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Asian Spine J > Volume 9(5); 2015 > Article
Lee, Kim, Oh, Lee, and Park: Lumbar Stenosis: A Recent Update by Review of Literature

Abstract

Degeneration of the intervertebral disc results in initial relative instability, hypermobility, and hypertrophy of the facet joints, particularly at the superior articular process. This finally leads to a reduction of the spinal canal dimensions and compression of the neural elements, which can result in neurogenic intermittent claudication caused by venous congestion and arterial hypertension around nerve roots. Most patients with symptomatic lumbar stenosis had neurogenic intermittent claudication with the risk of a fall. However, although the physical findings and clinical symptoms in lumbar stenosis are not acute, the radiographic findings are comparatively severe. Magnetic resonance imaging is a noninvasive and good method for evaluation of lumbar stenosis. Though there are very few studies pertaining to the natural progression of lumbar spinal stenosis, symptoms of spinal stenosis usually respond favorably to non-operative management. In patients who fail to respond to non-operative management, surgical treatments such as decompression or decompression with spinal fusion are required. Restoration of a normal pelvic tilt after lumbar fusion correlates to a good clinical outcome.

Introduction

Degeneration of the intervertebral disc results in initial relative instability and hypermobility of the facet joints [12]. This can lead to hypertrophy of the facet joint, particularly the superior articular process, resulting in reduced spinal canal dimensions and compressed neural elements (Fig. 1). The resultant venous congestion and hypertension around nerve roots are likely to be responsible for the symptom complex known as neurogenic intermittent claudication (NIC) [3].

Pathogenesis

Based on the pathology, spinal stenosis can be categorized into the congenital and the acquired forms [4]. Congenital spinal stenosis is composed of stenosis caused by achondroplasia and idiopathic stenosis. Acquired forms of spinal stenosis usually are degenerative, but can also be caused by combined congenital and degenerative stenosis, spondylolisthetic or spondylolytic stenosis, iatrogenic stenosis (such as post-laminectomy stenosis), post-traumatic stenosis, or metabolic stenosis (such as Paget disease) [4].
The most common type of spinal stenosis is caused by degenerative arthritis of the spine. This is most commonly localized to the facet joints and ligamentum flavum, with the resultant arthritic changes in the facet joints visible on radiographic studies [56]. Acquired stenosis of the degenerative type is brought on by changes in the three-joint complex, which consists of the disc, associated superior and inferior vertebral bodies, and the facet joints. Degeneration can start in any one of the joints (disc or facets), but eventually involves all three joints. The facets, which are diarthrodial joints, begin degenerating by developing synovitis [5]. As the synovitis progresses, the joint cartilage thins and the facet capsule loosens. Since this loosening allows for greater spinal motion, degeneration of the intervertebral disc is accelerated. As motion increases, osteophytes enlarge. Although the osteophytes can stabilize the motion segment, they can also narrow the spinal canal. Osteophytes on the superior articular facet narrow the lateral recess; osteophytes on the inferior articular facet narrow the central canal. The L4-5 level is involved most frequently.
Spinal stenosis can be categorized as central and lateral forms, according to the anatomical area of the spine affected. Central spinal stenosis denotes the involvement of the area between the facet joints, which is occupied by the dura mater and its contents. The most common symptom of central spinal stenosis is NIC. Lee et al. [7] classified the nerve root canal into three zones to clarify the anatomy and to describe the pathologic structures responsible for nerve root compression within the three zones: lateral recess, foraminal, and extraforaminal stenosis. The lateral recess, also known as "Lee's entrance zone," begins at the lateral border of the dura and extends to the medial border of the pedicle. This is where the nerve root exits the dura and courses distally and laterally under the superior articular facet [8]. Lee's midzone describes the foraminal region, which lies ventral to the pars. The dorsal root ganglion and ventral motor root occupy 30% of this space. Causes of stenosis in this area are pars defect with proliferative fibrocartilage or a lateral disc herniation. An 8% to 11% incidence of foraminal stenosis has been reported [9101112]. The most common roots involved were the fifth lumbar root (75%), followed by the fourth root (15%), and the third root (5.3%) [12]. The L4 and L5 dorsal root ganglion are more commonly intraforaminal, and S1 dorsal root ganglion are found to be more cephalad or intraspinal [1314]. The normal foraminal height varies from 20 to 23 mm, whereas the width of the superior foramen varies from 8 to 10 mm [15]. The indicator of potential foraminal stenosis is a foraminal height of 15 mm or less [15]. The exit zone is identified as the area lateral to the facet joint. The nerve root is present in this location and can be compressed by a "far-lateral" disc, spondylolisthesis and associated subluxation or facet arthritis [16]. Central stenosis results from the hypertrophy of the inferior facet articular process of cephalic vertebra. Lateral recess and foraminal stenosis are the result of the hypertrophy of the superior facet articular process of caudal vertebra. NIC resulted from the mechanical compression to the nerve root, the artery and vein surrounding the nerve root, provoking venous congestion or arterial ischemia of nerve root due to hypertension [17]. This vascular compromise leads to an ischemic neuritis that contributes to the clinical symptoms of stenosis [3]. Additionally, constriction of the cauda equina has experimentally been shown to lead to demyelination of the nerve roots [18]. This can play a part in creating unremitting pain.

Clinical Presentation

The most common form of degenerative stenosis generally becomes symptomatic during or after the seventh decade of life [19]. It is more common in women than in men [20]. Associated cervical stenosis is seen in patients with lumbar stenosis [21]. Although the physical findings and clinical symptoms of spinal stenosis are not acute, the radiographic findings are comparatively quite severe. In a study population of 100 patients, Amundsen et al. [22] found the occurrence of back pain and sciatica in 95%, and claudication in 91% of the patients. NIC usually had bilateral leg complaints. The distribution of pain in the lower extremities is dependent on the area of stenosis. It improves with trunk flexion, sitting, stooping or lying, and aggravates with prolonged standing or lumbar extension. As the condition becomes more advanced, sitting or lying down are less helpful in relieving the pain. In severe cases, rest pain or a neurogenic bladder can develop [23]. Therefore, the clinician must inquire about changes in bowel and bladder function, including the presence of urgency, frequency, and loss of control. If any of these complaints are present, a full urologic work-up is indicated. In patients with central stenosis, symptoms usually involve both the buttocks and both the posterior thighs in a non-dermatomal distribution. With lateral recess stenosis, symptoms are usually found dermatomal because specific nerves are compressed. Patients with lateral recess stenosis may have more pain during rest and at night, but more walking tolerance than patients with central stenosis. However, in general, physical findings with all forms of spinal stenosis are inconsistent. Straight leg raising and femoral nerve stretching test are usually normal [24]. The neurological examination is also usually normal, but some abnormality may be detected if the patient is allowed to walk to the limit of pain. The gait and posture after walking may reveal a positive "stoop test" [25]. This test is done by asking the patient to walk briskly [25]. As the pain intensifies, the patient may complain of sensory symptoms followed by motor symptoms [25]. If the patient is asked to continue to walk, he or she may assume a stooped posture and the symptoms may be eased [25]. If the patient sits in a chair bent forward, the same resolution of symptoms occurs [25].
In addition, patients with symptomatic lumbar stenosis have a risk of falling [26]. Evaluation of an age- and weight-matched case control study was conducted. The study consisted of two groups: 40 patients with symptomatic lumbar spinal stenosis and 40 patients with advanced osteoarthritis in both knees. The two groups were compared based on the results of functional mobility tests, such as a six-meter-walk test, sit-to-stand test, alternative-step test, and timed up and go test [26]. The patients with symptomatic lumbar stenosis had decreased functions of six-meter-walk test and sit-to-stand test [26].

Differential Diagnosis

It is important to differentiate the symptoms of vascular claudication from those of neurogenic claudication (Table 1). Patients with vascular claudication have a decreased or absent peripheral arterial pulse, such as dorsalis pedis. Vascular symptoms typically are relieved after a short rest (5 minutes) or while still standing; sitting or bending is not required. Symptoms get aggravated whilst walking uphill or riding a stationary bicycle. Neurogenic claudication improves with sitting and worsens with lumbar extension [27].
The common conditions confused with spinal stenosis are vascular claudication, hip joint problem [28] and peripheral neuropathy. Patients with evidence of both vascular claudication and spinal stenosis are more difficult to manage [29]. Consultation with a vascular surgeon can help to determine whether treatment of the vascular or spinal problem should take precedence. Electrodiagnostic studies should be used if a diagnosis of neuropathy is suspected, especially in patients with peripheral neuropathy. Differential diagnosis can also be aided by the use of exercise treadmill testing [30].
Spinal stenosis, with its insidious onset, chronicity, and bilaterality, is easily distinguished from other spinal conditions. Herniated discs generally occur in a younger patient population. The pain distribution is usually unilateral and neurological findings are common. Although a central disc herniation may mimic the pain of a classic spinal stenosis, it is usually more abrupt in onset, with increased pain while sitting, and has associated neurological findings and positive sciatic stretch tests. These features usually help in distinguishing a central disc herniation from spinal stenosis.
When the differential diagnosis is difficult, specialized medical imaging and electrodiagnostic testing can be helpful in determining the source of pain. These tests are discussed further in the section on preoperative evaluation.

Imaging Evaluation

Two practical definitions to describe stenosis are absolute stenosis (when the mid-sagittal diameter of the canal is less than 10 mm) or relative stenosis (when the mid-sagittal diameter of the canal is between 10 mm and 13 mm) [31]. In congenital and developmental stenosis, the primary problem is the inadequate canal size. Normal canal size has been defined as having a mid-sagittal diameter of more than 11.5 mm and an area more than 1.45 cm2 [32]. Although these measurements are useful guidelines, the actual symptoms do not always correspond to canal size; the degree of impingement on the neural elements by the bony and soft tissues has more importance [33].
Plain radiographs are useful in identifying fractures due to trauma, and helpful in evaluating alignment, loss of disc height and osteophyte formation. They enable us to find the defect of pars interarticularis with oblique views, and instability with dynamic view. Anteroposterior views in standing position, which include the hip joints, should also be obtained. Translation of more than 5 mm, or rotation of more than 10 to 15 degrees in the dynamic view, indicates instability. A reversal of the normal trapezoidal disc geometry with widening posteriorly and narrowing anteriorly may also indicate instability (Fig. 2).
Magnetic resonance imaging (MRI) is a noninvasive and suitable method to evaluate lateral recess stenosis. Because of its ability to differentiate tissues and assess the status of the intervertebral disc, it can replace computed tomography (CT) scans for many patients [34]. It is as accurate as CT and myelography in diagnosing spinal stenosis, while being more sensitive at identifying disc degeneration [35]. Midline T2-sagittal images may be useful in diagnosing central stenosis by noting sagittal narrowing of the intervertebral canal (Fig. 3). Sagittal T1-weighted images are evaluated with particular attention focused on the foramen. An absence of normal fat around the root indicates foraminal stenosis (Fig. 4). Extraforaminal stenosis is identified on axial T1-weighted images by obliteration of the normal interval of fat between the disc and nerve root (Fig. 5).
Water soluble myelography followed by CT scan is also useful [36]. This combined study gives an excellent picture of the central and lateral canal and defines any extradural cause of compression. It is best suited for patients with dynamic stenosis, postoperative leg pain, severe scoliosis or spondylolisthesis, metallic implants, any contraindications to MRI, and lower extremity symptoms in the absence of suitable findings on MRI (Fig. 6). However, direct measurement of the bony canal on CT images often gives an inaccurate assessment of the degree of stenosis [37].
Boden et al. [38] noted abnormal findings in 67% of asymptomatic patients evaluated by MRI. In patients older than 60 years, 57% of MRI scans were abnormal, including 36% of patients with herniated nucleus pulposus, and 21% with spinal stenosis [38]. Hence, findings of MRI should be matched with the symptoms and signs of patients having neurogenic claudication or radiculopathy. In addition, there is no correlation between the severity of clinical stenosis and the severity of symptoms of spinal stenosis [39]. In patients with moderate radiographic stenosis obliterating one-third to two-thirds of spinal canal on axial images, only 9.9% of patients showed symptoms [39]. In patients with severe radiographic stenosis, where more than two-thirds of spinal canal was obliterated on axial images, only 17.5% of patients had symptoms [39].
When compared with 40 patients without NIC, 53 patients having NIC due to lumbar stenosis had positive sagittal balance, loss of lumbar lordosis, and increased pelvic tilt [40]. In addition, the patients with degenerative disc disease (n=32), lumbar disc herniation (n=25), and degenerative spondylolisthesis (n=28) had positive sagittal balance, loss of lumbar lordosis, decreased sacral slope and increased pelvic tilt when compared with a control population of 154 asymptomatic adults [41]. In another study, at 6 months after discectomy, the positive sagittal balance, loss of lumbar lordosis and decreased sacral slope in 61 patients with lumbar disc herniation, had recovered to almost the same level as the control group of 60 asymptomatic adults [42].
Literature review to understand the relationship between sagittal balance and clinical outcomes in surgical treatment of degenerative spinal diseases (including degenerative stenosis, degenerative spondylolisthesis, degenerative scoliosis and degenerative kyphosis), revealed an increase in pelvic tilt after lumbar fusion correlated with postoperative back pain [43]. Restoration of a normal pelvic tilt after surgery correlates with a good clinical outcome [43]. Similarly, in a retrospective study of 18 patients who underwent decompression with spinal fusion after a diagnosis of degenerative spondylolisthesis, the patients showing an improvement in the pelvic tilt after lumbar fusion were found to achieve a good clinical outcome of visual analogue pain score and Oswestry disability index [44].

Natural Progression

Studies pertaining to the natural progression of lumbar spinal stenosis are few, with a limited number of patients per group. Johnsson et al. [45] reported that 19 of 27 patients (70%) with moderate, untreated spinal stenosis (≥11 mm anteroposterior canal diameter) remained unchanged after 4 years of observation; 4 patients (15%) showed an improvement, and 4 patients (15%) deteriorated without serious sequelae.
There have been five randomized controlled studies comparing the clinical outcomes of surgical and conservative treatment for spinal stenosis (Table 2) [2246474849]. In the short-term follow-up of 1 to 4 years, patients treated surgically had better clinical results with radicular and low back pain [4647]. However, in the long-term follow-up of 10 years, there were no significant differences of clinical results between surgery and conservative management for lower back pain, since it occurs due to degenerative changes [224849]. In the long-term follow-up of 10 years, the patients treated surgically had a better improvement for radicular pain [2246474849]. During initial follow up of 1-5 years in the long-term follow-up study, surgical intervention had better improvement for all measurements of radicular and back pain [49].

Treatment

Symptoms of spinal stenosis usually respond favorably to non-operative management [50]. Despite symptoms of back pain, radiculopathy, or neurogenic claudication, conservative management is successful in most patients and recommended for an initial treatment. Conservative measures usually include bed rest, nonsteroidal antiinflammatory drug, acetaminophen, exercise program, aerobic fitness and epidural steroid injections.
Conservative treatment is appropriate for patients with moderate pain, 50% of whom have pain relief in less than 3 months. Operative treatment is indicated for patients with severe pain and constant neurologic symptoms, and in patients where conservative treatment has failed [51]. Based on the results of a pilot study with 55 patients having lumbar stenosis, gabapentin treatment resulted in an increase in the walking distance, a decrease in the visual analogue scales of back pain and leg pain, and an improvement of sensory deficit, when compared to the standard treatment [52].
Surgery for spinal stenosis consists of either decompression alone, or decompression with spinal fusion. Decompression by laminectomy is the treatment of choice for central or lateral recess stenosis. On the other hand, fusion is required if foraminal stenosis is present. During the decompressive surgery, specific attention should be paid not to injure the pars interarticularis [53]. Whenever possible, the source of pain should be localized with selective root blocks preoperatively, to allow a more focal decompression. A good approach is to start the decompression at a point of lesser stenosis and work towards the area of most severe stenosis. This often frees the neural structures enough to make the final decompression simpler and decreases the risk of damage to dura or nerve roots. It is desirable to attain decompression with minimally invasive techniques, and preserving the paraspinal muscle, spinous processes, supraspinous and interspinous ligaments [54]. A microscope or magnifying loupes and tubular retractor system are helpful [54].
Fusion is required if there is excessive facetectomy, as more than 50% compromises stability [55], or if stenosis is combined with isthmic or degenerative spondylolisthesis [56], scoliosis, kyphosis or synovial facet joint cyst. Other indications for fusion include adjacent segment degeneration after prior fusion, and recurrent stenosis or herniated disc after decompressed site [57]. If fusion is likely, the hips should remain extended to prevent positional kyphosis.
In the United States, the rate of patients who underwent decompression merely on a diagnosis of lumbar stenosis, has decreased from 58% in 2004 to 49% in 2009 [58]. However, the rate of patients who underwent decompression with spinal fusion has increased from 21% in 2004 to 31% in 2009 [58]. This means that lack of consensus and worldwide variability exists in making a surgical decision for patients with lumbar stenosis.
Usually, 60% to 90% of patients have relief of their symptoms after surgical or conservative treatments [225960]. However, back pain may persist due to a preexisting degenerative arthritis. In patients with neurologic abnormality, 90% of patients usually experience relief after surgery [59]. Prognostic factors for better results are stenosis at a single level, weakness of less than 6 weeks duration, mono-radiculopathy, and where preoperative symptoms were relieved by postural change [2260]. However, the severity of narrowing is not a prognostic factor for better surgical outcome [22]. In a retrospective study for 10-year survival, patients older than 50 years who underwent either spinal decompression or decompression with spinal fusion after the diagnosis of spinal stenosis, the mortality was reduced as compared to the corresponding portion of the general population [61].

Conclusions

Patients with symptomatic stenosis may present with one or more of a combination of axial pain, radiculopathy and neurogenic claudication. The long-term outcome of patients with lumbar spinal stenosis treated conservatively was equivalent to the patients treated surgically. Decompressive surgery is the gold standard for treatment of central or lateral recess lumbar stenosis. Additional fusion is required if there is associated instability, resection of more than 50% of the facet joints, degenerative spondylolisthesis, scoliosis, kyphosis and previous decompression at the same level.

Conflict of Interest

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

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Fig. 1

Hypertrophy of the facet joint, particularly at the superior articular process, resulting spinal canal stenosis and compression of the neural elements (arrow) (A) compared to normal lumbar spine (B).

asj-9-818-g001.jpg
Fig. 2

A reversal of the normal trapezoidal disc geometry with widening posteriorly and narrowing anteriorly in the dynamic view may indicate instability (arrow) (B) compared to the view with flexed posture (A).

asj-9-818-g002.jpg
Fig. 3

Midline T2-sagittal images may be useful in diagnosing central stenosis by noting sagittal narrowing of the intervertebral canal (arrows).

asj-9-818-g003.jpg
Fig. 4

An absence of normal fat around the root indicates foraminal stenosis on sagittal T1-weighted images (arrows).

asj-9-818-g004.jpg
Fig. 5

Extraforaminal stenosis is identified on axial T1-weighted images by obliteration of the normal interval of fat between the disc and nerve root (arrow) at the lumbar 3-4 disc level (box).

asj-9-818-g005.jpg
Fig. 6

Myelography of lumbar spine in anteroposterior view (A) and lateral view (B).

asj-9-818-g006.jpg
Table 1

Differentiation of symptoms of vascular claudication from those of neurogenic claudication

asj-9-818-i001.jpg
Table 2

Randomized controlled studies compared clinical outcomes of surgical and conservative treatment for spinal stenosis (surgery: decompressive surgery only)

asj-9-818-i002.jpg

VAS, visual analogue scale; SF-36, short form 36.

a)Expressed as the number of patients treated with surgery/with conservative treatment; b)Mean follow-up period with years; c)Medical Outcomes Study SF-36 questionnaire.



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