13].

The study’s limitations include its focus on asymptomatic patients within a specific age group, not accounting for cervical pathology, and not using advanced imaging techniques to rule out degenerative pathology (e.g., magnetic resonance imaging). The asymptomatic cohort limits the clinical significance of the findings, as the correlations might be more relevant in patients with cervical malalignment or degenerative conditions. Additionally, the study is constrained by the small sample size and retrospective design, highlighting the need for a larger prospective study to obtain more robust findings.

Conclusions

Our study highlights that spinopelvic and cervical alignment are significantly interdependent in asymptomatic individuals. Key spinopelvic parameters (PT, PI, and PI–LL mismatch) correlate with cervical parameters (C2 slope, C7 slope, T1 slope, and TIA), highlighting the interconnectedness of the pelvis, lumbar spine, thoracic spine, and cervical spine in determining global spinopelvic sagittal alignment.

Key Points

Cervical sagittal parameters significantly correlate with spinopelvic parameters.
Pelvic tilt, pelvic incidence, and pelvic incidence–lumbar lordosis mismatch exhibit significant correlation with C2 slope, C7 slope, T1 slope, and thoracic inlet angle.
The study highlights the interconnectedness between the pelvis, lumbar spine, thoracic spine, and cervical spine in determining global spinopelvic sagittal alignment.

Notes

Conflict of Interest

No potential conflict of interest relevant to this article was reported.

Author Contributions

Conceptualization: JEMM, KR, APS. Methodology: JEMM, KR, PRI. Investigation: JEMM, KR, PRI, APS. Data curation: JEMM, KR, PRI. Formal analysis: JEMM, KR, APS. Writing–original draft: JEMM, KR. Visualization: KR, APS. Writing–review & editing: KR, APS, PRI, SR. Project administration: APS, SR. Supervision: APS, SR. Validation: SR, APS. Final approval of the manuscript: all authors.

Supplementary Materials

Supplementary materials can be available from https://doi.org/10.31616/asj.2025.0145.

Supplement 1. Age wise distribution of various parameters.

Supplement 2. Summary of a chain of correlation of the global spine alignment.

asj-2025-0145-Supplement.pdf

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Table 1

Definitions of various radiological parameters

Variable	Definition
C0–C2 Cobbs angle	The angle between the McRae line and inferior endplate of C2 vertebra
C1–C2 Cobbs angle	The angle created by a line drawn parallel to the inferior aspect of C1 and the line below C2
C2 slope	The angle between lower endplate of C2 and a horizontal reference line
Cervical lordosis (C2–C7)	The angle between superior endplate of C2 and inferior endplate of C7 vertebra
C7 slope	The angle created by a line parallel to the superior endplate of C7 and a horizontal reference line
Cervical sagittal vertical axis	The measurement of horizontal distance between the C7 vertebral body and the plumb line from the C2
McGregor slope	The angle between the line from the hard palate to the occipital bone and the horizontal line
Thoracic inlet angle (TIA)	The angle created by a line from the center of the T1UEP perpendicular to the T1UEP and a line connecting the center of the T1UEP and the upper end of the sternum
T1 slope (T1S)	T1 slope is the angle between the superior endplate of the T1 vertebra and a horizontal line
Neck tilt (NT)	The angle formed by the reference vertical line drawn in the upper end of the sternum and a line connecting the center of the T1 upper end plate
T1 slope–cervical lordosis mismatch	Difference between T1slope and cervical lordosis
Thoracic kyphosis (TK)	Angle between upper endplate of T1 and lower endplate of T12 vertebra
Upper thoracic kyphosis (UTK)	Angle between upper endplate of T1 and lower endplate of T5 vertebra
Lower thoracic kyphosis (LTK)	Angle between upper endplate of T5 and lower endplate of T12 vertebra
Lumbar lordosis (LL)	Angle created by a line parallel to the superior endplate of L1 and a line parallel to the superior endplate of S1
Pelvic incidence–lumbar lordosis mismatch	Difference between pelvic incidence and lumbar lordosis
Pelvic incidence (PI)	The angle created by a line drawn from the hip axis to the midpoint of the sacral end plate and a line perpendicular to the center of the sacral end plate
Sacral slope (SS)	The angle created by a line parallel to the superior endplate of S1 and a horizontal reference line
Pelvic tilt (PT)	The angle created by a straight line connecting the midpoint of the bilateral femoral head center to the midpoint of the sacral plate and the plumb line

Variable	Mean±SD	Min	Max
Thoracic alignment
TK: T1–T12 (°)	30.95±10.928	5	52
UTK: T1–T5 (°)	11.133±7.2546	2	32.4
LTK: T5–T12 (°)	30.041±11.4528	2.1	61
Cervical alignment
Cervical upper
McGregor slope (°)	2.118±13.3506	−29	37.8
C0–C2 angle (°)	4.3342±20.90135	−40	50
C1–C2 angle (°)	−21.63±11.381	4	−45
C2 slope (°)	2.31±11.420	−35	27
Cervical lower
CL: C2–C7 (°)	−24.27±14.902	4	−50
C7 slope (°)	23.0735±8.34865	0	42
cSVA C2–C7 (mm)	20.65±9.783	−6	39
Cervicothoracic
TIA (°)	85.20±10.646	55	120
NT (°)	59.62±9.290	38	85
T1 slope (°)	26.26±8.236	3	50
T1 slope–CL mismatch (°)	2.033±13.0149	−34	29
Pelvic parameter
PI (°)	45.43±9.717	20	75
SS (°)	33.51±7.968	11	50
PT (°)	11.88±8.096	−13	35
Lumbar parameter
LL: L1–S1 (°)	−51.26±12.456	−11	−75
LL: L4–S1 (°)	−41.606±8.74	−17	−60
LL: L1–L4 (°)	−20.096±12.68	29	−47
PI–LL mismatch (°)	−5.70±12.940	−36	38

Variable	Category	SS	PT	PI
SS	Pearson correlation	1	−0.259^**	0.602^**
	p-value	-	0.008	0.000
	No. of patients	104	104	104
PT	Pearson correlation	−0.259^**	1	0.613^**
	p-value	0.008	-	0.000
	No. of patients	104	104	104
LL: L1–S1	Pearson correlation	−0.734^**	0.312^**	−0.344^**
	p-value	0.000	0.001	0.000
	No. of patients	104	104	104
LL: L4–S1	Pearson correlation	−0.455^**	0.331^**	−0.086
	p-value	0.000	0.001	0.386
	No. of patients	104	104	104
LL: L1–L4	Pearson correlation	−0.534^**	0.162	−0.312^**
	p-value	0.000	0.101	0.001
	No. of patients	104	104	104
PL–LL mismatch	Pearson correlation	−0.256^**	0.762^**	0.419^**
	p-value	0.009	0.000	0.000
	No. of patients	104	104	104

Variable	Category	TK: T1–T12	UTK: T1–T5	LTK: T5–T12
PI	Pearson correlation	−0.114	−0.021	−0.032
	p-value	0.248	0.830	0.748
	No. of patients	104	104	104
PT	Pearson correlation	−0.085	−0.018	−0.117
	p-value	0.389	0.855	0.237
	No. of patients	104	104	104
SS	Pearson correlation	−0.051	−0.016	0.084
	p-value	0.604	0.871	0.396
	No. of patients	104	104	104
LL: L1–S1	Pearson correlation	−0.501^**	−0.181	−0.499^**
	p-value	0.000	0.065	0.000
	No. of patients	104	104	104
LL: L4–S1	Pearson correlation	−0.330^**	0.189	−0.463^**
	p-value	0.001	0.055	0.000
	No. of patients	104	104	104
LL: L1–L4	Pearson correlation	−0.330^**	−0.348^**	−0.267^**
	p-value	0.001	0.000	0.006
	No. of patients	104	104	104
PI–LL mismatch	Pearson correlation	−0.574^**	−0.191	−0.508^**
	p-value	0.000	0.052	0.000
	No. of patients	104	104	104

Table 5

Correlation between the thoracic parameters and cervical parameters

Variable	Category	TK: T1–T12	UTK: T1–T5	LTK: T5–T12
T1S	Pearson correlation	0.628^**	0.056	0.230^*
	p-value	0.000	0.575	0.019
	No. of patients	104	104	104
TIA	Pearson correlation	0.294^**	0.261^**	0.283^**
	p-value	0.002	0.008	0.004
	No. of patients	104	104	104
CL: C2–C7	Pearson correlation	−0.321^**	−0.036	−0.059
	p-value	0.001	0.714	0.550
	No. of patients	104	104	104
NT	Pearson correlation	−0.189	0.250^*	0.119
	p-value	0.055	0.010	0.227
	No. of patients	104	104	104
C0–C2	Pearson correlation	0.116	−0.090	−0.132
	p-value	0.243	0.366	0.183
	No. of patients	104	104	104
C1–C2	Pearson correlation	0.024	−0.181	−0.040
	p-value	0.807	0.067	0.689
	No. of patients	104	104	104
cSVA C2/C7	Pearson correlation	0.093	0.025	0.095
	p-value	0.350	0.803	0.338
	No. of patients	104	104	104
T1S–CL	Pearson correlation	0.044	0.007	0.065
	p-value	0.660	0.941	0.513
	No. of patients	104	104	104
McGregor slope	Pearson correlation	0.129	−0.072	−0.119
	p-value	0.194	0.465	0.228
	No. of patients	104	104	104
C7 slope	Pearson correlation	0.575^**	0.126	0.245^*
	p-value	0.000	0.202	0.012
	No. of patients	104	104	104
C2 slope	Pearson correlation	0.035	0.027	0.075
	p-value	0.723	0.786	0.449
	No. of patients	104	104	104

TK, thoracic kyphosis; UTK, upper thoracic kyphosis; LTK, lower thoracic kyphosis; TIA, thoracic inlet angle; CL, cervical lordosis; NT, neck tilt; cSVA, cervical sagittal vertical axis.

p<0.05: Correlation is significant at the 0.05 level (2-tailed).

^**

p<0.01: Correlation is significant at the 0.01 level (2-tailed).

Variable	Category	PI	SS	PT	LL	PI–LL mismatch
TIA	Pearson correlation	−0.018	0.015	−0.047	−0.191	−0.197^*
	p-value	0.859	0.883	0.637	0.053	0.045
	No. of patients	104	104	104	104	104
NT	Pearson correlation	0.076	0.096	−0.017	−0.098	−0.032
	p-value	0.444	0.335	0.862	0.321	0.751
	No. of patients	104	104	104	104	104
T1S	Pearson correlation	−0.126	−0.094	−0.059	−0.128	−0.228^*
	p-value	0.201	0.345	0.549	0.194	0.020
	No. of patients	104	104	104	104	104
CL	Pearson correlation	−0.015	0.120	−0.135	0.019	0.014
	p-value	0.877	0.225	0.173	0.847	0.891
	No. of patients	104	104	104	104	104
T1S–CL mismatch	Pearson correlation	−0.095	0.119	−0.229^*	−0.106	−0.171
	p-value	0.337	0.230	0.019	0.283	0.083
	No. of patients	104	104	104	104	104
C7 slope	Pearson correlation	−0.212^*	−0.172	−0.073	−0.098	−0.251^*
	p-value	0.031	0.080	0.459	0.322	0.010
	No. of patients	104	104	104	104	104
C2 slope	Pearson correlation	−0.073	0.121	−0.202^*	−0.088	−0.133
	p-value	0.463	0.223	0.039	0.373	0.178
	No. of patients	104	104	104	104	104