3498 PART 13 Neurologic Disorders
wrist is flexed for 30–60 s (Phalen sign); and weakness of thumb opposition and abduction. EDx is extremely sensitive and shows slowing
of sensory and, to a lesser extent, motor median potentials across the
wrist. Ultrasound can show focal swelling of the median nerve at the
wrist. Treatment options consist of avoidance of precipitating activities; control of underlying systemic-associated conditions if present;
nonsteroidal anti-inflammatory medications; neutral (volar) position
wrist splints, especially for night use; glucocorticoid/anesthetic injection into the carpal tunnel; and surgical decompression by dividing the
transverse carpal ligament. The surgical option should be considered
if there is a poor response to nonsurgical treatments; if there is thenar
muscle atrophy and/or weakness; and if there are significant denervation potentials on EMG.
Other proximal median neuropathies are very uncommon and
include the pronator teres syndrome and anterior interosseous neuropathy. These often occur as a partial form of brachial plexitis.
■ ULNAR NEUROPATHY AT THE ELBOW— “CUBITAL
TUNNEL SYNDROME”
The ulnar nerve passes through the condylar groove between the medial
epicondyle and the olecranon. Symptoms consist of paresthesias, tingling, and numbness in the medial hand and half of the fourth and the
entire fifth fingers, pain at the elbow or forearm, and weakness. Signs
consist of decreased sensation in an ulnar distribution, Tinel’s sign at
the elbow, and weakness and atrophy of ulnar-innervated hand muscles.
The Froment sign indicates thumb adductor weakness and consists of
flexion of the thumb at the interphalangeal joint when attempting to
oppose the thumb against the lateral border of the second digit. EDx
may show slowing of ulnar motor NCV across the elbow with prolonged
ulnar sensory latencies. Ultrasound can show swelling of the ulnar nerve
around the elbow as well. Treatment consists of avoiding aggravating
factors, using elbow pads, and surgery to decompress the nerve in the
cubital tunnel. Ulnar neuropathies can also rarely occur at the wrist in
the ulnar (Guyon) canal or in the hand, usually after trauma.
■ RADIAL NEUROPATHY
The radial nerve winds around the proximal humerus in the spiral
groove and proceeds down the lateral arm and enters the forearm,
dividing into the posterior interosseous nerve and superficial nerve.
The symptoms and signs consist of wrist drop; finger extension
weakness; thumb abduction weakness; and sensory loss in the dorsal
web between the thumb and index finger. Triceps and brachioradialis
strength is often normal, and triceps reflex is often intact. Most cases
of radial neuropathy are transient compressive (neuropraxic) injuries
that recover spontaneously in 6–8 weeks. If there has been prolonged
compression and severe axonal damage, it may take several months
to recover. Treatment consists of cock-up wrist and finger splints,
avoiding further compression, and physical therapy to avoid flexion
contracture. If there is no improvement in 2–3 weeks, an EDx study
is recommended to confirm the clinical diagnosis and determine the
degree of severity.
■ LATERAL FEMORAL CUTANEOUS NEUROPATHY
(MERALGIA PARESTHETICA)
The lateral femoral cutaneous nerve arises from the upper lumbar
plexus (spinal levels L2/3), crosses through the inguinal ligament near
its attachment to the iliac bone, and supplies sensation to the anterior
lateral thigh. The neuropathy affecting this nerve is also known as
meralgia paresthetica. Symptoms and signs consist of paresthesias,
numbness, and occasionally pain in the lateral thigh. Symptoms are
increased by standing or walking and are relieved by sitting. There is
normal strength, and knee reflexes are intact. The diagnosis is clinical,
and further tests usually are not performed. EDx is only needed to
rule out lumbar plexopathy, radiculopathy, or femoral neuropathy. If
the symptoms and signs are classic, EMG is not necessary. Symptoms
often resolve spontaneously over weeks or months, but the patient may
be left with permanent numbness. Treatment consists of weight loss
and avoiding tight belts. Analgesics in the form of a lidocaine patch,
nonsteroidal agents, and occasionally medications for neuropathic pain
can be used (Table 446-6). Rarely, locally injecting the nerve with an
anesthetic can be tried. There is no role for surgery.
■ FEMORAL NEUROPATHY
Femoral neuropathies can arise as complications of retroperitoneal
hematoma, lithotomy positioning, hip arthroplasty or dislocation, iliac
artery occlusion, femoral arterial procedures, infiltration by hematogenous malignancy, penetrating groin trauma, pelvic surgery including
hysterectomy and renal transplantation, and diabetes (a partial form of
lumbosacral diabetic plexopathy); some cases are idiopathic. Patients
with femoral neuropathy have difficulty extending their knee and
flexing the hip. Sensory symptoms occurring either on the anterior
thigh and/or medial leg occur in only half of reported cases. A prominent painful component is the exception rather than the rule, may be
delayed, and is often self-limited in nature. The quadriceps (patellar)
reflex is diminished.
■ SCIATIC NEUROPATHY
Sciatic neuropathies commonly complicate hip arthroplasty, pelvic
procedures in which patients are placed in a prolonged lithotomy position, trauma, hematomas, tumor infiltration, and vasculitis. In addition, many sciatic neuropathies are idiopathic. Weakness may involve
all motions of the ankles and toes as well as flexion of the leg at the
knee; abduction and extension of the thigh at the hip are spared. Sensory loss occurs in the entire foot and the distal lateral leg. The ankle
jerk and, on occasion, the internal hamstring reflex are diminished or
more typically absent on the affected side. The peroneal subdivision
of the sciatic nerve is typically involved disproportionately to the tibial counterpart. Thus, patients may have only ankle dorsiflexion and
eversion weakness with sparing of knee flexion, ankle inversion, and
plantar flexion; these features can lead to misdiagnosis of a common
peroneal neuropathy.
PERONEAL NEUROPATHY
The sciatic nerve divides at the distal femur into the tibial and peroneal nerve. The common peroneal nerve passes posterior and laterally
around the fibular head, under the fibular tunnel. It then divides into
the superficial peroneal nerve, which supplies the ankle evertor muscles and sensation over the anterolateral distal leg and dorsum of the
foot, and the deep peroneal nerve, which supplies ankle dorsiflexors
and toe extensor muscles and a small area of sensation dorsally in the
area of the first and second toes.
Symptoms and signs consist of foot drop (ankle dorsiflexion, toe
extension, and ankle eversion weakness) and variable sensory loss,
which may involve the superficial and deep peroneal pattern. There
is usually no pain. Onset may be on awakening in the morning. Peroneal neuropathy needs to be distinguished from L5 radiculopathy. In
L5 radiculopathy, ankle invertors and evertors are weak and needle
EMG reveals denervation. EDx can help localize the lesion. Peroneal
motor conduction velocity shows slowing and amplitude drop across
the fibular head. Management consists of rapid weight loss and avoiding leg crossing. Foot drop is treated with an ankle brace. A knee pad
can be worn over the lateral knee to avoid further compression. Most
cases spontaneously resolve over weeks or months.
RADICULOPATHIES
Radiculopathies are most often due to compression from degenerative
joint disease and herniated disks, but there are a number of unusual etiologies (Table 446-9). Degenerative spine disease affects a number of
different structures, which narrow the diameter of the neural foramen
or canal of the spinal column and compromise nerve root integrity;
these are discussed in detail in Chap. 17.
PLEXOPATHIES (PATTERN 4; TABLE 446-2)
■ BRACHIAL PLEXUS
The brachial plexus is composed of three trunks (upper, middle,
and lower), with two divisions (anterior and posterior) per trunk
(Fig. 446-2). Subsequently, the trunks divide into three cords (medial,
lateral, and posterior), and from these, arise the multiple terminal
3499Peripheral Neuropathy CHAPTER 446
TABLE 446-9 Causes of Radiculopathy
• Herniated nucleus pulposus
• Degenerative joint disease
• Rheumatoid arthritis
• Trauma
• Vertebral body compression fracture
• Pott’s disease
• Compression by extradural mass (e.g., meningioma, metastatic tumor,
hematoma, abscess)
• Primary nerve tumor (e.g., neurofibroma, schwannoma, neurinoma)
• Carcinomatous meningitis
• Perineurial spread of tumor (e.g., prostate cancer)
• Acute inflammatory demyelinating polyradiculopathy
• Chronic inflammatory demyelinating polyradiculopathy
• Sarcoidosis
• Amyloidoma
• Diabetic radiculopathy
• Infection (Lyme disease, herpes zoster, HIV, cytomegalovirus, syphilis,
schistosomiasis, Strongyloides)
• Arachnoiditis (e.g., postsurgical)
• Radiation
nerves innervating the arm. The anterior primary rami of C5 and C6
fuse to form the upper trunk; the anterior primary ramus of C7 continues as the middle trunk, while the anterior rami of C8 and T1 join to
form the lower trunk. There are several disorders commonly associated
with brachial plexopathy.
Immune-Mediated Brachial Plexus Neuropathy Immunemediated brachial plexus neuropathy (IBPN) goes by various
terms, including acute brachial plexitis, neuralgic amyotrophy, and
Parsonage-Turner syndrome. IBPN usually presents with an acute onset
of severe pain in the shoulder region. The intense pain usually lasts
several days to a few weeks, but a dull ache can persist. Individuals
who are affected may not appreciate weakness of the arm early in the
course because the pain limits movement. However, as the pain dissipates, weakness and often sensory loss are appreciated. Attacks can
occasionally recur.
Clinical findings are dependent on the distribution of involvement
(e.g., specific trunk, divisions, cords, or terminal nerves). The most
common pattern of IBPN involves the upper trunk or a single or
multiple mononeuropathies primarily involving the suprascapular,
long thoracic, or axillary nerves. Additionally, the phrenic and anterior interosseous nerves may be concomitantly affected. Any of these
nerves may also be affected in isolation. EDx is useful to confirm and
localize the site(s) of involvement. Empirical treatment of severe pain
with glucocorticoids is often used in the acute period.
Brachial Plexopathies Associated with Neoplasms Neoplasms involving the brachial plexus may be primary nerve tumors,
local cancers expanding into the plexus (e.g., Pancoast lung tumor or
lymphoma), and metastatic tumors. Primary brachial plexus tumors
are less common than the secondary tumors and include schwannomas, neurinomas, and neurofibromas. Secondary tumors affecting the
brachial plexus are more common and are always malignant. These
may arise from local tumors, expanding into the plexus. For example, a
Pancoast tumor of the upper lobe of the lung may invade or compress
the lower trunk, whereas a primary lymphoma arising from the cervical or axillary lymph nodes may also infiltrate the plexus. Pancoast
tumors typically present as an insidious onset of pain in the upper arm,
sensory disturbance in the medial aspect of the forearm and hand, and
weakness and atrophy of the intrinsic hand muscles along with an ipsilateral Horner’s syndrome. Chest computed tomography (CT) scans or
magnetic resonance imaging (MRI) can demonstrate extension of the
tumor into the plexus. Metastatic involvement of the brachial plexus
may occur with spread of breast cancer into the axillary lymph nodes
and local spread into the nearby nerves.
Perioperative Plexopathies (Median Sternotomy) The most
common surgical procedures associated with brachial plexopathy as a
complication are those that involve median sternotomies (e.g., openheart surgeries and thoracotomies). Brachial plexopathies occur in as
many as 5% of patients following a median sternotomy and typically
affect the lower trunk. Thus, individuals manifest with sensory disturbance affecting the medial aspect of forearm and hand along with
weakness of the intrinsic hand muscles. The mechanism is related to
the stretch of the lower trunk, so most individuals who are affected
recover within a few months.
Lumbosacral Plexus The lumbar plexus arises from the ventral primary rami of the first to the fourth lumbar spinal nerves
(Fig. 446-3). These nerves pass downward and laterally from the
vertebral column within the psoas major muscle. The femoral nerve
derives from the dorsal branches of the second to the fourth lumbar
ventral rami. The obturator nerve arises from the ventral branches
Dorsal scapular
Long thoracic
Medial
anterior
thoracic
Anterior Posterior
PERIPHERAL NERVES CORDS DIVISIONS TRUNKS ROOTS
Upper
subscapular
Axillary
Musculocutaneous
Radial
Median
Ulnar
Medial
antibrachial
cutaneous
Medial
brachial
cutaneous
M
P
L
Lateral
anterior
thoracic
Thoracodorsal
Lower
subscapular
Suprascapular
Subclavius
C5
C6
C7
C8
T1
FIGURE 446-2 Brachial plexus anatomy. L, lateral; M, medial; P, posterior. (Reproduced with permission J Goodgold: Anatomical Correlates of Clinical Electromyography.
Baltimore, Williams and Wilkins, 1974.)
3500 PART 13 Neurologic Disorders
of the same lumbar rami. The lumbar plexus communicates with the
sacral plexus by the lumbosacral trunk, which contains some fibers
from the fourth and all of the fibers from the fifth lumbar ventral
rami (Fig. 446-4).
The sacral plexus is the part of the lumbosacral plexus that is
formed by the union of the lumbosacral trunk with the ventral rami
of the first to fourth sacral nerves. The plexus lies on the posterior and
posterolateral wall of the pelvis with its components converging toward
the sciatic notch. The lateral trunk of the sciatic nerve (which forms the
common peroneal nerve) arises from the union of the dorsal branches
of the lumbosacral trunk (L4, L5) and the dorsal branches of the S1
and S2 spinal nerve ventral rami. The medial trunk of the sciatic nerve
(which forms the tibial nerve) derives from the ventral branches of the
same ventral rami (L4-S2).
■ LUMBOSACRAL PLEXOPATHIES
Plexopathies are typically recognized when motor, sensory, and if
applicable, reflex deficits occur in multiple nerve and segmental
distributions confined to one extremity. If localization within the
lumbosacral plexus can be accomplished, designation as a lumbar
plexopathy, a sacral plexopathy, a lumbosacral trunk lesion, or a panplexopathy is the best localization that can be expected. Although
lumbar plexopathies may be bilateral, usually occurring in a stepwise
and chronologically dissociated manner, sacral plexopathies are more
likely to behave in this manner due to their closer anatomic proximity. The differential diagnosis of plexopathy includes disorders of
the conus medullaris and cauda equina (polyradiculopathy). If there
is a paucity of pain and sensory involvement, motor neuron disease
should be considered as well.
The causes of lumbosacral plexopathies are listed in Table 446-
10. Diabetic radiculopathy (discussed above) is a fairly common
cause of painful leg weakness. Lumbosacral plexopathies are a wellrecognized complication of retroperitoneal hemorrhage. Various
primary and metastatic malignancies can affect the lumbosacral
plexus as well; these include carcinoma of the cervix, endometrium,
and ovary; osteosarcoma; testicular cancer; MM; lymphoma; acute
myelogenous leukemia; colon cancer; squamous cell carcinoma of the
rectum; adenocarcinoma of unknown origin; and intraneural spread
of prostate cancer.
■ RECURRENT NEOPLASTIC DISEASE OR
RADIATION-INDUCED PLEXOPATHY
The treatment for various malignancies is often radiation therapy, the
field of which may include parts of the brachial plexus. It can be difficult in such situations to determine if a new brachial or lumbosacral
plexopathy is related to tumor within the plexus or from radiationinduced nerve damage. Radiation can be associated with microvascular
abnormalities and fibrosis of surrounding tissues, which can damage
the axons and the Schwann cells. Radiation-induced plexopathy can
develop months or years following therapy and is dose dependent.
TERMINAL AND
COLLATERAL BRANCHES
BRANCHES FROM
POSTERIOR DIVISIONS
(From anterior
primary divisions)
(Posterior [black]
and anterior)
L4
L5
S1
S2
S3
(To pudendal plexus)
Sciatic
nerve
Common peroneal
nerve
(To hamstring muscles)
Tibial nerve
Inferior medial clunial nerve (S2, 3)
BRANCHES FROM ANTERIOR DIVISIONS
L5, S1, 2 To obturator internus and
gemellus superior muscles
Posterior femoral
cutaneous nerve
(S1, 2, 3)
(To lumbar plexus)
(Lumbosacral
trunk)
BRANCH FROM BOTH
ANTERIOR AND
POSTERIOR DIVISIONS
Inferior gluteal
nerve (L5, S1, 2)
Nerves to piriformis (S1, 2)
Superior gluteal nerve (L4, 5, S1)
To quadratus femons and
gemellus inferior muscles L4, 5, S1
DIVISIONS
PLEXUS ROOTS
FIGURE 446-4 Lumbosacral trunk sacral plexus and sciatic nerve. (From AA Amato,
JA Russell (eds): Neuromuscular Disorders, 2nd ed. McGraw-Hill Education, 2016,
Figure 24-4, p. 542, with permission.)
TABLE 446-10 Lumbosacral Plexopathies: Etiologies
• Retroperitoneal hematoma
• Psoas abscess
• Malignant neoplasm
• Benign neoplasm
• Radiation
• Amyloid
• Diabetic radiculoplexus neuropathy
• Idiopathic radiculoplexus neuropathy
• Sarcoidosis
• Aortic occlusion/surgery
• Lithotomy positioning
• Hip arthroplasty
• Pelvic fracture
• Obstetric injury
Genitofemoral nerve
L1
L2
L3
L4
L5
S1
S2
S3
S4
IIiohypogastric nerve
IIioinguinal nerve
Lateral cutaneous nerve of thigh
To lliacus and psoas muscles
Obturator nerve
Femoral nerve
Lumbo-sacral trunk
Gluteal nerves
Pudendal nerve
Sciatic nerve
Post. cutaneous nerve of thigh
FIGURE 446-3 Lumbosacral plexus. (From AA Amato, JA Russell (eds):
Neuromuscular Disorders, 2nd ed. McGraw-Hill Education, 2016, Figure 24-3, p. 542,
with permission.)
3501 Guillain-Barré Syndrome and Other Immune-Mediated Neuropathies CHAPTER 447
Tumor invasion is usually painful and more commonly affects the
lower trunk, whereas radiation injury is often painless and affects the
upper trunk. Imaging studies such as MRI and CT scans are useful but
can be misleading, especially when there is small microscopic invasion of the plexus. EMG can be informative if myokymic discharges
are appreciated, as this finding strongly suggests radiation-induced
damage.
■ EVALUATION AND TREATMENT OF
PLEXOPATHIES
Most patients with plexopathies will undergo both imaging with MRI
and EDx evaluations. Severe pain from acute idiopathic lumbosacral
plexopathy may respond to a short course of glucocorticoids.
■ FURTHER READING
Adams D et al: Patisiran, an RNAi therapeutic, for hereditary transthyretin amyloidosis. N Engl J Med 379:11, 2018.
Amato AA, Ropper AH: Sensory ganglionopathy. N Engl J Med
383:1657, 2020.
Amato AA, Russell J: Neuromuscular Disorders, 2nd ed. New York,
McGraw-Hill, 2016.
Barohn RJ, Amato AA: Pattern-recognition approach to neuropathy
and neuronopathy. Neurol Clin 31:343, 2013.
Barohn RJ et al: Patient Assisted Intervention for Neuropathy: Comparison of Treatment in Real Life Situations (PAIN-CONTRoLS)
Bayesian adaptive comparative effectiveness randomized trial. JAMA
Neurol 78:68, 2021.
Benson M et al: Inotersen treatment for patients with hereditary transthyretin amyloidosis. N Engl J Med 379:22, 2018.
Carroll AS et al: Inherited neuropathies. Semin Neurol 39:620, 2019.
England JD et al: Evaluation of distal symmetric polyneuropathy:
The role of autonomic testing, nerve biopsy, and skin biopsy
(an evidence-based review). Muscle Nerve 39:106, 2009.
England JD et al: Evaluation of distal symmetric polyneuropathy: The
role of laboratory and genetic testing (an evidence-based review).
Muscle Nerve 39:116, 2009.
Feldman EL et al: Diabetic neuropathy. Nat Rev Dis Primers 5:41,
2019.
Hobson-Webb LD, Juel VC: Common entrapment neuropathies.
Continuum (Minneap Minn) 23:487, 2017.
Jin PH, Shin SC: Neuropathy of connective tissue diseases and other
systemic diseases. Semin Neurol 39:651, 2019.
Waldfogel JM et al: Pharmacotherapy for diabetic peripheral neuropathy pain and quality of life: A systematic review. Neurology
87:978, 2016.
GUILLAIN-BARRÉ SYNDROME
Guillain-Barré syndrome (GBS) is an acute, frequently severe, and
fulminant polyradiculoneuropathy that is autoimmune in nature. It
occurs year-round at a rate of between 10 to 20 cases per million annually; in the United States, ~5000–6000 cases occur per year. Males are
at slightly higher risk for GBS than females, and in Western countries,
adults are more frequently affected than children.
Clinical Manifestations GBS manifests as a rapidly evolving
areflexic motor paralysis with or without sensory disturbance. The
usual pattern is an ascending paralysis that may be first noticed as
447 Guillain-Barré Syndrome
and Other Immune-Mediated
Neuropathies
Stephen L. Hauser, Anthony A. Amato
rubbery legs. Weakness typically evolves over hours to a few days and
is frequently accompanied by tingling dysesthesias in the extremities.
The legs are usually more affected than the arms, and facial diparesis is
present in 50% of affected individuals. The lower cranial nerves are also
frequently involved, causing bulbar weakness with difficulty handling
secretions and maintaining an airway; the diagnosis in these patients
may initially be mistaken for brainstem ischemia. Pain in the neck,
shoulder, back, or diffusely over the spine is also common in the early
stages of GBS, occurring in ~50% of patients. Most patients require
hospitalization, and in different series, up to 30% require ventilatory
assistance at some time during the illness. The need for mechanical
ventilation is associated with more severe weakness on admission, a
rapid tempo of progression, and the presence of facial and/or bulbar
weakness during the first week of symptoms. Fever and constitutional
symptoms are absent at the onset and, if present, cast doubt on the
diagnosis. Deep tendon reflexes attenuate or disappear within the
first few days of onset. Cutaneous sensory deficits (e.g., loss of pain
and temperature sensation) are usually relatively mild, but functions
subserved by large sensory fibers, such as deep tendon reflexes and
proprioception, are more severely affected. Bladder dysfunction may
occur in severe cases but is usually transient. If bladder dysfunction is
a prominent feature and comes early in the course or there is a sensory
level on examination, diagnostic possibilities other than GBS should
be considered, particularly spinal cord disease (Chap. 442). Once clinical worsening stops and the patient reaches a plateau (almost always
within 4 weeks of onset), further progression is unlikely.
Autonomic involvement is common and may occur even in patients
whose GBS is otherwise mild. The usual manifestations are loss of
vasomotor control with wide fluctuations in blood pressure, postural
hypotension, and cardiac dysrhythmias. These features require close
monitoring and management and can be fatal. Pain is another common
feature of GBS; in addition to the acute pain described above, a deep
aching pain may be present in weakened muscles that patients liken
to having overexercised the previous day. Other pains in GBS include
dysesthetic pain in the extremities as a manifestation of sensory nerve
fiber involvement. These pains are self-limited and often respond to
standard analgesics (Chap. 13).
Several subtypes of GBS are recognized, as determined primarily by
electrodiagnostic (EDx) and pathologic distinctions (Table 447-1). The
most common variant is acute inflammatory demyelinating polyneuropathy (AIDP). Additionally, there are two “axonal” or “nodal/paranodal” variants, which are often clinically severe: the acute motor axonal
neuropathy (AMAN) and acute motor sensory axonal neuropathy
(AMSAN) subtypes. In addition, a range of limited or regional GBS
syndromes are also encountered. Notable among these is the Miller
Fisher syndrome (MFS), which presents as rapidly evolving ataxia and
areflexia of limbs without weakness, and ophthalmoplegia, often with
pupillary paralysis. The MFS variant accounts for ~5% of all cases
and is strongly associated with antibodies to the ganglioside GQ1b
(see “Immunopathogenesis,” below). Other regional variants of GBS
include (1) pure sensory forms; (2) ophthalmoplegia with anti-GQ1b
antibodies as part of severe motor-sensory GBS; (3) GBS with severe
bulbar and facial paralysis, sometimes associated with antecedent
cytomegalovirus (CMV) infection and anti-GM2 antibodies; and (4)
acute pandysautonomia (Chap. 440).
Antecedent Events Approximately 70% of cases of GBS occur
1–3 weeks after an acute infectious process, usually respiratory or
gastrointestinal. Culture and seroepidemiologic techniques show that
20–30% of all cases occurring in North America, Europe, and Australia are preceded by infection or reinfection with Campylobacter jejuni.
A similar proportion is preceded by a human herpes virus infection,
often CMV or Epstein-Barr virus. Other viruses (e.g., HIV, hepatitis E,
Zika) and also Mycoplasma pneumoniae have been identified as agents
involved in antecedent infections, as have recent immunizations. The
swine influenza vaccine, administered widely in the United States in
1976, is the most notable example. Influenza vaccines in use from
1992 to 1994, however, resulted in only one additional case of GBS per
million persons vaccinated, and the more recent seasonal influenza
3502 PART 13 Neurologic Disorders
of cases), particularly in AMAN and AMSAN, and in those cases,
they are preceded by C. jejuni infection. Some AIDP autoantibodies
may recognize glycolipid heterocomplexes, rather than single species,
present on cell membranes. Furthermore, isolates of C. jejuni from
stool cultures of patients with GBS have surface glycolipid structures
that antigenically cross react with gangliosides, including GM1, concentrated in human nerves. Sialic acid residues from pathogenic C.
jejuni strains can also trigger activation of dendritic cells via signaling
through Toll-like receptor 4 (TLR4), promoting B-cell differentiation
and further amplifying humoral autoimmunity. Another line of evidence implicating humoral autoimmunity is derived from cases of GBS
that followed intravenous administration of bovine brain gangliosides
for treatment of various neuropathies; 5–15 days after injection, some
recipients developed AMAN with high titers of anti-GM1 antibodies
that recognized epitopes at nodes of Ranvier and motor endplates.
Experimentally, anti-GM1 antibodies can trigger complementmediated injury at paranodal axon-glial junctions, disrupting the clustering of sodium channels and likely contributing to conduction block
(see “Pathophysiology,” below).
Anti-GQ1b IgG antibodies are found in >90% of patients with
MFS (Table 447-2; Fig. 447-2), and titers of IgG are highest early in
the course. Anti-GQ1b antibodies are not found in other forms of
GBS unless there is extraocular motor nerve involvement. A possible explanation for this association is that extraocular motor nerves
are enriched in GQ1b gangliosides in comparison to limb nerves. In
addition, a monoclonal anti-GQ1b antibody raised against C. jejuni
isolated from a patient with MFS blocked neuromuscular transmission
experimentally.
Taken together, these observations provide strong but still inconclusive evidence that autoantibodies play an important pathogenic
role in GBS. Although antiganglioside antibodies have been studied
most intensively, other antigenic targets may also be important. Proof
that these antibodies are pathogenic requires that they be capable of
mediating disease following direct passive transfer to naïve hosts; this
has not yet been demonstrated, although one case of possible maternalfetal transplacental transfer of GBS has been described.
In AIDP, an early step in the induction of tissue damage appears
to be complement deposition along the outer surface of the Schwann
cell. Activation of complement initiates a characteristic vesicular
disintegration of the myelin sheath and also leads to recruitment
of activated macrophages, which participate in damage to myelin
and axons. In AMAN, the pattern is different in that complement is
deposited along with IgG at the nodes of Ranvier along large motor
axons. Interestingly, in cases of AMAN, antibodies against GD1a
appear to have a fine specificity that favors binding to motor rather
than sensory nerve roots, even though this ganglioside is expressed
on both fiber types.
Pathophysiology In the demyelinating forms of GBS, the basis
for flaccid paralysis and sensory disturbance is conduction block. This
finding, demonstrable electrophysiologically, implies that the axonal
connections remain intact. Hence, recovery can take place rapidly as
remyelination occurs. In severe cases of demyelinating GBS, secondary
TABLE 447-1 Subtypes of Guillain-Barré Syndrome (GBS)
SUBTYPE FEATURES ELECTRODIAGNOSIS PATHOLOGY
Acute inflammatory demyelinating
polyneuropathy (AIDP)
Adults affected more than children; 90%
of cases in Western world; recovery
rapid; anti-GM1 antibodies (<50%)
Demyelinating First attack on Schwann cell surface; widespread myelin
damage, macrophage activation, and lymphocytic
infiltration; variable secondary axonal damage
Acute motor axonal neuropathy (AMAN) Children and young adults; prevalent
in China and Mexico; may be seasonal;
recovery rapid; anti-GD1a antibodies
Axonal First attack at motor nodes of Ranvier; macrophage
activation, few lymphocytes, frequent periaxonal
macrophages; extent of axonal damage highly variable
Acute motor sensory axonal neuropathy
(AMSAN)
Mostly adults; uncommon; recovery
slow, often incomplete; closely related
to AMAN
Axonal Same as AMAN, but also affects sensory nerves and
roots; axonal damage usually severe
Miller Fisher syndrome (MFS) Adults and children; ophthalmoplegia,
ataxia, and areflexia; anti-GQ1b
antibodies (90%)
Axonal or
demyelinating
Few cases examined; resembles AIDP
vaccines appear to confer a GBS risk of <1 per million. Epidemiologic
studies looking at H1N1 vaccination demonstrated at most only a
slight increased risk of GBS. Meningococcal vaccinations (Menactra)
do not appear to carry an increased risk. Older-type rabies vaccine,
prepared in nervous system tissue, is implicated as a trigger of GBS
in developing countries where it is still used; the mechanism is presumably immunization against neural antigens. GBS also occurs more
frequently than can be attributed to chance alone in patients with lymphoma (including Hodgkin’s disease), in HIV-seropositive individuals,
and in patients with systemic lupus erythematosus (SLE). GBS, other
inflammatory neuropathies, and myositis can also occur as a complication of immune checkpoint inhibitors used to treat various cancers.
C. jejuni has also been implicated in summer outbreaks of AMAN
among children and young adults exposed to chickens in rural China.
Infection by Zika virus recently has been implicated in the increased
incidence of GBS in Brazil and other endemic regions. Recently, GBS
has been reported with SARS-CoV-2 infection during the COVID-19
pandemic, but a causal relationship has not been established. There
appears to be an increased risk of GBS with SARS-CoV-2 vaccines
using adenovirus vectors, but not the messenger RNA vaccines.
Immunopathogenesis Several lines of evidence support an autoimmune basis for acute inflammatory demyelinating polyneuropathy
(AIDP), the most common and best-studied type of GBS; the concept
extends to all of the subtypes of GBS (Table 447-1).
It is likely that both cellular and humoral immune mechanisms
contribute to tissue damage in AIDP. T-cell activation is suggested by
the finding that elevated levels of cytokines and cytokine receptors
are present in serum (interleukin [IL] 2, soluble IL-2 receptor) and in
cerebrospinal fluid (CSF) (IL-6, tumor necrosis factor α, interferon γ).
AIDP is also closely analogous to an experimental T cell–mediated
immunopathy designated experimental allergic neuritis (EAN). EAN is
induced in laboratory animals by immune sensitization against protein
fragments derived from peripheral nerve proteins and, in particular,
against the P2 protein. Based on analogy to EAN, it was initially
thought that AIDP was likely to be primarily a T cell–mediated disorder; however, abundant data now suggest that autoantibodies directed
against T cell–independent nonprotein determinants may be central
to many cases.
Circumstantial evidence suggests that all GBS results from
immune responses to nonself antigens (infectious agents, vaccines)
that misdirect to host nerve tissue through a resemblance-of-epitope
(molecular mimicry) mechanism (Fig. 447-1). The neural targets are
likely to be glycoconjugates, specifically gangliosides (Table 447-2;
Fig. 447-2). Gangliosides are complex glycosphingolipids that
contain one or more sialic acid residues; various gangliosides participate in cell-cell interactions (including those between axons
and glia), modulation of receptors, and regulation of growth. They
are typically exposed on the plasma membrane of cells, rendering
them susceptible to an antibody-mediated attack. Gangliosides and
other glycoconjugates are present in large quantity in human nervous
tissues and in key sites, such as nodes of Ranvier. Antiganglioside
antibodies, most frequently to GM1, are common in GBS (20–50%
3503 Guillain-Barré Syndrome and Other Immune-Mediated Neuropathies CHAPTER 447
axonal degeneration usually occurs; its extent can be estimated electrophysiologically. More secondary axonal degeneration correlates with a
slower rate of recovery and a greater degree of residual disability. With
AMAN and AMSAN, a primary axonal pattern is encountered electrophysiologically (low-amplitude compound muscle action potentials).
The implication has been that axons have degenerated and become disconnected from their targets, specifically the neuromuscular junctions,
and must therefore regenerate for recovery to take place. However, the
rapid recover in many cases suggests the low amplitudes are often from
reversible conduction block due to binding of antibodies to ion channel
proteins in the nodes and paranodes. In severe cases, axonal degeneration can occur, and it is in these cases that recovery is much slower.
Laboratory Features CSF findings are distinctive, consisting of
an elevated CSF protein level (1–10 g/L [100–1000 mg/dL]) without
accompanying pleocytosis. The CSF is often normal when symptoms
have been present for ≤48 h; by the end of the first week, the level
of protein is usually elevated. A transient increase in the CSF white
cell count (10–100/μL) occurs on occasion in otherwise typical GBS;
however, a sustained CSF pleocytosis suggests an alternative diagnosis (viral myelitis) or a concurrent diagnosis such as unrecognized
HIV infection, leukemia or lymphoma with infiltration of nerves, or
neurosarcoidosis. EDx features are mild or absent in the early stages
of GBS and lag behind the clinical evolution. In AIDP, the earliest features are prolonged F-wave latencies, prolonged distal latencies, and
reduced amplitudes of compound muscle action potentials (CMAPs),
probably owing to the predilection for involvement of nerve roots
and distal motor nerve terminals early in the course. Later, slowing
of conduction velocity, conduction block, and temporal dispersion
may be appreciated (Table 447-1). Occasionally, sensory nerve action
potentials (SNAPs) may be normal in the feet (e.g., sural nerve) when
abnormal in the arms. This is also a sign that the patient does not
have one of the more typical “length-dependent” polyneuropathies.
As mentioned, in AMAN and AMSAN, the principal EDx finding
is reduced amplitude of CMAPs (and also SNAPS with AMSAN)
without conduction slowing or prolongation of distal latencies, which
early on is caused by conduction block but later can be due to axonal
degeneration.
Diagnosis GBS is a descriptive entity. The diagnosis of AIDP is
made by recognizing the pattern of rapidly evolving paralysis with
areflexia, absence of fever or other systemic symptoms, and characteristic antecedent events. In 2011, the Brighton Collaboration
developed a new set of case definitions for GBS in response to needs
of epidemiologic studies of vaccination and assessing risks of GBS
(Table 447-3). These criteria have subsequently been validated.
Other disorders that may enter into the differential diagnosis include
acute myelopathies (especially with prolonged back pain and sphincter disturbances); diphtheria (early oropharyngeal disturbances);
Lyme polyradiculitis and other tick-borne paralyses; porphyria
(abdominal pain, seizures, psychosis); vasculitic neuropathy (check
erythrocyte sedimentation rate, described below); poliomyelitis and
acute flaccid myelitis (wild-type poliovirus, West Nile virus, enterovirus D68, enterovirus A71, Japanese encephalitis virus, and the wildtype poliovirus); CMV polyradiculitis (in immunocompromised
patients); critical illness neuropathy or myopathy; neuromuscular
junction disorders such as myasthenia gravis and botulism (pupillary
reactivity lost early); poisonings with organophosphates, thallium, or
arsenic; paralytic shellfish poisoning; or severe hypophosphatemia
(rare). Cases of acute flaccid myelitis may pose particular challenges
stnairavdnasepytbuS otseidobitnaotuaGgI
Guillain-Barré syndrome
Acute inflammatory demyelinating polyneuropathy
Facial variant: Facial diplegia and paresthesia
Acute motor axonal neuropathy
More and less extensive forms
Acute motor-sensory axonal neuropathy
Acute motor-conduction-block neuropathy
Pharyngeal-cervical-brachial weakness
None
None
GM1, GD1a
GM1, GD1a
GM1, GD1a
GT1a>GQ1b>>GD1a
GQ1b, GT1a
GQ1b, GT1a
GQ1b, GT1a
GQ1b, GT1a
Miller Fisher syndrome
Incomplete forms
Acute ophthalmoparesis (without ataxia)
Acute ataxic neuropathy (without ophthalmoplegia)
CNS variant: Bickerstaff’s brainstem encephalitis
Galactose
KEY
Glucose
N-Acetylgalactosamine
N-Acetylneuraminic acid
Cer Ceramide
GM1 Cer
GD1a Cer
Cer
Cer
GT1a
GQ1b
FIGURE 447-1 Spectrum of disorders in Guillain-Barré syndrome and associated antiganglioside antibodies. IgG autoantibodies against GM1 or GD1a are strongly
associated with acute motor axonal neuropathy (AMAN), as well as the more extensive acute motor-sensory axonal neuropathy (AMSAN), and the less extensive acute
motor-conduction-block neuropathy. IgG anti-GQ1b antibodies, which cross-react with GT1a, are strongly associated with Miller Fisher syndrome, its incomplete forms
(acute ophthalmoparesis [without ataxia] and acute ataxic neuropathy [without ophthalmoplegia]), and its more extensive form, Bickerstaff’s brainstem encephalitis.
Pharyngeal-cervical-brachial weakness is categorized as a localized form of acute motor axonal neuropathy or an extensive form of Miller Fisher syndrome. Half of patients
with pharyngeal-cervical-brachial weakness have IgG anti-GT1a antibodies, which often cross-react with GQ1b. IgG anti-GD1a antibodies have also been detected in a
small percentage of patients. The anti-GQ1b antibody syndrome includes Miller Fisher syndrome, acute ophthalmoparesis, acute ataxic neuropathy, Bickerstaff’s brainstem
encephalitis, and pharyngeal-cervical-brachial weakness. The presence of clinical overlap also indicates that Miller Fisher syndrome is part of a continuous spectrum with
these conditions. Patients who have had Guillain-Barré syndrome overlapped with Miller Fisher syndrome or with its related conditions have IgG antibodies against GM1
or GD1a as well as against GQ1b or GT1a, supporting a link between AMAN and anti-GQ1b syndrome. (From N Yuki, H-P Hartung: Guillain-Barré syndrome. N Engl J Med
366:2294, 2012. Copyright © 2012 Massachusetts Medical Society. Reprinted with permission from Massachusetts Medical Society.)
3504 PART 13 Neurologic Disorders
in distinguishing these from GBS because sphincter disturbances are
often absent.
Laboratory tests are helpful primarily to exclude mimics of GBS.
CSF pleocytosis is seen with poliomyelitis, acute flaccid myelitis, and
Lyme and CMV polyradiculitis. EDx features may be minimal early in
GBS, and the CSF protein level may not rise until the end of the first
week. If the diagnosis is strongly suspected, treatment should be initiated without waiting for evolution of the characteristic EDx and CSF
findings to occur. GBS patients with risk factors for HIV or with CSF
pleocytosis should have a serologic test for HIV.
TREATMENT
Guillain-Barré Syndrome
In the vast majority of patients with GBS, treatment should be
initiated as soon after diagnosis as possible. Each day counts;
~2 weeks after the first motor symptoms, it is not known whether
immunotherapy is still effective. If the patient has already reached
the plateau stage, then treatment probably is no longer indicated,
unless the patient has severe motor weakness and one cannot
exclude the possibility that an immunologic attack is still ongoing.
Either high-dose intravenous immune globulin (IVIg) or plasmapheresis (PLEX) can be initiated, as they are equally effective for
typical GBS. A combination of the two therapies is not significantly
better than either alone. IVIg is often the initial therapy chosen
because of its ease of administration and good safety record. IVIg
is usually administered as five daily infusions for a total dose of
2 g/kg body weight. There is some evidence that GBS autoantibodies are neutralized by anti-idiotypic antibodies present in IVIg preparations, perhaps accounting for the therapeutic effect. A course
of PLEX usually consists of ~40–50 mL/kg plasma exchange (PE)
4–5 times over 7–10 days. Meta-analysis of randomized clinical
trials indicates that treatment reduces the need for mechanical ventilation by nearly half (from 27 to 14% with PLEX) and increases the
likelihood of full recovery at 1 year (from 55 to 68%). Functionally
significant improvement may occur toward the end of the first
week of treatment or may be delayed for several weeks. The lack of
noticeable improvement following a course of IVIg or PLEX is not
an indication to treat with the alternate treatment. However, there
are occasional patients who are treated early in the course of GBS
and improve, who then relapse within a month. Brief retreatment
with the original therapy is usually effective in such cases. Glucocorticoids have not been found to be effective in GBS. Occasional
patients with very mild forms of GBS, especially those who appear
to have already reached a plateau when initially seen, may be managed conservatively without IVIg or PLEX.
In the worsening phase of GBS, most patients require monitoring
in a critical care setting, with particular attention to vital capacity,
heart rhythm, blood pressure, nutrition, deep-vein thrombosis prophylaxis, cardiovascular status, early consideration (after 2 weeks
of intubation) of tracheotomy, and chest physiotherapy. As noted,
~30% of patients with GBS require ventilatory assistance, sometimes for prolonged periods of time (several weeks or longer).
Frequent turning and assiduous skin care are important, as are daily
range-of-motion exercises to avoid joint contractures and daily
reassurance as to the generally good outlook for recovery.
Prognosis and Recovery Approximately 85% of patients with
GBS achieve a full functional recovery within several months to a
year, although minor findings on examination (such as areflexia) may
persist and patients often complain of continued symptoms, including
fatigue. The mortality rate is <5% in optimal settings; death usually
results from secondary pulmonary complications. The outlook is
worst in patients with severe proximal motor and sensory axonal
damage. Such axonal damage may be either primary or secondary in
nature (see “Pathophysiology,” above), but in either case, successful
regeneration cannot occur. Other factors that worsen the outlook for
recovery are advanced age, a fulminant or severe attack, and a delay
in the onset of treatment. Between 5 and 10% of patients with typical GBS have one or more late relapses; many of these cases are then
classified as chronic inflammatory demyelinating polyneuropathy
(CIDP).
CHRONIC INFLAMMATORY
DEMYELINATING POLYNEUROPATHY
CIDP is distinguished from GBS by its chronic course. In other
respects, this neuropathy shares many features with the common
demyelinating form of GBS, including elevated CSF protein levels
and the EDx findings of acquired demyelination. Most cases occur in
adults, and males are affected slightly more often than females. The
incidence of CIDP is lower than that of GBS, but due to the protracted
course, the prevalence is greater. As with GBS, CIDP and its variants
can be triggered by use of immune checkpoint inhibitors used to treat
various cancers.
Clinical Manifestations Onset is usually gradual over a few
months or longer, but in a few cases, the initial attack is indistinguishable from that of GBS. An acute-onset form of CIDP may mimic GBS
but should be considered if it deteriorates >9 weeks after onset or
relapses at least three times. Symptoms are both motor and sensory
in most cases. Weakness of the limbs is usually symmetric but can be
strikingly asymmetric in multifocal acquired demyelinating sensory
and motor (MADSAM) neuropathy variant (Lewis-Sumner syndrome)
in which discrete peripheral nerves are involved. There is considerable
TABLE 447-2 Principal Antiglycolipid Antibodies Implicated in
Immune Neuropathies
CLINICAL
PRESENTATION ANTIBODY TARGET USUAL ISOTYPE
Acute Immune Neuropathies (Guillain-Barré Syndrome)
Acute inflammatory
demyelinating
polyneuropathy (AIDP)
No clear patterns IgG (polyclonal)
GM1 most common
Acute motor axonal
neuropathy (AMAN)
GD1a, GM1, GM1b,
GalNAc–GD1a (<50%
for any)
IgG (polyclonal)
Miller Fisher syndrome
(MFS)
GQ1b (>90%) IgG (polyclonal)
Acute pharyngeal
cervicobrachial
neuropathy (APCBN)
GT1a (? most) IgG (polyclonal)
Chronic Immune Neuropathies
Chronic inflammatory
demyelinating
polyneuropathy
(CIDP) (75%)
Approximately 10% to
CNTN1 or NF155, less
often to NF140/186 and
Caspr1, and even more
rarely to P0, myelin P2
protein, or PMP22
IgG4 with CNTN1, NF155,
NF140/186, Caspr1
Rare IgM with NF155
CIDP-M (MGUS
associated) (25%)
Neural binding sites IgG, IgA (monoclonal)
Chronic sensory > motor
neuropathy
SGPG, SGLPG (on MAG)
(50%)
IgM (monoclonal)
Uncertain (50%) IgM (monoclonal)
Multifocal motor
neuropathy (MMN)
GM1, GalNAc–GD1a,
others (25–50%)
IgM (polyclonal,
monoclonal)
Chronic sensory ataxic
neuropathy
GD1b, GQ1b, and other
b-series gangliosides
IgM (monoclonal)
Abbreviations: CIDP-M, CIDP with a monoclonal gammopathy; Caspr1, contactin
associated protein-1; CNTN1, contactin-1; MAG, myelin-associated glycoprotein;
MGUS, monoclonal gammopathy of undetermined significance; NF140/186,
neurofascin 140/186; NF155, neurofascin 155; SGPG, sulfoglucuronyl paragloboside;
SGLPG, sulfoglucuronyl lactosaminyl paragloboside.
Source: Reproduced with permission from HJ Willison, N Yuki: Peripheral
neuropathies and anti‐glycolipid antibodies. Brain 125:2591, 2002.
3505 Guillain-Barré Syndrome and Other Immune-Mediated Neuropathies CHAPTER 447
variability from case to case. Some patients experience a chronic
progressive course, whereas others, usually younger patients, have a
relapsing and remitting course. A small proportion have cranial nerve
findings, including external ophthalmoplegia. Some have only motor
findings, and a small proportion present with a relatively pure syndrome of sensory ataxia. The latter can be seen in the chronic inflammatory sensory polyradiculopathy (CISP) variant of CIDP in which
demyelination predominantly occurs at the sensory roots or with the
distal acquired demyelinating symmetric (DADS) variant.
Approximately, 10% of cases are associated with IgG4 isotype
antibodies directed against contactin-1 (CNTN1) or neurofascin 155
(NF155), with early axonal damage, severe distal motor involvement,
or sensory ataxia with tremor. Less commonly, IgM anti-NF140/186
CIDP associated with sensory ataxia but without tremor, low-amplitude
CMAPs (conduction block or axonal degeneration), and nephrotic
syndrome have also been reported. Anti-contactin associated protein-1
(Caspr1) antibodies occur in CIDP associated with severe neuropathic
pain.
CIDP tends to ameliorate over time with treatment; the result is that
many years after onset, nearly 75% of patients have reasonable functional status. Death from CIDP is uncommon.
Diagnosis The diagnosis rests on characteristic clinical, CSF, and
electrophysiologic findings. The CSF is usually acellular with an
Macrophage
scavenging
A
Motor
neuron
Axon
Kv Caspr
Juxtaparanode
Axon
Myelin
Schwann-cell
microvilli
Paranode Node
Nav Cytoskeleton
KEY
KEY
IgG anti-GM1 or
anti-GD1a antibodies
C3 MAC
Unidentified antigen
Myelin
Nerve
injury
Macrophage
GM1,
GD1a
MAC
B
Axon
MAC
Myelin
Macrophage
Macrophage
Axon
Axon
Complement
activation
Antibody
binding
Axon
Macrophage
Myelin
FIGURE 447-2 Possible immune mechanisms in Guillain-Barré syndrome (GBS). Panel A shows the immunopathogenesis of AIDP. Although autoantigens have yet to be
unequivocally identified, autoantibodies may bind to myelin antigens and activate complement. This is followed by the formation of membrane-attack complex (MAC) on
the outer surface of Schwann cells and the initiation of vesicular degeneration. Macrophages subsequently invade myelin and act as scavengers to remove myelin debris.
Panel B shows the immunopathogenesis of acute axonal forms of GBS (acute motor axonal neuropathy [AMAN] and acute motor-sensory axonal neuropathy [AMSAN]).
Myelinated axons are divided into four functional regions: the nodes of Ranvier, paranodes, juxtaparanodes, and internodes. Gangliosides GM1 and GD1a are strongly
expressed at the nodes of Ranvier, where the voltage-gated sodium (Nav) channels are localized. Contactin-associated protein (Caspr) and voltage-gated potassium (Kv)
channels are respectively present at the paranodes and juxtaparanodes. IgG anti-GM1 or anti-GD1a autoantibodies bind to the nodal axolemma, leading to MAC formation.
This results in the disappearance of Nav clusters and the detachment of paranodal myelin, which can lead to nerve-conduction failure and muscle weakness. Axonal
degeneration may follow at a later stage. Macrophages subsequently invade from the nodes into the periaxonal space, scavenging the injured axons. (From N Yuki, H-P
Hartung: Guillain-Barré syndrome. N Engl J Med 366:2294, 2012. Copyright © 2012 Massachusetts Medical Society. Reprinted with permission from Massachusetts Medical
Society.)
3506 PART 13 Neurologic Disorders
elevated protein level, sometimes several times normal. As with GBS,
a CSF pleocytosis should lead to the consideration of HIV infection,
leukemia or lymphoma, and neurosarcoidosis. EDx findings reveal
variable degrees of conduction slowing, prolonged distal latencies,
distal and temporal dispersion of CMAPs, and conduction block as
the principal features. In particular, the presence of conduction block
is a certain sign of an acquired demyelinating process. Evidence of
axonal loss, presumably secondary to demyelination, is present in
>50% of patients. Serum protein electrophoresis with immunofixation
is indicated to search for monoclonal gammopathy and associated
conditions (see “Monoclonal Gammopathy of Undetermined Significance,” below). MRI can demonstrate enlarged nerves, clumping of
cauda equina, and enhancement. Ultrasound is cheaper and often more
readily available and can likewise show enlargement of nerves at the
roots or more distally. Studies have shown that imaging completements
EDx findings and increases sensitivity. In all patients with presumptive
CIDP, it is also reasonable to exclude vasculitis, collagen vascular disease (especially SLE), chronic hepatitis, HIV infection, amyloidosis,
and diabetes mellitus. Other associated conditions include inflammatory bowel disease and lymphoma.
Pathogenesis Biopsy in typical CIDP reveals little inflammation
and onion-bulb changes (imbricated layers of attenuated Schwann cell
processes surrounding an axon) that result from recurrent demyelination and remyelination (Fig. 447-1). The response to therapy suggests
that CIDP is immune-mediated; CIDP responds to glucocorticoids,
whereas GBS does not. Passive transfer of demyelination into experimental animals has been accomplished using IgG purified from the
serum of some patients with CIDP, lending support for a humoral autoimmune pathogenesis. A minority of patients have serum antibodies
TABLE 447-3 Brighton Criteria for Diagnosis of Guillain-Barré Syndrome (GBS) and Miller Fisher Syndrome
Clinical case definitions for diagnosis of GBS
Level 1 of diagnostic certainty
Bilateral AND flaccid weakness of the limbs
AND
Decreased or absent deep tendon reflexes in weak limbs
AND
Monophasic illness pattern and interval between onset and nadir of weakness
between 12 h and 28 days and subsequent clinical plateau
AND
Electrophysiologic findings consistent with GBS
AND
Cytoalbuminologic dissociation (i.e., elevation of CSF protein level above laboratory
normal value AND CSF total white cell count <50 cells/μL)
AND
Absence of an identified alternative diagnosis for weakness
Level 2 of diagnostic certainty
Bilateral AND flaccid weakness of the limbs
AND
Decreased or absent deep tendon reflexes in weak limbs
AND
Monophasic illness pattern and interval between onset and nadir of weakness
between 12 h and 28 days and subsequent clinical plateau
AND
CSF total white cell count <50 cells/μL (with or without CSF protein elevation above
laboratory normal value)
OR
If CSF not collected or results not available, electrophysiologic studies consistent
with GBS
AND
Absence of identified alternative diagnosis for weakness
Level 3 of diagnostic certainty
Bilateral and flaccid weakness of the limbs
AND
Decreased or absent deep tendon reflexes in weak limbs
AND
Monophasic illness pattern and interval between onset and nadir of weakness
between 12 h and 28 days and subsequent clinical plateau
AND
Absence of identified alternative diagnosis for weakness
Clinical case definitions for diagnosis of Miller Fisher syndrome
Level 1 of diagnostic certainty
Bilateral ophthalmoparesis and bilateral reduced or absent tendon reflexes, and
ataxia
AND
Absence of limb weakness
AND
Monophasic illness pattern and interval between onset and nadir of
weakness between 12 h and 28 days and subsequent clinical plateau
AND
Cytoalbuminologic dissociation (i.e., elevation of cerebrospinal protein above
the laboratory normal and total CSF white cell count <50 cells/μL)
AND
Nerve conduction studies are normal, OR indicate involvement of sensory
nerves only
AND
No alterations in consciousness or corticospinal tract signs
AND
Absence of identified alternative diagnosis
Level 2 of diagnostic certainty
Bilateral ophthalmoparesis and bilateral reduced or absent tendon reflexes
and ataxia
AND
Absence of limb weakness
AND
Monophasic illness pattern and interval between onset and nadir of
weakness between 12 h and 28 days and subsequent clinical plateau
AND
CSF with a total white cell count <50 cells/μL) (with or without CSF protein
elevation above laboratory normal value)
OR
Nerve conduction studies are normal, OR indicate involvement of sensory
nerves only
AND
No alterations in consciousness or corticospinal tract signs
AND
Absence of identified alternative diagnosis
Level 3 of diagnostic certainty
Bilateral ophthalmoparesis and bilateral reduced or absent tendon reflexes
and ataxia
AND
Absence of limb weakness
AND
Monophasic illness pattern and interval between onset and nadir of
weakness between 12 h and 28 days and subsequent clinical plateau
AND
No alterations in consciousness or corticospinal tract signs
AND
Absence of identified alternative diagnosis
Abbreviation: CSF, cerebrospinal fluid.
Source: From JJ Sejvar et al: Guillain-Barré syndrome and Fisher syndrome: Case definitions and guidelines for collection, analysis, and presentation of immunization safety
data. Vaccine 29:599, 2011. Validation study published by C Fokke et al: Diagnosis of Guillain-Barré syndrome and validation of Brighton criteria. Brain 137:33, 2014.
3507 Guillain-Barré Syndrome and Other Immune-Mediated Neuropathies CHAPTER 447
against P0, myelin P2 protein, or PMP22 (proteins whose genes are
mutated in certain forms of hereditary Charcot-Marie-Tooth neuropathy). As previously mentioned, antibodies of IgG4 isotype directed
against CNTN1, NF155, NF140/186, and Caspr1 have been associated
with early nodal and paranodal damage with and a poor response to
IVIg. CNTN1 and its partner Caspr1 interact with NF155 at paranodal axoglial junctions. Passive transfer of IgG4 CNTN1 antibodies
produces paranodal damage and ataxia in rodents. It is also of interest
that a CIDP-like illness developed spontaneously in the nonobese diabetic (NOD) mouse when the immune co-stimulatory molecule B7-2
(CD86) was genetically deleted; this suggests that CIDP can result from
altered triggering of T cells by antigen-presenting cells.
As many as 25% of patients with clinical features of CIDP also have
a monoclonal gammopathy of undetermined significance (MGUS),
discussed below. Cases associated with monoclonal IgA or IgG kappa
usually respond to treatment as favorably as cases without a monoclonal gammopathy. Patients with IgM-kappa monoclonal gammopathy and antibodies directed against myelin-associated glycoprotein
(MAG) have a distinct demyelinating polyneuropathy with more
sensory findings, usually only distal weakness, and a poor response to
immunotherapy.
TREATMENT
Chronic Inflammatory Demyelinating
Polyneuropathy
Most authorities initiate treatment for CIDP when progression is
rapid or walking is compromised. If the disorder is mild, management can be expectant, awaiting spontaneous remission. Controlled
studies have shown that high-dose IVIg, subcutaneous Ig (scIg),
PLEX, and glucocorticoids are all more effective than placebo.
Initial therapy is usually with IVIg, administered as 2.0 g/kg
body weight given in divided doses over 2–5 days; three monthly
courses are generally recommended before concluding a patient
has failed treatment. If the patient responds, the infusion intervals
can be gradually increased or the dosage decreased (e.g., starting at
1 g/kg every 3–4 weeks). Patients who require more frequent IVIg,
experience side effects with IVIg (headaches), have poor venous
access, or find it more convenient are treated with scIg (2–3 times
a week such that the total dosage per month is the same or slightly
higher than the monthly dosage of IVIg). PLEX, which appears to
be as effective as IVIg, is initiated at 2–3 treatments per week for
6 weeks; periodic retreatment may also be required. Treatment with
glucocorticoids is another option (60–80 mg prednisone PO daily
for 1–2 months, followed by a gradual dose reduction of 10 mg
per month as tolerated), but long-term adverse effects including
bone demineralization, gastrointestinal bleeding, and cushingoid
changes are problematic. As many as one-third of patients with
CIDP fail to respond adequately to the initial therapy chosen; a
different treatment should then be tried. Patients who fail therapy
with IVIg, scIg, PLEX, and glucocorticoids may benefit from
treatment with immunosuppressive agents such as azathioprine,
methotrexate, cyclosporine, and cyclophosphamide, either alone or
as adjunctive therapy. CIDP associated with anti-CNTN1, NF155,
NF140/186, and Caspr1 antibodies (IgG4 subclass antibodies) is
typically refractory to IVIg, but several studies suggest a response
to rituximab. Use of these therapies requires periodic reassessment
of their risks and benefits. In patients with a CIDP-like neuropathy
who fail to respond to treatment, it is important to evaluate for
POEMS syndrome (polyneuropathy, organomegaly, endocrinopathy, monoclonal gammopathy, skin changes; see below).
MULTIFOCAL MOTOR NEUROPATHY
Multifocal motor neuropathy (MMN) is a distinctive but uncommon
neuropathy that presents as slowly progressive motor weakness and
atrophy evolving over years in the distribution of selected nerve trunks,
associated with sites of persistent focal motor conduction block in the
same nerve trunks. Sensory fibers are relatively spared. The arms are
affected more frequently than the legs, and >75% of all patients are
male. Some cases have been confused with lower motor neuron forms
of amyotrophic lateral sclerosis (Chap. 437). Less than 50% of patients
present with high titers of polyclonal IgM antibody to the ganglioside
GM1. It is uncertain how this finding relates to the discrete foci of
persistent motor conduction block, but high concentrations of GM1
gangliosides are normal constituents of nodes of Ranvier in peripheral
nerve fibers. Pathology reveals demyelination and mild inflammatory
changes at the sites of conduction block.
Most patients with MMN respond to high-dose IVIg or scIg (dosages as for CIDP, above); periodic retreatment is required (usually at
least monthly) to maintain the benefit. Some refractory patients have
responded to rituximab or cyclophosphamide. Glucocorticoids and PE
are not effective.
NEUROPATHIES WITH MONOCLONAL
GAMMOPATHY
■ MULTIPLE MYELOMA
Clinically overt polyneuropathy occurs in ~5% of patients with the
commonly encountered type of multiple myeloma, which exhibits
either lytic or diffuse osteoporotic bone lesions. These neuropathies
are sensorimotor, are usually mild and slowly progressive but may be
severe, and generally do not reverse with successful suppression of the
myeloma. In most cases, EDx and pathologic features are consistent
with a process of axonal degeneration.
In contrast, myeloma with osteosclerotic features, although representing only 3% of all myelomas, is associated with polyneuropathy
in one-half of cases. These neuropathies, which may also occur with
solitary plasmacytoma, are distinct because they (1) are demyelinating or mixed axonal and demyelinating by EDx, have elevated CSF
protein, and clinically resemble CIDP; (2) often respond to radiation
therapy or removal of the primary lesion; (3) are associated with different monoclonal proteins and light chains (almost always lambda as
opposed to primarily kappa in the lytic type of multiple myeloma); (4)
are typically refractory to standard treatments of CIDP; and (5) may
occur in association with other systemic findings including thickening of the skin, hyperpigmentation, hypertrichosis, organomegaly,
endocrinopathy, anasarca, and clubbing of fingers. These are features
of POEMS syndrome. Levels of vascular endothelial growth factor
(VEGF) are increased in the serum, and this factor is thought to somehow play a pathogenic role in this syndrome. Treatment of the neuropathy is best directed at the osteosclerotic myeloma using surgery,
radiotherapy, chemotherapy, or autologous peripheral blood stem cell
transplantation.
Neuropathies are also encountered in other systemic conditions
with gammopathy, including Waldenström macroglobulinemia, primary systemic amyloidosis, and cryoglobulinemic states (mixed essential cryoglobulinemia, some cases of hepatitis C).
■ MONOCLONAL GAMMOPATHY OF
UNDETERMINED SIGNIFICANCE
Chronic polyneuropathies occurring in association with MGUS are
usually associated with the immunoglobulin isotypes IgG, IgA, and
IgM. Most patients present with isolated sensory symptoms in their
distal extremities and have EDx features of an axonal sensory or
sensorimotor polyneuropathy. These patients otherwise resemble
idiopathic sensory polyneuropathy, and the MGUS might just be coincidental. They usually do not respond to immunotherapies designed
to reduce the concentration of the monoclonal protein. Some patients,
however, present with generalized weakness and sensory loss and EDx
studies indistinguishable from CIDP without monoclonal gammopathy (see “Chronic Inflammatory Demyelinating Polyneuropathy,”
above), and their response to immunosuppressive agents is also similar.
An exception is the syndrome of IgM-kappa monoclonal gammopathy associated with an indolent, long-standing, sometimes static
3508 PART 13 Neurologic Disorders
sensory neuropathy, frequently with tremor and sensory ataxia. Most
patients are men and aged >50 years. In the majority, the monoclonal
IgM immunoglobulin binds to a normal peripheral nerve constituent, MAG, found in the paranodal regions of Schwann cells. Binding
appears to be specific for a polysaccharide epitope that is also found in
other normal peripheral nerve myelin glycoproteins, P0 and PMP22,
and also in other normal nerve-related glycosphingolipids (Fig. 447-1).
In the MAG-positive cases, IgM paraprotein is incorporated into the
myelin sheaths of affected patients and widens the spacing of the
myelin lamellae, thus producing a distinctive ultrastructural pattern.
Demyelination and remyelination are the hallmarks of the lesions, but
axonal loss develops over time. These anti-MAG polyneuropathies are
typical refractory to immunotherapy. In a small proportion of patients
(30% at 10 years), MGUS will in time evolve into frankly malignant
conditions such as multiple myeloma or lymphoma.
VASCULITIC NEUROPATHY
Peripheral nerve involvement is common in polyarteritis nodosa
(PAN), appearing in half of all cases clinically and in 100% of cases
at postmortem studies (Chap. 363). The most common pattern is
multifocal (asymmetric) motor-sensory neuropathy (mononeuropathy
multiplex) due to ischemic lesions of nerve trunks and roots; however,
some cases of vasculitic neuropathy present as a distal, symmetric
sensorimotor polyneuropathy. Symptoms of neuropathy are a common
presenting complaint in patients with PAN. The EDx findings are those
of an axonal process. Small- to medium-sized arteries of the vasa nervorum, particularly the epineural vessels, are affected in PAN, resulting
in a widespread ischemic neuropathy. A high frequency of neuropathy
occurs in eosinophilic granulomatosis with polyangiitis (Churg-Strauss
syndrome [CSS]).
Systemic vasculitis should always be considered when a subacute or
chronically evolving mononeuropathy multiplex occurs in conjunction
with constitutional symptoms (fever, anorexia, weight loss, loss of
energy, malaise, and nonspecific pains). Diagnosis of suspected vasculitic neuropathy is made by a combined nerve and muscle biopsy, with
serial section or skip-serial techniques.
Approximately one-third of biopsy-proven cases of vasculitic neuropathy are “nonsystemic” in that the vasculitis appears to affect only
peripheral nerves. Constitutional symptoms are absent, and the course
is more indolent than that of PAN. The erythrocyte sedimentation rate
may be elevated, but other tests for systemic disease are negative. Nevertheless, clinically silent involvement of other organs is likely, and vasculitis is frequently found in muscle biopsied at the same time as nerve.
Vasculitic neuropathy may also be seen as part of the vasculitis
syndrome occurring in the course of other connective tissue disorders.
The most frequent is rheumatoid arthritis, but ischemic neuropathy
due to involvement of vasa nervorum may also occur in mixed cryoglobulinemia, Sjögren’s syndrome, granulomatosis with polyangiitis
(formerly known as Wegener’s), hypersensitivity angiitis, SLE, and
progressive systemic sclerosis.
Some vasculitides are associated with antineutrophil cytoplasmic
antibodies (ANCAs), which in turn are subclassified as cytoplasmic
(cANCA) or perinuclear (pANCA). cANCAs are directed against
proteinase 3 (PR3), whereas pANCAs target myeloperoxidase (MPO).
PR3/cANCAs are associated with eosinophilic granulomatosis with
polyangiitis, whereas MPO/pANCAs are typically associated with
microscopic polyangiitis, CSS, and less commonly PAN. Of note,
MPO/pANCA has also been seen in minocycline-induced vasculitis.
Management of these neuropathies, including the “nonsystemic”
vasculitic neuropathy, consists of treatment of the underlying condition as well as the aggressive use of glucocorticoids and cyclophosphamide. Use of these immunosuppressive agents has resulted in
dramatic improvements in outcome, with 5-year survival rates now
>80%. Clinical trials found that the combination of rituximab and
glucocorticoids is not inferior to cyclophosphamide and glucocorticoids. Thus, combination therapy with glucocorticoids and rituximab
is recommended as the standard initial treatment, particularly for
ANCA-associated vasculitis. Mepolizumab, an anti-IL-5 monoclonal
antibody, when added to standard care, is also effective for treatment
of eosinophilic granulomatosis with polyangiitis.
ANTI-Hu PARANEOPLASTIC NEUROPATHY
(CHAP. 94)
This uncommon immune-mediated disorder manifests as a sensory
neuronopathy (i.e., selective damage to sensory nerve bodies in dorsal root ganglia). The onset is often asymmetric with dysesthesias
and sensory loss in the limbs that soon progress to affect all limbs,
the torso, and the face. Marked sensory ataxia, pseudoathetosis, and
inability to walk, stand, or even sit unsupported are frequent features
and are secondary to the extensive deafferentation. Subacute sensory
neuronopathy may be idiopathic, but more than half of cases are
paraneoplastic, primarily related to lung cancer, and most of those
are small-cell lung cancer (SCLC). Diagnosis of the underlying SCLC
requires awareness of the association, testing for the paraneoplastic
antibody, and often positron emission tomography (PET) scanning for
the tumor. The target antigens are a family of RNA-binding proteins
(HuD, HuC, and Hel-N1) that in normal tissues are only expressed by
neurons. The same proteins are usually expressed by SCLC, triggering
in some patients an immune response characterized by antibodies and
cytotoxic T cells that cross-react with the Hu proteins of the dorsal root
ganglion neurons, resulting in immune-mediated neuronal destruction. An encephalomyelitis may accompany the sensory neuronopathy
and presumably has the same pathogenesis. Neurologic symptoms
usually precede, by ≤6 months, the identification of SCLC. The sensory
neuronopathy runs its course in a few weeks or months and stabilizes,
leaving the patient disabled. Most cases are unresponsive to treatment
with glucocorticoids, IVIg, PE, or immunosuppressant drugs.
■ FURTHER READING
Amato AA, Ropper AH: Sensory ganglionopathy. N Engl J Med
383:1657, 2020.
Amato AA, Russell JA (eds): Neuromuscular Disorders, 2nd ed.
New York, McGraw-Hill, 2016, pp 320–383.
Beachy N et al: Vasculitic neuropathies. Semin Neurol 39:608, 2009.
Bunschoten C et al: Progress in diagnosis and treatment of chronic
inflammatory demyelinating polyradiculoneuropathy. Lancet Neurol
18:784, 2019.
Fatemi Y et al: Acute flaccid myelitis: A clinical overview for 2019.
Mayo Clin Proc 94:875, 2019.
Guidon AC, Amato AA: COVID-19 and neuromuscular disorders.
Neurology 94:959, 2020.
Leonard SE et al: Diagnosis and management of Guillain-Barré syndrome in ten steps. Nat Rev Neurol 15:671, 2019.
Maramattom BV et al: Guillain-Barre Syndrome following
ChAdOx1-S/nCoV-19 vaccine. Ann Neurol 90:312, 2021.
Puwanant A et al: Clinical spectrum of neuromuscular complications
after immune checkpoint inhibition. Neuromuscul Disord 29:127,
2019.
Toscano G et al: Guillain-Barré syndrome associated with SARSCoV-2. N Engl J Med 382:2574, 2020.
Uncini A, Vallat J-M: Autoimmune nodo-paranodopathies of
peripheral nerve: The concept is gaining ground. J Neurol Neurosurg
Psychiatry 89:627, 2018.
Wijdicks EF, Klein CJ: Guillain-Barré syndrome. Mayo Clin Proc
92:467, 2017.
3509 Myasthenia Gravis and Other Diseases of the Neuromuscular Junction CHAPTER 448
Myasthenia gravis (MG) is a neuromuscular junction (NMJ) disorder
characterized by weakness and fatigability of skeletal muscles. The
underlying defect is a decrease in the number of available acetylcholine
receptors (AChRs) at NMJs due to an antibody-mediated autoimmune
attack. Treatment now available for MG is highly effective, although a
specific cure has remained elusive.
■ PATHOPHYSIOLOGY
At the NMJ (Fig. 448-1, Video 448-1), acetylcholine (ACh) is synthesized in the motor nerve terminal and stored in vesicles (quanta).
When an action potential travels down a motor nerve and reaches the
448
nerve terminal, ACh from 150 to 200 vesicles is released and combines
with AChRs that are densely packed at the peaks of postsynaptic folds.
The AChR consists of five subunits (2α, 1β, 1δ, 1γ, or ε) arranged
around a central pore. When ACh combines with the binding sites on
the α subunits of the AChR, the channel in the AChR opens, permitting
the rapid entry of cations, chiefly sodium, which produces depolarization at the end-plate region of the muscle fiber. If the depolarization is
sufficiently large, it initiates an action potential that is propagated along
the muscle fiber, triggering muscle contraction. This process is rapidly
terminated by hydrolysis of ACh by acetylcholinesterase (AChE),
which is present within the synaptic folds, and by diffusion of ACh
away from the receptor.
In MG, the fundamental defect is a decrease in the number of
available AChRs at the postsynaptic muscle membrane. In addition,
the postsynaptic folds are flattened, or “simplified.” These changes
result in decreased efficiency of neuromuscular transmission. Therefore, although ACh is released normally, it produces small end-plate
potentials that may fail to trigger muscle action potentials. Failure of
transmission results in weakness of muscle contraction.
The amount of ACh released per impulse normally declines on
repeated activity (termed presynaptic rundown). In the myasthenic
Myasthenia Gravis and
Other Diseases of the
Neuromuscular Junction
Anthony A. Amato
Agrin
Voltage-gated
K+ channel
ChAT Choline acetyltransferase
Acetylcholine receptor
SNARE proteins
Syntaxin-1
SNAP 25
Synaptotagmin
Synaptobrevin
Axon
Myelin
sheath
Acetate
Choline
ChAT
Ca+ ions
AChE
Voltage-gated
Na+ channels
Voltage-gated
Ca+ channel
Myofibril
Active zone
A
FIGURE 448-1 Illustrations of (A) a normal presynaptic neuromuscular junction, (B) a normal postsynaptic terminal, and (C) a myasthenic neuromuscular junction. AChE,
acetylcholinesterase. See text for description of normal neuromuscular transmission. The myasthenia gravis (MG) junction demonstrates a reduced number of acetylcholine
receptors (AChRs); flattened, simplified postsynaptic folds; and a widened synaptic space. See Video 448-1 also. (From AA Amato, J Russell: Neuromuscular Disorders,
2nd ed. New York, McGraw-Hill, 2016, Figures 25-3 [p 588], 25-4 [p 589], and 25-5 [p 590]; with permission.)
3510 PART 13 Neurologic Disorders
patient, the decreased efficiency of neuromuscular transmission combined with the normal rundown results in the activation of fewer and
fewer muscle fibers by successive nerve impulses and hence increasing
weakness, or myasthenic fatigue. This mechanism also accounts for the
decremental response to repetitive nerve stimulation seen on electrodiagnostic testing.
MG is an autoimmune disorder most commonly caused by antiAChR antibodies. The anti-AChR antibodies reduce the number of
available AChRs at NMJs by three distinct mechanisms: (1) accelerated
turnover of AChRs by a mechanism involving cross-linking and rapid
endocytosis of the receptors; (2) damage to the postsynaptic muscle
membrane by the antibody in collaboration with complement; and
(3) blockade of the active site of the AChR (i.e., the site that normally
binds Ach). An immune response to muscle-specific kinase (MuSK),
a protein involved in AChR clustering at the NMJ, can also result in
MG, with reduction of AChRs demonstrated experimentally. AntiMuSK antibody occurs in ~10% of patients (~40% of AChR antibody–
negative patients), whereas 1–3% have antibodies to another protein at
the NMJ—low-density lipoprotein receptor-related protein 4 (LRP4)—
that is also important for clustering of AChRs. The pathogenic antibodies are IgG and are T-cell dependent. Thus, immunotherapeutic
strategies directed against either the antibody-producing B cells or
helper T cells are effective in this antibody-mediated disease.
How the autoimmune response is initiated and maintained in MG
is not completely understood, but the thymus appears to play a role
in this process. The thymus is abnormal in ~75% of patients with
AChR antibody–positive MG; in ~65%, the thymus is “hyperplastic,”
with the presence of active germinal centers detected histologically,
although the hyperplastic thymus is not necessarily enlarged. An
additional 10% of patients have thymic tumors (thymomas). Musclelike cells within the thymus (myoid cells), which express AChRs on
their surface, may serve as a source of autoantigen and trigger the
autoimmune reaction within the thymus gland.
■ CLINICAL FEATURES
MG has a prevalence as high as 200 in 100,000. It affects individuals in
all age groups, but peak incidences occur in women in their twenties and
thirties and in men in their fifties and sixties. Overall, women are affected
more frequently than men, in a ratio of ~3:2. The cardinal features are
weakness and fatigability of muscles. The weakness increases during
repeated use (fatigue) or late in the day and may improve following rest or
sleep. The course of MG is often variable. Exacerbations and remissions
may occur, particularly during the first few years after the onset of the
disease. Unrelated infections or systemic disorders can lead to increased
myasthenic weakness and may precipitate “crisis” (see below).
The distribution of muscle weakness often has a characteristic pattern. The cranial muscles, particularly the lids and extraocular muscles
(EOMs), are typically involved early in the course of MG; diplopia
and ptosis are common initial complaints. Facial weakness produces a
“snarling” expression when the patient attempts to smile. Weakness in
chewing is most noticeable after prolonged effort, as in chewing meat.
Speech may have a nasal timbre caused by weakness of the palate or
a dysarthric “mushy” quality due to tongue weakness. Difficulty in
swallowing may occur as a result of weakness of the palate, tongue,
or pharynx, giving rise to nasal regurgitation or aspiration of liquids
or food. Bulbar weakness and more frequent episodes of respiratory
depression can be especially prominent in MuSK antibody–positive
MG. In ~85% of patients, the weakness becomes generalized, affecting
the limb muscles as well. If weakness remains restricted to the EOMs
for 3 years, it is likely that it will not become generalized, and these
patients are said to have ocular MG. The limb weakness in MG is often
proximal and may be asymmetric. Despite the muscle weakness, deep
ACh
(acetylcholine) Vesicle SNARE proteins
Syntaxin-1
SNAP 25
Synaptotagmin
Synaptobrevin
Vesicle
fusion
Agrin
Dystroglycan
Lrp4
MuSK
Dok-7
Rapsyn
δ
Na+ channels Myofibril
ACh
receptor
AChE
α α γ
β
B
ACh
AChE
Vesicle SNARE proteins
Syntaxin-1
SNAP 25
Synaptotagmin
Vesicle Synaptobrevin
fusion
Agrin
Dystroglycan
Lysis of
ACh receptors
Na+ channel
Myofibril
AChR autoantibody
Complement
α α α α
C
FIGURE 448-1 (Continued)
3511 Myasthenia Gravis and Other Diseases of the Neuromuscular Junction CHAPTER 448
tendon reflexes are preserved. If ventilatory weakness becomes requires
respiratory assistance, the patient is said to be in crisis.
■ DIAGNOSIS AND EVALUATION (TABLE 448-1)
The diagnosis is suspected on the basis of weakness and fatigability
in the typical distribution described above, without loss of reflexes or
impairment of sensation or other neurologic function. The suspected
diagnosis should always be confirmed definitively before treatment is
undertaken; this is essential because (1) other treatable conditions may
closely resemble MG and (2) the treatment of MG may involve surgery
and the prolonged use of drugs with potentially adverse side effects.
Ice-Pack Test If a patient has ptosis, application of a pack of ice
over a ptotic eye often results in improvement if the ptosis is due to an
NMJ defect. This is hypothesized to be due to less depletion of quanta
of AChR in the cold and reduced activity of AChE at the NMJ. It is a
quick and easy test to do in the clinic or at the bedside of a hospitalized
patient.
Autoantibodies Associated with MG As previously mentioned,
anti-AChR antibodies are detectable in the serum of ~85% of all myasthenic patients but in only ~50% of patients with weakness confined to
the ocular muscles. The presence of anti-AChR antibodies is virtually
diagnostic of MG, but a negative test does not exclude the disease.
The measured level of anti-AChR antibody does not correspond well
with the severity of MG in different patients. Antibodies to MuSK are
present in ~40% of AChR antibody–negative patients with generalized
MG. MuSK antibodies are rarely present in AChR antibody–positive
patients or in patients with MG limited to ocular muscles. These
antibodies may interfere with clustering of AChRs at NMJs. A small
proportion of MG patients without antibodies to AChR or MuSK
have antibodies to LRP4. Interestingly, antibodies against agrin also
have been found in rare patients with MG. Agrin is a protein derived
from motor nerves that normally binds to LRP4 and is important for
normal clustering of AChRs at NMJ. Additionally, anti-striated muscle
antibodies directed against titin and other skeletal muscle components
are found in ~30% of myasthenics without thymoma, 24% of thymoma
patients without myasthenia, and 70–80% of patients with both
myasthenia and thymoma. Furthermore, antibodies directed against
Netrin-1 receptors and Caspr2 (contactin-associated protein-like 2)
often coexist and are associated in patients with thymoma who have
MG and neuromyotonia or Morvan’s syndrome.
Electrodiagnostic Testing Repetitive nerve stimulation may provide helpful diagnostic evidence of MG. Anti-AChE medication should
be stopped 6–12 h before testing. It is best to test weak muscles or
proximal muscle groups. Electrical stimulation is delivered at a rate of
two or three per second to the appropriate nerves, and action potentials
are recorded from the muscles. In normal individuals, the amplitude of
the evoked muscle action potentials does not change by >10% at these
rates of stimulation. However, in myasthenic patients, there is a rapid
reduction of >10% in the amplitude of the evoked responses.
Anticholinesterase Test Drugs that inhibit the enzyme AChE
allow ACh to interact repeatedly with the limited number of AChRs
in MG, producing improvement in muscle strength. Edrophonium
is used most commonly for diagnostic testing because of the rapid
onset (30 s) and short duration (~5 min) of its effect. An objective end
point must be selected to evaluate the effect of edrophonium, such as
weakness of EOMs, impairment of speech, or the length of time that
the patient can maintain the arms in forward. An initial IV dose of
2 mg of edrophonium is given. If definite improvement occurs, the
test is considered positive and is terminated. If there is no change,
the patient is given an additional 8 mg IV. The dose is administered
in two parts because some patients react to edrophonium with side
effects such as nausea, diarrhea, salivation, fasciculations, and rarely
with severe symptoms of syncope or bradycardia. Atropine (0.6 mg)
should be drawn up in a syringe and ready for IV administration if
these symptoms become troublesome. The edrophonium test is now
reserved for patients with clinical findings that are suggestive of MG
but who have negative antibody, electrodiagnostic testing, or ice-pack
test. False-positive tests occur in occasional patients with other neurologic disorders, such as amyotrophic lateral sclerosis (Chap. 437), and
in placebo-reactors. False-negative or equivocal tests may also occur.
Pulmonary Function Tests (Chap. 284) Measurements of ventilatory function are valuable because of the frequency and seriousness
of respiratory impairment in myasthenic patients.
Differential Diagnosis Other conditions that cause weakness of
the cranial and/or somatic musculature include the nonautoimmune
congenital myasthenia, drug-induced myasthenia, Lambert-Eaton
myasthenic syndrome (LEMS), neurasthenia, hyperthyroidism (Graves’
disease), botulism, intracranial mass lesions, oculopharyngeal dystrophy, and mitochondrial myopathy (Kearns-Sayre syndrome, progressive external ophthalmoplegia). Treatment with immune checkpoint
inhibitors for cancer may also result in autoimmune MG. Myositis and
myocarditis are also often found in combination with MG as a complication of checkpoint inhibitors (Chap. 365). Symptoms typically begin
after the first or second cycle of treatment, with ptosis, diplopia, and
bulbar and occasionally extremity weakness. Patients usually improve
when the immune checkpoint inhibitor is discontinued and a short
course of glucocorticoids or intravenous immunoglobulin (IVIg) is
administered. Treatment with penicillamine (used for scleroderma or
rheumatoid arthritis) has also been associated with MG. Aminoglycoside antibiotics or procainamide can cause exacerbation of weakness
in myasthenic patients; very large doses can cause neuromuscular
weakness in normal individuals.
The congenital myasthenic syndromes (CMS) comprise a rare heterogeneous group of disorders of the NMJ that are not autoimmune but
rather are due to genetic mutations in which virtually any component
of the NMJ may be affected. Alterations in function of the presynaptic
nerve terminal, in the various subunits of the AChR, AChE, or the
other molecules involved in end-plate development or maintenance,
have been identified in the different forms of CMS. These disorders
share many of the clinical features of autoimmune MG, including
weakness and fatigability of proximal or distal extremity muscles
TABLE 448-1 Diagnosis of Myasthenia Gravis (MG)
History
Diplopia, ptosis, dysarthria, dysphagia, dyspnea
Weakness in characteristic distribution: proximal limbs, neck extensors,
generalized
Fluctuation and fatigue: worse with repeated activity, improved by rest
Effects of previous treatments
Physical examination
Evaluation for ptosis at rest and following 1 min of exercise, extraocular
muscles and subjective diplopia, orbicularis oculi and oris strength, jaw
opening and closure
Assessment of muscle strength in neck and extremities
Weakness following repeated shoulder abduction
Vital capacity measurement
Absence of other neurologic signs
Laboratory testing
Anti-AChR radioimmunoassay: ~85% positive in generalized MG; 50% in ocular
MG; definite diagnosis if positive; negative result does not exclude MG; ~40%
of AChR antibody–negative patients with generalized MG have anti-MuSK
antibodies and ~2% have LRP-4 antibodies
Repetitive nerve stimulation: decrement of >10% at 3 Hz: highly probable
Single-fiber electromyography: blocking and jitter, with normal fiber density;
confirmatory, but not specific
Edrophonium chloride (Enlon®) 2 mg + 8 mg IV; highly probable diagnosis if
unequivocally positive
Ice-pack test looking for improvement in ptosis is very sensitive
For ocular or cranial MG: exclude intracranial lesions by CT or MRI
Abbreviations: AChR, acetylcholine receptor; CT, computed tomography; LRP4,
lipoprotein receptor-related protein 4; MRI, magnetic resonance imaging; MuSK,
muscle-specific tyrosine kinase.
3512 PART 13 Neurologic Disorders
and often involving EOMs and the eyelids similar to the distribution
in autoimmune MG. CMS should be suspected when symptoms of
myasthenia have begun in infancy or childhood, but they can present
in early adulthood. As in acquired autoimmune MG, repetitive nerve
stimulation is associated with a decremental response. Some forms
(e.g., AChE deficiency, prolonged open channel syndrome) have a feature of after-discharges that are not seen in MG. An additional clue is
the absence of AChR and MuSK antibodies, although these are absent
in ~10% of generalized MG patients (so-called double seronegative
MG).
The prevalence of CMS is estimated at ~3.8 per 100,000. The most
common genetic defects occur in the ε subunit of the AChR, accounting for ~50% of CMS cases, with mutations in the genes encoding for
rapsin, COLQ, DOK7, agrin, and GFPT together accounting for ~40%.
In most of the recessively inherited forms of CMS, the mutations are
heteroallelic; that is, different mutations affecting each of the two alleles
are present. Features of the most common forms of CMS are summarized in Table 448-2. Molecular analysis is required for precise elucidation of the defect; this may lead to helpful treatment as well as genetic
counseling. Some forms of CMS improve with AChE inhibitors, while
others (e.g., slow channel syndrome, AChE deficiency, DOK7-related
CMS) actually worsen. Fluoxetine and quinidine can be useful for slow
channel syndrome, and albuterol for mutations affecting AChE, DOK7,
rapsyn, and agrin. Additionally, ephedrine and 3,4-diaminopyridine
(3,4-DAP) may be of benefit in some forms of CMS.
LEMS is a presynaptic disorder of the NMJ that can cause weakness
similar to that of MG. The proximal muscles of the lower limbs are
most commonly affected, but other muscles may be involved as well.
Cranial nerve findings, including ptosis of the eyelids and diplopia,
occur in up to 70% of patients and resemble features of MG. However,
TABLE 448-2 Congenital Myasthenic Syndromes (CMS)
CMS SUBTYPE GENE CLINICAL FEATURES
ELECTROPHYSIOLOGIC
FEATURES
RESPONSE TO
ACHE INHIBITORS TREATMENT
Presynaptic Disorders
CMS with paucity of ACh
release
CHAT; CHT AR; early onset, respiratory failure at
birth, episodic apnea, improvement
with age
Decremental response
to RNS
Improve AChE inhibitors; 3,4-DAP
Synaptic Disorders
AChE deficiency COLQ AR; early onset; variable severity;
axial weakness with scoliosis; apnea;
+/– EOM involvement, slow or absent
pupillary responses
After discharges on
nerve stimulation and
decrement on RNS
Worsen Albuterol; ephedrine; 3,4-
DAP; avoid AChE inhibitors
Postsynaptic Disorders Involving AChR Deficiency or Kinetics
Primary AChR deficiency AChR subunit
genes
AR; early onset; variable severity;
fatigue; typical MG features
Decremental response
to RNS
Improve AChE inhibitors; 3,4-DAP
AChR kinetic disorder:
slow channel syndrome
AChR subunit
genes
AD; onset childhood to early adult; weak
forearm extensors and neck; respiratory
weakness; variable severity
After discharges on
nerve stimulation and
decrement on RNS
Worsen Fluoxetine and quinidine;
avoid AChE inhibitors
AChR kinetic disorder:
fast channel syndrome
AChR subunit
genes
AR; early onset; mild to severe; ptosis,
EOM involvement; weakness and
fatigue
Decremental response
to RNS
Improve AChE inhibitors; caution with
3,4-DAP
Postsynaptic Disorders Involving Abnormal Clustering/Function of AChR
DOK 7 AR; limb girdle weakness with ptosis
but no EOM involvement
Decremental response
to RNS
Variable Albuterol; ephedrine; may
worsen with AChE inhibitors
Rapsyn AR; early onset with hypotonia,
respiratory failure, and arthrogryposis
at birth to early adult onset resembling
MG
Decremental response
to RNS
Variable Albuterol
Agrin AR; limb girdle or distal weakness,
apnea
Decremental response
to RNS
Variable Albuterol; may worsen with
AChE inhibitors
MuSK AR; congenital or childhood onset of
ptosis, EOM and progressive limb girdle
weakness
Decremental response
to RNS
Variable Variable response to AChE
inhibitors and 3,4-DAP
Positive response to
albuterol
LRP4 AR; congenital onset with hypotonia;
ventilatory failure, mild ptosis, and EOM
weakness
Decremental response
to RNS
Worsen Worsen with AChE inhibitors
Other Postsynaptic Disorders
Limb-girdle CMS with
tubular aggregates
GFPT1; DPAGT1;
ALG2;
ALG14;
DPAGT1
AR; limb-girdle weakness usually
without ptosis or EOM weakness; onset
in infancy or early adult
Decremental response
to RNS
Variable Albuterol; ephedrine;
variable response to AChE
inhibitors and 3,4-DAP;
albuterol
Congenital muscular
dystrophy with
myasthenia
Plectin AR; infantile or childhood onset of
generalized weakness including
ptosis and EOM; epidermolysis bullosa
simplex; elevated CK
Decremental response
to RNS
Variable No response to AChE and
3,4-DAP
Abbreviations: ACh, acetylcholine; AChE, acetylcholinesterase; AChR, acetylcholine receptor; AD, autosomal dominant; AR, autosomal recessive; CHAT, choline acetyl
transferase; CHT, sodium-dependent high-affinity choline transport 1; CK, creatine kinase; CMA, congenital myasthenic syndrome; COLQ, collaganic tail of endplate
acetylcholinesterase; 3,4-DAP, 3,4-diaminopyridine; Dok7, downstream of tyrosine kinase 7; DPAGT1, UDP-N-acetylglucosamine-dolichyl-phosphate N-acetylglucosamine
phosphotransferase; EOM, extraocular muscle; GFPT1, glutamine-fructose-6-phosphate aminotransferase 1; LRP4, lipoprotein receptor-related protein 4; MG, myasthenia
gravis; MuSK, muscle specific kinase; RNS, repetitive nerve stimulation.
Source: From AA Amato, J Russell: Neuromuscular Disorders, 2nd ed. McGraw-Hill, 2016, Table 26-2, p. 627; with permission.
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