Magnetic Resonance Imaging of Trunk Musculature and Intervertebral Discs in Patients with Spinal Cord Injury with Thoracolumbar Vertebral Fractures: A Prospective Study

Article information

Asian Spine J. 2020;14(6):829-846
Publication date (electronic) : 2020 March 30
doi : https://doi.org/10.31616/asj.2019.0003
1Department of Orthopaedic Surgery, Paraplegia & Rehabilitation, Pandit Bhagwat Dayal Sharma Post Graduate Institute of Medical Sciences, Rohtak, India
2Department of Anaesthesiology and Critical Care, Pandit Bhagwat Dayal Sharma Post Graduate Institute of Medical Sciences, Rohtak, India
Corresponding author: Roop Singh Department of Orthopaedic Surgery, 52/9-J, Medical Enclave, Post Graduate Institute of Medical Sciences, Rohtak-124001, Haryana, India Tel: +91-1262-283171, Fax: +91-1262-281308, E-mail: drroopsingh@rediffmail.com
Received 2019 January 6; Revised 2019 September 25; Accepted 2019 October 23.

Abstract

Study Design

This study is a prospective clinical study.

Purpose

This study aims to evaluate the characteristics of trunk musculature and intervertebral discs by using magnetic resonance imaging in patients with spinal cord injuries (SCIs) with thoracic and lumbar fractures.

Overview of Literature

Muscle atrophy is an immediate consequence of SCI and is associated with secondary complications. At present, there are limited clinical data on muscle and disc responses to fractures of the thoracic and lumbar spine.

Methods

A total of 51 patients with a mean age of 31.75±10.42 years who suffered traumatic SCI were included in this study. Complete neurological examinations (American Spinal Injury Association grading) and magnetic resonance imaging (MRI) were performed at the time of admission and at 3–6 months after injury to study the neurological status and disc and trunk parameters. The type of management (operative or conservative) was decided on the basis of clinical, radiological, and MRI evaluations, and a robust rehabilitation program was initiated.

Results

Disc parameters including disc angle, skin angle, cross-sectional area (CSA), and disc height and trunk parameters (mean trunk width, mean trunk depth, and CSA of the lumbar muscles) decreased significantly (p <0.001) during the first 3 months after SCI. However, improvements were observed in disc and muscle parameters at the 6-month follow-up, but these parameters did not return to normal levels. Neither initial neurological status (complete vs. incomplete) nor type of management (operative vs. conservative) had a significant effect on these parameters.

Conclusions

Spinal trauma leads to alterations in the morphology of the vertebral column, spinal cord, intervertebral discs, and paraspinal muscles in the initial phase of injury. The extent of these changes may determine the initial neurological deficit and subsequent recovery. Although this study did not identify any statistically significant effect of neurological status or management strategy on these parameters, rehabilitation was found to result in the improvement of these parameters in the later phase of recovery. Future studies are required to evaluate the exact causes of these alterations and the potential benefits of rehabilitation strategies and to minimize these changes.

Introduction

Acute traumatic spinal cord injury (SCI) is one of the most devastating injuries for the human body. This injury causes immediate and, in some areas, permanent gravitational unloading, thus resulting in structural changes due to disuse and associated metabolic consequences. Osteoporosis and muscle atrophy are the frequently encountered complications of SCI [1,2], and these conditions occur rapidly after injury and are associated with several secondary complications. Inactivation and extreme unloading following SCI can lead to marked atrophy of the leg and thigh skeletal muscles within a few months of injury [3].

A number of studies have evaluated the utility of various magnetic resonance imaging (MRI) parameters in relation to neurological performance following SCI; however, there is little information available on the response of intervertebral disc and paravertebral muscles to spinal trauma. The present study was conducted to evaluate the MRI data of trunk musculature and discs in patients who had suffered SCI with thoracic and lumbar vertebral fractures. We hypothesized that spinal trauma affects the trunk musculature and intervertebral discs and suggest that the information presented here deepens our understanding of muscular wasting, appropriate rehabilitation strategies, and approaches for improving the ultimate outcome of SCI.

Materials and Methods

This prospective study was performed from June 2015 to December 2017 and included patients who presented to our tertiary care institution with posttraumatic SCI. Owing to time constraints and the paucity of previous data related to the present research question, this study was conducted as a pilot study with 51 subjects recruited prospectively on the basis of the availability of patients undergoing treatment. The study and all its protocols were approved by the institutional review board and ethical committee (IRB approval no., Endst. No. Surg/Dean/16/1640-45; dated 08/06/2016). Written informed consent was obtained from all individual participants. We recruited all adult patients who suffered posttraumatic SCI. After emergency stabilization, a detailed history was taken from each patient in chronological order, and a thorough general physical and neurological examination was performed.

Each patient underwent a thorough clinical examination including spinal X-ray and MRI. The 1.5 Tesla machine was used to obtain MRI data with the patient lying comfortably in the supine position with knees and hips extended. Multislice sagittal and transverse sections were taken with MRI sequences. The locations of vertebral levels for MRI were determined from pilot parasagittal sections. Measurements were performed using on-screen calipers. Various parameters (detailed in Table 1) were measured at the L1–L2, L2–L3, L3–L4, L4–L5, and L5–S1 level of the intervertebral disc (as per the institutional protocol published previously [4]).

Various quantitative parameters measured with section at level of intervertebral discs

The clinical assessments of sensory score, motor score, and zone of partial preservation were performed at the time of admission and at 3 days, 7 days, 3 months, and 6 months postadmission according to the international scoring system of the American Spinal Injury Association (ASIA) [5]. Deep anal pressure (DAP), voluntary anal contraction (VAC), and any anal sensations were noted during each clinical assessment. The neurological level of injury (sensory and motor) was evaluated and defined as complete or incomplete. SCI was classified into five categories (A to E) according to the ASIA impairment scale (AIS) [6].

Plain roentgenogram examinations (lateral images, anteroposterior film) were conducted. Routine laboratory investigations including hemoglobin level, bleeding time, clotting time, complete urine examination, blood urea, blood sugar, serum electrolytes, electrocardiogram, and chest roentgenogram were performed in all cases. We performed MRI within 48 hours of injury in all cases. Patients who required surgery for unstable vertebral column injuries were operated on according to the requirements. Spinal stability was evaluated for thoracolumbar injuries according to lumbar spinal stenosis [7], and the thoracolumbar injury classification system [8]. Unstable spine was considered an indication for spinal surgery (either stabilization alone or stabilization with decompression). The type of surgery was decided on the basis of the characteristics of the fracture. Patients with stable spinal injuries were advised to stay on bed rest until pain subsided and were later mobilized with the use of braces. Patients who underwent surgical stabilization were usually mobilized on the third day after surgery following dressing change unless there were any contraindications. Rehabilitation for early mobilization and active/assisted limb and paraspinal muscle strengthening exercises were initiated as soon as possible for all patients.

Patients attended follow-up appointments at 3 and 6 months postinjury. Clinical evaluations and plain radiography examinations were performed at each follow-up, and MRI was performed at the 3- and 6-month follow-up appointments. Neurological recovery was documented on the basis of AIS.

The collected data were compiled and entered into spreadsheets. Statistical analysis was performed using the statistical software IBM SPSS for Windows ver. 20.0 (IBM Corp., Armonk, NY, USA). Continuous variables are presented as mean and standard deviation, and categorical variables are presented as proportions. The independent Student t-test was used to analyze statistical differences in continuous variables between two independent groups. To compare more than two independent groups or ordinal dependent variables, we used one-way analysis of variance (ANOVA). For repeated-measures analysis, repeatedmeasures ANOVA, Friedman’s ANOVA, and Cochran’s Q test were used on the basis of whether the dependent variable being measured was continuous, ordinal, or categorical, respectively. The level of significance was taken as 5% with 95% confidence intervals.

Results

Fifty-one patients (40 males, 11 females) were included in this study. The mean age of the study population was 31.75±10.42 years (range, 18–65 years), and the modal group was 21–30 years (n=27, 52.9%).

Table 2 shows the symptomatology at admission and subsequent evaluations. All symptoms decreased significantly over time (p<0.001), except in two patients wherein incontinence persisted at 6 months postadmission.

Distribution of subjects according to their symptomatology (n=51)

Table 3 shows the neurological involvement and improvement over time. Neurological involvement showed a statistically significant improvement (p<0.001).

Distribution of subjects according to their neurological assessment (n=51)

There was no significant difference in the distribution of initial clinical assessment values (VAC, motor index score, and sensory index score), and DAP was managed operatively and conservatively. The superficial abdominal reflex was initially absent in 45.1% (23) of patients but remained absent in only 31.4% (16) of patients at the 6-month follow-up (p=0.001). The Babinski reflex was initially absent and remained absent throughout the followup for all patients. Knee and ankle reflexes were initially absent in 92.2% (47) of patients but remained absent in only 25.5% (13) of patients at the 6-month follow-up; this decrease was statistically significant (p<0.001). The median neurological grade at initial presentation was D. The grade improved to E in the first 3 months after admission and remained as E for the next 3 months. Neurological recovery was found to be highly significant (p<0.001) by the Friedman ANOVA test. Initially, more than half of the study population (56.9%, 29 patients) were classified as grade D, 19.6% (10) of patients were classified as grade A (complete injury), 15.7% (8) of patients were classified as grade C, and 3.9% (2) of patients were classified as grades B and E each. At the 6-month follow-up, the majority of patients exhibited no deficit (74.5%, 38 patients), whereas 19.6% (10) were classified as grade C. Thirty-five (68.6%) patients were managed conservatively, and 16 patients (31.37%) were managed operatively. There was no significant difference in the distribution of the initial ASIA score between these two groups.

The mean trunk widths at various levels of the spinal cord decreased at the 3-month follow-up compared with that at the initial recordings but increased at the 6-month follow-up. Posthoc analysis revealed that this change is statistically significant (p<0.001) at all disc levels of the lumbar spinal cord from L1–S1 and at all time points (Table 4).

Trunk width at various levels of lumbar discs initially and on follow-up (n=51)

Table 5 shows the mean trunk depths at various levels of the spinal cord. Except at the L2–L3 disc levels, mean trunk depth at all levels decreased at the 3-month followup compared with that at the initial recordings. However, the mean trunk depth increased between the 3- and 6-month follow-up. Posthoc analysis revealed that this change is statistically significant (p<0.001) at all disc levels and at all time points, except for L3–L4 (p=0.049, initial versus 3 months) and L4–L5 (p=1.000, 3- versus 6-month follow-up data).

Trunk depth at various levels of lumbar discs initially and on follow-up (n=51)

The mean disc angle at all disc levels of the vertebral column (except for L2–L3 and L4–L5) was significantly decreased (p<0.001) at the 6-month follow-up. At the L2–L3 and L4–L5 levels, the mean disc angle was significantly decreased at the 3-month follow-up compared with the initial recordings but significantly increased at the 6-month follow-up (p<0.001) (Table 6). Posthoc analysis showed that this change is not statistically significant at the L2–L3, L3–L4, or L4–L5 at the 3-month follow-up versus the 6-month follow-up.

Disc angle at various levels of lumbar discs initially and on follow-up (n=51)

The mean skin angle was decreased at follow-up compared with the initial values at all lumbar vertebral levels. Posthoc analysis showed that this change was not statistically significant at the L2–L3 (p=0.194) or L4–L5 lumbar spine levels at the 3-month follow-up compared with the 6-month follow-up (Table 7).

Skin angle at various levels of lumbar spine initially and on follow-up (n=51)

Table 8 shows the mean cross-sectional area (CSA) of the disc at various levels of the lumbar spine at the time of admission and at follow-up. Posthoc analysis showed that this change was not statistically significant at the L3–L4 (p=0.275, 3- versus 6-month follow-up), L4–L5 (p=0.492, initial versus 3-month follow-up), or L5–S1 levels (p=1.000, initial versus three-month follow-up; p=0.075, initial versus 6-month follow-up). There was no significant change in mean muscle disc ratio at any disc level, except L5–S1 (p=0.000, initial versus 3-month follow-up; p=0.011, 3- versus 6-month follow-up) (Table 9).

Mean cross-sectional area of disc at various levels of lumbar spine initially and on follow-up (n=51)

Muscle disc ratio at various levels of lumbar spine initially and on follow-up (n=51)

The mean intervertebral disc height was significantly decreased at the 3-month follow-up compared with the initial recordings at all levels, but this value was increased at the 6-month follow-up. Posthoc analysis showed that this change was not statistically significant at the L1–L2 (p=1.000, initial versus 3-month follow-up) or L4–L5 levels (p=0.151, 3- versus 6-month follow-up) (Table 10).

Intervertebral disc height at various levels of lumbar spine initially and on follow-up (n=51)

Table 11 shows the mean CSA of lumbar muscles at all disc levels of the lumbar spine at the time of admission and follow-up. Intergroup comparisons were performed to investigate the changes over different periods of time. The results revealed a significant decrease in the mean CSA of the lumbar muscles at the follow-up compared with that at admission. When the CSA of the lumbar muscles was analyzed according to the type of management (operative/conservative), no significant differences were found in the majority of muscles, except for the right erector spinae and left rectus abdominis at the L1–L2 level at the 3-month follow-up compared with at admission (Table 12). When the CSA of the lumbar muscles was analyzed according to the severity of the initial injury, no significant differences were noted over time for most of the lumbar muscles according to posthoc analysis (Tables 1317).

Cross-sectional area & fat content of lumbar muscles at disc level of lumbar spine initially and on follow-up (n=51)

CSA & fat content of lumbar muscles at disc level of lumbar spine initially and on follow-up according to their type of management (n=51)

CSA & fat content of lumbar muscles at L1–L2 disc level of lumbar spine according to neurological status in terms of complete and incomplete injury (n=51)

CSA & fat content of lumbar muscles at L2–L3 disc level of lumbar spine according to initial neurological status in terms of complete and incomplete injury (n=51)

CSA & fat content of lumbar muscles at L3–L4 disc level of spine according to initial neurological status in terms of complete and incomplete injury (n=51)

CSA & fat content of lumbar muscles at L4–L5 disc level of spinal cord initially according to initial neurological status in terms of complete and incomplete injury (n=51)

CSA & fat content of lumbar muscles at L5–S1 disc level of spinal cord initially according to neurological status in terms of complete and incomplete injury (n=51)

Fig. 1 shows measurements of cross sectional area of trunk muscles on axial T2 weighted images; fig. 2 shows measurements of trunk depth and width on axial T2 weighted images at lumbar disc levels.

Fig. 1.

Measurements of the cross-sectional areas of trunk muscles on axial T2-weighted images at the (A) L1–L2, (B) L2–L3, (C) L3–L4, (D) L4–L5, and (E) L5–S1 lumbar disc levels. RA, rectus abdominis; ES, erector spinae; QL, quadratus lumborum.

Fig. 2.

Measurements of trunk depth and width on axial T2-weighted images at the (A) L1–L2, (B) L2–L3, (C) L3–L4, (D) L4–L5, and (E) L5–S1 lumbar disc levels.

Discussion

The asymmetry of the size and composition of the paraspinal muscle has been reported in patients with a clinical presentation of unilateral low back pain (LBP) with or without radiculopathy [6,7,9,10]. Singh et al. [4] observed that in patients with chronic LBP, trunk width, depth, and skin angle were comparable at the L3–L4, L4–L5, and L5–S1 disc levels. By contrast, significant differences were observed between patients with LBP and healthy volunteers regarding disc angle at the L3–L4 (p=0.005) and L4–L5 levels (p=0.02) and in the CSA of the disc at the L4–L5 level (p=0.01). The CSA of the paraspinal and abdominal oblique muscles tended to be smaller among patients, but this was not statistically different to that of healthy volunteers. These studies indicate that paravertebral muscles respond to changes in the normal biomechanics or anatomy of the vertebral column [4,6-10]. The present study supports these studies by providing corroborative data from patients with SCI in whom biomechanical and anatomical changes occurred after the traumatic event. We also highlight the fact that even normal discs distal to the lesion respond to the traumatic event, thus resulting in decreased disc angle, disc CSA, and skin angle. The factors underlying these changes may include altered biomechanics, abnormal stresses, and changes in the nutrition of the discs.

We observed significant decreases in trunk depth and width at most levels of the spinal cord at the 3-month follow-up after SCI compared with that at admission, thus demonstrating the response of the paraspinal muscles to SCI. The decrease in mean CSA of all the lumbar muscles and subsequent increase might be due to the neurological improvement and active rehabilitation of the patient. As weight bearing begins and neurological improvement occurs, the observed changes may begin to revert to normal levels in response to the restoration of the normal biomechanics and anatomical alignment of the vertebral column. Many previous studies have highlighted the need for early rehabilitation and weight bearing (if possible) after the initial management of vertebral column injuries [11,12]. The limited strength observed in patients with SCI may be due to neurological factors or the insufficient muscle mass (more accurately, insufficient physiological muscle CSA) of neurally intact muscles. The neurologically intact muscles of a person with SCI are likely to respond to strength in the same way as those of an able-bodied person [5]. Indeed, clinical trials involving patients with SCI have demonstrated that progressive resistance training for nonparalyzed muscles increases the strength and quality of life of the patients [13,14]. It is not clear why partially paralyzed muscles are directly affected by SCI, although there is strong evidence to indicate that people who suffer partial paralysis following SCI become stronger over time [15].

Clinical trials and nonrandomized studies have consistently demonstrated that the strength of partially paralyzed muscles increases over time. It is generally assumed that this is due to a combination of central and peripheral factors. Peripheral factors include muscle hypertrophy, whereas central factors include adaptations either at the site of SCI or within the brain. It is unclear how much of the observed increase in the strength of partially paralyzed muscles can be attributed to physiotherapy intervention as opposed to natural recovery [5]. It has been reported that reversing the changes in muscles or at least restoring the normal proportions of fat and contractile tissue in the cervical spine muscles may contribute to the improvement of the functional rate of recovery in chronic whiplash injury [5]. The reinnervation of denervated paraspinal muscles has been reported following posterior spinal surgery in patients with lumbar degenerative disease [12]. Postoperative computed tomography (CT) and MRI imaging studies have shown that reductions in the CSA of the spinal muscles occur, as well as changes in muscular density. Gille et al. [16] reported that erector spinae muscle alterations mainly occur at locations distal to the posterior lumbar surgical procedures. Kim et al. [17] observed a significant decrease in the CSA of the multifidus muscle in patients who underwent open pedicle fixation. Fan et al. [10,18] reported that multifidus atrophy was reduced among patients who underwent minimally invasive treatment (p<0.001), with mean reductions in the CSA of 12.2% at the operative level and 8.5% at the adjacent levels compared with 36.8% and 29.3%, respectively, among patients who underwent conventional open surgery. Conversely, Keller et al. [19] observed that there was no decrease in spinal muscle CSA after surgery, but muscle density (determined by CT) was adversely affected.

The abovementioned studies indicate that surgical intervention with pedicle screws for the traumatic or degenerative disorders of the spine can lead to alteration in the CSA and fat contents of the paravertebral muscles [10,16-18]. In the present study, we were unable to clarify whether operative intervention with pedicle screws causes further damage to paravertebral muscles because no significant differences were observed in the CSAs of various muscles (except at the L1–L2 level, which was adjacent to the most commonly injured site, for the erector spinae and rectus abdominis) between groups divided according to conservative or operative management. However, all patients in this study underwent open pedicle screw fixation. Ntilikina et al. [20] compared the MRI findings of paravertebral muscles after implant removal in thoracolumbar fractures after open versus percutaneous instrumentation. They reported that percutaneous instrumentation led to decreased muscle atrophy compared with open surgery. The MRI signal differences for T12 and L1 fractures suggested reduced fat infiltration within the CSA of patients who received percutaneous treatment. A major difference between the study of Ntilikina et al. [20] and the present study was that none of the patients in the former had neurological deficits. Similarly, other studies (such as those of Gille et al. [16], Kim et al. [17], and Fan et al. [10,18]) reported differences in the pre- and postoperative CSA of muscles after lumbar spine surgery on patients without major neurological deficits. Anecdotal evidence from the literature suggests that further damage should be expected after open pedicle screw in previously paralyzed muscles [10,13,15-17].

The degree of neurological involvement has a significant effect on the wastage of the paravertebral muscle post-SCI [2]. We did not find any statistically significant differences between patients categorized as motor complete (ASIA A) and motor incomplete (ASIA B, C, or D) in the present study, and intergroup comparisons at different time points did not reveal any significant changes in the majority of the muscles studied. To the best of our knowledge, no study has reported such findings. This could be due to the short follow-up of the present study (6 months) and our robust post-SCI rehabilitation protocol irrespective of the degree of neurological involvement. Furthermore, the lack of significant differences could have been influenced by the small number of patients with complete SCI in the present cohort. Larger studies involving more patients and longer follow-up are required to verify these findings.

Conclusions

Spinal trauma leads to alterations in the vertebral column, spinal cord, intervertebral discs, and paraspinal muscle morphology in the initial phase after injury. The extent of these changes may determine the initial neurological deficit and subsequent recovery. Although the present study did not identify any statistically significant effects of neurological status or management strategy on these parameters, improvement in the later phase of recovery was observed in response to rehabilitation. Future studies are needed to evaluate the exact mechanisms underlying these alterations and the benefits of rehabilitation strategies with regard to these parameters.

Notes

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

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Article information Continued

Fig. 1.

Measurements of the cross-sectional areas of trunk muscles on axial T2-weighted images at the (A) L1–L2, (B) L2–L3, (C) L3–L4, (D) L4–L5, and (E) L5–S1 lumbar disc levels. RA, rectus abdominis; ES, erector spinae; QL, quadratus lumborum.

Fig. 2.

Measurements of trunk depth and width on axial T2-weighted images at the (A) L1–L2, (B) L2–L3, (C) L3–L4, (D) L4–L5, and (E) L5–S1 lumbar disc levels.

Table 1.

Various quantitative parameters measured with section at level of intervertebral discs

Variable Description
1 Trunk dimensions Width (maximum width was be taken)
Depth (anteroposterior diameter of trunk at midsagittal section)
2 CSA of muscle Erector spinae
Multifidus
Psoas major
Quadratus lumborum
Rectus abdominis
Obliques
3 Disc angle The angle between the vertical line and the midplane of each lumbar disc
4 Skin angle The angle between the vertical line and the line tangent to the overlying skin
5 CSA of disc

CSA, cross-sectional area.

Table 2.

Distribution of subjects according to their symptomatology (n=51)

Symptoms Initial 3 mo 6 mo p-value
Pain <0.001a)
 Absent 0 34 (66.7) 49 (96.1)
 Mild 0 17 (33.3) 2 (3.9)
 Moderate 0 0 0
 Severe 51 (100.0) 0 0
Swelling <0.001a)
 Absent 0 48 (94.1) 51 (100.0)
 Mild 0 3 (5.9) 0
 Moderate 20 (39.2) 0 0
 Severe 31 (60.8) 0 0
Deformity <0.001a)
 Absent 0 33 (64.7) 46 (90.2)
 Mild 2 (3.9) 18 (35.3) 5 (9.8)
 Moderate 38 (74.5) 0 0
 Severe 11 (21.6) 0 0
Weakness upper limb 0 0 0 -
Weakness lower limb 49 (96.1) 18 (35.3) 12 (23.5) <0.001b)
Incontinence 0 0 2 (3.9) 0.135b)
Retention 46 (90.2) 16 (31.4) 10 (19.6) <0.001b)

Values are presented as number (%).

a)

By Friedman analysis of variance test.

b)

By Cochran’s Q test.

Table 3.

Distribution of subjects according to their neurological assessment (n=51)

Neurological assessment Initial 3 mo 6 mo p-value
Decreased muscle tone 49 (96.1) 18 (35.3) 13 (25.5) <0.001a)
Mean MIS-upper limb 50 50 50 -
Mean MIS-lower limb 27.28±17.30 40.51±14.96 44.33±10.88 <0.001b)
Voluntary anal contraction (absent) 26 (51.0) 18 (35.3) 10 (19.6) <0.001a)
SIS-light touch 96.0±23.33 105.84±12.58 109.18±6.91 <0.001b)
SIS-pin prick 95.69±23.79 105.10±14.96 109.49±6.23 <0.001b)
Temperature sense (absent) 11 (21.6) 4 (7.8) 4 (7.8) 0.001a)
Deep anal pressure (absent) 17 (33.3) 11 (21.6) 5 (9.8) <0.001a)
Clonus (absent) 51 (100.0) 51 (100.0) 51 (100.0) 1.000a)
Zone of partial preservation 0 0 0 -
Bladder-bowel involvement 49 (96.1) 16 (31.4) 11 (21.6) <0.001a)

Values are presented as number (%) or mean±standard deviation.

MIS, Motor Index Score; SIS, Sensory Index Score.

a)

By Cochran’s Q test.

b)

By repeated measures analysis of variance.

Table 4.

Trunk width at various levels of lumbar discs initially and on follow-up (n=51)

Vertebral level Trunk width (mm)
Intergroup comparisons: p-valuea) (post hoc analysis)
Initial (A) 3 mo (B) 6 mo (C) A-B A-C B-C
L1–2 297.06±13.35 282.25±13.39 290.06±14.08 0.000 0.000 0.000
L2–3 299.33±11.21 287.55±11.15 294.31±12.14 0.000 0.000 0.000
L3–4 303.24±10.79 291.43±11.05 297.31±11.65 0.000 0.000 0.000
L4–5 305.16±9.17 291.55±8.08 299.78±9.49 0.000 0.000 0.000
L5–S1 306.04±8.97 292.27±13.76 299.53±11.07 0.000 0.000 0.000

Values are presented as mean±standard deviation. A-B means initial versus 3 months; B-C means 3 months versus 6 months; A-C means initial versus 6 months.

a)

By repeated measures analysis of variance test.

Table 5.

Trunk depth at various levels of lumbar discs initially and on follow-up (n=51)

Vertebral level Trunk depth (mm)
Intergroup comparisons: p-valuea) (post hoc analysis)
Initial (A) 3 mo (B) 6 mo (C) A-B A-C B-C
L1–2 198.47±16.92 176.65±12.00 195.55±16.25 0.000 0.019 0.000
L2–3 195.61±10.17 190.63±13.04 178.29±8.03 0.002 0.000 0.000
L3–4 198.71±16.54 179.18±13.58 196.18±15.29 0.000 0.049 0.000
L4–5 202.55±15.48 189.84±19.75 193.98±16.17 0.016 0.000 1.00
L5–S1 197.41±16.79 185.76±15.95 191.88±15.55 0.000 0.000 0.000

Values are presented as mean±standard deviation. A-B means initial versus 3 months; B-C means 3 months versus 6 months; A-C means initial versus 6 months.

a)

By repeated measures analysis of variance test.

Table 6.

Disc angle at various levels of lumbar discs initially and on follow-up (n=51)

Vertebral level Disc angle (°)
Intergroup comparisons: p-valuea) (post hoc analysis)
Initial (A) 3 mo (B) 6 mo (C) A-B A-C B-C
L1–2 6.98±0.81 6.27±0.53 6.02±0.86 0.000 0.000 0.003
L2–3 6.76±0.79 5.98±0.93 6.12±1.01 0.000 0.000 0.579
L3–4 1.75±0.44 1.02±0.86 0.84±0.81 0.000 0.000 0.870
L4–5 -6.88±0.86 -6.06±0.86 -6.18±1.05 0.000 0.000 0.729
L5–S1 -21.35±2.90 -19.37±2.91 -20.00±3.30 0.000 0.000 0.000

Values are presented as mean±standard deviation. A-B means initial versus 3 months; B-C means 3 months versus 6 months; A-C means initial versus 6 months.

a)

By repeated measures analysis of variance test.

Table 7.

Skin angle at various levels of lumbar spine initially and on follow-up (n=51)

Vertebral level Skin angle (°)
Intergroup comparisons: p-valuea) (post hoc analysis)
Initial (A) 3 mo (B) 6 mo (C) A-B A-C B-C
L1–2 -96.02±3.04 -93.02±4.53 -93.41±3.83 0.000 0.000 0.009
L2–3 -99.67±3.90 -97.00±4.36 -97.33±3.72 0.000 0.000 0.194
L3–4 -105.33±1.26 -103.00±1.43 -104.00±1.65 0.000 0.000 0.000
L4–5 -115.67±2.52 -111.00±2.97 -113.00±2.97 0.000 0.000 NA
L5–S1 -112.00±2.47 -108.67±0.95 -110.00±1.43 0.000 0.000 0.000

Values are presented as mean±standard deviation. A-B means initial versus 3 months; B-C means 3 months versus 6 months; A-C means initial versus 6 months.

a)

By repeated measures analysis of variance test.

Table 8.

Mean cross-sectional area of disc at various levels of lumbar spine initially and on follow-up (n=51)

Vertebral level Cross-sectional area (cm2)
Intergroup comparisons: p-valuea) (post hoc analysis)
Initial (A) 3 mo (B) 6 mo (C) A-B A-C B-C
L1–2 14.82±0.61 14.50±0.58 14.67±0.58 0.000 0.005 0.000
L2–3 14.85±0.59 14.53±0.26 14.60±0.22 0.000 0.001 0.000
L3–4 14.89±0.57 14.70±0.30 14.73±0.35 0.003 0.010 0.275
L4–5 14.88±0.58 14.69±0.21 14.78±0.18 0.048 0.492 0.000
L5–S1 14.80±0.61 14.80±0.38 14.90±0.52 1.000 0.075 0.000

Values are presented as mean±standard deviation. A-B means initial versus 3 months; B-C means 3 months versus 6 months; A-C means initial versus 6 months.

a)

By repeated measures analysis of variance test.

Table 9.

Muscle disc ratio at various levels of lumbar spine initially and on follow-up (n=51)

Vertebral level Muscle disc ratio (cm2)
Intergroup comparisons: p-valuea) (post hoc analysis)
Initial (A) 3 mo (B) 6 mo (C) A-B A-C B-C
L1–2 0.55±0.05 0.56±0.05 0.54±0.05 1.000 1.000 0.491
L2–3 0.56±0.05 0.56±0.05 0.54±0.05 1.000 1.000 0.491
L3–4 0.55±0.05 0.54±0.05 0.54±0.05 1.000 1.000 0.491
L4–5 1.07±0.05 1.05±0.05 1.05±0.05 0.032 0.694 1.000
L5–S1 1.35±0.07 1.31±0.04 1.34±0.05 0.000 1.000 0.011

Values are presented as mean±standard deviation. A-B means initial versus 3 months; B-C means 3 months versus 6 months; A-C means initial versus 6 months.

a)

By repeated measures analysis of variance test.

Table 10.

Intervertebral disc height at various levels of lumbar spine initially and on follow-up (n=51)

Vertebral level Intervertebral disc height (mm)
Intergroup comparisons: p-valuea) (post hoc analysis)
Initial (A) 3 mo (B) 6 mo (C) A-B A-C B-C
L1–2 11.87±0.42 11.73±0.45 11.73±0.50 0.000 0.000 1.000
L2–3 11.37±0.42 11.23±0.39 11.27±0.41 0.000 0.000 0.000
L3–4 11.73±0.29 11.57±0.17 11.60±0.25 0.000 0.000 0.047
L4–5 11.66±0.37 11.51±0.28 11.55±0.39 0.000 0.000 0.151
L5–S1 10.92±0.10 10.77±0.10 10.80±0.08 0.000 0.000 0.016

Values are presented as mean±standard deviation. A-B means initial versus 3 months; B-C means 3 months versus 6 months; A-C means initial versus 6 months.

a)

By repeated measures analysis of variance test.

Table 11.

Cross-sectional area & fat content of lumbar muscles at disc level of lumbar spine initially and on follow-up (n=51)

Level Lumbar muscles Cross-sectional area (cm2)
Intergroup comparisons
Initial (A) 3 mo (B) 6 mo (C) p-valuea)
L1–L2 Multifidus Left 4.55±0.45 4.07±0.27 4.36±0.52 <0.001 -
Right 4.33±0.42 3.89±0.39 4.05±0.55 <0.001 B-C= 0.153
Erector spinae Left 9.78±0.62 9.27±0.78 9.39±0.49 0.001 B-C=0.412
Right 9.69±0.53 9.27±0.60 9.65±0.77 0.003 A-C=1.00
Ilio-psoas Left 6.65±0.39 6.71±0.93 6.57±0.36 0.378 A-B=1.00, B-C=0.798, C-A=0.318
Right 6.54±0.37 6.12±0.37 6.19±0.48 <0.001 B-C=0.782
Quadratus lumborum Left 4.92±0.29 4.70±0.45 4.68±0.39 <0.001 B-C=1.00
Right 4.74±0.35 4.45±0.46 4.54±0.33 0.002 B-C-=0.836
Rectus abdominis Left 4.94±0.38 4.57±0.44 4.69±0.47 <0.001 -
Right 5.38±0.38 5.07±0.26 5.17±0.33 <0.001 B-C=0.192
Obliques Left 22.07±2.83 19.55±2.96 20.11±3.46 <0.001 B-C=0.893
Right 22.92±3.00 18.87±2.92 21.17±2.48 <0.001 -
L2–L3 Multifidus Left 4.55±0.44 4.10±0.29 4.37±0.50 <0.001 -
Right 4.31±0.43 3.92±0.38 4.05±0.55 <0.001 B-C=0.354
Erector spinae Left 10.09±1.02 9.30±2.27 9.51±0.73 0.058 A-B=0.187, B-C=1.00
Right 10.29±1.19 8.98±1.26 10.01±0.95 <0.001 A-C=0.188
Ilio-psoas Left 6.66±0.39 6.37±0.61 6.57±0.36 0.374 B-C=0.066, C-A=0.220
Right 6.55±0.37 6.16±0.36 6.21±0.48 <0.00 B-C=1.00
Quadratus lumborum Left 4.93±0.29 4.68±0.40 4.68±0.40 <0.001 B-C=1.00
Right 4.76±0.34 4.47±0.40 4.57±0.30 0.002 B-C=0.398
Rectus abdominis Left 4.94±0.38 4.53±0.45 4.69±0.48 <0.001 -
Right 5.38±0.38 5.06±0.28 5.16±0.33 <0.001 B-C=0.164
Obliques Left 22.14±2.99 18.12±3.26 20.54±3.17 <0.001 -
Right 23.15±3.21 18.73±3.57 21.91±2.19 <0.001 -
L3–4 Multifidus Left 4.56±0.43 4.08±0.27 4.33±0.52 <0.001 -
Right 4.33±0.42 3.89±0.39 4.05±0.55 <0.001 B-C=0.153
Erector spinae Left 12.42±3.13 12.27±3.60 12.09±3.21 0.325 A-B=1.00, B-C=1.00, A-C=0.073
Right 12.62±3.54 11.75±3.03 11.77±2.86 <0.001 B-C=1.00
Ilio-psoas Left 6.66±0.40 6.39±0.69 6.57±0.36 0.374 B-C=0.155, A-C=0.206
Right 6.54±0.37 6.11±0.37 6.20±0.47 <0.00 B-C=0.332
Quadratus lumborum Left 4.92±0.29 4.68±0.45 4.68±0.39 <0.001 B-C=1.00
Right 4.74±0.35 4.46±0.45 4.55±0.33 0.002 -
Rectus abdominis Left 4.94±0.37 4.56±0.45 4.69±0.47 <0.001 -
Right 5.40±0.35 5.01±0.30 5.16±0.32 <0.001 -
Obliques Left 21.87±2.89 18.58±3.14 19.92±3.82 <0.001 -
Right 22.86±3.14 19.05±3.28 22.07±2.25 <0.001 -
L4–L5 Multifidus Left 7.44±1.40 6.10±1.14 7.35±1.42 <0.001 A-C=1.00
Right 7.12±1.41 6.31±1.27 7.00±1.42 <0.001 A-C=1.00
Erector spinae Left 9.79±0.62 9.27±0.55 9.38±0.50 0.001 B-C=0.376
Right 9.72±0.53 9.32±0.50 9.50±0.52 0.003 B-C=0.176
Ilio-psoas Left 6.65±0.39 6.47±0.61 6.58±0.38 0.373 B-C=0.354, A-C=0.541
Right 6.54±0.36 6.11±0.37 6.20±0.38 <0.001 B-C=0.227
Quadratus lumborum Left 4.94±0.30 4.65±0.46 4.67±0.40 <0.001 B-C=1.00
Right 4.76±0.33 4.47±0.45 4.53±0.33 0.003 B-C=1.00
Rectus abdominis Left 4.95±0.37 4.53±0.45 4.68±0.47 <0.001 -
Right 5.37±0.39 5.05±0.29 5.17±0.33 <0.001 B-C=0.110
Obliques Left 22.22±2.85 19.36±2.66 19.95±3.51 <0.001 B-C=0.434
Right 23.20±2.63 19.53±3.99 21.27±2.70 <0.001 -
L5–S1 Multifidus Left 9.39±0.95 9.01±0.86 9.14±0.95 0.325 B-C=0.171
Right 9.53±0.89 8.90±1.27 9.06±1.01 <0.001 B-C=0.876
Erector spinae Left 9.79±0.62 9.40±0.58 9.43±0.43 0.001 B-C=1.00
Right 9.69±0.52 9.26±0.60 9.51±0.57 0.003 B-C=0.085, C-A=0.171
Ilio-psoas Left 16.37±1.18 14.77±1.13 14.74±1.47 <0.001 B-C=1.00
Right 14.64±1.92 13.38±2.15 14.09±1.70 <0.001 -
Rectus abdominis Left 4.94±0.38 4.53±0.46 4.69±0.47 <0.001 -
Right 5.38±0.38 5.00±0.31 5.15±0.33 <0.001 -

Values are presented as mean±standard deviation. A-B means initial versus 3 months; B-C means 3 months versus 6 months; A-C means initial versus 6 months. Intergroup comparisons are all significant except these below mentioned.

a)

By repeated measures analysis of variance test.

Table 12.

CSA & fat content of lumbar muscles at disc level of lumbar spine initially and on follow-up according to their type of management (n=51)

Level Mean CSA (cm2) of lumbar muscles Initial
3 mo
6 mo
Operative (n=35) Conservative (n=16) p-valuea) Operative (n=35) Conservative (n=16) p-valuea) Operative (n=35) Conservative (n=16) p-valuea)
L1–L2 Multifidus Left 4.55±0.44 4.54±0.47 0.972 4.08±0.27 4.06±0.29 0.860 4.39±0.48 4.31±0.60 0.605
Right 4.38±0.48 4.21±0.22 0.100 3.96±0.41 3.74±0.31 0.055 4.15±0.59 3.84±0.37 0.066
Erector spinae Left 9.72±0.52 9.90±0.80 0.349 9.26±0.63 9.27±1.06 0.980 9.44±0.40 9.28±0.64 0.285
Right 9.65±0.55 9.78±0.49 0.433 9.15±0.67 9.51±0.33 0.013 9.51±0.51 9.97±1.12 0.133
Ilio-psoas Left 6.62±0.41 6.71±0.33 0.482 6.73±1.09 6.66±0.43 0.717 6.55±0.30 6.61±0.48 0.562
Right 6.55±0.39 6.53±0.33 0.855 6.14±0.37 6.09±0.40 0.646 6.21±0.52 6.16±0.41 0.738
Quadratus lumborum Left 4.89±0.27 5.00±0.32 0.204 4.66±0.44 4.79±0.49 0.333 4.65±0.41 4.76±0.37 0.360
Right 4.74±0.36 4.73±0.33 0.888 4.46±0.50 4.44±0.36 0.924 4.56±0.36 4.51±0.27 0.615
Rectus abdominis Left 5.00±0.37 4.79±0.34 0.056 4.66±0.43 4.36±0.40 0.021 4.75±0.44 4.54±0.50 0.125
Right 5.34±0.55 5.47±0.42 0.255 5.05±0.24 5.11±0.32 0.451 5.13±0.30 5.24±0.38 0.251
Obliques Left 22.53±2.78 21.06±2.75 0.085 19.61±2.74 19.40±3.48 0.815 20.74±3.42 18.73±0.48 0.053
Right 22.78±3.10 18.66±2.99 0.638 18.66±2.99 19.31±2.80 0.466 21.14±2.56 21.23±2.39 0.911
L2–3 Multifidus Left 4.55±0.43 4.56±0.45 0.972 4.09±0.28 4.11±0.31 0.812 4.40±0.48 4.32±0.53 0.605
Right 4.35±0.49 4.23±0.20 0.100 3.98±0.43 3.80±0.22 0.125 4.15±0.59 3.84±0.37 0.066
Erector spinae Left 10.14±1.04 9.99±1.00 0.349 9.33±2.37 9.26±2.09 0.920 9.57±0.72 9.38±0.76 0.387
Right 10.27±1.01 10.34±1.56 0.433 8.98±1.08 8.96±1.62 0.945 9.87±0.74 10.33±1.28 0.190
Ilio-psoas Left 6.63±0.41 6.73±0.34 0.482 6.28±0.69 6.56±0.34 0.121 6.56±0.31 6.58±0.48 0.869
Right 6.55±0.39 6.54±0.33 0.855 6.13±0.37 6.23±0.35 0.366 6.20±0.51 6.22±0.39 0.898
Quadratus lumborum Left 4.90±0.28 5.00±0.32 0.204 4.63±0.35 4.78±0.48 0.199 4.65±0.41 4.75±0.38 0.403
Right 4.77±0.35 4.73±0.33 0.888 4.48±0.41 4.44±0.36 0.783 4.60±0.31 4.51±0.27 0.322
Rectus abdominis Left 5.00±0.38 4.81±0.36 0.056 4.64±0.43 4.28±0.38 0.006 4.76±0.45 4.52±0.52 0.090
Right 5.34±0.36 5.47±0.42 0.255 5.04±0.26 5.11±0.32 0.412 5.13±0.30 5.23±0.38 0.319
Obliques Left 22.72±2.90 20.88±2.89 0.085 18.44±3.10 17.42±3.60 0.306 21.03±2.98 19.48±3.42 0.105
Right 22.79±3.17 23.95±3.25 0.638 17.70±3.04 20.99±3.67 0.002 21.60±2.18 22.60±2.11 0.131
L3–L4 Multifidus Left 4.55±0.44 4.57±0.44 0.896 4.07±0.26 4.10±0.31 0.759 4.34±0.47 4.29±0.62 0.727
Right 4.38±0.48 4.21±0.23 0.100 3.96±0.41 3.74±0.31 0.055 4.15±0.59 3.84±0.37 0.066
Erector spinae Left 12.83±3.39 11.51±2.32 0.112 12.55±3.86 11.65±2.98 0.369 12.46±3.50 11.28±2.34 0.162
Right 13.15±3.84 11.46±2.51 0.069 12.25±3.35 10.66±1.83 0.034 12.23±3.16 10.75±1.78 0.038
Ilio-psoas Left 6.64±0.43 6.71±0.33 0.568 6.30±0.77 6.59±0.42 0.157 6.55±0.31 6.60±0.50 0.693
Right 6.54±0.39 6.53±0.33 0.918 6.13±0.36 6.06±0.40 0.527 6.21±0.51 6.19±0.36 0.917
Quadratus lumborum Left 4.89±0.27 5.00±0.32 0.190 4.63±0.44 4.78±0.47 0.307 4.64±0.40 4.74±0.37 0.400
Right 4.75±0.36 4.73±0.33 0.846 4.32±0.46 4.33±0.33 0.969 4.56±0.36 4.52±0.25 0.657
Rectus abdominis Left 5.01±0.38 4.79±0.34 0.051 4.66±0.43 4.34±0.41 0.016 4.76±0.45 4.53±0.50 0.109
Right 5.34±0.35 5.52±0.32 0.095 4.99±0.31 5.07±0.29 0.365 5.12±0.29 5.24±0.38 0.198
Obliques Left 22.28±2.81 20.96±2.96 0.133 18.64±2.81 18.46±3.85 0.853 20.58±3.40 18.49±4.40 0.070
Right 22.35±2.97 23.97±3.32 0.087 18.35±2.87 20.58±3.71 0.023 21.56±2.33 23.18±1.64 0.015
L4–L5 Multifidus Left 7.43±1.51 7.46±1.14 0.959 6.23±1.27 5.83±0.76 0.169 7.45±1.50 7.11±1.23 0.430
Right 7.25±1.56 6.85±1.00 0.353 6.48±1.42 5.93±0.78 0.083 7.11±1.54 6.77±1.13 0.434
Erector spinae Left 9.73±0.52 9.93±0.81 0.314 9.20±0.56 9.43±0.53 0.180 9.43±0.43 9.28±0.64 0.338
Right 9.66±0.55 9.86±0.46 0.221 9.23±0.55 9.51±0.33 0.029 9.51±0.51 9.48±0.53 0.877
Ilio-psoas Left 6.62±0.42 6.71±0.33 0.453 6.41±0.68 6.59±0.42 0.338 6.56±0.33 6.63±0.48 0.559
Right 6.54±0.39 6.53±0.32 0.917 6.14±0.36 6.05±0.39 0.425 6.21±0.38 6.18±0.40 0.755
Quadratus lumborum Left 4.91±0.29 5.00±0.33 0.330 4.63±0.43 4.69±0.51 0.642 4.63±0.41 4.75±0.39 0.346
Right 4.76±0.36 4.77±0.27 0.860 4.45±0.50 4.49±0.35 0.773 4.55±0.35 4.49±0.27 0.554
Rectus abdominis Left 5.03±0.36 4.79±0.34 0.032 4.62±0.45 4.36±0.40 0.058 4.75±0.44 4.54±0.50 0.139
Right 5.33±0.37 5.47±0.42 0.231 5.03±0.28 5.08±0.33 0.632 5.14±0.31 5.23±0.37 0.430
Obliques Left 22.64±2.79 21.29±2.86 0.116 19.69±2.47 18.63±2.99 0.189 20.56±3.47 18.63±3.33 0.067
Right 22.71±2.40 24.28±2.87 0.047 19.19±3.55 20.28±4.86 0.370 21.15±2.45 21.52±3.26 0.660
L5–S1 Multifidus Left 9.53±0.95 9.09±0.90 0.124 9.11±0.91 8.78±0.72 0.212 9.18±0.97 9.04±0.94 0.617
Right 9.65±0.95 9.24±0.72 0.129 8.83±1.23 9.05±1.37 0.562 9.15±1.00 8.85±1.05 0.330
Erector spinae Left 9.73±0.52 9.93±0.80 0.284 9.32±0.54 9.56±0.64 0.172 9.43±0.43 9.43±0.44 0.984
Right 9.65±0.54 9.78±0.49 0.451 9.15±0.66 9.50±0.33 0.014 9.51±0.52 9.51±0.70 0.977
Ilio-psoas Left 16.36±1.30 16.39±0.87 0.950 14.66±1.18 15.04±0.96 0.300 14.62±1.55 15.04±1.25 0.365
Right 14.47±1.98 15.03±1.78 0.369 13.14±2.23 13.98±1.90 0.223 13.88±1.80 14.59±1.39 0.147
Rectus abdominis Left 5.01±0.37 4.79±0.34 0.047 4.64±0.44 4.29±0.41 0.008 4.76±0.45 4.54±0.50 0.123
Right 5.34±0.35 5.47±0.42 0.273 4.99±0.31 5.03±0.32 0.635 5.11±0.30 5.23±0.38 0.237

Values are presented as mean±standard deviation.

CSA, cross-sectional area.

a)

By independent Student t -test.

Table 13.

CSA & fat content of lumbar muscles at L1–L2 disc level of lumbar spine according to neurological status in terms of complete and incomplete injury (n=51)

Duration CSA (cm2) of lumbar muscles (initially) Severity of initial injury
Intergroup comparisons
Complete SCI (ASIA grade A) (n=10) Incomplete SCI (ASIA grade B, C, D) (n=39) No deficit (ASIA grade E) (n=2) p-valea)
Initial Multifidus Left 4.67±0.42 4.52±0.46 4.40±0.28 0.655 Insignificant
Right 4.38±0.41 4.30±0.43 4.65±0.35 0.411 Insignificant
Erector spinae Left 10.36±0.86 9.64±0.47 9.60±0.00 0.245 Insignificant
Right 9.82±0.71 9.65±0.48 9.85±0.35 0.500 Insignificant
Ilio-psoas Left 6.63±0.44 6.65±0.39 6.70±0.00 0.279 Insignificant
Right 6.34±0.50 6.539±0.32 6.55±0.50 0.679 Insignificant
Quadratus lumborum Left 4.81±0.23 4.97±0.30 4.65±0.07 0.205 Insignificant
Right 4.46±0.38 4.80±0.31 4.90±0.28 0.261 Insignificant
Rectus abdominis Left 4.95±0.43 4.92±0.37 5.10±0.00 0.117 Insignificant
Right 5.35±0.18 5.36±0.41 5.90±0.00 0.145 Insignificant
Obliques Left 21.44±3.27 22.21±2.79 22.50±1.70 0.377 Insignificant
Right 23.17±3.08 22.57±2.81 22.92±3.00 0.851 Insignificant
3 mo Multifidus Left 3.99±0.18 4.10±0.29 3.95±0.35 0.256 Insignificant
Right 3.87±0.23 3.90±0.43 3.95±0.21 0.816 Insignificant
Erector spinae Left 8.98±1.15 9.33±0.68 9.50±0.00 0.519 Insignificant
Right 9.34±0.55 9.24±0.64 9.45±0.21 0.036 A-B=0.031
Ilio-psoas Left 6.49±1.12 6.75±0.90 6.95±0.78 0.903 Insignificant
Right 5.98±0.55 6.16±0.32 6.20±0.28 0.993 Insignificant
Quadratus lumborum Left 4.66±0.34 4.74±0.46 4.10±0.57 0.347 Insignificant
Right 4.81±0.43 4.36±0.43 4.40±0.42 0.042 A-B=0.039
Rectus abdominis Left 4.72±0.55 4.53±0.42 4.50±0.00 0.040 B-C=0.035
Right 5.03±0.16 5.09±0.29 4.85±0.07 0.033 A-C=0.034
Obliques Left 19.18±2.61 19.49±3.06 22.50±0.14 0.796 Insignificant
Right 19.80±2.37 18.63±2.71 18.90±9.19 0.320 Insignificant
6 mo Multifidus Left 4.22±0.21 4.41±0.58 4.15±0.07 0.559 Insignificant
Right 4.02±0.77 4.06±0.51 4.10±0.14 0.259 Insignificant
Erector spinae Left 9.16±0.65 9.44±0.44 9.60±0.00 0.898 Insignificant
Right 9.44±0.56 9.73±0.82 9.25±0.78 0.346 Insignificant
Ilio-psoas Left 6.45±0.30 6.59±0.38 6.70±0.14 0.002 B-C=0.002, A-C=0.002
Right 5.85±0.54 6.27±0.44 6.25±0.50 0.880 Insignificant
Quadratus lumborum Left 4.33±0.56 4.78±0.29 4.45±0.07 0.233 Insignificant
Right 4.41±0.38 4.57±0.32 4.60±0.28 0.553 Insignificant
Rectus abdominis Left 4.81±0.40 4.65±0.48 4.85±0.78 0.020 B-C=0.017, A-C=0.031
Right 5.13±0.16 5.16±0.36 5.50±0.00 0.227 Insignificant
Obliques Left 20.66±2.52 19.90±3.73 21.50±2.26 0.481 Insignificant
Right 21.00±2.56 21.03±2.43 24.65±0.50 0.288 Insignificant

Values are presented as mean±standard deviation. A-B means complete SCI versus incomplete SCI; B-C means incomplete SCI versus no deficit; A-C means complete SCI versus no deficit. Intergroup comparisons are all significant except below mentioned.

CSA, cross-sectional area; SCI, spinal cord injury; ASIA, American Spinal Injury Association.

a)

By one way analysis of variance test.

Table 14.

CSA & fat content of lumbar muscles at L2–L3 disc level of lumbar spine according to initial neurological status in terms of complete and incomplete injury (n=51)

Duration CSA (cm2) of lumbar muscles (initially) Severity of initial injury
Intergroup comparison
Complete SCI (ASIA grade A) (n=10) Incomplete SCI (ASIA grade B, C, D) (n=39) No deficit (ASIA grade E) (n=2) p-valuea)
Initial Multifidus Left 4.67±0.42 4.53± 0.45 4.40±0.28 0.655 Insignificant
Right 4.37± 0.40 4.28± 0.43 4.65±0.35 0.729 Insignificant
Erector spinae Left 10.36±0.86 10.11± 0.99 10.45± 1.63 0.796 Insignificant
Right 9.82±0.71 10.42± 1.29 10.35±0.07 0.278 Insignificant
Ilio-psoas Left 6.63±0.44 6.66± 0.39 6.70±0.00 0.266 Insignificant
Right 6.34±0.50 6.60±0.32 6.55±0.50 0.689 Insignificant
Quadratus lumborum Left 4.81±0.23 4.97±0.30 4.65±0.07 0.238 Insignificant
Right 4.57± 0.40 4.80±0.31 4.90±0.28 0.272 Insignificant
Rectus abdominis Left 4.95±0.43 4.93± 0.38 5.10±0.00 0.115 Insignificant
Right 5.35±0.18 5.36±0.41 5.90±0.00 0.145 Insignificant
Obliques Left 21.83± 3.75 22.20± 2.89 22.50±1.70 0.472 Insignificant
Right 23.17±3.08 22.88± 3.13 28.35± 0.07 0.987 Insignificant
3 mo Multifidus Left 4.08± 0.25 4.11± 0.30 3.95± 0.35 0.370 Insignificant
Right 3.87± 0.23 3.93± 0.42 3.95±0.21 0.483 Insignificant
Erector spinae Left 8.98± 1.15 9.13± 1.98 14.25±6.72 0.105 Insignificant
Right 9.34± 0.55 8.85± 1.39 14.60± 0.00 0.001 A-B=0.034, B-C=0.003, A-C=0.038
Ilio-psoas Left 6.49± 1.12 6.34± 0.43 6.35± 0.07 0.455 Insignificant
Right 5.97± 0.54 6.20±0.30 6.20± 0.28 0.976 Insignificant
Quadratus lumborum Left 4.63± 0.35 4.72± 0.39 4.10± 0.57 0.205 Insignificant
Right 4.73± 0.40 4.40±0.38 4.40±0.42 0.069 Insignificant
Rectus abdominis Left 4.63± 0.60 4.50± 0.42 4.50±0.00 0.054 Insignificant
Right 5.03± 0.16 5.08± 0.30 4.85± 0.07 0.048 A-C=0.049
Obliques Left 18.92± 3.51 17.75± 3.18 21.35± 1.77 0.780 Insignificant
Right 18.18± 2.83 18.95± 3.65 17.35±7.00 0.224 Insignificant
6 mo Multifidus Left 4.25± 0.23 4.42± 0.55 4.15±0.07 0.527 Insignificant
Right 4.02± 0.77 4.06± 0.51 4.10± 0.14 0.259 Insignificant
Erector spinae Left 9.16± 0.65 9.57± 0.72 10.25±0.92 0.665 Insignificant
Right 9.44±0.56 10.17± 1.00 9.80±0.00 0.043 Insignificant
Ilio-psoas Left 6.50± 0.34 6.58± 0.38 6.70± 0.14 0.001 B-C=0.003, A-C=0.001
Right 5.84± 0.54 6.30±0.42 6.25± 0.50 0.918 Insignificant
Quadratus lumborum Left 4.33±0.56 4.78± 0.30 4.45± 0.07 0.236 Insignificant
Right 4.48± 0.34 4.59± 0.29 4.60±0.28 0.348 Insignificant
Rectus abdominis Left 4.81± 0.40 4.65± 0.49 4.85± 0.78 0.024 B-C=0.021, A-C=0.034
Right 5.13±0.16 5.15± 0.36 5.50± 0.00 0.259 Insignificant
Obliques Left 21.03± 4.01 20.37± 3.02 21.50± 2.26 0.697 Insignificant
Right 21.80± 2.16 21.80± 2.18 24.65±0.50 0.379 Insignificant

Values are presented as mean±standard deviation. A-B means complete SCI versus incomplete SCI; B-C means incomplete SCI versus no deficit; A-C means complete SCI versus no deficit.

CSA, cross-sectional area; SCI, spinal cord injury; ASIA, American Spinal Injury Association.

a)

By one way analysis of variance test.

Table 15.

CSA & fat content of lumbar muscles at L3–L4 disc level of spine according to initial neurological status in terms of complete and incomplete injury (n=51)

Duration CSA (cm2) of lumbar muscles (initially) Severity of initial injury
Intergroup comparison
Complete SCI (ASIA grade A) (n=10) Incomplete SCI (ASIA grade B, C, D) (n=39) No deficit (ASIA grade E) (n=2) p-valuea)
Initial Multifidus Left 4.67±0.42 4.54±0.45 4.40±0.28 0.740 Insignificant
Right 4.38±0.41 4.30±0.43 4.65±0.35 0.411 Insignificant
Erector Spinae Left 10.74±1.05 12.74±3.30 14.50±5.09 0.308 Insignificant
Right 9.82±0.71 13.23±3.61 14.70±5.09 0.057 Insignificant
Ilio-psoas Left 6.63±0.44 6.65±0.39 6.95±0.35 0.273 Insignificant
Right 6.35±0.50 6.59±0.32 6.55±0.50 0.708 Insignificant
Quadratus lumborum Left 4.81±0.23 4.96±0.29 4.65±0.07 0.212 Insignificant
Right 4.46±0.38 4.80±0.31 4.90±0.28 0.267 Insignificant
Rectus abdominis Left 4.95±0.43 4.93±0.38 5.10±0.00 0.114 Insignificant
Right 5.35±0.18 5.39±0.37 5.90±0.00 0.281 Insignificant
Obliques Left 21.42±3.26 21.95±2.89 22.50±1.70 0.818 Insignificant
Right 23.22±2.43 22.76±3.17 22.90±7.64 0.264 Insignificant
3 mo Multifidus Left 4.09±0.25 4.09±0.28 3.95±0.35 0.277 Insignificant
Right 3.87±0.23 3.90±0.43 3.95±0.21 0.816 Insignificant
Erector spinae Left 10.17±1.13 12.77±3.87 12.90±3.82 0.103 Insignificant
Right 9.34±0.55 12.30±3.12 13.00±3.82 0.071 Insignificant
Ilio-psoas Left 6.42± 1.08 6.37±0.59 6.65 ± 0.35 0.260 Insignificant
Right 5.99± 0.53 6.14±0.33 6.20± 0.28 0.826 Insignificant
Quadratus lumborum Left 4.63± 0.32 4.73±0.46 3.95± 0.35 0.375 Insignificant
Right 4.25±0.41 4.34±0.43 4.40±0.42 0.315 Insignificant
Rectus abdominis Left 4.73±0.54 4.52±0.43 4.50±0.00 0.044 B-C=0.039
Right 4.98±0.23 5.03±0.32 4.85±0.07 0.601 Insignificant
Obliques Left 18.62±3.73 18.37±2.96 22.50±0.14 0.449 Insignificant
Right 18.85±2.82 19.11±3.34 18.85±6.58 0.310 Insignificant
6 mo Multifidus Left 4.19±0.27 4.37±0.57 4.15±0.07 0.633 Insignificant
Right 4.02±0.77 4.06±0.51 4.10±0.14 0.259 Insignificant
Erector spinae Left 9.72±0.95 12.61±3.30 13.75±4.45 0.135 Insignificant
Right 9.44±0.56 12.32±2.95 12.65±3.18 0.072 Insignificant
Ilio-psoas Left 6.43±0.36 6.60±0.39 6.70±0.14 0.003 B-C=0.004, A-C=0.003
Right 5.92±0.53 6.28±0.43 6.20±0.42 0.910 Insignificant
Quadratus lumborum Left 4.33±0.56 4.77±0.29 4.45±0.07 0.210 Insignificant
Right 4.41±0.38 4.58±0.31 4.70±0.14 0.540 Insignificant
Rectus abdominis Left 4.80±0.41 4.65±0.48 4.85±0.78 0.021 B-C=0.018, A-C=0.033
Right 5.13±0.16 5.15±0.35 5.50±0.00 0.248 Insignificant
Obliques Left 20.03±3.51 19.82±4.00 21.50±2.26 0.415 Insignificant
Right 22.35±2.05 22.03±2.28 21.45±4.03 0.348 Insignificant

Values are presented as mean±standard deviation. A-B means complete SCI versus incomplete SCI; B-C means incomplete SCI versus no deficit; A-C means complete SCI versus no deficit.

CSA, cross-sectional area; SCI, spinal cord injury; ASIA, American Spinal Injury Association.

a)

By one way analysis of variance test.

Table 16.

CSA & fat content of lumbar muscles at L4–L5 disc level of spinal cord initially according to initial neurological status in terms of complete and incomplete injury (n=51)

Duration CSA (cm2) of lumbar muscles Severity of initial injury
Intergroup comparison
Complete SCI (ASIA grade A) (n=10) Incomplete SCI (ASIA grade B, C, D) (n=39) No deficit (ASIA grade E) (n=2) p-valuea)
Initial Multifidus Left 8.31±0.66 7.12±1.38 9.35±1.34 0.130 Insignificant
Right 7.31±0.84 7.00±1.50 8.70±1.27 0.690 Insignificant
Erector spinae Left 10.36±0.86 9.66±0.48 9.60±0.00 0.250 Insignificant
Right 9.82±0.71 9.69±0.49 9.85±0.35 0.470 Insignificant
Ilio-psoas Left 6.63±0.44 6.65±0.39 6.70±0.00 0.287 Insignificant
Right 6.34±0.50 6.59±0.31 6.55±0.50 0.465 Insignificant
Quadratus lumborum Left 4.81±0.29 4.98±0.30 4.65±0.07 0.192 Insignificant
Right 4.50±0.39 4.81±0.30 4.90±0.28 0.260 Insignificant
Rectus abdominis Left 5.05±0.38 4.92±0.38 5.10±0.00 0.129 Insignificant
Right 5.35±0.18 5.35±0.42 5.90±0.00 0.179 Insignificant
Obliques Left 21.47±3.30 22.40± 2.81 22.50±1.70 0.496 Insignificant
Right 22.66±1.22 23.26±2.81 24.80±4.95 0.258 Insignificant
3 mo Multifidus Left 6.40±0.37 5.92±1.17 8.05±1.63 0.251 Insignificant
Right 6.50±0.37 6.20±1.38 7.50±1.70 0.538 Insignificant
Erector spinae Left 9.44±0.47 9.22±0.58 9.50±0.00 0.434 Insignificant
Right 9.29±0.57 9.32±0.50 9.45±0.21 0.525 Insignificant
Ilio-psoas Left 6.52±0.72 6.43±0.58 6.95±0.78 0.214 Insignificant
Right 5.97±0.55 6.14±0.31 6.20±0.28 0.691 Insignificant
Quadratus lumborum Left 4.49±0.33 4.71±0.46 4.10±0.57 0.147 Insignificant
Right 4.93±0.32 4.37±0.42 4.40±0.42 0.062 Insignificant
Rectus abdominis Left 4.72±0.55 4.48±0.42 4.50±0.00 0.051 Insignificant
Right 5.03±0.16 5.06±0.33 4.85±0.07 0.021 Insignificant
Obliques Left 19.68±2.72 19.20±2.69 22.85±2.19 0.913 Insignificant
Right 19.50±2.32 19.86±4.09 13.35±5.73 0.485 Insignificant
6 mo Multifidus Left 8.47±0.69 6.97±1.38 9.05±0.64 0.042 Insignificant
Right 8.40±0.73 6.61±1.34 7.60±1.41 0.084 Insignificant
Erector spinae Left 9.16±0.65 9.43±0.47 9.60±0.00 0.707 Insignificant
Right 9.42±0.57 9.53±0.50 9.25±0.78 0.599 Insignificant
Ilio-psoas Left 6.51±0.33 6.60±0.40 6.70±0.00 0.005 B-C=0.006, A-C=0.004
Right 5.97±0.53 6.26±0.32 6.25±0.50 0.487 Insignificant
Quadratus lumborum Left 4.25±0.60 4.78±0.29 4.45±0.07 0.214 Insignificant
Right 4.36±0.41 4.56±0.31 4.60±0.28 0.599 Insignificant
Rectus abdominis Left 4.81±0.40 4.63±0.48 4.85±0.78 0.020 B-C=0.016, A-C=0.044
Right 5.13±0.16 5.16±0.37 5.50±0.00 0.139 Insignificant
Obliques Left 20.01±3.27 19.86±3.66 21.50±2.26 0.297 Insignificant
Right 20.50±1.96 21.29±2.82 24.65±0.50 0.274 Insignificant

Values are presented as mean±standard deviation. A-B means complete SCI versus incomplete SCI; B-C means incomplete SCI versus no deficit; A-C means complete SCI versus no deficit.

CSA, cross-sectional area; SCI, spinal cord injury; ASIA, American Spinal Injury Association.

a)

By one way analysis of variance test.

Table 17.

CSA & fat content of lumbar muscles at L5–S1 disc level of spinal cord initially according to neurological status in terms of complete and incomplete injury (n=51)

Duration CSA (cm2) of lumber muscles Severity of initial injury
Intergroup comparison
Complete SCI (ASIA grade A) (n=10) Incomplete SCI (ASIA grade B, C, D) (n=39) No deficit (ASIA grade E) (n=2) p-valuea)
Initial Multifidus Left 9.41±1.43 9.40±0.82 9.10±0.85 0.885 Insignificant
Right 9.43±0.98 9.56±0.90 9.40±0.85 0.441 Insignificant
Erector spinae Left 10.36±0.86 9.66±0.48 9.60±0.00 0.212 Insignificant
Right 9.82±0.71 9.65±0.48 9.85±0.35 0.481 Insignificant
Ilio-psoas Left 16.87±2.51 16.25±0.58 16.25±0.35 0.989 Insignificant
Right 16.96±2.07 14.15±1.45 13.25±1.63 0.191 Insignificant
Rectus abdominis Left 4.95±0.43 4.93±0.37 5.10±0.00 0.107 Insignificant
Right 5.35±0.18 5.36±0.41 5.90±0.00 0.130 Insignificant
3 mo Multifidus Left 8.70±1.17 9.07±0.77 9.20±0.99 0.466 Insignificant
Right 8.72±1.42 8.99±1.25 8.00±0.00 0.881 Insignificant
Erector spinae Left 9.46±0.58 9.38±0.60 9.50±0.00 0.200 Insignificant
Right 9.34±0.55 9.23±0.62 9.45±0.21 0.037 A-B=0.032
Ilio-psoas Left 15.92±2.15 14.51±0.46 14.40±0.28 0.437 Insignificant
Right 15.76±1.81 12.84±1.87 12.85±1.91 0.461 Insignificant
Rectus abdominis Left 4.72±0.55 4.49±0.44 4.50±0.00 0.065 Insignificant
Right 4.96±0.14 5.02±0.35 4.85±0.07 0.019 A-C=0.025
6 mo Multifidus Left 8.87±1.70 9.19±0.69 9.40±0.42 0.649 Insignificant
Right 9.01±1.02 9.08±1.04 8.85±0.92 0.240 Insignificant
Erector spinae Left 9.40±0.33 9.43±0.46 9.60±0.00 0.677 Insignificant
Right 9.39±0.48 9.55±0.60 9.25±0.78 0.666 Insignificant
Ilio-psoas Left 16.18±2.17 14.39±1.06 14.70±0.28 0.834 Insignificant
Right 16.04±1.49 13.66±1.42 13.15±1.77 0.164 Insignificant
Rectus abdominis Left 4.81±0.40 4.65±0.48 4.85±0.78 0.021 B-C=0.017, A-C=0.032
Right 5.13±0.16 5.14±0.36 5.50±0.00 0.277 Insignificant

Values are presented as mean±standard deviation. A-B means complete SCI versus incomplete SCI; B-C means incomplete SCI versus no deficit; A-C means complete SCI versus no deficit.

CSA, cross-sectional area; SCI, spinal cord injury; ASIA, American Spinal Injury Association.

a)

By one way analysis of variance test.