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Yang, Kim, Kim, and Park: Analysis of Factors Contributing to Postoperative Spinal Instability after Lumbar Decompression for Spinal Stenosis

Abstract

Objective

Decompressive laminectomy is one of the most commonly used surgical methods for the treatment of spinal stenosis. We retrospectively examined the risk factors that induce spinal instability, including slippage (spondylolisthesis) and/or segmental angulation after decompressive laminectomy on the lumbar spine.

Methods

From January 1, 2006 to June 30, 2010, 94 consecutive patients underwent first-time single level decompressive laminectomy without fusion and discectomy. Of these 94 patients, 42 with a follow-up period of at least 2 years were selected. We measured the segmental angulation and slippage in flexion and extension dynamic lumbar radiographs. We analyzed the following contributing factors to spinal instability: age/sex, smoking history, disc space narrowing, body mass index (kg/m2), facet joint tropism, effect of the lordotic angle on lumbar spine, asymmetrical paraspinal muscle volume, and surgical method and level.

Results

Female patients, normal lordotic angle, and asymmetrical paraspinal muscle volume were factors more significantly associated with spondylolisthesis (p-value=0.026, 0.015, <0.01). Statistical results indicated that patients with facet tropism were more likely to have segmental angulation (p-value=0.046). Facet tropism and asymmetry of paraspinal muscle volume were predisposing factors to spinal instability (p-value=0.012, <0.01).

Conclusion

Facet joint tropism and asymmetry of paraspinal muscle volume are the most important factors associated with spinal instability; therefore, careful follow-up after decompressive laminectomy in affected patients is necessary.

INTRODUCTION

Lumbar spinal stenosis is recognized with increasing frequency as a cause of low back pain and lower extremity pain, and is a degenerative disease that most often requires surgery in elderly patients. Laminectomy is a commonly used surgical method. The occurrence of spinal stenosis may increase with advancing age. However, approximately one-third of surgically treated patients are not satisfied with the outcome of surgerys7,17). Decompressive laminectomy appears to reduce pain and restore function in many patients, and the procedure is probably associated with an acceptably low rate of complications22). Patients with symptomatic spinal stenosis treated surgically maintain substantially greater improvement in pain and function over a 4-year period than those treated nonsurgically23). However, the optimal surgical treatment method is not clear. Maintaining spinal stability is important after surgical treatment, although the occurrence of spinal instability is not correlated with clinical outcomes6). The purpose of this study was to investigate the factors that contribute to spondylolisthesis and segmental angulation.

MATERIALS AND METHODS

From January 1, 2006 to June 30, 2010, 94 consecutive patients underwent first-time single level decompressive laminectomy without fusion and discectomy of the lumbar spine. We excluded patients in whom revision surgery or other lumbar surgical procedures had been performed. Patients with preoperative instability were also excluded. Decompressive laminectomy was performed with preservation of the facet joint. We selected 42 patients with a follow-up period of at least 2 years. We analyzed the following contributing factors to spinal instability: age/sex, smoking history, osteoporosis on bone mineral density, disc space narrowing, previous surgery on an orthopedic joint (hip, knee, or ankle), body mass index (kg/m2), facet joint tropism, effect of the lordotic angle on the lumbar spine, paraspinal muscle volume asymmetry, and surgical method and level. Preoperative and postoperative radiographic examinations were performed in 42 patients. Using dynamic lumbar radiographs, we measured the preoperative and postoperative segmental angulation and degree of slippage in flexion and extension. To determine the amount of sagittal rotation angle, lines were drawn between the anterior and posterior borders of the end plate on flexion-extension lateral views. The sum of each angle between two lines was defined as the sagittal rotation angle in the segment5). More than 3mm of slippage was defined as postoperative spondylolisthesis. More than 15° of sagittal rotation angle was defined as segmental angulation in the laminectomized segment5,6). Spinal instability was thought to have occurred if any one of these factors was observed. There was no postoperative mortality and neurologic deterioration. Three patients underwent reoperation. One of patient underwent discectomy and the other had subtotal laminectomy because of canal restenosis. Only 1 patient showed signs of symptomatic spinal instability. Therefore, this patient underwent spinal fusion with instrumentation.

Patient Characteristics

The 42 patients were 38 men and 4 women. The mean age was 67.5 years (range, 38-81 years). There were 18 patients who smoked and 24 who did not; only 2 patients with osteoporosis and had undergone preoperative orthopedic joint surgery. Because of the small number of patients, statistical analysis was not performed. The body mass index (BMI) was calculated and divided by 25.

Radiologic Assessment

The lordotic angle was determined at the intersection of the lines at the level of the inferior plateau of T12 and the superior plateau of S1, Cobb's method, in the neutral position. Normal lordotic angle was defined between 31° and 50°. Facet joint tropism is defined as an asymmetry of the left and right vertebral facet joint angles, with 1 joint having a more sagittal orientation than the other10,15). We regarded facet tropism as a >10° difference in the facet joint angles between the right and left sides10). The volume of the paraspinal muscle was defined as the cross-sectional area, thickness, and width of the multifidus muscle on the magnetic resonance imagingslice parallel to the disc space on the surgical level4,19). The volume of the multifidus muscle was defined by manual tracing of the fascial boundary of the muscles at both sides by using m-view image-analysis software (5.4 version, Marotech Inc.). Paraspinal muscle volume asymmetry was defined as a >10% difference between the right and left sides.

Surgical Method and Level

The surgical method comprised subtotal laminectomy, bilateral partial hemilaminectomy, and unilateral partial hemilaminectomy (including bilateral decompression). Thirty-six patients were operated upon at the L 4-5 level.

Statistical Analysis

Statistical analyses were performed using Fisher's exact test to compare the occurrence. A p value of less than 0.05 was considered significant.

RESULTS

Occurrence of Spondylolisthesis

Spondylolisthesis occurred in 9 patients (21.4%). Six patients were men and 3 were women. Female patients were more prevalent than male patients (75.0% and 15.8%, respectively). Spondylolisthesis was more common in patients aged >65 years (27.3% versus 15.0%). Patients who smoked and those with obesity (body mass index> 25) had more prevalent spondylolisthesis (27.8% versus 16.7% in those who smoked and those who did not respectively, and 25.0% versus 18.2% in obese and nonobese patients, respectively). Post-operative spondylolisthesis developed in all patients with a normal lordotic angle and those who underwent laminectomy at the L 4-5 level. Patients with facet joint tropism and disc space narrowing had more prevalent spondylolisthesis (33.3% and 16.7% in those with and without facet joint tropism, respectively; 36.4% versus 16.1% in those with and without disc space narrowing, respectively). Patients with asymmetrical of paraspinal muscle volume had statically more frequent spondylolisthesis (p-value <0.01). The patients who underwent subtotal laminectomy had spondylolisthesis more often than bilateral partial hemilaminectomy and unilateral laminectomy (27.3%, 25.0%, and 8.3%, respectively). However, all factors were not found to be correlated with the occurrence of spondylolisthesis. Female patients and those with a normal lordotic angle more often had spondylolisthesis (p-value=0.026, and 0.015, respectively) (Table 1).

Occurrence of Segmental Angulation

Segmental angulation occurred in 6 male patients (14.3%). The patients aged <65 years were more likely to have segmental angulation (13.6% versus 15.0% in older and younger patients, respectively). Segmental angulation was more prevalent in those who smoked (16.7% versus 12.5% in patients who smoked and those who did not, respectively). Obese patients and those with a normal lordotic angle had segmental angulation less often (10.0% versus 18.2% in obese and nonobese patients, respectively; 7.1% versus 14.3% in those with a normal and abnormal lordotic angle, respectively). Patients with facet joint tropism had segmental angulation more often (33.3% versus 6.7% in those with or without facet joint tropism, respectively). Patients with asymmetrical paraspinal muscle volume had segmental angulation more frequently (20.0% versus 12.5% in those with/without asymmetry), but the difference was not statistically significant. Patients who underwent subtotal laminectomy had segmental angulation more often than bilateral partial hemilaminectomy and unilateral laminectomy (18.2%, 12.5%, and 8.3%, respectively). Patients with facet joint tropism were more likely to have segmental angulation statistically (p-0.046) (Table 2).

Occurrence of Spinal Instability (Spondylolisthesis and/or segmental angulation)

Spinal instability occurred in 15 patients (35.7%). Twelve patients were men and 3 patients were women. Spinal instability occurred more often in patients aged >65 years (40.9% versus 30.0%), and was more prevalent in those who smoked (44.4% versus 29.2%). Spinal instability was more prevalent in patients with facet joint tropism and disc space narrowing(66.7% versus 23.3%, and 45.5% versus 32.3%, respectively). Spinal instability was also more prevalent in with asymmetrical paraspinal muscle volume (p-<0.01). Patients who underwent subtotal laminectomy had spinal instability that occurred more often than bilateral partial hemilaminectomy and unilateral laminectomy (45.5%, 37.5%, and 16.7%, respectively). Facet joint tropism was the only predisposing factor to spinal instability statistically (p-0.012) (Table 3).

DISCUSSION

Lumbar spinal stenosis is major reason for back pain and claudication with advancing age. The natural course of lumbar spinal stenosis fluctuates and is not necessarily progressive. Management of this condition is by conservative treatment and decompression using various methods. Positive results for both treatments were maintained for 2-4 years23).
Bilateral and unilateral laminotomy allowed adequate and safe decompression of lumbar stenosis, resulting in a highly significant reduction of symptoms and disability, and improved health-related quality of life21). Total laminectomy is preferable for patients with severe degenerative stenosis or marked degenerative spondylolisthesis14). Posterior decompression without fusion with instrumentation is safe and effective11,12,13,18), but approximately one-third of surgically treated patients were not satisfied with the outcome7). Decompressive laminectomy alone rather than fusion can be considered, if there is no overt instability for patients with lumbar spinal stenosis at ≥2 levels18). Bilateral laminotomy was found to be associated with significantlyimproved outcome parameters compared to those of unilateral laminotomy and laminectomy during a minimum follow-up period of 12 months21).
Regular analgesic use for ≤12 months and cessation of smoking led to good postoperative functional improvement. Age ≤75 years and no previous lumbar surgery were predictive of good postoperative outcomes1). Multiple laminectomy was thought to be a risk factor for poor outcome5). Patients with a <4-year preoperative duration of symptoms, no preoperative back pain,and absence of other conditions affecting walking tended to have better surgical outcomes9). Leg pain lasting more than 2 years and low preoperative function predicted poor clinical outcome. A narrow dural sac area was predictive of greater improvement in terms of back pain17). One study showed no definite clinical or radiological factors that preoperatively predict patients at risk for poor outcomes3).
Low bone mineral density, small intervertebral discs and absence of osteophytes could predict the possible development of instability following laminectomy2). A sagittal rotation angle >10° would indicate the possibility of a poor outcome5). Occurrence or progression of instability seems to be associated with the resection of the posterior spinal elements rather than the disc6). Instability is affected by the surgical procedure rather than the follow-up period6). In our study, the patients who underwent subtotal laminectomy were more likely to experience spinal instability than bilateral and unilateral laminectomty, but the difference was not statistically significant. The incidence of instability at the surgical level in patients aged <60 years was significantly higher in cases of wide laminectomy than in those of partial laminectomy. A partial laminectomy is preferred to prevent postoperative instability. Unilateral laminectomy for bilateral decompression can result in satisfactory decompression and tolerable clinical outcome8). The significance of postoperative spondylolisthesis is not entirely clear. Postoperative spondylolisthesis could be avoided by a more limited decompression, or by fusion of the segment at the time of surgery. Sagittal facet joint orientation and a reduced coronal facet joint dimension before decompression are associated with development of postoperative spondylolisthesis. Furthermore, there is an association between well-maintained disc height and postoperative spondylolisthesis16). In vitro, segmental instability is less likely to develop in the presence of posterior complex integrity than in a lumbar spine with a destroyed anchoring point for the supraspinous ligament. Under flexion motion, intervertebral displacement of the laminectomy at decompression level L4-L5 was greater than that in intact or bilateral laminotomy specimens in vitro20). In our study, the patient who underwent discectomy during the follow-up period had subtotal laminectomy at L4-5.
Preservation of paraspinal muscles and decreased incidence of injury to muscle is the most important factors associated with a positive effect on long-term clinical outcome4,19). Our study showed that asymmetry of the paraspinal muscles also influenced the occurrence of postoperative instability.
Facet tropism was not associated with the occurrence of facet joint osteoarthritis or degenerative spondylolisthesis10). Facet tropism was also not associated with postoperative instability2,10). However, our study demonstrated that facet tropism was associated with segmental angulation, not spondylolisthesis.
The retrospective study design, relatively small number of patients, and short follow-up periods can be considered limitations of our study. More than one-third patients progress to spinal instability, but only 1 patient underwent spinal fusion. Therefore, the relationship between postoperative spinal instability and the related symptoms should be evaluated.

CONCLUSION

Facet joint tropism and asymmetry of paraspinal muscle volume are the most important factors affecting spinal instability. Patients with facet joint tropism and asymmetrical paraspinal muscle volume should be followed up more carefully than other patients after decompressive laminectomy.

References

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Table 1.
Prognostic factors relating to occurrence of spondylolisthesis
Spondylolisthesis (n=9) Non-spondylolisthesis (n=33) p-value
Sex Male 6 32 0.026
Female 3 1
Age More than 65 6 16 0.278
Less than 65 3 17
Smoking (+) 5 13 0.311
(-) 3 20
Body mass index More than 25 5 15 0.319
Less than 25 4 18
Lordotic angle 31°- 50° 9 19 0.015
31°< or >50° 0 14
Facet tropism (+) 4 8 0.216
(-) 5 25
Disc space narrowing (+) 4 7 0.163
(-) 5 26
Asymmetry of paraspinal muscle (+) 6 4 <0.001
(-) 3 29
Level L4-5 9 27 0.211
L2-3, 3-4, L5-S1 0 6
Operative method Subtotal laminectomy 6 16 0.278
Bilateral or unilateral partial laminectomy 3 17
Table 2.
Prognostic factors relating to occurrence of segmental angulation
Angulation (n=6) Non-angulation (n=36) p-value
Sex Male 6 32 0.526
Female 0 4
Age More than 65 3 19 0.620
Less than 65 3 17
Smoking (+) 3 15 0.519
(-) 3 21
Body mass index More than 25 2 18 0.379
Less than 25 4 18
Lordotic angle 31°-50° 2 26 0.407
31°< or >50° 2 12
Facet tropism (+) 4 8 0.046
(-) 2 28
Disc space narrowing (+) 1 10 0.497
(-) 5 26
Asymmetry of paraspinal muscle (+) 2 8 0.626
(-) 4 26
Level L4-5 5 31 0.629
L2-3, 3-4, L5-S1 1 5
Operative method Subtotal laminectomy 4 18 0.379
Bialteral or unilateral partial laminectomy 2 18
Table 3.
Prognostic factors relating to occurrence of spinal instability
Instability (n = 15) Non-instability (n=27) p-value
Sex Male 12 26 0.121
Female 3 1
Age More than 65 9 13 0.340
Less than 65 6 14
Smoking (+) 8 10 0.242
(-) 7 17
Body mass index More than 25 7 13 0.591
Less than 25 8 14
Lordotic angle 31°-50° 11 17 0.095
31 °< or >50° 2 12
Facet tropism (+) 8 4 0.012
(-) 7 23
Disc space narrowing (+) 5 6 0.333
(-) 10 21
Asymmetry of paraspinal muscle (+) 8 2 <0.001
(-) 7 25
Level L4-5 14 22 0.287
L2-3, 3-4, L5-S1 1 5
Operative method Subtotal laminectomy 10 12 0.145
Bialteral or unilateral partial laminectomy 5 15


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