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Degenerative disease
Degenerative disease of the spine is a major health problem in the Western World. It is of considerable economical importance, since back pain and sciatica caused by degenerative disease lead to numerous consultations and prevent the patient from working for long periods. Furthermore, the patients are often middle-aged and therefore belong to one of the most important groups of workers. The diagnostic work is often difficult because in many patients there is a poor correlation between radiological findings and clinical symptoms. Thus, it is not unusual that a patient has advanced degenerative changes with large osteophytic spurs in the spine without symptoms, while others have severe symptoms with rather discrete radiological findings. The discrepancy between clinical symptoms and findings is especially pronounced in the cervical region. Another complicating element is the combination of psychosocial factors and low back pain. Therefore, it is of extreme importance that the radiologist liaises closely with the clinicians, preferably during dedicated clinico-radiological conferences. There are a number of different modalities and techniques that can be used for diagnosis and the choice between these is based on several factors, such as availability, cost and experience of the radiologist with the method. Furthermore, the situation is also changing due to the rapid spread, technical development and improved film quality of MRI, which certainly will influence working practice in the future.
Modalities
Plain films
Although plain films do not give
information about the soft tissue, each evaluation should start with this
modality which gives a good overview and shows anomalies, which are important
for determining the level at which surgery should be undertaken. Plain films
also show the degree of spondylosis, scoliosis and different dislocations. Such
images guide the choice of modality for further soft tissue evaluation.
Myelography
Myelography has been used for many
decades for evaluation of low-back pain and most radiologists are familiar with
the method. The advantages of the method are that it gives a good overview,
shows intradural morphology with a very high spatial resolution and is not as
sensitive for patient motion as MRI. Furthermore, it has the capability of
showing spinal block and provocation can easily be performed. This is of special
importance in patients with spinal stenosis. In patients with intradural cyst
formation and inflammatory adhesions, myelography is usually superior to CT and
also to MR in the majority of cases. Myelography is of special value in patients
with spinal stenosis, and even more when the spinal stenosis is combined with
scoliosis. In patients with cervical root symptoms, in whom MRI has failed to
give an explanation of the patient's symptoms, myelography and CT-myelography
are also valuable. The disadvantages of myelography are that the method is
invasive and that the area beyond the root-sleeve is not visualized. When there
is a free choice of modality in well-equipped centres, myelography is nowadays
seldom used routinely and is used only in selected patients.
Computed tomography (CT)
Today almost every
major hospital in the Western World is equipped with a CT -scanner and most
radiologists have considerable experience in the diagnosis of lumbar disease
with this modality. CT is very valuable for the evaluation of degenerative
disease in the spine for many reasons: the method is non-invasive, it is quick,
it provides excellent visualization of bone in the axial projection and it shows
the root-canals and paraspinal area. It is usually easy to make a diagnosis of
disc herniation, as well as to detect bony elements narrowing the spinal canal,
recesses and/or root-canals. CT is therefore especially useful for the diagnosis
of the different causes of spinal stenosis. The draw-backs are that for
practical reasons only a limited number of disk levels are routinely covered at
most institutions, and only direct axial views can be obtained. Projections
other than the axial view can be obtained by using thin slices and reformatting.
However, if a large area is to be visualized, there will be significant
irradiation of the patient. Another, and probably more important drawback is
that the content of the dural sac is not visualized, unless contrast has been
injected into the subarachnoid space, and therefore intradural pathology, such
as a tumor, might be missed.
Magnetic resonance imaging (MRI)
MRI is the
latest modality for morphological evaluation of the lumbar spine. The method has
been available already for more than ten years, but the images obtained before
the introduction of surface coils were of poor quality. There is a dramatic
technical development still going on in this field, and the quality is steadily
improving. Furthermore, MRI is now rapidly becoming more available in general
hospitals, and the modality must therefore be evaluated against others in the
diagnostic work-up in patients with degenerative disease of the spine. The
advantages of the method are that it is non-invasive, it gives a good overview
from the sacrum to the conus, all slice orientations can be obtained, and the
content of the dural sac, root-canals and paraspinal area are visualized (Fig.
14). MRI also provides good information about the bone marrow. Cortical bone is
not as well visualized as with CT, but with improving quality this difference
has been diminished. Another drawback of the method is that
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Figure 14. MRI and CT of patient with a huge central disc herniation at the L5-SI level. a) T1-weighted image shows a disc herniation and also a normal conus ending at the L1-L2-level. b) T2-weighted image shows the border of the disc better and degeneration of the L5-SI disk. Other discs have an essentially normal nucleus pulposus. c) Axial T1-weighted image shows central position of the disc herniation. d) Corresponding CT-examination. In a case like this any modality would show the disc herniation but the advantage of MRI compared to CT is that it also shows other levels and the content of the dural sac. |
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it is rather time-consuming, but this is changing due to technical development allowing high resolution examinations with modem scanners in a few minutes. Several investigations have shown that MRI provides equal or better information than myelography or CT in the diagnosis of degenerative disease in the lumbar spine. With modem MR-scanners this will probably shift further in favour of MRI. A standard evaluation of the lumbar spine should include T1-weighted sagittal images covering the area from the conus down to the sacrum, from neural foramen to neural foramen. Axial views should always be obtained at the levels of interest. This is especially important in the evaluation of the lateral part of the spinal canal which is difficult to evaluate on sagittal views. T2-weighted images with standard spin-echo-technique are time-consuming and usually not required, but can be helpful when the disk is difficult to delineate and when a more thorough evaluation of the disk content is necessary, as for instance in a suspected infection. Using newer techniques, fast spin echo T2weighted images can be obtained in a much shorter time, and this technique might be the standard for evaluation in the near future. The specificity of MRI is high since not only pathology in the spinal canal is disclosed, but also pathology in adjacent organs, such as the aorta, which might mimic disease originating in the spine (Fig. 15). MRI is therefore superior to other methods, especially in cases with unclear symptoms. However, in patients with a typical history and location of the symptoms to one level and one side, CT is usually sufficient for diagnosis. If all modalities are available the following strategy for evaluation of patients with low-back pain and sciatica is suggested: Routine patient: 1) plain films, 2) MRI. Patient with advanced spinal stenosis or severe scoliosis: 1) plain films, 2) myelography, 3) CT at selected levels, after myelography.
Discography
Discography is necessary in the
evaluation of patients intended for chemonucleolysis and might be helpful in the
evaluation before percutaneous discectomy. The method has also been used for the
evaluation of patients presenting diagnostic difficulty and in selecting the
proper level in cases with multiple pathology. However, there are different
opinions on the value of the method in this respect. Some authors have tried to
correlate the induced pain with the therapeutical result. In a recent large
study, the value of the method in this respect was found to be low.
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Figure 15. |
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Diagnostic lumbar nerve-rootblock
Another method for evaluation of patients with normal findings on MR, CT or myelography, or multiple pathological levels, is diagnostic nerveroot block. In this method, a small amount of carbocain is injected in dose relation to the nerve under investigation. The neurological state before and after nerve-block is carefully recorded. The method is easy to perform and has been shown to be of value in the determination of the level of pathology and in the evaluation of patients with uncertain findings.
Pathology
Lumbar spine
Anatomical considerations
The spinal card usually ends at the
L1-L2-level and puncture of the subarachnoid space should not be performed above
the L2-L3-level. The nerve-roots have a more cranio-caudal course in the lower
lumbar spine than in the upper, and the root-sleeves of the lower lumbar nerves
are larger and longer than those in the upper lumbar spine. Common normal
variants are root-sleeve cysts and conjoined nerve-roots. This can cause
diagnostic problems using CT or MRI, because they can be misinterpreted as disk
herniation (Fig. 16). The epidural space is thickest at the L5-S1 level and
tissue which contains numerous vessels is normally seen as a symmetrical soft
tissue mass in dose relation to the L5 - S1 disk. It is important not to
misinterpret this as a disk herniation. On MRI and CT images the dural sac is
surrounded by fat, which is of great help for diagnosis. Also the nerve-roots in
the root-canals are surrounded by fat in the normal patient. An important area
to identify is the lateral recess where the nerve-root is turning in the lateral
direction and then passes under the pedicle into the root-canal. The ligamentum
flavum and the intervertebral joints can usually easily be identified on both CT
and MRI.
Disc herniation
A bulging disc is a common finding and is often
seen in combination with reduction of the height of a disc. In bulging discs
there is a general expansion of the disc beyond the margins of the adjacent
vertebral endplates. Bulging discs, not necessarily related to symptoms, are
very common in the middle-aged population and there is a considerable risk
that
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Figure 16. |
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bulging discs are misinterpreted as disc herniations. In disk herniations, which affect the L4-L5 or L5-S1 discs in 90 %, there is a focal extension of different size of the disk outside the vertebral body. In international literature this is called "focal disc bulge" or "protrusion" . These terms are used interchangeably and usually represent different degrees of the same condition, protrusion being the larger disc herniation. Common to both is that the nucleus material remains within the confines of the outermost fibres of the anulus fibrosus which is focally weakened. In "prolapse" or "extruded disk" the nucleus material has penetrated the annulus fibrosus but is contained in front of the posterior longitudinal ligament. With the present imaging modalities it is often impossible to differentiate between these types of disc herniation. In sequestration or free fragment the disc material is no longer contiguous with the intervertebral disk and usually it has penetrated the posterior longitudinal ligament (Fig. 17). This is important for the choice of surgical technique. Most disk herniations are found in the posterolateral direction (Fig. 18), because the posterior longitudinal ligament is weakest in this part. Disk herniations are divided into central, posterolateral, lateral (foraminal) (Fig. 19), and lateral (extraforaminal). The latter group is also called "far lateral" disk herniation. Sequesters or free fragment can migrate both in the upward and downward direction and can sometimes be found at considerable
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Figure 17. Schematic illustration of a bulging disc and various types of disc herniation. The thick dark grey line represents the posterior longitudinal ligament. a) Normal b) Bulging disk c) Focal bulge or protrusion. The nucleus material remains within the outermost fibres of the annulus fibrosus. d) Prolapse or extrusion. The nucleus material has penetrated the annulus fibrosus but is contained in front of the posterior longitudinal ligament. e) Sequester or free fragment. |
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Figure 18. |
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Figure 19. CT and MRl of patient with lateral (foraminal) disc herniation at L2-L3-level. a) CT Disc herniation is seen in right root canal, compressing the L2-nerve. Note normal low attenuation fat on left side. b) T1-weighted sagittal MRl shows disc herniation in root-canal, replacing normal fat. Compare with the level below. c) Axial T1-weighted view, showing disk herniation in right root-canal and high signal fat in left. Note intermediate signal from cauda equina in posterior dural sac and low signal in CSF-containing anterior dural sac. |
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distance from the disc of origin. Intradural disc herniations are very rare. A firm attachment between the dura and posterior longitudinal ligament due to inflammatory adhesion is thought to play an important role in intradural disc herniation. A sudden increase in disc pressure can then push the disc material through the dura into an intradural position.
In the radiological report it is important not only to describe the disc
herniation but also its influence on nerve-roots and the dural sac. The general
rule is that the common posterolateral disc herniation compresses the nerve-root
which exits in the neural foramen below the intervertebral disc, i.e. a L4-L5
disc herniation will compress the L5-root. In lateral disc herniation, the root
in the root-canal will be compressed and in this situation a L4-L5 disc
herniation will compress the L4-root. It is not uncommon for disc herniation to
disappear on conservative treatment (Fig. 20). Imaging following surgery should
be interpreted with caution since there is a poor correlation between findings
on imaging and clinical outcome. All of the three modalities, myelography, CT
and MRI, can be used for the diagnosis of a disc herniation with the advantages
and disadvantages previously described. On CT, disc herniation will have a high
attenuation (Fig. 14 d, 16 a, 18, 19 a) relative to the dural sac, and on
T1-weighted MRI, the signal intensity will be increased in relation to the
subarachnoid space (Fig. 14 a + c, 19 a + c, 20 a), and on T2-weighted images
decreased (Fig. 14 b).
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Figure 20. T1-weighted axial MR-image, showing huge right-sided posterolateral disc herniation and compression of the S1-nerve (a). Following conservative treatment, the disk herniation has almost disappeared six months later (b). Note that epidural fat is now seen in front of the dural sac on left side, but there is still some compression of the epidural fat on right side. |
A special problem is the differentiation between recurrent disc herniation and postoperative scar. Scar tissue is more vascularized than disk material, and therefore it is possible to differentiate these two tissues by using intravenous contrast media. This can be done by using CT, but is more efficient using contrast enhanced MRI with gadolinium-containing compounds. Using this technique, contrast enhancement will usually be seen early after injection (approximately 5 minutes) in scar tissue but not in disc herniations (Fig. 21). However, in disc herniations there is not uncommonly a rim enhancement caused by surrounding granulation tissue. The differentiation between hemia and scar is very important since reoperation on scar tissue is associated with poor results, while reoperation of disc herniation often leads to cure.
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Figure 21. |
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Figure 22. |
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Spinal stenosis
Spinal stenosis can be divided into central
or lateral, and there is often a combination of both types. In spinal stenosis,
pain can be induced by activity or in special positions. Typically, the pain
disappears at rest or in certain positions. Spinal stenosis can be congenital
and is always seen in some conditions, such as ach[안내]태그제한으로등록되지않습니다-ondroplasia. In acquired
spinal stenosis the spinal canal is narrowed in the sagittal direction by bony
spurs on the vertebral bodies, bulging discs, thick ligaments, and new bone
formation adjacent to intervertebral joints. An anteroposterior diameter of less
than 10 mm is usually associated with the symptoms. In lateral spinal stenosis
facet hypertrophy, vertebral body bony spurs, and bulging disks narrow the
lateral recess and the root-canal. The narrowing of the spinal canal can be
estimated by measuring the cross-sectional area of the dural sac. It has been
shown that there is a critical cross sectional area of about 75 mm2 at the
L3-level. Below this measurement patients are almost always symptomatic. In the
diagnosis of spinal stenosis, a combination of myelography and CT is very
efficient (Fig. 22), because these methods visualize the bony changes so well.
MRI can be used, but is more difficult to interpret.
Miscellaneous
Spondylolisthesis is readily identified on plain
films, and the most common types are degenerative and isthmic or spondylolytic
spondylolisthesis. Isthmic spondylolisthesis results from a defect in the pars
interarticularis. Plain films are usually sufficient for the management of
these
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Figure 23. |
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Figure 24. |
patients, but MRI might be helpful in showing pedicular kinking and narrowing of the root-canal which is causing nerve-compression (Fig. 23).
Degenerative disease in the intervertebral joints is a frequent finding in combination with spinal stenosis and disc degeneration but can occasionally be the single cause of nerve-root compression in the lateral recess or root-canal.
Gas collections in intervertebral disks are commonly demonstrated with CT.
The cause is excessive mobility, causing a vacuum phenomenon, leading to an
accumulation of nitrogen. Gas collection in the canal in the extradural space
can occasionally be seen in disk herniations (Fig. 24).
Cervical spine
Anatomical considerations
In the cervical region the
nerve-roots are directed laterally and do not have the descending pattern seen
in the lumbar region. On myelography the root-sleeves are easily identified and
also subtle compression can be disclosed. Normally, the cord is somewhat thicker
in the cervical region than in the thoracic, which should not be interpreted as
a tumor. On MRI both the bony components as well as the soft tissues of the
spinal canal can be visualized. The root-sleeves should always be identified and
in high quality MRI both the dorsal and ventral root can be identified. The root
-canals are easily identified on MRI because of fat content. The spinal cord has
an oval shape with the long axis in the horizontal direction on axial views. On
high quality images the H-shaped gray matter of the spinal cord can be
identified.
Disc herniation
Isolated soft disc herniations, which are seen in
young and middle-aged adults are relatively uncommon in the cervical spine.
However, the majority of disc herniations are found in combination with
degenerative osteophytic spurs with narrowing of the spinal canal as well as the
rootcanals. As in the lumbar spine the disc herniations are usually
posterolateral
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Figure 25. |
raising the possibility of nerve-root compression. Large posterolateral and central disk herniations sometimes cause compression of the cord (Fig. 25). In the cervical spine free fragments are unusual. MRI is usually sufficient for diagnosis, however, minor nerve-root compressions might be difficult to see on MRI. In cases where there is a discrepancy between clinical symptoms and findings on MRI, cervical myelography, preferably in combination with CT, should be performed. It is often difficult to separate compression caused by bony spurs from disk herniation on MRI. In this situation plain films are usually helpful for analysis of the bony components.
Spinal stenosis
Bony spurs causing narrowing of the spinal canal and root-canals are very common in the middle-aged and in the elderly. There is often a poor correlation between these degenerative changes and clinical symptoms, except in the most advanced cases. The most frequent location of advanced degenerative disease is seen at the C5-C6 and C6-C7 levels, where mobility is most pronounced. Osteophytic spurs from the vertebral bodies encroach upon the central spinal canal and osteophytes from
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Figure 26. |
the uncovertebral joints and intervertebral joints encroach upon the rootcanals (Fig. 26). MRI or myelography in combination with CT can be used for diagnosis. The previously mentioned difficulty in distinguishing between bony spurs and calcified hard disk herniations is from the practical point of view, of minor importance. The clinical information needed is knowledge of the presence of a cord or nerve-root compression, at what level it is found, and whether there are single or multiple affected levels. All of this information is important for the choice of surgical procedure, i.e. laminectomy, facetectomy or anterior approach.
Miscellaneous
Ossification of posterior longitudinal ligament
(OPLL) is a well recognized cause of cervical canal stenosis and myelopathy. Its
cause is unknown. Although ossification can be seen on plain films, CT
-myelography is valuable for diagnosis and more precise information (Fig. 27).
OPLL might be difficult to observe on MRI, especially if only T1-weighted images
are used, in which case the calcified ligament might mimic normal
CSF.
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Figure 27. |
Thoracic spine
Degenerative changes are less frequent in the thoracic spine than in other
parts because of better stability in this region due to mechanical support from
the ribs. Thoracic disc herniations are uncommon, with a reported
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Figure
28. T1-weighted MRI (a) and myelography (b) show a thoracic disc herniation, however, detailed information is not obtained. The lesion is better visualized on CT myelography which shows a huge calcified herniation with compression of the cord (c). |
incidence of approximately 1/1 000 000/year. Recent investigations have shown that this figure is probably too low. The diagnosis of thoracic disc herniation is often difficult, because the symptoms are often vague and usually don't indicate the level. All imaging modalities have limited usefulness in this region due to anatomical factors and disturbance from motion in adjacent organs, such as heart and lungs. However, with modem MR-scanners, an adequate image quality can usually be achieved. In other cases a combination of myelography for identification of level and CT for detailed information is recommended (Fig. 28). Thoracic disk herniations are often calcified.