Lumbar Spinal Stenosis: A Review

Review Article

Lumbar Spinal Stenosis: A Review

Abstract

Lumbar Spinal Stenosis (LSS) is one of the most common radiologic-anatomical syndromes in all population. Magnetic Resonance Imaging (MRI) of lumbar spine is the standard test to identify the narrowing of the spinal canal and adjacent vascular structures. Population of least developed countries those work for bread and butter are at highest risk of this disorder. This review attempts to describe the types, patho-anatomy, patho-physiology, clinical presentation, diagnosis, treatment and complication of lumbar stenosis. The effectiveness of conversative treatment and the need for surgery according to the severity of the stenosis play a crucial role for patient management. Spinal stenosis is categorized as primary and secondary. MRI provides detail anatomic structures which is adequate for surgical planning.

Introduction

Lumbar spinal stenosis (LSS)) is a one of the commonest disorder in aging as well as adolescent population.[1] It is characterized by the narrowing of the spinal canal and the nerve root canals.[2] Aching, cramping, or heaviness in the buttocks, hips, thighs, knees or lower legs with standing or walking, is the classic clinical symptom of neurogenic claudication. LSS thus have become most common cause for spinal surgery in patients over age 65 years.¹ LSS is not life threatening, but it negatively impacts the quality of life (QOL) due to substantial disability, with limitations in performing routine daily life activities.[3]

MRI is suggested as the standard non-invasive test to confirm the presence of anatomic narrowing of the spinal canal or the presence of nerve root impingement. It seems to be useful to consider the dynamic aspect of LSS and assess neural and vascular tissue impingement based on morphology of the dural sac and its content.[4] Machado et al, (2015) investigated the effectiveness of spinal surgery. They concluded that the relative efficacy of various surgical options remained uncertain.⁴

Supe et al. (2015) stated the spinal synovial cyst are associated with pain in back with radicular pain and are most common at L4-L5 as this region is the most mobile. They recommended MRI scan of the spine is best diagnostic modality for these cysts.[5] In appropriately selected patients, surgical intervention has been demonstrated to provide for improvement in pain, disability and quality of life. Outcomes seemed less favorable with greater complication rates among patients with diabetes or obesity. Elderly patients are recommended to be excluded from surgical intervention for symptomatic LSS.[6]

Pathoanatomy

Ligamentum flavum, the facet joints and the disk space are the three primary structures that contribute to spinal stenosis. With degenerative changes, the ligamentum flavum and facet joints may hypertrophy, secondary to mechanical stresses. The aging process results in diminished disk height, which if pronounced can allow buckling of the ligamentum flavum into the spinal canal. Ligament hypertrophy, osteophytes or disk bulging can all encroach on the spinal canal.[7]

Pathophysiology

The pathophysiological changes of Lumbar spinal stenosis (LSS) are caused by degenerative changes of the lumbar spine which include thickening and buckling of ligamentum flavum (LF), osteophyte formation, facet hypertrophy, and bulging of the intervertebral disk. Consequently, the central spinal canal is narrowed resulting in compression-induced ischemia of the cauda equine. Venous congestion is another proposed mechanism of intermittent postural radiculopathy in lumbar stenosis.^{6, [8]}

Clinical Presentation

Patients classically present with Low Back Pain (LBP) that may be associated with neurogenic claudication, described as radiating pain along the lower extremities usually down to the knees or even to the calf muscle level. The pain is triggered and is worsened as the patient ambulates or stands and is relieved with flexion of the spine or sitting down. Neurogenic claudication is believed to be a result of structural narrowing of the spinal central canal, which impedes venous return thus causing venous hypertension, resulting in arterial ischemia of the cauda equine.²

Diagnosis

Definitive diagnostic information is most readily obtained from lumbar spinal MR images and/or CT scans with sagittal reconstructions. These studies clearly show the size, shape and anatomic relationships of spinal and neural elements and can demonstrate the relative contribution of developmental stenosis as well as disk, facet and ligamentous elements of nerve root compression.⁶

In addition, MRI usually provides anatomic information sufficient for surgical planning. Axial MRI scan of central stenosis typically demonstrates a circumferentially narrowed canal. Hypertrophic bone appears as a dark region of low signal of T1-weighted and T2-weighted images, hypertrophic ligamentum flavum as an intermediate signal on T1-weighted and T2=weighted images, and loss of fat in the epidural space due to prolonged compression as a loss of high T1 signal. T2 weighted sagittal images are useful for their myelogram like representation of the thecal sac. Lateral stenosis appears on axial and sagittal views as bone encroachment and loss of fat signal (best appreciated on T1-weighted images) surrounding the exiting nerve root.⁶

Classification

Spinal stenosis is classified as either primary or secondary. In primary stenosis, the spinal canal is constricted due to a congenital abnormality or a disorder in postnatal development. Primary stenosis is extremely rare. However, secondary stenosis is due to degenerative changes of the vertebral bodies, facet joints and disks.[9]

Treatment

Current treatment options range from conservative management to invasive spinal surgical decompression and lumbar fusion, with or without instrumentation.

Conservative Therapy VS Surgery

Conservative methods of therapy may be of use in early and moderately severe cases; it is certainly useful and appropriate to initially pursue nonsurgical measures. Conservative measures usually include bed rest, non-steroidal anti-inflammatory drug, acetaminophen, exercise program, aerobic fitness and epidural steroid injections. Once patients progress past the point of moderate symptom severity, conservative methods may become ineffective or unrealistic. Surgical decompression has been helpful in about two-thirds of patients, but is associated with considerable morbidities. Patients who delay surgery have similar outcomes to patients who proceed immediately with surgery. Thus, the consideration of proceeding with surgery should await evaluation of comorbidities as well as assessing the patient’s response to conservative therapy.²

Weight loss is recommended for obese patients. to reduce symptoms, including pain, patients are generally advised to avoid activities that place mechanical stress on the lower back, particularly those that place the spine in extension. When oral drugs and physical therapy fail to provide relief of symptoms, epidural steroid injections may be used on the assumption that symptoms result from inflammation at the interface between the nerve root and compressing tissues. The goal of surgery is to decompress the central spinal canal and neural foramina to eliminate pressure on nerve roots. Alternatively, a minimally invasive laminectomy can be done using several smaller incisions.

Complications

Although lumbar spinal stenosis is not life-threatening, it can cause chronic and substantial pain and can severely limit patient activity.

Discussion

Lumbar spinal stenosis has a high prevalence in older adults and a strong negative influence on quality of life, preventing many older adults from maintaining an active independent life.¹ Surgery is superior to nonsurgical treatment for improving pain and function. Symptoms may recur with either approach.¹ The chief complaint of patients with symptomatic spinal stenosis is claudication, an intense pain brought on by walking and usually felt in one or both lower extremities.⁹

Knutsson et al in 2015 described the experience of being a person with LSS and how life and suffering were managed under the influence of their disease. Being a patient with LSS included suffering. Both physicians and patients needed to work towards salutogenic perspective, focusing on resources to improve care, making it more comprehensible, manageable and meaningful.[10]

K. Kato et al, 2014 conducted LSS support tool project in 1657 hospitals and evaluated the diagnostic accuracy of the Self-administered, Self-reported History Questionnaire in Japan. They concluded the improved version can be used for LSS screening and its use may improve the quality of LSS diagnostic practice in Japanese primary care settings.[11]

Yaldiz et al, 2015 retrospectively, demographically and clinically investigated the causes of postoperative infection in patients with lumbar spinal stenosis who underwent posterior stabilization. Implant-related infections (IRIs) still appeared to be a major problem in spinal surgery, even though the infection rate has been reported to be around 1%. However, PSI rate increased upto 2.1% to 8% as the frequently performed spine surgeries such as laminectomies and discectomies with plantation increased. Dead space in the surgical field, foreign bodies, necrotic tissue and prolonged surgical procedures are among the factors that increase the risk of IRI. Implant use in spinal surgery increased the risk of infection about 3 fold.[12] Beyer et al in 2015 studied the influence of spinopelvic parameters on non-operative treatment of lumbar spinal stenosis.[13]

Kim et al, 2015displayed patients with high pain sensitivity may display less improvement in back pain, leg pain, and disability after surgery for LSS compared with patients with low pain sensitivity. Furthermore, the Pain Sensitivity Questionnaire (PSQ) can be used to predict surgical outcomes after spine surgery for LSS.[14]  

Shamji et al, in 2015 systematically reviewed the effectiveness of lumbar spinal surgery for symptomatic LSS in elderly patients (over age 65 years). They revealed that the majority of elderly patients exhibited significant symptomatic improvement. Outcomes seem less favorable with greater complication rates among patients with diabetes or obesity. They recommended that elderly patients should not be excluded from surgical intervention for symptomatic LSS.[15]

Ulrich in 2015 concluded the patients 80 years or older can expect a clinically meaningful improvement after lumbar decompression for symptomatic DLSS and the patients showed significant positive development in quality of life in the short and long term follow ups.[16] Ferrari et al, 2015 investigated the clinical validity of clinical tests for the diagnosis of lumbar instability. They suggested Passive Lumbar Extension (PLE) test was the most appropriate test to detect lumbar instability in specific LBP.[17]

LBP is a growing health problem in the industrialized world. Despite the high medical expenses required for its management, the prevalence of LBP is increasing. LBP is a heterogeneous condition, and the identification of different sub-groups could help the management decisions.¹⁴

Lurie et al, 2015 compared 8-year outcomes of surgery with non-operative care for symptomatic LSS. They concluded symptomatic spinal stenosed patients showed diminishing benefits of surgery in as-treated analyses of the randomized group between 4 and 8 years, whereas outcomes in the observational group remained stable.[18]

Maugeri et al (2015) also gave a new concept to treat LSS in a mini invasive way.[19]

Dahal et al (2012) noticed most common spinal pathology in patients with low back ache was degenerative changes of the spine. MRI, though expensive was beneficial in early diagnosis and management of lumbar spine abnormalities.[20] Markman and Nandigam (2015) assessed changes in spine segment biomechanics due to laminotomy and laminectomy.[21]

Segar et al (2015) also investigated that obesity might be associated with clinical diagnosis of LSS but not lumbar disc herniation or degenerative spondylolisthesis.[22] Burton et al (1981) noticed 800 Failed Back Surgery Syndrom (FBSS) and stated FBSS is actually a spectrum of organic disease processes complicated by secondary financial gain and learned chronic pain behavior. While many of the patients can be salvaged to varying degrees by comprehensive rehabilitation programs, it is uncommon to achieve complete pain relief by any combination of therapeutic measures. This is due in part to the great difficulty in quantitating pain and associated psychologic occupational, social, monetary, intellectual, motivational and education factors.[23]

Atlas et al (1996) resulted the patients with severe LSS who were treated surgically had greater improvement than patients treated non-surgically.[24]They again assessed outcomes till 4 year and concluded for severe LSS, surgical treatment was associated with greater improvement in patient-reported outcomes than non-surgical treatment. The relative benefit of surgery declined over time but remained superior to non-surgical treatment.[25] Atlas et al (2005) again completed follow-up for 8 to 10 years and concluded LBP relief, predominant symptom improvement and satisfaction with the current state were similar in patients initially treated surgically or non-surgically. These results support a shared decision-making approach among physicians and patients when considering treatment options for LSS.[26]

Kuslich (1991) defined the tissue origin of low back pain and sciatica. He took 193 patients who had surgery for herniated discs, spinal stenosis, or both.[27] Pasqualini et al. (2012) concluded there was no correlation between the degree of stenosis and  the Oswestry index and MRI in cases and controls.[28] Paine et al (1974) defined LSS as a condition in which the A-P and lateral diameters of the bony canal are narrower than normal and/or in which the shape of the canal in cross section is often abnormal.[29]

DA Chad (2007) also stated LSS may be congenital or acquired. A classic clinical presentation is described as neurogenic claudication. Physical signs of sensory loss, weakness and attenuation of reflexes often are mild and limited in distribution.[30] Bowen et al (1978) reviewed LSS as a condition not only affecting the middle-aged and elderly but young adults may produce symptoms.[31] J Englund (2007) stated LSS is a clinical syndrome first described in the 1950s. It is defined as narrowing of the spinal canal with cord or nerve root impingement resulting in symptoms of radiculopathy or pseudoclaudication.[32]

Conclusion

In summary, LBP resulting from degenerative disease of the lumbosacral spine is a major cause of morbidity, disability, and lost productivity. So, rapid diagnosis and treatment are essential if patients are to be returned to their previous levels of activity.

References

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