Review of Neck CT Studies Without CNS Windows Can Miss Crucial Spinal Cord Findings Jonathan G....
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Transcript of Review of Neck CT Studies Without CNS Windows Can Miss Crucial Spinal Cord Findings Jonathan G....
Review of Neck CT Studies Without CNS Windows Can Miss Crucial Spinal Cord Findings
Jonathan G. Murnick, MD, PhDChildren’s National Health SystemWashington, DCPresentation #1915
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Disclosures
None.
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CT Image Contrast
• CT viewing windows are chosen to maximize image contrast
• Table shows approximate Hounsfield unit (HU) values for different types of tissue found in the neck on a contrast-enhanced CT
Tissue HU
Bone 500
Air -1000
Muscle 70
IV Contrast (intravascular)
250
Fat -80
CSF 10
Spinal cord 50
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CT Image Contrast
• A neck CT is typically viewed using two different sets of windows: “bone windows” and “soft tissue windows”
• Bone windows• Center ~400; Width ~2000• Optimize visualization of bone
• Soft tissue windows• Center ~50; Width ~400• Optimize soft tissue contrast,
including vessels, muscle, lymph nodes, fat
Tissue HU
Bone 500
Air -1000
Muscle 70
IV Contrast (intravascular)
250
Fat -80
CSF 10
Spinal cord 50
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Normal Neck CT
Bone windows Soft tissue windows
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Using CNS Windows
• Contrast between spinal cord and CSF is poor on both bone and soft tissue windows
Soft tissue windowsBone windows
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Using CNS Windows
• CNS windows dramatically improve contrast in the spinal canal
Soft tissue windowsBone windows
CNS windows
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CNS Windows
• CNS windows are typically used to view intracranial structures
• Easy to differentiate brain parenchyma from CSF
• Show intracranial hemorrhage• When used in the neck, these
windows differentiate spinal cord from CSF
• Following are three missed cases where CNS windows demonstrate important pathology
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Case #1: Neck Pain after Fall
• An 8-year-old girl presented to the ED with neck pain after a fall during gymnastics
• Cervical spine CT was performed
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Case #1: Neck Pain after Fall
• No fracture was identified, and the patient was discharged home.
Bone windows
Soft tissue windows
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Case #1: Neck Pain after Fall
• Review in CSF windows (not performed at time of interpretation) shows expansion of the cervical spinal cord, with loss of surrounding subarachnoid space
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Case #1: Neck Pain after Fall
• 4 days later, the patient again presented to the ED with new symptoms of left arm weakness
• The patient was admitted, and MRI showed an expansile mass lesion in the cervical cord
• Biopsy was consistent with GBM
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Case #2: Neck pain and stiffness
• An 18-month-old girl presented to the ED with 5 days of sore throat, cough, neck pain, and neck stiffness
• Contrast-enhanced CT of the neck was performed
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Case #2: Neck pain and stiffness
• CT of the neck was read as notable for mild tonsillar and retropharyngeal edema; no abscess identified
• The patient was admitted to the hospital for antibiotics for presumed tonsillitis
Soft tissue windows
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Case #2: Neck pain and stiffness
• 6 hours later, the CT was re-reviewed in CNS windows
• A hyperdense spinal epidural lesion was identified, with severe mass effect on the cord
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Case #2: Neck pain and stiffness
• MRI was consistent with an epidural hematoma at the cervicothoracic junction; no mass lesion or vascular malformation was seen
• Bland hematoma was evacuated at surgery
• The patient is well, with no neurologic sequela
T1 precontrast
FSEIR
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Case #2: Neck pain and stiffness
• Spontaneous spinal epidural hematoma is a rare but known cause of spinal cord compression in young children
• Most commonly at the cervicothoracic junction
• Hypothesized to result when an epidural vein ruptures due to transiently raised intrathoracic pressure. (Note that this patient had a history of cough.)
T1 precontrast
FSEIR
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Case #3: Jaw pain and trismus
• A 3-year-old boy presented to oral surgery clinic with 4 weeks of jaw pain and trismus (inability to open the mouth)
• CT of the face was ordered
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Case #3: Jaw pain and trismus
• Nonspecific periosteal reaction was noted of the right mandibular condyle
• Study was read as otherwise normal• Note that no abnormality is readily apparent in the spinal canal
on soft tissue windows
Bone windows
Soft tissue windows
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Case #3: Jaw pain and trismus
• Review in CNS windows (not performed at time of interpretation) shows a large cervical cord syrinx
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Case #3: Jaw pain and trismus
• 5 days later, the patient was admitted to the hospital for optimization of nutrition (he had lost 11 pounds due to trismus) and further workup
• MRI of the brain showed a Chiari 1 malformation, with a large syrinx dissecting upward into the brainstem (syringobulbia)
• The patient underwent Chiari decompression surgery with near-complete resolution of the syrinx and substantial improvement in symptoms of trismus
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Case #3: Jaw pain and trismus
• Syrinx likely led to trismus by affecting the trigemenal motor nucleus in the dorsal pons
• Trismus secondary to injury to the dorsal pons has been previously reported in cases of stroke, trauma, and tumor
www.neuroanatomy.wisc.edu/virtualbrain
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Summary Points
• CT scans of the neck, face, and cervical spine all include portions of the spinal canal in the imaged volume, even if it is not the primary focus of the study
• It is important to review the spinal canal in windows optimized for CNS structures; otherwise, key findings can be missed
• Although unusual, syringobulbia can present as trismus
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References
Schoonjans A-S, et al. “Spontaneous spinal epidural hematoma in infancy: Review of the literature and the “seventh” case report.” Eur J Paediatr Neurol (2013) 17: 537-542.
Seo J-H, et al. “Severe spastic trismus without generalized spasticity after unilateral brain stem stroke.” Ann Rehabil Med (2012) 36: 154-158
Jelasic F & Freitak V. “Inverse activity of masticatory muscles with and without trismus: a brainstem syndrome.” J Neurol Neurosurg Psych (1978) 41: 798-804