The association of vertebral compression fracture progression with paraspinal muscle and psoas muscle degeneration

The association of VCF progression with sarcopenia

Article information

J Korean Soc Geriatr Neurosurg. 2022;18(1):1-7

Publication date (electronic) : 2022 June 27

doi : https://doi.org/10.51638/jksgn.2022.00045

, Hae Yu Kim

, Sun Il Lee

Department of Neurosurgery, Inje University Haeundae Paik Hospital, Inje University College of Medicine, Busan, Korea

Corresponding Author: Joon-Bum Woo, MD Department of Neurosurgery, Inje University Haeundae Paik Hospital, Inje University College of Medicine, 875 Haeun-daero, Haeundae-gu, Busan 48108, Korea Tel: +82-51-797-0840; Fax: +82-51-797-0841; E-mail: nanna0225@naver.com

Received 2022 March 29; Revised 2022 May 20; Accepted 2022 May 20.

Abstract

Objective

Few studies have investigated the relationship between spinal muscle fatty degeneration and vertebral compression fracture (VCF) progression. This study investigated the associations among spinal muscle fatty degeneration, functional support of the spinal muscles, and VCF progression.

Methods

We retrospectively evaluated 49 consecutive elderly patients over 65 years of age who had VCFs between 2013 and 2020. Change in height loss was defined as the difference in height loss in vertebral collapse between the initial and >6-month follow-up visits. Fatty infiltration of the paraspinal and psoas muscles was measured using T2-weighted magnetic resonance imaging at L3 and L4.

Results

The VCF height loss change was 6.53±4.90 mm. The cross-sectional area of the paraspinal muscle was 2,418.00±496.00 mm². The fatty infiltration rate of the paraspinal muscle was 4.46%±1.70%. Mild VCF height loss (a change o≤9 mm) was found in 36 patients (group 0), while severe height loss (a change >9 mm) was observed in 13 patients (group 1). The paraspinal-to-psoas muscle ratio was 2.51 in group 0 and 3.33 in group 1 (P=0.002). The paraspinal muscle mass (P=0.02), bone mineral density (P=0.05), and paraspinal-to-psoas muscle mass ratio (P=0.01) affected VCF progression. The odds ratio of the paraspinal-to-psoas muscle ratio was 4.39.

Conclusion

The paraspinal-to-psoas muscle ratio strongly influences VCF progression. In patients with VCF, progression can be predicted using the paraspinal-to-psoas muscle ratio before ambulation.

Keywords: Paraspinal muscles; Fractures, compression; Sarcopenia; Spine

Introduction

The prevalence of degenerative diseases, such as osteoporosis, muscle degeneration, and degenerative spine disease, is high in the elderly. In addition, the aging population is rapidly increasing, and the incidence of osteoporosis and degenerative diseases is increasing along with it. Osteoporosis is characterized by bone microarchitecture destruction and bone quality degradation [1], leading to decreased bone strength due to decreased bone mineral density (BMD) or poor bone quality. Osteoporotic fractures can occur easily with minor trauma or even without any noticeable trauma in these patients [2]. However, elderly patients with degenerative diseases may develop vertebral compression fracture (VCF), with or without osteoporosis. VCF affects quality of life, daily activities, and mortality in elderly patients [3]. In South Korea, the 5-year incidence of osteoporotic VCF per 100,000 persons is 852.24 cases, and 45% of osteoporotic VCF cases occur in patients over 70 years of age. Moreover, vertebral body cement augmentation or any surgical approach rate and total cost related to VCF are increasing [4].

Patients with VCF are treated with conservative care with bed rest and bracing. Conservative care generally has a good outcome. However, some VCF patients have severe vertebral body height loss and fractured bony fragment compression of the spinal cord or thecal sac. VCF progression can result in neurological deficits and spinal deformity, in which patients experience reduced daily activities, prolonged severe back pain, and reduced quality of life. In this case, surgical treatment is subsequently required.

Therefore, it is important to predict and prevent the progression of VCF. Previous studies have focused on VCF progression and have analyzed vertebral body fracture shape, presence of an intravertebral cleft, posterior wall damage, middle column damage, and VCF progression [5,6]. However, few studies have investigated the association between spinal muscle fatty degeneration and VCF progression, which were published only recently [7,8]. Therefore, our study is an additional study on the association between spinal muscles fatty degeneration, functional support of the spinal muscles, and VCF progression.

Material and Method

The study protocol was approved by the Institutional Review Board of Inje University Haeundae Paik Hospital (IRB no.2022-05-024). The requirement for informed consent was waived owing to the retrospective nature of this study. We retrospectively evaluated 186 consecutive elderly patients over 65 years of age who had VCFs between 2013 and 2020. Patients who was examined lumbar magnetic resonance imaging (MRI) and follow-up X-ray were selected. VCF levels were limited to thoracolumbar and lumbar lesions. Patients with BMD and osteoporosis were also included. The exclusion criteria were as follows: (1) no MRI performed, (2) no follow-up X-ray image (>6 months) and (3) image could not be evaluated. In total, 49 patients were enrolled in this study.

Radiological parameters

All patients underwent plain X-ray and MRI. Sagittal plain X-ray was obtained for the initial VCF, first follow-up X-ray image one weeks later and at 1, 3, and >6 months. MRI was performed during hospitalization after VCF onset. VCF height loss was measured as the point of maximal collapse of the affected vertebral body; vertebral collapse (%) was measured using the formula {(upper vertebral height+lower vertebral height)/2–(affected vertebral height)/(upper vertebral height+lower vertebral height)/2}×100 (Fig. 1) [9]. Change in height loss was defined as difference in height loss in vertebral collapse between the initial and >6-month follow-up. Fatty infiltration of the paraspinal and psoas muscles was measured using T2-weighted MRI at L3 and L4. We used the open-source software ImageJ (ver. 1.53 k, Wayne Rasband, National Institutes of Health, Bethesda, MD, USA). Fatty infiltration of the multifidus, erect spinae, and psoas muscle were determined by measuring the cross-sectional area (CSA) of the muscles in T2-weighted MRI using the threshold grayscale in ImageJ (Fig. 2) [7,8]. The paraspinal muscle mass, excluding fat, was calculated by multiplying the ratio of fat by the simple area of the paraspinal muscle. The actual paraspinal muscle mass was measured using the following formula {CSA of the paraspinal muscle−[paraspinal muscle fat ratio (%)×CSA of the paraspinal muscle (mm²)]}. We evaluated all methods used previously was applied to measure the psoas muscle mass. The paraspinal muscle to psoas muscle mass ratio was measured using the formula (CSA of the paraspinal muscle/CSA of the psoas muscle).

Fig. 1.

Vertebral compression fracture height loss was measured as the point of maximal collapse of the affected vertebral body. Vertebral collapse (%) was measured using the formula {(upper vertebral height+lower vertebral height)/2–(affected vertebral height)/(upper vertebral height+lower vertebral height)/2}×100. a, Upper vertebral height; b, lower vertebral height; c, affected vertebral height.

Fig. 2.

Fatty infiltration of the multifidus, erect spinae, and psoas muscle were determined by measuring the cross-sectional area of the muscles in T2-weighted magnetic resonance images using the threshold grayscale in ImageJ.

Statistical analysis

All statistical analyzes were performed using R ver. 4.1.2. A 2-sample t-test was performed for continuous variables that satisfied covariance. Welch’s 2-sample t-test was performed for continuous variables that did not satisfy covariance. Logistic regression analysis was performed for categorical and continuous variables. Stepwise logistic regression analysis was performed using backward elimination. Odds ratios (ORs) between the related factors were calculated. Statistical significance was set at a P-value of <0.05.

Results

Patient characteristics and radiological parameters

The average age of the 49 patients was 79.12±8.59 years, and there were 30 female and 19 male patients. BMD was −2.02±1.87. Body mass index (BMI) was 23.65±2.00 kg/m². The follow-up VCF height loss change was 6.53±4.90 mm. The CSA of the paraspinal muscle was 2,418.00±496.00 mm². Fatty infiltration rate of the paraspinal muscle was 4.46%±1.70%. The CSA of the psoas muscle was 962.00±351.00 mm². Fatty infiltration rate of the psoas muscle was 1.00%±0.50%. The revised paraspinal muscle is a value obtained by subtracting the fatty infiltration area from the CSA of the paraspinal muscle area. The revised paraspinal muscle was 2,310.00±481.00 mm². The paraspinal-to-psoas muscle mass ratio was 2.73±0.82. Sixteen patients required surgical procedures, including posterolateral fusion in 3 cases, corpectomy with posterior pedicle screw insertion in 2 cases, and vertebroplasty in 11 cases. The mean number of cases that received osteoporosis medications was 20 (Table 1).

Table 1.

Patients’ characteristics and radiological parameters

Relationship between VCF height loss progression and fatty infiltration of the paraspinal and psoas muscle

The mild VCF height loss group (n=36, group 0) included cases of VCF height loss change of ≤9 mm, and the severe height loss group (n=13, group 1) included cases of VCF height loss change of >9 mm. The groups were divided using the mean and standard deviation of height loss in all cases. The paraspinal-to-psoas muscle ratio was 2.51 in group 0 and 3.33 in group 1 (P=0.002). The CSA of fatty infiltration of the paraspinal muscle was 102.17 mm² for group 0 and 121.96 mm² for group 1 (P=0.28). The paraspinal muscle mass was 2,383.63 mm² in group 0 and 2,512.07 mm² in group 1 (P=0.43). The revised paraspinal muscle [CSA paraspinal muscle (mm²)×Paraspinal muscle fat infiltration(%)−CSA Psoas muscle (mm²)×Psoas muscle fat infiltration (%)] was 2,281.46 mm² in group 0 and 2,390.11 mm² in group 1 (P=0.49). The revised psoas muscle was 1,004.8 mm² in group 0 and 844.80 mm² in group 1 (P=0.16) (Table 2).

Table 2.

Relationship between vertebral compression fracture height loss change and fatty infiltration of the paraspinal and psoas muscles

Logistic regression was performed to verify the relationship between the number of radiological factors and VCF height loss changes. The paraspinal-to-psoas muscle ratio showed an OR,13.42; 95% confidence interval (CI), 0.75−882.90; P=0.10, fatty infiltration of the paraspinal muscle had an OR, 0.17; 95% CI, 0−4.8; P=0.30, and BMD showed a negative relationship with an OR, 0.50; 95% CI, 0.18−1.10; P=0.10). Stepwise logistic regression analysis was performed using backward elimination. The paraspinal muscle mass (P=0.02), BMD (P=0.05), and paraspinal-to-psoas muscle mass ratio (P=0.01) remained unchanged. The OR of the paraspinal-to-psoas muscle ratio was OR, 4.39; 95% CI, 1.32−14.56 (P=0.01). However, the paraspinal muscle OR was 1, which did not significantly affect the results. (Table 3, Fig. 3)

Table 3.

Logistic regression between parameters and vertebral compression fracture progression

Fig. 3.

The odds ratio (OR) of the paraspinal-to-psoas muscle ratio was 4.39. However, the OR for the paraspinal muscle was 1, showing a non-significant effect. CI, confidence interval; BMD, bone mineral density.

Discussion

Muscle degeneration is associated with an increased risk of bone fracture and difficulty in performing daily living activities. Sarcopenia is the loss of muscle mass associated with aging and advanced disease. It has previously been shown to predict complications and mortality in patients undergoing emergency surgery, surgical oncology, and organ transplantation [10–12].

VCF has a high prevalence in older patients, and VCF height loss change greatly reduces their quality of life. The paraspinal and psoas muscles are expected to influence VCF progression. Bayram et al. [13] previously reported that psoas muscle degeneration was associated with mortality in VCF patients using the psoas muscle:lumbar vertebral index. Although no statistical significance was observed in this study, group 1 (severe VCF height loss) showed lower psoas muscle mass. In addition, Bokshan et al. [14] reported that L4 total psoas muscle sarcopenia increased postoperative morbidity in patients who underwent spine surgery.

Paraspinal muscles have a major impact on the maintenance of spinal alignment. Thus, paraspinal muscle atrophy, fatty infiltration, and degeneration affect the spinal sagittal balance and global alignment [15,16]. The relationship between paraspinal muscle and lumbar pathology has been reported in previous studies. Jun et al. [15] reported that fatty infiltration of the paraspinal muscles was significantly negatively correlated with the thoracolumbar curve. Habibi et al. [17] reported that fatty infiltration of the paraspinal muscle in the thoracolumbar region is correlated with the occurrence of new osteoporotic VCF. Katsu et al. [18] reported that the erect spinal muscle has a marked influence on fracture union of the VCF. However, Osterhoff et al. [7] reported that the multifidus area and fatty infiltration had no significant effect on the occurrence of adjacent vertebral fractures within 1 year of the index fracture. In addition, the paraspinal muscle does not affect vertebral collapse but the revised paraspinal muscle does. The paraspinal muscle affects functional movement and stability of the vertebral column [19,20]. In this study, the paraspinal muscle mass was greater in group 1, but fatty infiltration showed a higher average in group 1, regardless of muscle mass. However, the difference was not statistically significant. Moreover, it was difficult to determine the relationship with paraspinal muscle VCF progression, even when logistic regression was performed.

Therefore, in this study, unlike previous studies that independently studied the psoas and paraspinal muscles, we investigated how the relationship between the degeneration of the 2 muscles affects VCF progression. As a result, the paraspinal-to-psoas muscle ratio was higher in group 1. This suggests that degeneration in the psoas muscle is more associated with VCF progression than that in the paraspinal muscle. In addition, when logistic regression analysis with various factors was performed, the paraspinal-to-psoas muscle ratio (P=0.05) showed the greatest correlation with the OR of 4.39. Many studies have independently investigated the paraspinal and psoas muscles, but ours is the first to report on the relationship between the 2 muscles, and as such, there has not been a study on the cause of VCF progression in a group with a large paraspinal-to-psoas muscle ratio. With respect to muscle function, the psoas muscle affects the bipedal walking function [21]. In group 1, with a large paraspinal-to-psoas muscle ratio, bipedal walking function further decreases and muscle fatigue occurs because of the small size of the functional muscle mass when standing or walking. So group 1 patient should be need a more absolute bed resting and early bed side rehabilitation for psoas muscle and paraspinal muscle. During in hospitalization, if group 1 patient low back pain will not improve, it may be a sign that there is no bone union in the vertebral body [8].

This study had several limitations. First, the sample size was small. Further research based on additional cases in follow-up studies is required. Second, muscle mass and fatty infiltration were assessed using images at specific time points. MRI obtained at regular intervals would have resulted in better results. Third, there may have been errors during measurement. Because millimeter is a very small and sensitive unit, there may have been errors during measurement.

Conclusion

In this study, the associations between BMI, BMD, paraspinal muscle, psoas muscle, muscle fatty infiltration, paraspinal-to-psoas muscle ratio, and VCF progression were analyzed. Among the various factors, the paraspinal–psoas muscle ratio strongly influences VCF progression. In patients with VCF, VCF progression can be predicted using the paraspinal-to-psoas muscle ratio before ambulation.

Notes

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

References

1. Rubin MP, Chechurin RE, Zubova OM. Osteoporosis: diagnosis, current approaches to treatment, prophylaxis. Ter Arkh 2002;74:32–7.

2. Kim SS, Lee DH, Kim JH, et al. Risk Factors for subsequent vertebral compression fracture following osteoporotic compression fracture. J Korean Orthop Assoc 2016;51:479–85.

3. Crans GG, Silverman SL, Genant HK, Glass EV, Krege JH. Association of severe vertebral fractures with reduced quality of life: reduction in the incidence of severe vertebral fractures by teriparatide. Arthritis Rheum 2004;50:4028–34.

4. Choi SH, Kim DY, Koo JW, Lee SG, Jeong SY, Kang CN. Incidence and management trends of osteoporotic vertebral compression fractures in South Korea: a nationwide population-based study. Asian Spine J 2020;14:220–8.

5. Ha KY, Kim YH. Risk factors affecting progressive collapse of acute osteoporotic spinal fractures. Osteoporos Int 2013;24:1207–13.

6. Goldstein S, Smorgick Y, Mirovsky Y, Anekstein Y, Blecher R, Tal S. Clinical and radiological factors affecting progressive collapse of acute osteoporotic compression spinal fractures. J Clin Neurosci 2016;31:122–6.

7. Osterhoff G, Asatryan G, Spiegl UJ, Pfeifle C, Jarvers JS, Heyde CE. Impact of multifidus muscle atrophy on the occurrence of secondary symptomatic adjacent osteoporotic vertebral compression fractures. Calcif Tissue Int 2022;110:421–7.

8. Jeon I, Kim SW, Yu D. Paraspinal muscle fatty degeneration as a predictor of progressive vertebral collapse in osteoporotic vertebral compression fractures. Spine J 2022;22:313–20.

9. Baba H, Maezawa Y, Kamitani K, Furusawa N, Imura S, Tomita K. Osteoporotic vertebral collapse with late neurological complications. Paraplegia 1995;33:281–9.

10. Du Y, Karvellas CJ, Baracos V, Williams DC, Khadaroo RG; Acute Care and Emergency Surgery (ACES) Group. Sarcopenia is a predictor of outcomes in very elderly patients undergoing emergency surgery. Surgery 2014;156:521–7.

11. Reisinger KW, van Vugt JL, Tegels JJ, et al. Functional compromise reflected by sarcopenia, frailty, and nutritional depletion predicts adverse postoperative outcome after colorectal cancer surgery. Ann Surg 2015;261:345–52.

12. Englesbe MJ, Patel SP, He K, et al. Sarcopenia and mortality after liver transplantation. J Am Coll Surg 2010;211:271–8.

13. Bayram S, Akgül T, Adıyaman AE, Karalar Ş, Dölen D, Aydoseli A. Effect of sarcopenia on mortality after percutaneous vertebral augmentation treatment for osteoporotic vertebral compression fractures in elderly patients: a retrospective cohort study. World Neurosurg 2020;138:e354–60.

14. Bokshan SL, Han AL, DePasse JM, et al. Effect of sarcopenia on postoperative morbidity and mortality after thoracolumbar spine surgery. Orthopedics 2016;39:e1159–64.

15. Jun HS, Kim JH, Ahn JH, et al. The effect of lumbar spinal muscle on spinal sagittal alignment: evaluating muscle quantity and quality. Neurosurgery 2016;79:847–55.

16. Masaki M, Ikezoe T, Fukumoto Y, et al. Association of walking speed with sagittal spinal alignment, muscle thickness, and echo intensity of lumbar back muscles in middle-aged and elderly women. Aging Clin Exp Res 2016;28:429–34.

17. Habibi H, Takahashi S, Hoshino M, et al. Impact of paravertebral muscle in thoracolumbar and lower lumbar regions on outcomes following osteoporotic vertebral fracture: a multicenter cohort study. Arch Osteoporos 2021;16:2.

18. Katsu M, Ohba T, Ebata S, Haro H. Comparative study of the paraspinal muscles after OVF between the insufficient union and sufficient union using MRI. BMC Musculoskelet Disord 2018;19:143.

19. Crisco JJ 3rd, Panjabi MM. The intersegmental and multisegmental muscles of the lumbar spine: a biomechanical model comparing lateral stabilizing potential. Spine (Phila Pa 1976) 1991;16:793–9.

20. McGill SM, Grenier S, Kavcic N, Cholewicki J. Coordination of muscle activity to assure stability of the lumbar spine. J Electromyogr Kinesiol 2003;13:353–9.

21. Sanaka K, Hashimoto K, Kurosawa D, et al. The psoas major muscle is essential for bipedal walking: an analysis using a novel upright bipedal-walking android model. Gait Posture 2022;94:15–8.

Article information Continued

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Table 1.

Patients’ characteristics and radiological parameters

Characteristic	Value
Age (yr)	79.12±8.59
Sex (female/male)	30/19
Bone mineral density	−2.02±1.87
Body mass index (kg/m²)	23.65±2.00
VCF height loss change (mm)	6.53±4.90
CSA of the paraspinal muscle (mm²)	2,418.00±496.00
Paraspinal muscle fat infiltration (%)	4.46±1.70
CSA of the psoas muscle (mm²)	962.00±351.00
Psoas muscle fat infiltration (%)	1.00±0.50
Revised paraspinal muscle (mm²)	2,310.00 ±481.00
Paraspinal-to-psoas muscle ratio	2.73±0.82
Operation cases	16
Posterior lateral fusion	5
Mesh	2
Vertebroplasty	11
Fracture site
Multiple	18
T12	1
L1	11
L2	10
L3	4
L4	5
Osteoporosis medication	20

Values are presented as mean±standard deviation or number only.

VCF, vertebral compression fracture; CSA, cross-sectional area.

Table 2.

Relationship between vertebral compression fracture height loss change and fatty infiltration of the paraspinal and psoas muscles

	Mild height loss	Severe height loss	P-value
	Group 0 (n=36)	Group 1 (n=13)	P-value
Paraspinal-to-psoas muscle ratio^*	2.51	3.33	0.002
Paraspinal muscle fat infiltration (mm²)	102.17	121.96	0.28
Paraspinal muscle (mm²)	2,383.63	2,512.07	0.43
Revised paraspinal muscle (mm²)	2,281.46	2,390.11	0.49
Psoas muscle (mm²)	1,004.80	844.80	0.16

P<0.05.

Table 3.

Logistic regression between parameters and vertebral compression fracture progression

	OR	95% CI	P-value
Multivariate
Paraspinal fat infiltration	0.17	0−4.8	0.30
Paraspinal muscle	1.08	0.95−1.30	0.10
Bone mineral density	0.50	0.18−1.10	0.10
Bone mass index	1.11	0.83−1.50	0.50
Paraspinal-to-psoas muscle ratio	13.42	0.75−882.90	0.10
Revised paraspinal muscle	0.92	0.76−1.10	0.10
Psoas muscle	1.00	0.99−1.00	0.10
Stepwise logistic regression
Paraspinal muscle	1.00	1.00−1.00	0.02
Bone mineral density	0.46	0.21−1.02	0.05
Paraspinal-to-psoas muscle ratio	4.39	1.32−14.56	0.01

OR, odds ratio; CI, confidence interval.