3451 Diseases of the Spinal Cord CHAPTER 442
additional symptoms of an immune-mediated disease. Transverse
myelitis refers to a pattern of extensive spinal cord injury, clinically
manifest as bilateral sensory symptoms, unilateral or bilateral weakness, and bladder and/or bowel disturbance. In most of the developed
world MS is the most common inflammatory cause of an acute myelitis
but involvement is usually partial and not transverse. Recurrent episodes of myelitis are usually due to one of the immune-mediated diseases or to infection with herpes simplex virus (HSV) type 2 (below).
MULTIPLE SCLEROSIS MS may present with acute myelitis, particularly in individuals of Asian or African ancestry. In whites, MS attacks
rarely cause a transverse myelopathy (i.e., attacks of bilateral sensory
disturbances, unilateral or bilateral weakness, and bladder or bowel
symptoms), but MS is among the most common causes of a partial cord
syndrome. MRI findings in MS-associated myelitis typically consist
of mild swelling of the cord and diffuse or multifocal “shoddy” areas
of abnormal signal on T2-weighted sequences. Contrast enhancement, indicating disruption in the blood-brain barrier associated with
inflammation, is present in many acute cases. In one study 68% of
patients presenting with partial myelitis developed MS after a mean
follow-up of 4 years; risk factors for conversion to MS included age <40
years; inflammatory CSF, and >3 periventricular lesions on brain MRI.
Treatment of acute episodes of MS-associated myelitis consists
of intravenous methylprednisolone (500 mg qd for 3 days) followed
by oral prednisone (1 mg/kg per day for several weeks, then gradual
taper). A course of plasma exchange may be indicated for severe cases
if glucocorticoids are ineffective. MS is discussed in Chap. 444.
NEUROMYELITIS OPTICA NMO is an immune-mediated demyelinating disorder consisting of a severe myelopathy that is typically
longitudinally extensive, meaning that the lesion spans three or more
vertebral segments. NMO is associated with optic neuritis that is often
bilateral and may precede or follow myelitis by weeks or months, and
also by brainstem and, in some cases, hypothalamic or focal cerebral
white matter involvement. Recurrent myelitis without optic nerve
or other involvement can also occur in NMO. CSF studies reveal a
variable mononuclear pleocytosis of up to several hundred cells per
microliter (higher than in typical MS) with occasional cases showing
polymorphonuclear predominant pattern; oligoclonal bands are present in <20% of NMO cases. Diagnostic serum autoantibodies against
the water channel protein aquaporin-4 (AQP-4) are present in 90%
of patients with NMO; in some AQP-4 negative cases autoantibodies
against the CNS myelin protein myelin oligodendrocyte glycoprotein
(MOG) are found. NMO has also been associated with SLE (see below)
as well as with other systemic autoimmune diseases; rare cases are
paraneoplastic. Acute relapses of NMO are treated with glucocorticoids
and, for severe or refractory cases, plasma exchange. Three monoclonal
antibodies are now available for prophylactic treatment: eculizumab, a
terminal complement inhibitor; inebilizumab, a B-cell depleter; and
satralizumab, an IL-6 receptor blocker. Off-label use of azathioprine,
mycophenolate, or rituximab are other options. Treatment for 5 years
or longer is generally recommended. NMO is discussed in Chap. 445.
SARCOIDOSIS Sarcoid myelopathy may present as a slowly progressive
or relapsing disorder. Clinically, sensory involvement often predominates. MRI reveals edematous swelling of the spinal cord that may
mimic tumor and subpial gadolinium enhancement of active lesions
typically along the dorsal surface of the cord. In some cases nodular
enhancing lesions can be seen; lesions may be single or multiple, and
on axial images enhancement of the central cord is often present.
The typical CSF profile consists of a mild lymphocyte-predominant
pleocytosis and elevated protein level; in a minority of cases, reduced
glucose and oligoclonal bands are found. The diagnosis is particularly
difficult when systemic manifestations of sarcoid are minor or absent
(nearly 50% of cases) or when other typical neurologic manifestations
of the disease, such as cranial neuropathy, hypothalamic involvement,
or meningeal enhancement visualized by MRI, are lacking. A slit-lamp
examination of the eye to search for uveitis, chest x-ray and CT to
assess pulmonary involvement and mediastinal lymphadenopathy,
serum or CSF angiotensin-converting enzyme (ACE; lacks specificity
and values are elevated in only a minority of cases), serum calcium, and
a gallium scan may assist in the diagnosis. Initial treatment is with high
doses of glucocorticoids, which need to be administered long term and
tapered slowly while monitoring resolution of clinical and MRI signs
of active disease; relapses are managed with high-dose glucocorticoids
plus a steroid-sparing immunosuppressant drug (typically mycophenolate mofetil, azathioprine, or methotrexate), or with the tumor necrosis
factor α-inhibitor infliximab. Sarcoidosis is discussed in Chap. 367.
SYSTEMIC IMMUNE-MEDIATED DISORDERS Myelitis occurs in a small
number of patients with SLE, many cases of which are associated with
antibodies to AQP-4 and satisfy diagnostic criteria for NMO (discussed
above). These patients are at high risk of developing future episodes of
myelitis and/or optic neuritis. In others the etiology of SLE-associated
myelitis is uncertain; antiphospholipid antibodies have been suggested
to play a role; however, the presence of these antibodies appears to be
no more frequent in SLE patients with and without myelitis. The CSF
in NMO-associated myelitis typically shows a pleocytosis often with
polymorphonuclear leukocytes, and no oligoclonal bands; in cases not
due to NMO a mild lymphocytic pleocytosis and oligoclonal bands are
variable findings. Although there are no systematic trials of therapy for
SLE myelitis, based on limited data high-dose glucocorticoids followed
by cyclophosphamide have been recommended. Severe episodes that
do not initially respond to glucocorticoids are often treated with a
course of plasma exchange. Sjögren’s syndrome (Chap. 361) can also be
associated with NMO and also with cases of chronic progressive myelopathy. Other immune-mediated myelitides include Behçet’s disease
(Chap. 364), antiphospholipid antibody syndrome (Chap. 357), mixed
connective tissue disease (Chap. 360), and vasculitis related to polyarteritis nodosa, perinuclear antineutrophilic cytoplasmic (p-ANCA)
antibodies, or primary central nervous system vasculitis (Chap. 363).
Occasional cases of myelitis, often accompanied by other manifestations that can include encephalitis or optic neuritis, have been recently
associated with autoantibodies against glial fibrillary acidic protein
(GFAP) (Chap. 444). Other rare etiologies are chronic lymphocytic
inflammation with pontine perivascular enhancement responsive to
steroids (CLIPPERS), and Erdheim-Chester disease producing inflammatory masslike lesions that can be intramedullary or extraaxial and
compressive.
POSTINFECTIOUS MYELITIS Many cases of myelitis, termed postinfectious or postvaccinal, follow an infection or vaccination. Numerous
organisms have been implicated, including Epstein-Barr virus (EBV),
cytomegalovirus (CMV), mycoplasma, influenza, measles, varicella,
mumps, and yellow fever. As in the related disorder acute disseminated
encephalomyelitis (Chap. 444), postinfectious myelitis often begins as
the patient appears to be recovering from an acute febrile infection,
or in the subsequent days or weeks, but an infectious agent cannot be
isolated from the nervous system or CSF. Serum anti-MOG antibodies
are present acutely in about half of cases. The presumption is that the
myelitis represents an autoimmune disorder triggered by infection and
is not due to direct infection of the spinal cord. No randomized controlled trials of therapy exist; treatment is usually with glucocorticoids
or, in fulminant cases, plasma exchange.
ACUTE INFECTIOUS MYELITIS Many viruses have been associated
with an acute myelitis that is infectious in nature rather than postinfectious. Nonetheless, the two processes are often difficult to distinguish.
Herpes zoster is the best characterized viral myelitis, but HSV types 1
and 2, EBV, CMV, and rabies virus are other well-described causes and
Zika virus has also been recognized as a cause of infectious myelitis.
HSV-2 (and less commonly HSV-1) produces a distinctive syndrome
of recurrent sacral cauda equina neuritis in association with outbreaks
of genital herpes (Elsberg’s syndrome). Poliomyelitis is the prototypic
viral myelitis, but it is more or less restricted to the anterior gray matter
of the cord containing the spinal motoneurons. A polio-like syndrome
can also be caused by a large number of enteroviruses (including
enterovirus A-71 and coxsackie), and with Japanese encephalitis and
other flaviviruses such as West Nile virus. Beginning in 2012, cases
of acute flaccid paralysis in children and adolescents have appeared
3452 PART 13 Neurologic Disorders
associated with enterovirus A-71 and D-68 infection. Chronic viral
myelitic infections, such as those due to HIV or human T-cell lymphotropic virus type 1 (HTLV-1), are discussed below.
Bacterial and mycobacterial myelitis (most are essentially abscesses)
are less common than viral causes and much less frequent than cerebral
bacterial abscess. Almost any pathogenic species may be responsible,
including Borrelia burgdorferi (Lyme disease), Listeria monocytogenes,
Mycobacterium tuberculosis, and Treponema pallidum (syphilis). Mycoplasma pneumoniae may be a cause of myelitis, but its status is uncertain because many cases are more properly classified as postinfectious.
Schistosomiasis (Chap. 234) is an important cause of parasitic
myelitis in endemic areas. The process is intensely inflammatory and
granulomatous, caused by a local response to tissue-digesting enzymes
from the ova of the parasite, typically Schistosoma haematobium or
Schistosoma mansoni. Toxoplasmosis (Chap. 228) can occasionally
cause a focal myelopathy, and this diagnosis should especially be considered in patients with AIDS (Chap. 202). Cysticercosis (Chap. 235) is
another consideration, although myelitis from this helminth is far less
common than parenchymal brain or meningeal involvement.
In cases of suspected viral myelitis, it may be appropriate to begin
specific therapy pending laboratory confirmation. Herpes zoster, HSV,
and EBV myelitis are treated with intravenous acyclovir (10 mg/kg
q8h) or oral valacyclovir (2 g tid) for 10–14 days; CMV is treated with
ganciclovir (5 mg/kg IV bid) plus foscarnet (60 mg/kg IV tid) or cidofovir (5 mg/kg per week for 2 weeks).
High-Voltage Electrical Injury Spinal cord injuries are prominent following electrocution from lightning strikes or other accidental
electrical exposures. The syndrome consists of transient weakness
acutely (often with an altered sensorium and focal cerebral disturbances), sometimes followed several days or even weeks later by a myelopathy that can be severe and permanent. This is a rare injury type,
and limited data incriminate a vascular pathology involving the anterior spinal artery and its branches in some cases. Therapy is supportive.
CHRONIC MYELOPATHIES
■ SPONDYLOTIC MYELOPATHY
Spondylotic myelopathy is the most common cause of myelopathy and
of gait difficulty in the elderly, accounting for more than half of nontraumatic spinal cord injuries in some series. Neck and shoulder pain
with stiffness are early symptoms; impingement of bone and soft tissue
overgrowth on nerve roots results in radicular arm pain, most often
in a C5 or C6 distribution. Compression of the cervical cord, which
occurs in fewer than one-third of cases, produces a slowly progressive
spastic paraparesis, at times asymmetric and often accompanied by
paresthesias in the feet and hands. Vibratory sense is diminished in the
legs, there is a Romberg sign, and occasionally there is a sensory level
for vibration or pinprick on the upper thorax. In some cases, coughing
or straining produces leg weakness or radiating arm or shoulder pain.
Dermatomal sensory loss in the arms, atrophy of intrinsic hand muscles, increased deep-tendon reflexes in the legs, and extensor plantar
responses are common. Urinary urgency or incontinence occurs in
advanced cases, but there are many alternative causes of these problems
in older individuals. A tendon reflex in the arms is often diminished
at some level; most often at the biceps (C5-C6). In individual cases,
radicular, myelopathic, or combined signs may predominate. The diagnosis should be considered in appropriate cases of progressive cervical
myelopathy, paresthesias of the feet and hands, or wasting of the hands.
Diagnosis is usually made by MRI and may be suspected from CT
images; plain x-rays are less helpful. Extrinsic cord compression and
deformation are appreciated on axial MRI views, and T2-weighted
sequences may reveal areas of high signal intensity within the cord
adjacent to the site of compression. A cervical collar may be helpful
in milder cases, but the likelihood of progression of medically treated
myelopathy is high, estimated at 8% over 1 year. Definitive therapy
consists of surgical decompression, either posterior laminectomy or
an anterior approach with resection of the protruded disk and bony
material. Cervical spondylosis and related degenerative diseases of
the spine are discussed in Chap. 17.
■ VASCULAR MALFORMATIONS OF THE
CORD AND DURA
Vascular malformations, comprising ~4% of all mass lesions of the
cord and overlying dura, are treatable causes of progressive myelopathy. Most common are fistulas located within the dura or posteriorly
along the surface of the cord. Most dural arteriovenous (AV) fistulas
are located at or below the midthoracic level, usually consisting of a
direct connection between a radicular feeding artery in the nerve root
sleeve with dural veins. The typical presentation is a middle-aged man
with a progressive myelopathy that worsens slowly or intermittently
and may have periods of remission, sometimes mimicking MS. Acute
deterioration due to hemorrhage into the spinal cord (hematomyelia)
or subarachnoid space may also occur but is rare. In many cases,
progression results from local ischemia and edema due to venous
congestion. Most patients have incomplete sensory, motor, and bladder disturbances. The motor disorder may predominate and produce a
mixture of upper and restricted lower motor neuron signs, simulating
amyotrophic lateral sclerosis (ALS). Pain over the dorsal spine, dysesthesias, or radicular pain may be present. Other symptoms suggestive
of AV malformation (AVM) or dural fistula include intermittent
claudication; symptoms that change with posture, exertion, Valsalva
maneuver, or menses; and fever.
Less commonly, AVM disorders are intramedullary rather than
dural. One unusual disorder is a progressive thoracic myelopathy with
paraparesis developing over weeks or months, characterized pathologically by abnormally thick, hyalinized vessels within the cord (subacute
necrotic myelopathy or Foix-Alajouanine syndrome).
Spinal bruits are infrequent but may be sought at rest and after
exercise in suspected cases. A vascular nevus on the overlying skin
may indicate an underlying vascular malformation as occurs with
Klippel-Trenaunay-Weber syndrome. MR angiography and CT angiography can detect the draining vessels of many AVMs (Fig. 442-6).
Definitive diagnosis requires selective spinal angiography, which
defines the feeding vessels and the extent of the malformation. Treatment is tailored to the anatomy and location of the lesion, and generally
consists of microsurgical resection, endovascular embolization of the
major feeding vessels, or a combination of the two approaches.
FIGURE 442-6 Arteriovenous malformation. Sagittal magnetic resonance scans
of the thoracic spinal cord: T2 fast spin-echo technique (left) and T1 postcontrast
image (right). On the T2-weighted image (left), abnormally high signal intensity is
noted in the central aspect of the spinal cord (arrowheads). Numerous punctate
flow voids indent the dorsal and ventral spinal cord (arrow). These represent the
abnormally dilated venous plexus supplied by a dural arteriovenous fistula. After
contrast administration (right), multiple, serpentine, enhancing veins (arrows) on
the ventral and dorsal aspect of the thoracic spinal cord are visualized, diagnostic
of arteriovenous malformation. This patient was a 54-year-old man with a 4-year
history of progressive paraparesis.
3453 Diseases of the Spinal Cord CHAPTER 442
■ RETROVIRUS-ASSOCIATED MYELOPATHIES
The myelopathy associated with HTLV-1, formerly called tropical
spastic paraparesis, is a slowly progressive spastic syndrome with variable sensory and bladder disturbance. Approximately half of patients
have mild back or leg pain. The neurologic signs may be asymmetric,
often lacking a well-defined sensory level; the only sign in the arms
may be hyperreflexia after several years of illness. The onset is usually
insidious, and the tempo of progression of the illness occurs at a variable rate; in one study, median time for progression to cane-, walker-,
or wheelchair-dependent state was 6, 13, and 21 years, respectively.
Progression appears to be more rapid in older patients and those with
higher viral loads. Diagnosis is made by demonstration of HTLV-1-
specific antibody in serum by enzyme-linked immunosorbent assay
(ELISA), confirmed by radioimmunoprecipitation or Western blot
analysis. Especially in endemic areas, a finding of HTLV-1 seropositivity in a patient with myelopathy does not necessarily prove that
HTLV-1 is causative. The CSF/serum antibody index may provide
support by establishing intrathecal synthesis of antibodies, including
oligoclonal antibodies, favoring HTVL-1 myelopathy over asymptomatic carriage. Measuring proviral DNA by polymerase chain reaction
(PCR) in serum and CSF cells can be useful as an ancillary part of diagnosis. The pathogenesis of the myelopathy is uncertain. It could result
from an immune response directed against HTLV-1 antigens in the
nervous system, or alternatively to secondary autoimmunity triggered
by the viral infection. There is no proven effective treatment. Based
on limited evidence, the use of chronic low-dose oral glucocorticoids
can be tried; interferon is of uncertain value, and antiviral treatment is
ineffective. Symptomatic therapy for spasticity and bladder symptoms
may be helpful.
A progressive myelopathy can also result from HIV infection
(Chap. 197). It is characterized by vacuolar degeneration of the posterior and lateral tracts, resembling subacute combined degeneration
(see below).
SYRINGOMYELIA
Syringomyelia is a developmental cavity in the cervical cord that may
enlarge and produce progressive myelopathy or may remain asymptomatic. Symptoms begin insidiously in adolescence or early adulthood,
progress irregularly, and may undergo spontaneous arrest for several
years. Many young patients acquire a cervical-thoracic scoliosis. More
than half of all cases are associated with Chiari type 1 malformations
in which the cerebellar tonsils protrude through the foramen magnum and into the cervical spinal canal. The pathophysiology of syrinx
expansion is controversial, but some interference with the normal flow
of CSF seems likely, perhaps by the Chiari malformation. Acquired cavitations of the cord in areas of necrosis are also termed syrinx cavities;
these follow trauma, myelitis, necrotic spinal cord tumors, and chronic
arachnoiditis due to tuberculosis and other etiologies.
The presentation is a central cord syndrome consisting of a regional
dissociated sensory loss (loss of pain and temperature sensation with
sparing of touch and vibration) and areflexic weakness in the upper
limbs. The sensory deficit has a distribution that is “suspended” over
the nape of the neck, shoulders, and upper arms (cape distribution) or
in the hands. Most cases begin asymmetrically with unilateral sensory
loss in the hands that leads to injuries and burns that are not appreciated by the patient. Muscle wasting in the lower neck, shoulders, arms,
and hands with asymmetric or absent reflexes in the arms reflects
expansion of the cavity in the gray matter of the cord. As the cavity
enlarges and compresses the long tracts, spasticity and weakness of the
legs, bladder and bowel dysfunction, and Horner’s syndrome appear.
Some patients develop facial numbness and sensory loss from damage
to the descending tract of the trigeminal nerve (C2 level or above). In
cases with Chiari malformations, cough-induced headache and neck,
arm, or facial pain may be reported. Extension of the syrinx into the
medulla, syringobulbia, causes palatal or vocal cord paralysis, dysarthria, horizontal or vertical nystagmus, episodic dizziness or vertigo,
and tongue weakness with atrophy.
MRI accurately identifies developmental and acquired syrinx cavities and their associated spinal cord enlargement (Fig. 442-7). Images
of the brain and the entire spinal cord should be obtained to delineate
the full longitudinal extent of the syrinx, assess posterior fossa structures for the Chiari malformation, and determine whether hydrocephalus is present.
TREATMENT
Syringomyelia
Treatment of syringomyelia is generally unsatisfactory. The Chiari
tonsillar herniation may be decompressed, generally by suboccipital
craniectomy, upper cervical laminectomy, and placement of a dural
graft. Fourth ventricular outflow is reestablished by this procedure.
If the syrinx cavity is large, some surgeons recommend direct
decompression or drainage, but the added benefit of this procedure
is uncertain, and complications are common. With Chiari malformations, shunting of hydrocephalus generally precedes any attempt
to correct the syrinx. Surgery may stabilize the neurologic deficit,
and some patients improve. Patients with few symptoms and signs
from the syrinx do not require surgery and are followed by serial
clinical and imaging examinations.
Syrinx cavities secondary to trauma or infection, if symptomatic,
are treated with a decompression and drainage procedure in which
a small shunt is inserted between the cavity and subarachnoid
space; alternatively, the cavity can be fenestrated. Cases due to
intramedullary spinal cord tumor are generally managed by resection of the tumor.
■ CHRONIC MYELOPATHY OF MULTIPLE
SCLEROSIS
A chronic progressive myelopathy is the most frequent cause of disability in both primary progressive and secondary progressive forms
of MS. Involvement is typically bilateral but asymmetric and produces
motor, sensory, and bladder/bowel disturbances. Fixed motor disability appears to result from extensive loss of axons in the corticospinal
tracts. Diagnosis is facilitated by identification of earlier attacks such
as optic neuritis. MRI, CSF, and evoked-response testing are confirmatory. Treatment with ocrelizumab, an anti-CD20 B-cell monoclonal
antibody, is effective in patients with primary progressive MS, and
disease-modifying therapy is also indicated in patients with secondary
FIGURE 442-7 Magnetic resonance imaging of syringomyelia associated with a
Chiari malformation. Sagittal T1-weighted image through the cervical and upper
thoracic spine demonstrates descent of the cerebellar tonsils below the level of the
foramen magnum (black arrows). Within the substance of the cervical and thoracic
spinal cord, a cerebrospinal fluid collection dilates the central canal (white arrows).
3454 PART 13 Neurologic Disorders
progressive MS who have clinical or MRI evidence of active disease.
MS is discussed in Chap. 444.
■ SUBACUTE COMBINED DEGENERATION
(VITAMIN B12 DEFICIENCY)
This treatable myelopathy presents with subacute paresthesias in the
hands and feet, loss of vibration and position sensation, and a progressive spastic and ataxic weakness. Loss of reflexes due to an associated
peripheral neuropathy in a patient who also has Babinski signs is a
helpful diagnostic clue. Optic atrophy and irritability or other cognitive changes may be prominent in advanced cases and are occasionally
the presenting symptoms. The myelopathy of subacute combined
degeneration tends to be diffuse rather than focal; signs are generally
symmetric and reflect predominant involvement of the posterior and
lateral tracts, including Romberg sign. Causes include dietary deficiency, especially in vegans, and gastric malabsorption syndromes
including pernicious anemia (Chap. 99). The diagnosis is confirmed
by the finding of macrocytic red blood cells, a low serum B12 concentration, and elevated serum levels of homocysteine and methylmalonic
acid. Treatment is by replacement therapy, beginning with 1000 μg of
intramuscular vitamin B12 daily for 5 days and then continued as a once
monthly maintenance dose; oral maintenance is also reasonable, except
in cases of pernicious anemia.
Two closely related conditions deserve mention here. The first is
folate deficiency–associated myelopathy, now only rarely seen since
widespread programs of dietary fortification with folate have been
implemented. A second is due to inhalation with nitrous oxide (laughing gas), an irreversible inhibitor of vitamin B12, which also produces a
myelopathy identical to subacute combined degeneration. Exposure to
nitrous oxide may occur during dental or surgical procedures or from
recreational inhalation (“doing whippets”).
■ HYPOCUPRIC MYELOPATHY
This myelopathy is similar to subacute combined degeneration
(described above), except serum levels of B12 are normal. Low levels of
serum copper are found, and often there is also a low level of serum
ceruloplasmin. Some cases follow gastrointestinal procedures, particularly bariatric surgery, that result in impaired copper absorption; others
have been associated with excess zinc from health food supplements or
in the past zinc-containing denture creams, all of which impair copper
absorption via induction of metallothionein, a copper-binding protein.
Many cases are idiopathic. There is often a coexisting anemia. Improvement or at least stabilization may be expected with reconstitution of
copper stores by oral supplementation.
■ TABES DORSALIS
The classic syphilitic syndromes of tabes dorsalis and meningovascular
inflammation of the spinal cord are now less frequent than in the past
but must be considered in the differential diagnosis of spinal cord disorders. The characteristic symptoms of tabes are fleeting and repetitive
lancinating pains, primarily in the legs or less often in the back, thorax,
abdomen, arms, and face. Ataxia of the legs and gait due to loss of
position sense occurs in half of patients. Paresthesias, bladder disturbances, and acute abdominal pain with vomiting (visceral crisis) occur
in 15–30% of patients. The cardinal signs of tabes are loss of reflexes in
the legs; impaired position and vibratory sense; Romberg sign; and,
in almost all cases, bilateral Argyll Robertson pupils, which fail to
constrict to light but accommodate. Diabetic polyradiculopathy may
simulate this condition. Treatment of tabes dorsalis and other forms
of neurosyphilis consists of penicillin G administered intravenously,
or intramuscularly in combination with oral probenecid (Chap. 182).
■ HEREDITARY SPASTIC PARAPLEGIA
Many cases of slowly progressive myelopathy are genetic in origin
(Chap. 437). More than 80 different causative loci have been identified,
including autosomal dominant, autosomal recessive, and X-linked
forms. Especially for the recessive and X-linked forms, a family history of myelopathy may be lacking. Most patients present with almost
imperceptibly progressive spasticity and weakness in the legs, usually
but not always symmetrical. Sensory symptoms and signs are absent
or mild, but sphincter disturbances may be present. In some families,
additional neurologic signs are prominent, including nystagmus,
ataxia, or optic atrophy. The onset may be as early as the first year of
life or as late as middle adulthood. Only symptomatic therapies are
available.
PRIMARY LATERAL SCLEROSIS
This is a mid- to late-life onset degenerative disorder characterized by
progressive spasticity with weakness, eventually accompanied by dysarthria and dysphonia; bladder symptoms occur in approximately half
of patients. Sensory function is spared. The disorder resembles ALS
and is considered a variant of the motor neuron degenerations, but
without the characteristic lower motor neuron disturbance and with
typically a slower progression. Some cases may represent late-onset
cases of familial spastic paraplegia, particularly autosomal recessive or
X-linked varieties in which a family history may be absent. (See also
Chap. 437.)
■ ADRENOMYELONEUROPATHY
This X-linked disorder is a variant of adrenoleukodystrophy (ALD).
Most affected males have a history of adrenal insufficiency and then
develop a progressive spastic (or ataxic) paraparesis beginning in
early or sometimes middle adulthood; some patients also have a mild
peripheral neuropathy. Female heterozygotes may develop a slower,
insidiously progressive spastic myelopathy beginning later in adulthood and without adrenal insufficiency. Diagnosis is usually made
by demonstration of elevated levels of very-long-chain fatty acids in
plasma and in cultured fibroblasts. The responsible gene encodes the
adrenoleukodystrophy protein (ALDP), a peroxisomal membrane
transporter involved in carrying long-chain fatty acids to peroxisomes
for degradation. Corticosteroid replacement is indicated if hypoadrenalism is present. Allogeneic bone marrow transplantation has been
successful in slowing progression of cognitive decline in some patients
with ALD treated early in their disease but appears to be ineffective for
the myelopathy of ALD. Nutritional supplements (Lorenzo’s oil) have
also been attempted for this condition without evidence of efficacy.
■ CANCER-RELATED SYNDROMES
Cancer-related causes of chronic myelopathy, besides the common
neoplastic compressive myelopathy discussed earlier, include radiation
injury (Chap. 90), and a myelopathy resembling subacute combined
degeneration that can follow intrathecal administration of methotrexate (a folate antagonist). Rare paraneoplastic myelopathies are most
often associated with lung cancer and anti-amphiphysin (also breast),
anti-collapsin response mediator 5 (CRMP5) (also lymphoma), or
anti-Hu antibodies (Chap. 94). Another uncommon lymphomaassociated paraneoplastic syndrome is a progressive flaccid paresis with
destruction of anterior horn cells. NMO with aquaporin-4 antibodies
(Chap. 445) can also rarely be paraneoplastic in origin. Metastases to
the cord are probably more common than any of these disorders in
patients with cancer.
■ OTHER CHRONIC MYELOPATHIES
Tethered cord syndrome is a developmental disorder of the lower spinal
cord and nerve roots that rarely presents in adulthood as low back pain
accompanied by a progressive lower spinal cord and/or nerve root
syndrome. Some patients have a small leg or foot deformity indicating
a long-standing process, and in others, a dimple, patch of hair, or sinus
tract on the skin overlying the lower back is the clue to a congenital
lesion. Diagnosis is made by MRI, which demonstrates a low-lying
conus medullaris and thickened filum terminale. The MRI may also
reveal diastematomyelia (division of the lower spinal cord into two
halves), lipomas, cysts, or other congenital abnormalities of the lower
spine coexisting with the tethered cord. Treatment is with surgical
release.
There are a number of rare toxic causes of spastic myelopathy,
including lathyrism due to ingestion of chickpeas containing the
excitotoxin β-N-oxalylamino-L-alanine (BOAA), seen primarily in
the developing world or during famines, and Konzo due to ingestion
of the cyanogen-containing casava plant found in sub-Saharan Africa.
3455 Diseases of the Spinal Cord CHAPTER 442
Often, a cause of intrinsic myelopathy can be identified only
through periodic reassessment.
REHABILITATION OF SPINAL
CORD DISORDERS
The prospects for recovery from an acute destructive spinal cord
lesion fade after ~6 months. There are currently no effective means
to promote repair of injured spinal cord tissue; promising but entirely
experimental approaches include the use of factors that influence
reinnervation by axons of the corticospinal tract, nerve and neural
sheath graft bridges, forms of electrical stimulation at the site of injury,
and the local introduction of stem cells. The disability associated with
irreversible spinal cord damage is determined primarily by the level of
the lesion and by whether the disturbance in function is complete or
incomplete (Table 442-4). Even a complete high cervical cord lesion
may be compatible with a productive life. The primary goals are development of a rehabilitation plan framed by realistic expectations and
attention to the neurologic, medical, and psychological complications
that commonly arise.
Many of the usual symptoms associated with medical illnesses,
especially somatic and visceral pain, may be lacking because of the
destruction of afferent pain pathways. Unexplained fever, worsening
of spasticity, or deterioration in neurologic function should prompt a
search for infection, thrombophlebitis, or an intraabdominal pathology. The loss of normal thermoregulation and inability to maintain
normal body temperature can produce recurrent fever (quadriplegic
fever), although most episodes of fever are due to infection of the urinary tract, lung, skin, or bone.
Bladder dysfunction generally results from loss of supraspinal
innervation of the detrusor muscle of the bladder wall and the sphincter musculature. Detrusor spasticity is treated with anticholinergic
drugs (oxybutynin, 2.5–5 mg qid) or tricyclic antidepressants with
anticholinergic properties (imipramine, 25–200 mg/d). Failure of the
sphincter muscle to relax during bladder emptying (urinary dyssynergia)
may be managed with the α-adrenergic blocking agent terazosin
hydrochloride (1–2 mg tid or qid), with intermittent catheterization,
or, if that is not feasible, by use of a condom catheter in men or a permanent indwelling catheter. Surgical options include the creation of an
artificial bladder by isolating a segment of intestine that can be catheterized intermittently (enterocystoplasty) or can drain continuously to
an external appliance (urinary conduit). Bladder areflexia due to acute
spinal shock or conus lesions is best treated by catheterization. Bowel
regimens and disimpaction are necessary in most patients to ensure at
least biweekly evacuation and avoid colonic distention or obstruction.
Patients with acute cord injury are at risk for venous thrombosis and
pulmonary embolism. Use of calf-compression devices and anticoagulation
with low-molecular-weight heparin are recommended. In cases of persistent paralysis, anticoagulation should probably be continued for 3 months.
Prophylaxis against decubitus ulcers should involve frequent changes
in position in a chair or bed, the use of special mattresses, and cushioning of areas where pressure sores often develop, such as the sacral prominence and heels. Early treatment of ulcers with careful cleansing, surgical
or enzyme debridement of necrotic tissue, and appropriate dressing and
drainage may prevent infection of adjacent soft tissue or bone.
Spasticity is aided by stretching exercises to maintain mobility of
joints. Drug treatment is effective but may result in reduced function,
as some patients depend on spasticity as an aid to stand, transfer, or
walk. Baclofen (up to 240 mg/d in divided doses) is effective; it acts
by facilitating γ-aminobutyric acid–mediated inhibition of motor
reflex arcs. Diazepam acts by a similar mechanism and is useful
for leg spasms that interrupt sleep (2–4 mg at bedtime). Tizanidine
(2–8 mg tid), an α2
adrenergic agonist that increases presynaptic
inhibition of motor neurons, is another option. For nonambulatory
patients, the direct muscle inhibitor dantrolene (25–100 mg qid) may
be used, but it is potentially hepatotoxic. In refractory cases, intrathecal baclofen administered via an implanted pump, botulinum toxin
injections, or dorsal rhizotomy may be required to control spasticity.
Despite the loss of sensory function, many patients with spinal cord
injury experience chronic pain sufficient to diminish their quality of
life. Randomized controlled studies indicate that gabapentin or pregabalin is useful in this setting. Epidural electrical stimulation and intrathecal infusion of pain medications have been tried with some success.
Management of chronic pain is discussed in Chap. 13.
A paroxysmal autonomic hyperreflexia may occur following lesions
above the major splanchnic sympathetic outflow at T6. Headache,
flushing, and diaphoresis above the level of the lesion, as well as hypertension with bradycardia or tachycardia, are the major symptoms. The
trigger is typically a noxious stimulus—for example, bladder or bowel
distention, a urinary tract infection, or a decubitus ulcer—below the
level of the cord lesion. Treatment consists of removal of offending
stimuli; ganglionic blocking agents (mecamylamine, 2.5–5 mg) or
other short-acting antihypertensive drugs are useful in some patients.
Attention to these details allows longevity and a productive life for
patients with complete transverse myelopathies.
■ FURTHER READING
Badhiwala JH et al: Degenerative cervical myelopathy—update and
future directions. Nat Rev Neurol 16:108, 2020.
Barreras P et al: Clinical biomarkers differentiate myelitis from vascular and other causes of myelopathy. Neurology 90:12, 2018.
Kühl JS et al: Long-term outcomes of allogeneic haematopoietic stem
cell transplantation for adult cerebral X-linked adrenoleukodystrophy. Brain 140:953, 2017.
Levi AD, Schwab JM: A critical reappraisal of corticospinal tract
somatotopy and its role in traumatic cervical spinal cord syndromes.
J Neurosurg Spine 12:1, 2021.
Ozpinar A et al: Epidemiology, clinical presentation, diagnostic evaluation, and prognosis of spinal arteriovenous malformations. Handb
Clin Neurol 143:145, 2017.
Parks NE: Metabolic and toxic myelopathies. Continuum (Minneap
Minn) 27:143, 2021.
Patchell RA et al: Direct decompressive surgical resection in the
treatment of spinal cord compression caused by metastatic cancer:
A randomised trial. Lancet 366:643, 2005.
Robertson CE et al: Recovery after spinal cord infarcts: Long-term
outcome in 115 patients. Neurology 78:114, 2012.
Ropper AE, Ropper AH: Acute spinal cord compression. N Engl J Med
376:1358, 2017.
Ruet A et al: Predictive factors for multiple sclerosis in patients with
clinically isolated spinal cord syndrome. Mult Scler 17:312, 2011.
Yáñez ML et al: Diagnosis and treatment of epidural metastases.
Cancer 123:1106, 2017.
Zalewski NL, Flanagan EP: Autoimmune and paraneoplastic
myelopathies. Semin Neurol 38:278, 2018.
Zalewski NL et al: Characteristics of spontaneous spinal cord infarction and proposed diagnostic criteria. JAMA Neurol 76:56, 2019.
TABLE 442-4 Expected Neurologic Function Following Complete Cord Lesions
LEVEL SELF-CARE TRANSFERS MAXIMUM MOBILITY
High quadriplegia (C1–C4) Dependent on others; requires respiratory
support
Dependent on others Motorized wheelchair
Low quadriplegia (C5–C8) Partially independent with adaptive
equipment
May be dependent or independent May use manual wheelchair, drive an
automobile with adaptive equipment
Paraplegia (below T1) Independent Independent Ambulates short distances with aids
Source: Adapted from JF Ditunno, CS Formal: Chronic spinal cord injury. N Engl J Med 330:550, 1994.
3456 PART 13 Neurologic Disorders
■ INTRODUCTION
Traumatic brain injury (TBI) represents a significant global public health
problem. In the United States, estimates of the frequency of TBI range
between 2.5 and 4 million cases per year, depending on the study and
methods used to define and include cases. Age-specific rates show a
bimodal distribution, with highest risk in younger individuals and
older adults. The most common mechanism of injury in the young is
motor vehicle accidents and is more common in men, whereas in older
adults, falls are the major cause of injury and are more likely to occur
in women.
TBI imposes substantial demands on health care systems. Worldwide, at least 10 million TBIs are serious enough to result in death or
hospitalization, producing a global economic burden of $400 billion
annually. In the United States, the estimated annual cost is >$76 billion.
Due to advances in medical care and other factors, more people are
surviving TBI than ever before. Brain injury accounts for more lost
productivity at work among Americans than any other form of injury.
An estimated 5.3 million Americans are living with significant disabilities resulting from TBI that complicate their return to a full and productive life. Increased media attention to military and sports-related
TBI has highlighted the growing concern that injuries that were previously dismissed can have lifelong consequences for some individuals.
Head injuries are so common that almost all physicians will be
called upon to provide some aspect of immediate care or to see
patients who are suffering from various sequelae. Patients and their
families initially need education regarding the natural history of TBI
along with treatment of acute symptoms such as headache. Continued
follow-up is important to ensure that the sequelae experienced by
some patients—such as postconcussive disorder (PCD), depression,
or sleep disorder—are identified and treated appropriately. Effective
management of TBI and its consequences often requires a coordinated
multidisciplinary care team.
■ DEFINITION AND CLASSIFICATION
TBI is commonly defined as an alteration in brain function, or other evidence of brain pathology, caused by an external force, and characterized
by the following: (1) any period of loss or decreased level of consciousness
(LOC), (2) any loss of memory for events immediately before (retrograde)
or after (posttraumatic) the injury, (3) any neurologic deficits, and/or (4)
any alteration in mental state at the time of injury.
Evidence of TBI can include visual, neuroradiologic, or laboratory
confirmation of damage to the brain, but TBI is more often diagnosed
on the basis of acute clinical criteria. In addition to standard CT imaging, structural MRI and functional imaging (resting-state functional
MRI) techniques show increasing sensitivity, and it is likely that sensitive blood-based biomarkers will play an increasingly important role in
the diagnosis and treatment of these patients (described below).
MECHANISMS OF TBI Common mechanisms of TBI include the head
being struck by an object, the head striking an object, the brain
undergoing an acceleration/deceleration movement, a foreign body
penetrating the brain, or forces generated from events such as a blast
or explosion. Motor vehicle crashes have historically been cited as the
most common cause of TBI. All forms of transportation, however,
are common causes of TBI, including motorcycle crashes, bicycle
accidents, skateboarding, and pedestrian injuries. The other leading
causes of TBI are falls, assaults, and sports, with varied frequency
across the lifespan. Certainly, there has been an increased focus on the
high frequency of mild TBI (mTBI), often referred to as concussion,
encountered by athletes participating in contact and collision sports
443
at all competitive levels, as well as the potential short-term effects and
long-term risks associated with sport-related concussion.
CLASSIFICATION OF TBI SEVERITY Numerous systems have been developed over the years to define and classify TBI severity along a continuum from mild to moderate to severe. These systems are usually
most applicable to closed head injuries. In nearly all classification
systems, TBI severity is graded based on acute injury characteristics
rather than postacute injury status, as other factors can intervene
to influence functional outcome. This can be problematic, as some
patients with severe TBI will have a full recovery and some with mild
TBI will be left with lifetime disability. Historically, the presence
and duration of unconsciousness and amnesia have been the main
points of distinction along the gradient of TBI severity. Current TBI
classification systems remain symptom-based and do not incorporate patho-anatomical or molecular features, such as CT findings and
blood-based biomarkers.
The Glasgow Coma Scale (GCS) is the most recognized and widely
used method for grading TBI severity. The GCS provides a practical
indicator of gross neurologic status by assessing motor function, verbal
responses, and the patient’s ability to open his or her eyes voluntarily or
in response to external commands and stimuli. The grading is applied
to the best response that can be elicited from the patient at the time of
assessment, preferably before any paralyzing or sedating medication
is administered or the patient is intubated, as these interventions confound interpretation of the score. The GCS assessment produces scores
ranging from 3 to 15 (Table 443-1).
Upon the 40th anniversary of the GCS in 2014, the wording for
responses was revised, and recommendations were made to improve its
utility. Importantly, individual patients are best described by the three
components of the coma scale (eye, verbal, motor, e.g., E3V4M6); the
derived total coma score (e.g., 13) is less informative and should only
be used to characterize groups of patients.
Several injury-classification systems have been developed to go
beyond GCS score or acute injury characteristics and incorporate chief
signs and symptoms in defining mTBI. The use of multiple severity
indicators is intended to improve sensitivity in the detection of mTBI
(GCS 13–15), while also taking into consideration traditional acute
injury characteristics that have been presumed to predict outcome following mild and moderate brain injury. Loss of consciousness (LOC)
and posttraumatic amnesia (PTA) remain the most common injury
characteristics referenced in these classification systems. In the case
of moderate (GCS 9–12) and severe (GCS 3–8) TBI, GCS score and
the duration of LOC and PTA can be robust predictors of long-term
outcome and morbidity. In cases of mTBI, however, while PTA and
LOC are important indicators of acute injury, they are less predictive
of eventual recovery time and outcome.
Concussion and Other
Traumatic Brain Injuries
Geoffrey T. Manley, Benjamin L. Brett,
Michael McCrea
TABLE 443-1 Glasgow Coma Scale
EYE OPENING (E) VERBAL RESPONSE (V)
Spontaneous 4 Oriented 5
To speech 3 Confused 4
To pressure 2 Words 3
None 1 Sounds 2
None 1
Best Motor Response (M)
Obeying commands 6
Localizing 5
Normal flexion 4
Abnormal flexion 3
Extension 2
None 1
Note: Revised GCS (2014).
Source: Reproduced with permission from G Teasdale et al: The Glasgow Coma
Scale at 40 years: Standing the test of time. Lancet Neurol 13:844, 2014.
3457Concussion and Other Traumatic Brain Injuries CHAPTER 443
■ TBI TYPES AND PATHOLOGIES
MILD TBI (CONCUSSION) It is estimated that 70–90% of all treated TBIs
are mild in severity based on traditional case definitions and acute
injury characteristics, with most reported estimates in the order of
85%. The published figures likely underrepresent the true incidence of
mTBI because of variable case definitions and heterogeneous methods.
Moreover, because a subgroup of individuals with milder brain injuries
does not seek medical attention, epidemiologic studies that depend on
hospital-based data also underestimate the true incidence.
The term concussion, while popular, is vague and is not based on
widely accepted objective criteria, resulting in multiple definitions from
various groups. There has been debate as to whether concussion is part
of the TBI spectrum or a separate entity. In 2017, the Concussion in
Sports Group issued a consensus statement that “concussion is a traumatic brain injury” (McCrory et al, 2017). By firmly placing concussion
in the spectrum of TBI, the underlying pathophysiologic processes
common to all TBI presentations can now be considered together.
CT imaging is often normal in this population. However, emerging
evidence indicates that 3-tesla (3T) MRI scans can identify pathology
consistent with acute brain injury such as contusion and microhemorrhage. When patients with mTBI have CT and/or MRI abnormalities,
they are often referred to as complicated mTBI and are more likely to
have an unfavorable outcome.
■ SKULL FRACTURE, EXTRA-AXIAL HEMATOMA,
CONTUSION, AND AXONAL INJURY
Skull Fracture A blow to the skull that exceeds the elastic tolerance
of the bone causes a fracture. Intracranial lesions accompany roughly
two-thirds of skull fractures, and the presence of a fracture increases
many-fold the chances of an underlying subdural or epidural hematoma.
Consequently, fractures are primarily markers of the site and severity of
injury. If the underlying arachnoid membrane has been torn, fractures
also provide potential pathways for entry of bacteria to the cerebrospinal
fluid (CSF) with a risk of meningitis and for leakage of CSF outward
through the dura. If there is leakage of CSF, severe orthostatic headache
results from lowered pressure in the spinal fluid compartment.
Most fractures are linear and extend from the point of impact
toward the base of the skull. Basilar skull fractures are often extensions
of adjacent linear fractures over the convexity of the skull but may
occur independently owing to stresses on the floor of the middle cranial fossa or occiput. Basilar fractures are usually parallel to the petrous
bone or along the sphenoid bone and directed toward the sella turcica
and ethmoidal groove. Although most basilar fractures are uncomplicated, they can cause CSF leakage, pneumocephalus, and delayed
cavernous-carotid fistulas. Hemotympanum (blood behind the tympanic membrane), ecchymosis over the mastoid process (Battle sign),
and periorbital ecchymosis (“raccoon sign”) are clinical signs associated
with basilar fractures.
■ EPIDURAL AND SUBDURAL HEMATOMAS
Hemorrhages between the dura and skull (epidural) or beneath the
dura (subdural) have characteristic clinical and imaging features. They
are sometimes associated with underlying brain contusions and other
injuries, often making it difficult to determine the relative contribution
of each component to the clinical state. The mass effect of raised intracranial pressure (ICP) caused by these hematomas can be life threatening, making it imperative to identify them rapidly by CT or MRI scan
and to surgically remove them when appropriate.
Epidural Hematoma (Fig. 443-1) These highly dangerous lesions
usually arise from an injury to a meningeal arterial vessel and evolve
rapidly. They are often accompanied by a “lucid interval” of several
minutes to hours prior to neurologic deterioration. They occur in up
to 10% of cases of severe head injury, but are less often associated with
underlying cortical damage compared to subdural hematomas. Rapid
surgical evacuation and ligation or cautery of the damaged vessel,
usually the middle meningeal artery that has been lacerated by an
overlying skull fracture, is indicated. If recognized and treated rapidly,
patients often have a favorable outcome.
Acute Subdural Hematoma (Fig. 443-2) Direct cranial trauma
may be minor and is not always required for acute subdural hemorrhage
to occur, especially in the elderly and those taking anticoagulant medications. Acceleration forces alone, as from whiplash, are sometimes sufficient to produce subdural hematoma. Up to one-third of patients have
a lucid interval lasting minutes to hours before coma supervenes, but
most are drowsy or comatose from the moment of injury. A unilateral
headache and slightly enlarged pupil on the side of the hematoma are
frequently, but not invariably, present. Small subdural hematomas may
be asymptomatic and usually do not require surgical evacuation if they
do not enlarge. Stupor or coma, hemiparesis, and unilateral pupillary
enlargement are signs of larger hematomas. The bleeding that causes
larger subdural hematomas is primarily venous in origin, although
arterial bleeding sites are sometimes found at operation, and a few large
hematomas have a purely arterial origin. In an acutely deteriorating
patient, an emergency craniotomy is required. In contrast to epidural
hematomas, there is significant morbidity and mortality associated
with acute subdural hematomas that require surgery.
Chronic Subdural Hematoma A subacutely evolving syndrome
due to subdural hematoma occurs days or weeks after injury with
drowsiness, headache, confusion, or mild hemiparesis, usually in the
elderly with age-related atrophy and often after only minor or unnoticed
trauma. On imaging studies, chronic subdural hematomas appear as
crescentic clots over the convexity of one or both hemispheres, most
FIGURE 443-1 Acute epidural hematoma. The tightly attached dura is stripped from
the inner table of the skull, producing a characteristic lenticular-shaped hemorrhage
on noncontrast CT scan. Epidural hematomas are usually caused by tearing of the
middle meningeal artery following fracture of the temporal bone.
FIGURE 443-2 Acute subdural hematoma. Noncontrast CT scan reveals a
hyperdense clot that has an irregular border with the brain and causes more
horizontal displacement (mass effect) than might be expected from its thickness.
The disproportionate mass effect is the result of the large rostral-caudal extent of
these hematomas. Compare to Fig. 443-1.
3458 PART 13 Neurologic Disorders
commonly in the frontotemporal region (Fig. 443-3). A history of
trauma may or may not be elicited in relation to chronic subdural hematoma; the injury may have been trivial and forgotten, particularly in
the elderly and those with clotting disorders. Headache is common but
not invariable. Additional features that may appear weeks later include
slowed thinking, vague change in personality, seizure, or a mild hemiparesis. The headache typically fluctuates in severity, sometimes with
changes in head position. Drowsiness, inattentiveness, and incoherence
of thought are generally more prominent than focal signs such as hemiparesis. Rarely, chronic hematomas cause brief episodes of hemiparesis
or aphasia that are indistinguishable from transient ischemic attacks.
CT without contrast initially shows a low-density mass over the
convexity of the hemisphere. Between 2–6 weeks after the initial bleeding, the clot becomes isodense compared to adjacent brain and may be
inapparent. Many subdural hematomas that are several weeks in age
contain areas of blood and intermixed serous fluid. Infusion of contrast
material demonstrates enhancement of the vascular fibrous capsule
surrounding the collection. MRI reliably identifies both subacute and
chronic hematomas.
Clinical observation coupled with serial imaging is a reasonable
approach to patients with few symptoms and small chronic subdural
collections that do not cause mass effect. Treatment with surgical evacuation through burr holes is usually successful, if a cranial drain is used
postoperatively. The fibrous membranes that grow from the dura and
encapsulate the collection may require removal with a craniotomy to
prevent recurrent fluid accumulation.
■ TRAUMATIC SUBARACHNOID HEMORRHAGE
Subarachnoid hemorrhage (SAH) is common in TBI. Rupture of small
cortical arteries or veins can cause bleeding into the subarachnoid
space. Traumatic SAH is often seen in the sulci and is frequently the
only radiographic finding on CT following mild TBI. SAH occurs
diffusely after severe TBI and confers an increase in mortality. In mild
TBI, SAH provides an objective imaging biomarker for TBI, and in
some patients is associated with unfavorable outcomes.
Contusion (Fig. 443-4) A surface bruise of the brain, or contusion,
consists of varying degrees of petechial hemorrhage, edema, and tissue
destruction. Contusions and deeper hemorrhages result from mechanical forces that displace and compress the hemispheres forcefully and
by deceleration of the brain against the inner skull, either under a point
of impact (coup lesion) or, as the brain swings back, in the antipolar
area (contrecoup lesion). Trauma sufficient to cause prolonged unconsciousness usually produces some degree of contusion. Blunt deceleration impact, as occurs against an automobile dashboard or from falling
forward onto a hard surface, causes contusions on the orbital surfaces
of the frontal lobes and the anterior and basal portions of the temporal
lobes. With lateral forces, as from impact on an automobile door frame,
contusions are situated on the lateral convexity of the hemisphere. The
clinical signs of contusion are determined by the location and size of
the lesion; often, there are no focal abnormalities with a routine neurologic exam, but these injured regions are later the sites of gliotic scars
that may produce seizures. A hemiparesis or gaze preference is fairly
typical of moderately sized contusions. Large bilateral contusions produce stupor with extensor posturing, while those limited to the frontal
lobes cause a taciturn state. Contusions in the temporal lobe may cause
delirium or an aggressive, combative syndrome. Torsional or shearing
forces within the brain can cause hemorrhages of the basal ganglia and
other deep regions. Large contusions and hemorrhages after minor
trauma should raise concerns for coagulopathy due to an underlying
disease or more commonly anticoagulant therapy.
Acute contusions are easily visible on CT and MRI scans, appearing
as inhomogeneous hyperdensities on CT and as hyperintensities on T2
and fluid-attenuated inversion recovery (FLAIR) MRI sequences; there
is usually surrounding localized brain edema and some subarachnoid
bleeding. Blood in the CSF due to trauma may provoke a mild inflammatory reaction. Over a few days, contusions acquire a surrounding contrast
enhancement and edema that may be mistaken for tumor or abscess.
Axonal Injury (Fig. 443-5) Traumatic axonal injury (TAI) is
one of the most common injuries after TBI. There is disruption, or
shearing, of axons at the time of impact and this is associated with
FIGURE 443-3 CT scan of chronic bilateral subdural hematomas of different
ages. The collections began as acute hematomas and have become hypodense in
comparison to the adjacent brain after a period during which they were isodense
and difficult to appreciate. Some areas of resolving blood are contained on the more
recently formed collection on the left (arrows).
FIGURE 443-4 Traumatic cerebral contusion. Noncontrast CT scan demonstrating a
hyperdense hemorrhagic region in the anterior temporal lobe.
FIGURE 443-5 Multiple small areas of hemorrhage and tissue disruption in the
white matter of the frontal lobes on noncontrast CT scan. These appear to reflect
an extreme type of the diffuse axonal shearing lesions that occur with closed head
injury.
3459Concussion and Other Traumatic Brain Injuries CHAPTER 443
microhemorrhages. It occurs following high-speed deceleration injuries, such as motor vehicle collisions (Johnson et al, 2013). The presence of ≥4 areas of TAI is called diffuse axonal injury (DAI), and when
widespread, has been proposed to explain persistent coma and the vegetative state after TBI (Chap. 28). Only severe TAI lesions that contain
substantial blood are visualized by CT, usually in the corpus callosum
and centrum semiovale. More commonly, the CT will be negative for
TAI, but subsequent MRI, particularly gradient-echo or susceptibility
-weighted imaging, will show hemosiderin deposits reflective of microhemorrhages in addition to the axonal damage on diffusion sequences.
Traditionally, TAI and DAI have been considered as sequelae much
more likely to result from moderate and severe injuries. Accumulating
evidence has demonstrated that diffuse white matter abnormalities
purportedly reflective of axonal injury, such as changes in microstructure and neurite density, are quite common in mild TBI as well. The
degree of these changes correlates with metrics of injury severity (e.g.,
symptom burden) and recovery duration.
■ CRANIAL NERVE INJURIES
The cranial nerves most often injured with TBI are the olfactory, optic, oculomotor, and trochlear nerves; the first and second
branches of the trigeminal nerve; and the facial and auditory nerves.
Anosmia and an apparent loss of taste (actually a loss of perception
of aromatic flavors, with retained elementary taste perception) occur
in ~10% of persons with serious head injuries, particularly from falls
on the back of the head. This is the result of displacement of the brain
and shearing of the fine olfactory nerve filaments that course through
the cribriform bone. At least partial recovery of olfactory and gustatory function is expected, but if bilateral anosmia persists for several
months, the prognosis is poor. Partial optic nerve injuries from closed
trauma result in blurring of vision, central or paracentral scotomas,
or sector defects. Direct orbital injury may cause short-lived blurred
vision for close objects due to reversible iridoplegia. Diplopia limited
to downward gaze and corrected when the head is tilted away from
the side of the affected eye indicates trochlear (fourth nerve) nerve
damage. It occurs frequently as an isolated problem after minor head
injury or may develop for unknown reasons after a delay of several
days. Facial nerve injury caused by a basilar fracture is present immediately in up to 3% of severe injuries; it may also be delayed for
5–7 days. Fractures through the petrous bone, particularly the less
common transverse type, are liable to produce facial palsy. Delayed
facial palsy occurring up to a week after injury, the mechanism of
which is unknown, has a good prognosis. Injury to the eighth cranial
nerve from a fracture of the petrous bone causes loss of hearing, vertigo, and nystagmus immediately after injury. Deafness from eighth
nerve injury is rare and must be distinguished from blood in the middle ear or disruption of the middle ear ossicles. Dizziness, tinnitus,
and high-tone hearing loss occur from cochlear concussion.
■ SEIZURES
Convulsions are surprisingly uncommon immediately after TBI, but a
brief period of tonic extensor posturing or a few clonic movements of
the limbs just after the moment of impact can occur. However, the cortical scars that evolve from contusions are highly epileptogenic and may
later manifest as seizures, even after many months or years (Chap. 425).
The severity of injury roughly determines the risk of future seizures.
It has been estimated that 17% of individuals with brain contusion,
subdural hematoma, or prolonged LOC will develop a seizure disorder
and that this risk extends for an indefinite period of time, whereas the
risk is ≤2% after mild injury. The majority of convulsions in the latter
group occur within 5 years of injury but may be delayed for decades.
Penetrating injuries have a much higher rate of subsequent epilepsy.
CLINICAL SYNDROMES AND TREATMENT
OF HEAD INJURY
■ CONCUSSION/MILD TBI
The patient who has briefly lost consciousness or been stunned after
a minor head injury usually becomes fully alert and attentive within
minutes but may complain of headache, dizziness, faintness, nausea, a
single episode of emesis, difficulty with concentration, a brief amnestic
period, or slight blurring of vision. This typical concussion syndrome
has a good prognosis with little risk of subsequent deterioration.
Children are particularly prone to drowsiness, vomiting, and irritability, symptoms that are sometimes delayed for several hours after
apparently minor injuries. Vasovagal syncope that follows injury may
cause undue concern. Generalized or frontal headache is common in
the following days. It may be migrainous (throbbing and hemicranial)
in nature or aching and bilateral. After several hours of observation,
patients with minor injury may be accompanied home and observed
for a day by a family member or friend, with written instructions to
return if symptoms worsen.
Persistent severe headache and repeated vomiting in the context
of normal alertness and no focal neurologic signs is usually benign,
but CT should be obtained and a longer period of observation is
appropriate. The decision to perform imaging tests also depends on
clinical signs that indicate that the impact was severe (e.g., persistent
confusion, repeated vomiting, palpable skull fracture); the presence
of other serious bodily injuries, an underlying coagulopathy, or age
>65 years; and on the degree of surveillance that can be anticipated after discharge. Guidelines have also indicated that older age
(>65 years), two or more episodes of vomiting, >30 min of retrograde
or persistent anterograde amnesia, seizure, and concurrent drug or
alcohol intoxication are sensitive (but not specific) indicators of intracranial hemorrhage that justify CT scanning.
Though not incorporated into conventional clinical practice guidelines, growing evidence suggests that MRI improves sensitivity for
detection of small intracranial hemorrhages and other lesions in
mild TBI patients, particular among those with negative findings
on CT. Specifically, intracranial abnormalities are fairly common
on MRI (27%) in CT-negative patients. Further, acute MRI findings
have prognostic utility in predicting recovery and outcome after mTBI/
concussion (e.g., risk of functional impairment, time to return to activity).
Blood-based (serum and plasma) biomarkers of astrocyte damage/
astrogliosis (glial fibrillary acidic protein [GFAP]) and neuronal injury
(ubiquitin carboxy-terminal hydrolase L1 [UCHL1]) also hold promise
in improving detection and outcome prediction across the full spectrum of TBI. With development of new rapid assay systems, these can
now be used for real-time point-of-care assessment; GFAP in particular
has high discriminant ability to detect intracranial abnormalities, as
well as potential to differentiate CT+, CT–/MRI+, and CT–/MRI–
patients. Similar to MRI, emerging biomarkers appear to have not
only diagnostic but also prognostic utility in predicting the trajectory
of recovery and functional impairments weeks and months after TBI.
■ SPORT-RELATED CONCUSSION
Based on its reported prevalence, acute effects, and fears over potential long-term neurologic consequences, sport-related concussion has
become the focus of increasing concern from clinicians, researchers,
sporting organizations, and athletes themselves. Concussion is a frequent injury in contact and collision sports (e.g., football, hockey, wrestling) at all levels of participation, including youth sports. Head injury
associated with sport and recreational activity accounts for 45% of
TBI-related emergency department visits in children age 17 years and
under. Between 1997 to 2007, emergency department visits for 8- to
13-year-old children affected by concussion in organized team sports
doubled, and increased by >200% in the 14- to 19-year-old group.
Over the last decade, data from the Centers for Disease Control and
Prevention indicate that this trend has reversed, with a 27% decrease
in emergency department visits for sport- and recreation-related TBI
in the United States between 2012 and 2018. Given that national and
state surveillance systems continue to report increased sport-related
concussion rates over the same time period, it could be inferred that
diagnosis and management of sport-related concussion outside of the
emergency department has increased.
The natural history of clinical recovery following sport-related concussion has been a subject of substantial ongoing research. In general,
the findings on acute recovery are favorable. A 2003 report was the first
to chart the continuous time course of acute recovery within several
3460 PART 13 Neurologic Disorders
days after concussion, indicating that >90% of athletes reported symptom recovery within 1 week. Several other prospective studies have
since demonstrated that the overwhelming majority of athletes achieve
a complete recovery in symptoms, cognitive functioning, postural
stability, and other functional impairments over a period of 1–3 weeks
following concussion.
In recent years, a paradigm shift toward a more rapid return to
activity and a focus on rehabilitation has occurred. Specifically, while
experts agree that initial rest post-injury is beneficial for recovery,
extended inactivity beyond 5 days can be detrimental and increase risk
for protracted recovery. Rather, active rehabilitation involving supervised subthreshold exercise has been shown to improve duration of
symptoms and decrease risk of protracted recovery.
There are many anecdotal reports, however, of athletes who remain
symptomatic or impaired on functional testing well beyond the window of recovery commonly reported in group studies. The greatest
challenge arguably still facing sport medicine clinicians and public
health experts is how to most effectively manage and reduce risk in this
subset of athletes who do not follow the “typical” course of recovery.
The precise frequency of athletes who do not follow the typical course
of rapid, spontaneous recovery and instead exhibit prolonged postconcussive symptoms or other functional impairments after concussion
remains unclear. Postinjury symptom burden is the most robust predictor of recovery and risk of prolonged symptoms. Preinjury mental
health diagnosis and history of prior concussion are two factors that
have been consistently identified as being associated with potential for
prolonged recovery as well.
Following acute concussion, multimodal advanced neuroimaging
has demonstrated a variety of changes, including decreased cerebral
blood flow, increased global and local functional connectivity, and
alterations in white matter microstructure reflecting axonal organization. In general, these metrics correlate with measures of injury
severity, and resolution of these changes tends to parallel clinical
recovery. However, a number of studies have shown that slight changes
on advanced multimodal imaging can persist even after symptoms
have fully resolved, supporting the concept that the “tail” of neurobiologic recovery may extend beyond the time course of apparent clinical
recovery.
In the current absence of adequate data, a commonsense approach
to athletic concussion has been to remove the individual from play
immediately and avoid contact sports for at least several days after a
mild injury, and for a longer period if there are more severe injuries
or if there are protracted neurologic symptoms such as headache and
difficulty concentrating. No individual should return to play unless
all concussion-related symptoms have resolved and an assessment
has been made by a health care professional who has experience with
treatment of concussion. Validated symptom inventories, such as the
Rivermead Post-Concussion Symptom Questionnaire (Table 443-2),
have been developed to aid clinicians with recording and quantifying
the diverse range of physical, cognitive, and behavioral symptoms
that can occur following concussion. In addition to characterizing the
constellation of acute symptoms and their severity, symptom inventories can be beneficial to track the course and resolution of symptoms
through recovery. Differentiating concussion-related symptoms from
factors that may be also influencing endorsement (e.g., preinjury mood
difficulties) is an important component of managing recovery from
sport-related concussion. Once cleared, the individual can then begin a
graduated program of increasing activity. Younger athletes are particularly likely to experience protracted concussive symptoms, and a slower
return to play in this age group may be reasonable. These guidelines
are designed in part to avoid a perpetuation of symptoms but also to
prevent the rare second-impact syndrome, in which diffuse and fatal
cerebral swelling follows a second minor head injury.
■ POSTCONCUSSIVE STATES
The postconcussion syndrome (PCS) refers to a state following mild
TBI consisting of combinations of fatigue, dizziness, headache, and
difficulty in concentration. Management is difficult and generally
requires the identification and management of the specific problem or
problems that are most troubling to the individual. A clear explanation
and education around the symptoms that may follow concussion has
been shown to reduce subsequent complaints. Care is taken to avoid
prolonged use of drugs that produce dependence. Headache may initially be treated with acetaminophen and small doses of amitriptyline.
Vestibular exercises (Chap. 22) and small doses of vestibular suppressants such as promethazine (Phenergan) may be helpful when dizziness
is the main problem. Patients, who after mild or moderate injury have
difficulty with memory or with complex cognitive tasks at work, may
be reassured to know that these problems usually improve over several
months, and a reduced workload or other accommodations may be
prescribed in the interim.
For the vast majority of individuals with mTBI, the symptoms of
PCS subside and resolve within a few weeks of injury. For a subset of
individuals with mTBI, however, complaints of postconcussion symptoms persist beyond the expectation derived from TBI severity markers. The term postconcussion disorders (PCDs) has been proposed for
diagnostic use and to improve characterization of specific symptoms
or types of sequelae following mTBI. These include neurologic, cognitive, behavioral, or somatic complaints that continue beyond the acute
and subacute periods, becoming chronic and often operationalized as
persisting beyond 3 months. Although the overall risk of developing
PCD following mTBI is low, the frequency of mTBI patients who
meet criteria for a diagnosis of PCD and present in a clinical setting is
believed to be higher.
mTBI patients with PCD frequently present to the outpatient clinics of primary care physicians, physiatrists, or neurologists seeking
relief for lingering PCD-related symptoms. While some patients will
have already received an initial medical workup to rule out a more
serious brain injury during the acute phase, many patients will have
had no prior contact with health care specialists. A medical workup
ordered in the outpatient setting for PCD-related complaints is typically unremarkable for any identifiable neurologic cause to account
for the persisting symptoms reported by the patient. The development
of uniform decision trees or “standard of care” treatment regimens for
PCD-related symptoms has been limited by the diversity of symptoms
that patients experience, even within mTBI subgroups that have sustained very similar injury patterns. While some patients experience
somatic symptoms, others complain of subjective cognitive or behavioral changes. Symptom inventories (Table 443-2) can be helpful in
documenting the broad range of these symptoms and serve as a metric
for improvement following symptom-based treatment.
Active rehabilitation for the treatment of PCD involving subthreshold exercise has increased in popularity over recent years and has
gained empirical support for its effectiveness as a useful intervention
for protracted recovery.
PCD is not a unidimensional condition but rather an outcome
influenced by diverse cognitive, emotional, medical, psychosocial, and
motivational factors. Because of this complexity, treatments targeting
TABLE 443-2 Review of Concussion Symptoms
PHYSICAL COGNITIVE BEHAVIORAL
Headaches Forgetfulness or poor
memory
Being irritable, easily
angered
Dizziness Poor concentration Feeling depressed or
tearful
Nausea and/or vomiting Taking longer to think Feeling frustrated or
impatient
Noise sensitivity Restlessness
Sleep disturbance
Fatigue
Blurred vision
Light sensitivity
Double vision
Note: Items were adapted from the Rivermead Post-Concussion Symptom
Questionnaire. Each item is rated on a 5-point Likert scale (0–4), as follows: 0 = Not
experienced at all; 1 = No more of a problem now than preinjury; 2 = A mild problem;
3 = A moderate problem; 4 = A severe problem. Total scores can range from 0–64.
3461Concussion and Other Traumatic Brain Injuries CHAPTER 443
persistent and refractory PCD-related symptoms should be tailored to
the needs and expectations of the individual patient, with referrals to
specialists as needed for assistance with management of headache, neck
and back pain, dizziness and vertigo, and other symptoms reported
within the context of PCD. A comprehensive review of concussion- and
PCD-related symptoms presented in Table 443-2 allows for development of an individualized approach that leverages currently available
treatment for those sequelae that are most bothersome to the patient
(e.g., vestibular rehabilitation therapy for vertigo, melatonin for sleep
disturbance). Patients are frequently referred to behavioral health providers such as neuropsychologists, rehabilitation psychologists, health
psychologists, and/or psychiatrists for a variety of reasons, but particularly when they are experiencing cognitive, emotional, or behavioral
changes that accompany PCD. Patients with mood disorders (e.g.,
depression), anxiety disorders (e.g., posttraumatic stress disorder), or
adjustment reactions may benefit from psychiatric consultation for
appropriate medication trials or from time-limited psychotherapy such
as cognitive behavioral therapy.
Due to the complexity of presentation and varying diagnostic criteria, there are limited studies regarding overall prognosis of PCD. However, treatment of PCD-related symptoms targeted to the individual’s
specific difficulties can improve functional outcomes and patient-rated
quality of life. Further, collaborative care has been shown to improve
outcomes among patients experiencing persistent postconcussion
symptoms. These improved outcomes are likely due to a multidisciplinary team’s ability to simultaneously address the diverse set of symptoms
that can occur with PCD.
■ INJURY OF INTERMEDIATE SEVERITY
Patients who are not fully alert or have persistent confusion, behavioral changes, extreme dizziness, or focal neurologic signs such as
hemiparesis should be admitted to the hospital and undergo a cerebral
imaging study. A cerebral contusion or hematoma will usually be
found. Common syndromes include: (1) delirium with a disinclination
to be examined or moved, expletive speech, and resistance if disturbed
(anterior temporal lobe contusions); (2) a quiet, disinterested, slowed
mental state (abulia) alternating with irascibility (inferior frontal
and frontopolar contusions); (3) a focal deficit such as aphasia or mild
hemiparesis (due to subdural hematoma or convexity contusion or,
less often, carotid artery dissection); (4) confusion and inattention,
poor performance on simple mental tasks, and fluctuating orientation
(associated with several types of injuries, including those described
above, and with medial frontal contusions and interhemispheric
subdural hematoma); (5) repetitive vomiting, nystagmus, drowsiness,
and unsteadiness (labyrinthine concussion, but occasionally due to a
posterior fossa subdural hematoma or vertebral artery dissection); and
(6) diabetes insipidus (damage to the median eminence or pituitary
stalk). Injuries of this degree can be complicated by drug or alcohol
intoxication, and clinically inapparent cervical spine injury may be
present. Blast injuries are often accompanied by rupture of the tympanic membranes.
After surgical removal of hematomas, patients in this category
improve over weeks to months. During the first week, the state of
alertness, memory, and other cognitive functions often fluctuate, and
agitation and somnolence are common. Behavioral changes tend to
be worse at night, as with many other encephalopathies, and may be
treated with small doses of antipsychotic medications. Subtle abnormalities of attention, intellect, spontaneity, and memory return toward
normal weeks or months after the injury, sometimes abruptly. However, the full extent of recovery may not be realized for several years.
Persistent cognitive problems are discussed below.
■ SEVERE INJURY
Patients who are comatose from the moment of injury require immediate neurologic attention and resuscitation. After intubation, with
care taken to immobilize the cervical spine, the depth of coma, pupillary size and reactivity, limb movements, and Babinski responses are
assessed. As soon as vital functions permit and cervical spine x-rays
and a CT scan have been obtained, the patient should be transported
to a critical care unit. Hypoxia should be reversed, and normal saline
used as the resuscitation fluid in preference to albumin. The finding of
an epidural or subdural hematoma or large intracerebral hemorrhage
is usually an indication for prompt surgery and intracranial decompression in an otherwise salvageable patient. Measurement of ICP
with a ventricular catheter or fiberoptic device in order to guide treatment has been favored by many units but has not improved outcome.
Similarly, induced hypothermia has shown no benefit. Hyperosmolar
intravenous solutions are used in various regimens to limit intracranial
pressure. Prophylactic antiepileptic medications are recommended for
7 days and should be discontinued unless there are multiple seizures
postinjury. Management of raised ICP, a frequent feature of severe head
injury, is discussed in Chap. 307.
Despite the improvement in mortality for severe TBI over the past
few decades, a great deal of therapeutic nihilism persists in TBI. The
common use of a 6-month outcome for TBI clinical studies reinforces
this misconception. The recovery from severe TBI can take years. Furthermore, the ability to predict long-term outcome is limited and frequently incorrect. Best-practice guidelines recommend, in the absence
of brain death, that aggressive therapy be instituted for at least 72 h in
the acute injury period.
■ LONG-TERM OUTCOMES IN TBI
TBI (aggregated mild to severe) is associated with a 63–96% increased
risk of all-cause dementia. The degree of risk for dementia ranges along
the gradient of TBI severity (i.e., greatest risk among severe injuries).
To date, investigations have less reliably established mTBI as a robust
risk factor for dementia, likely due to methodologic heterogeneity
(e.g., use of different diagnostic criteria, exposure misclassification,
self-report vs. physician diagnoses of TBI or dementia). Though an
identified risk factor for all-cause dementia, pathophysiologic and
epidemiologic factors that underlie the association between TBI with
risk of specific neurodegenerative pathologies and dementia-subtypes
are not well understood. As a result, associations between TBI with
clinical syndromes (e.g., Alzheimer’s disease, Parkinson’s disease,
amyotrophic lateral sclerosis) or distinct neuropathologies (e.g., betaamyloid, Lewy bodies, transactive response DNA-binding protein 43)
have been inconsistently reported in the literature. In a large study
involving clinical and neuropathologic data from three pooled prospective studies of community-based cohorts, a significant relationship
was found between TBI with LOC >1 h and subsequent Parkinson’s
disease diagnosis, progression rate of parkinsonism, and Lewy body
accumulation at postmortem examination.
There is some evidence that repeated mTBI or sport-related concussions, particularly among boxing and professional American football
athletes, are associated with delayed and potentially progressive neurobehavioral changes. The brains of these patients display a characteristic
deposition of tau protein in neurons located in the superficial cortical
layers and perivascular regions, and particularly in the depths of sulci.
This pattern has been defined as the pathognomonic lesion of chronic
traumatic encephalopathy (CTE). A variety of neurodegenerative
pathologies are commonly found in the presence of CTE, adding to the
complexity of diagnosis. While staging criteria for this neuropathologic
entity have yet to be established, a consensus meeting to define the neuropathologic criteria for CTE proposed an algorithm assessing CTE as
“low” or “high” in severity. Overall, its contribution, if any, to late-life
dementia and parkinsonism in former athletes, soldiers, or others who
have sustained repeated concussive injuries is unknown.
Research criteria for the clinical diagnosis of CTE have been proposed, and include a range of cognitive and/or behavioral symptoms,
including executive dysfunction, depression, insomnia, and behavioral
dyscontrol. Multiple studies have suggested that these proposed criteria
lack specificity (i.e., they are frequent in other conditions and non-CTE
cases). As such, CTE remains a postmortem diagnosis. Advances in
positron emission tomography (PET) have allowed for in vivo investigation of tau deposition. Significant correlations between greater years
of football participation and greater standardized uptake value ratio
(SUVR) of 18F-flortaucipir (purportedly representative of tau deposition) in the bilateral superior frontal, bilateral medial temporal, and left
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