IM Neurology 1 (3) PDF

Summary

This document provides an overview of several neurological conditions including Huntington's Disease, Myasthenia Gravis, and Encephalitis, discussing their various aspects like etiology, symptoms, diagnosis, physical examination, and management. It also briefly touches upon Hepatic Encephalopathy.

Full Transcript

Neurology 1
PHAS 6340: INTERNAL MEDICINE
 Huntington
Disease

Gradual onset and progression
of chorea and dementia or
behavioral change
Inherited in an autosomal
dominant manner and occurs
throughout the world
 Huntington
Disease
Etiology is Genetic:
 Inherited
in an
autosomal dominant
manner and occurs
throughout the world
 The gene responsible
for the disease has
been located on the
short arm of
chromosome 4
Huntington
Disease
Symptoms
May consist of either abnormal movements or
intellectual changes
However, both ultimately occur
Earliest mental changes
Often behavioral, with irritability, moodiness,
antisocial behavior, or psychiatric disturbance
However, a more obvious dementia subsequently
develops
Huntington
Disease
Dyskinesia
May initially be no more than an apparent
fidgetiness or restlessness
However, choreiform movements and some
dystonic posturing eventually occur
A parkinsonian syndrome with progressive
rigidity and akinesia (rather than chorea)
sometimes occurs in association with dementia,
especially in cases with childhood onset
 Huntington
Disease
Diagnosis:
Genetic testing
permits
presymptomatic
detection and
definitive diagnosis
of the disease
Offspring of
patients diagnosed
with Huntington’s
disease should be
offered genetic
counseling
Huntington Disease
 Imaging Studies
CT scanning or MRI
usually demonstrates
cerebral atrophy and
atrophy of the caudate
nucleus in established
cases
Positron emission
tomography (PET) has
shown reduced striatal
metabolic rate
Huntington Disease

Prognosi
Treatment s
Dopamine receptor
There is no cure for Huntington
blockers, such as disease
phenothiazines or
Progression cannot be halted
haloperidol, may control
Treatment is purely
the dyskinesia and any symptomatic
behavioral disturbances
The disease is usually fatal
within 15–20 years
 Huntington Disease

Management
 Allpatients should be referred to
neurology and, ultimately, to one of
the 50 U.S. Huntington's Disease
Centers of Excellence
Multi-disciplinary care teams
that have expertise in
Huntington disease
All share an exemplary
commitment to providing
comprehensive care
Myastheni
a Gravis
Fluctuating weakness of voluntary muscles
The external ocular muscles and certain
other cranial muscles, including the
masticatory, facial, and pharyngeal
muscles, are especially likely to be
affected
Myasthenia
Gravis

Pathophysiology

Symptoms are due to
blocks of neuromuscular
transmission caused by
autoantibodies binding to
acetylcholine receptors

Can be associated with the
presence of a thymoma
 Myasthenia
gravis

Symptoms:
Weakness
 May remain localized to a few muscle groups,
especially the ocular muscles
 May become generalized
Myasthenia Gravis

 Symptoms often fluctuate in  The bulbar and limb muscles are
intensity during the day often weak, but the pattern of
 involvement is variable
Sustained activity of 
affected muscles increases Bulbar (oropharyngeal) weakness

the weakness, which Fatigue with prolonged
improves after a brief rest chewing
  Dysphagia
Respiratory muscle
weakness may lead to  Dysphonia
respiratory failure  Dysarthria
(Myasthenia crisis)
Myasthenia Gravis

Physical exam Diagnosis
 Sensation is normal  Initial test of choice is
 Acetylcholine receptor
Usually no reflex changes
antibody assay
 Ice pack test  Repetitive nerve stimulation
 Applicationof ice pack (electrophysiology) and single
for 10 minutes fiber electromyography
improves ocular (SFEMG) are the most acute
symptoms tests
 Myasthenia Gravis

 Long term Treatment
 Acetylcholinesterase
inhibitors
provide symptomatic relief (first line
option)
 Neostigmine

 Pyridostigmine

 Treatment of severe disease or
Myasthenic crisis
 IVIG (intravenous immunoglobulin)
 Plasmapheresis
 Myasthenia
Gravis
 Surgery
 Thymectomy
 Usuallyleads to symptomatic
benefit or remission
 Should be considered in all
patients younger than age 65
unless weakness is restricted to
the extraocular muscles
 Avoid medications known to worsen MG
 Aminoglycosides, Fluoroquinolones,
Beta Blockers
Lambert-Eaton
Myasthenic
syndrome
Defective release
of acetylcholine in
response to a
nerve impulse,
leading to
weakness,
especially of the
proximal muscles
of the limbs
Lambert-Eaton
Myasthenic
syndrome
May be associated
with small-cell
carcinoma,
sometimes
developing before
the tumor is
diagnosed, and
occasionally occurs
with certain
autoimmune
diseases
Lambert-Eaton Myasthenic syndrome

Clinical
findings Diagnosis
Variable weakness, typically improving with  Electrophysiologic
activity
testing
Dysautonomic symptoms may also be
 Serological
present
A history of malignant disease may be
testing P/Q type
obtained voltage-gated
Unlike myasthenia gravis, power steadily calcium channel
increases with sustained contraction antibody assay
 Lambert-Eaton
Myasthenic
syndrome
Treat the
underlying
malignancy
Symptomatic
management
Amifampridine
IVIG/
plasmapheresis
Encephalitis
 Encephalitis is defined as an inflammation of the
brain caused either by infection, usually with a virus,
or from a primary autoimmune process.
 Similar to meningitis, encephalitis is typically an
acute febrile illness.
 The patient with encephalitis commonly has an
altered level of consciousness (confusion, behavioral
abnormalities), or a depressed level of consciousness
ranging from mild lethargy to coma, and evidence of
either focal or diffuse neurologic signs and
symptoms.
Encephalitis

 Virtually every possible type of focal neurologic
disturbance has been reported in viral encephalitis;
the signs and symptoms reflect the sites of infection
and inflammation.
 Patients with encephalitis may have hallucinations,
agitation, personality change, behavioral disorders,
and, at times, a frankly psychotic state. Focal or
generalized seizures occur.
 Encephaliti
s
Hundreds of viruses are capable of causing
encephalitis, although only a limited subset is
responsible for most cases in which a specific
cause is identified. Herpes Simplex Virus 1 is
the most commonly identified virus

Some commonly identified
Viruses *
HSV1, HSV2, Human herpes virus 6 West Nile virus

HIV, Cytomegalovirus, Epstein-Barr St Louis encephalitis
virus virus

Varicella-zoster virus Zika

Enteroviruses La Crosse virus
Arthropod-borne viruses
 Encephalitis
 Physical exam
 Focal neurological deficits
Hemiparesis

Sensory deficits
Cranial nerve palsies
Exaggerated deep tendon reflexes
Myoclonus

Tremor

Ataxia
 Encephaliti
s
 Diagnosis
 Lumbar puncture:
 The characteristic CSF profile is
indistinguishable from that of viral
meningitis and typically consists of
a lymphocytic pleocytosis, a mildly
elevated protein concentration, and
a normal glucose concentration.
 PCR testing of CSF can identify the
cause
 CT scan should be performed to rule
out space occupying lesions
 Encephaliti
s
 Vital functions, including respiration
and blood pressure, should be
monitored continuously and
supported as required. In the initial
stages of encephalitis, many
patients will require care in an
intensive care unit.
 Acyclovir is of benefit in the
treatment of HSV and should be
started empirically in patients with
suspected viral encephalitis,
especially if focal features are
present, while awaiting viral
diagnostic studies.
Encephalopathies
Encephalopathies
Encephalopathy refers to altered
brain function in the absence of
inflammation.

Encephalitis is an infection of the
brain parenchyma predominantly
caused by viruses.
Encephalopathies

Common manifestations of
encephalopathy include confusion,
personality changes,
disorientation, aphasia, delirium,
and dementia.

In general, patients with
encephalopathy do not have fever,
headache, seizures, focal
neurologic signs, and an increased
wbc count in the blood and spinal
fluid, whereas patients with
encephalitis often do.
Encephalopathies

Common manifestations of
encephalopathy include confusion,
personality changes,
disorientation, aphasia, delirium,
and dementia.

In general, patients with
encephalopathy do not have fever,
headache, seizures, focal
neurologic signs, and an increased
wbc count in the blood and spinal
fluid, whereas patients with
encephalitis often do.
 Hepatic Encephalopathy

 A state of disordered central
nervous system function resulting
from failure of the liver to detoxify
noxious agents of gut origin
because of hepatocellular
dysfunction and portosystemic
shunting
 Generally occurs in patients with
cirrhosis or acute liver failure
(sometimes both)
 Hepatic Encephalopathy

 Ammonia is the most readily identified toxin but
is not solely responsible for the disturbed
mental status
 Hepatic Encephalopathy

 Precipitants of hepatic
encephalopathy
Gastrointestinal (GI) bleeding—
increases protein in the bowel and
rapidly precipitates hepatic
encephalopathy
Constipation
Alkalosis
Potassium deficiency induced by
diuretics
 Hepatic Encephalopathy

 Precipitants of hepatic
encephalopathy
Opioids, hypnotics, and sedatives
Medications containing
ammonium or amino compounds
Paracentesis with consequent
hypovolemia
Hepatic or systemic infection
Portosystemic shunts
 Hepatic Encephalopathy

 Signs
Day–night reversal
Asterixis, tremor, dysarthria
Delirium
Drowsiness, stupor, and
ultimately coma
 Hepatic Encephalopathy

 Diagnosis:
Liver biochemical tests often
consistent with advanced chronic
liver disease
Serum (and cerebrospinal fluid)
ammonia level is generally elevated
 Ultimately a clinical diagnosis
supported by asterixis, elevated
serum ammonia with exclusion of
other causes of delirium
 Hepatic Encephalopathy

 Treatment
 Lactulose in most patients
 Withhold dietary protein during acute
episodes
 If due to GI bleeding
 Purge blood from the GI tract with
120 mL of magnesium citrate by
mouth or nasogastric (NG) tube
every 3–4 hours until the stool is
free of gross blood
 Hepatic Encephalopathy

 Prevention of reoccurrence:
When the patient resumes oral intake,
protein intake should be restricted to 60–80
g/day as tolerated, and vegetable protein is
better tolerated than meat protein
Continued use of lactulose after an
episode of acute encephalopathy
reduces the frequency of recurrences
  This is a special type of
nonicteric hepatic
encephalopathy occurring in
Reye children and adolescents and
characterized by acute brain
Syndrome swelling in association with fatty
infiltration of the viscera,
AKA Reye-Johnson
particularly the liver.
syndrome
 Rare but very dangerous
encepholapthy with a mortality
rate of 21%
  The cause is unknown but may
be related to viruses, vaccines,
Aspirin and possibly congenital
metabolic disorders.
Reye
 Illness begins with protracted
Syndrome vomiting and delirium, which
progresses to coma within 2
AKA Reye-Johnson
syndrome days. Seizures are common but
are usually self-limited.
 Sustained hyperventilation and
hepatomegaly are usually noted.
 Wernicke Encephalopathy
 Wernicke encephalopathy is
characterized by confusion, ataxia,
and nystagmus leading to
ophthalmoplegia (lateral rectus
muscle weakness, conjugate gaze
palsies); peripheral neuropathy
may also be present.
 It is due to thiamine deficiency and
in the United States occurs most
commonly in patients with alcohol
use disorder.
 Wernicke Encephalopathy

 In suspected cases, thiamine (100 mg) is
given intravenously immediately and then
intramuscularly on a daily basis until a
satisfactory diet can be ensured after
which the same dose is given orally.
 The diagnosis is confirmed by the
response in 1 or 2 days to treatment,
which must not be delayed while awaiting
laboratory confirmation of thiamine
deficiency from a blood sample obtained
prior to thiamine administration.
 Korsakoff Syndrome

 Occurs in more severe cases of
Wernicke encephalopathy

 It includes anterograde and
retrograde amnesia and sometimes
confabulation and may not be
recognized until after the initial
delirium has lifted.
Chronic traumatic
encephalopathy
 Chronic
traumatic
encephalopathy
(CTE) is a
disease that
causes brain
tissue to break
down over time.
 Repeated head
injuries have
caused all cases
of CTE so far.
Anoxic encephalopathy

 Anoxic encephalopathy, or  Common causes:
hypoxic-ischemic brain  carbon monoxide poisoning
injury, is a process that  drug overdose
begins with the cessation of
 vascular injury or insult
cerebral blood flow to brain
tissue  cardiac arrest
Hypercapnic pulmonary disease

Diseases of the lungs or medullary respiratory centers cause
permanent respiratory acidosis.
 Symptoms:
 headache, papilledema, mental dullness, drowsiness,
confusion, stupor and coma, and asterixis
 Prognosis
 Unlike pure hypoxic encephalopathy, prolonged coma
because of hypercapnia is relatively rare and unlikely to
lead to irreversible brain damage.
Hypertensive
encephalopathy

One of the types of
end organ damage in
hypertensive
emergency
Without treatment,
there may be cerebral
ischemia, hemorrhage,
or both, with focal
cerebral symptoms or
signs.
Hypertensive
encephalopathy

Hypertensive encephalopathy is one
of several forms of
posterior reversible encephalopathy
syndrome (PRES), a syndrome also
encompassing other etiologies,
including renal failure,
immunosuppressive therapy, and
eclampsia.
Posterior reversible
encephalopathy
syndrome (PRES)
An illness in which a person can
present with acutely altered
mentation, drowsiness or sometimes
stupor, visual impairment (e.g., visual
hallucinations, cortical blindness,
hemianopia, quadrantanopia, and
diplopia), seizures (focal or general
tonic-clonic), and sudden or constant,
non-localized headaches.
  Symptoms appear when the
blood glucose has descended
to about 30 mg/dL,
nervousness, hunger, flushed
facies, sweating, headache,
Hypoglycemic palpitation, trembling, and
encephalopathy anxiety.
 These gradually give way to
confusion and drowsiness or
occasionally, to excitement,
overactivity, and bizarre or
combative behavior.
  Blood glucose levels of
approximately 10 mg/dL are
associated with deep coma,
dilatation of pupils, pale
Hypoglycemic
skin, shallow respiration,
encephalopathy slow pulse, and hypotonia,
what had in the past been
termed the “medullary
phase” of hypoglycemia.
Common causes of hypoglycemic encephalopathy

Depletion of liver
glycogen, which
Accidental or occasionally follows
deliberate Islet cell insulin- a prolonged
overdose of insulin secreting tumor of
or an oral diabetic the pancreas alcoholic binge,
agent starvation, or any
form of severe liver
failure
 Uremia is a clinical condition associated
with declining renal function and is
characterized by fluid overload, electrolyte
imbalances, metabolic abnormalities, and
physiological changes.

Uremic
encephalopathy Urea exhibits direct and indirect toxicity to
various tissues, notably affecting the
neurological system. Urea acts as a
marker for uremic toxins in general, with
over 100 substances identified as potential
uremic toxins, which are present in varying
concentrations in the blood.
 Apathy, fatigue, inattentiveness, and
irritability are usually the initial
symptoms; later, there is confusion,
dysarthria, tremor, and asterixis.

Uremic Infrequently, this takes the form of a
encephalopathy toxic psychosis, with hallucinations,
delusions, insomnia, or catatonia

As the uremia worsens, the patient
lapses into a quiet coma. Unless the
accompanying metabolic acidosis is
corrected, Kussmaul breathing appears
and gives way to Cheyne-Stokes
breathing and death.
 Apathy, fatigue, inattentiveness, and
irritability are usually the initial
symptoms; later, there is confusion,
dysarthria, tremor, and asterixis.

Uremic Infrequently, this takes the form of a
encephalopathy toxic psychosis, with hallucinations,
delusions, insomnia, or catatonia

As the uremia worsens, the patient
lapses into a quiet coma. Unless the
accompanying metabolic acidosis is
corrected, Kussmaul breathing appears
and gives way to Cheyne-Stokes
breathing and death.
Cranial nerve
palsies
 OLFACTORY NERVE (CN I): PROVIDING THE SENSE OF SMELL.
OPTIC NERVE (CN II): PROVIDING VISION.
OCULOMOTOR NERVE (CN III): OPENING AND MOVING YOUR EYES AND
ADJUSTING PUPIL WIDTH.
TROCHLEAR NERVE (CN IV): LOOKING DOWN AND MOVING YOUR EYES
TOWARD YOUR NOSE OR AWAY FROM IT.
TRIGEMINAL NERVE (CN V): PROVIDING SENSATIONS IN YOUR EYES, MOST
OF YOUR FACE AND INSIDE YOUR MOUTH. IT ALSO ALLOWS YOU TO CHEW
FOOD.
There are 12 ABDUCENS NERVE (CN VI): MOVING YOUR EYES FROM LEFT TO RIGHT.

Cranial nerves FACIAL NERVE (CN VII): CONTROLLING SEVERAL FACIAL MUSCLES TO MAKE
FACIAL EXPRESSIONS AND PROVIDING THE SENSE OF TASTE IN PART OF YOUR
TONGUE.
but only some VESTIBULOCOCHLEAR NERVE (CN VIII): PROVIDING THE SENSE OF HEARING

of them control
AND BALANCE.
GLOSSOPHARYNGEAL NERVE (CN IX): PROVIDING TASTE SENSATIONS TO

motor function
PART OF YOUR TONGUE AND CONTROLLING MUSCLES FOR SWALLOWING. IT
ALSO HAS PARASYMPATHETIC NERVE FIBERS THAT PLAY A ROLE IN
BLOOD PRESSURE REGULATION AND SALIVA (SPIT) PRODUCTION.
VAGUS NERVE (CN X): REGULATING SEVERAL AUTOMATIC BODILY
PROCESSES, INCLUDING YOUR DIGESTION, BLOOD PRESSURE, HEART RATE,
BREATHING, MOOD, SALIVA PRODUCTION AND MORE. IT’S THE MAIN NERVE OF
YOUR PARASYMPATHETIC NERVOUS SYSTEM.
ACCESSORY NERVE OR SPINAL ACCESSORY NERVE (CN
XI): CONTROLLING SHOULDER AND NECK MOVEMENT.
HYPOGLOSSAL NERVE (CN XII): CONTROLLING TONGUE MOVEMENT, WHICH
PLAYS A ROLE IN SPEAKING, EATING AND SWALLOWING.
A ROLE IN SPEAKING, EATING AND SWALLOWING.
CN III: Occulomotor
nerve
 The somatic efferent portion of the
nerve innervates the levator
palpebrae superioris muscle;
the superior, medial, and inferior
rectus muscles; and the inferior
oblique muscle.
 The visceral efferent portion
innervates two smooth intraocular
muscles: the ciliary and
the constrictor pupillae.
CN III: Occulomotor
nerve

In a complete third
nerve palsy, there is
ptosis with a
divergent and slightly
depressed eye.
Extraocular
movements are
restricted in all
directions except
laterally (preserved
lateral rectus
function)
CN III: Occulomotor
nerve
Pupillary involvement,
manifesting as a relatively
dilated pupil that does not
constrict normally to light

Causes of isolated third nerve
palsy without pupillary
involvement include diabetes
mellitus, hypertension, giant cell
arteritis, and herpes zoster.
CN IV: Trochlear nerve

 The trochlear nerve innervates the superior
oblique muscle.
 is the only crossed cranial nerve. It originates
from the trochlear nucleus, crosses within the
midbrain, and then emerges contralaterally on
the dorsal surface of the brain stem.
 The trochlear nerve enters the orbit via the
superior orbital fissure from where it innervates
the superior oblique muscle
CN IV: Trochlear nerve
 Fourth nerve
palsy causes upward
deviation of the eye with
failure of depression on
adduction. In acquired
cases, there is vertical and
torsional diplopia that is
most apparent on looking
down.
CN IV: Trochlear nerve

 For superior oblique palsies, the
patient tilts the head away from the
side of the palsy, and the diplopia
worsens with downgaze away from
the side of the affected eye
 In Brown’s syndrome, the
superior oblique is restricted in the
trochlea, causing inability to
elevate the eye in adduction
CN VI: Abducens nerve
 The abducens nerve arises from neurons of
the abducens nucleus , emerges from the
pontomedullary fissure, passes through
the cavernous sinus close to the internal
carotid, and exits from the cranial cavity
via the superior orbital fissure.
 Its long intracranial course makes it
vulnerable to pathologic processes in the
posterior and middle cranial fossae.
 The nerve innervates the lateral rectus
muscle
CN VI: Abducens nerve
 Sixth nerve palsy causes convergent
squint in the primary position with
failure of abduction of the affected
eye, producing horizontal diplopia
that increases on gaze to the
affected side and on looking into the
distance
 It is an important sign of raised
intracranial pressure and may also
be due to trauma, neoplasms,
brainstem lesions, petrous apex
lesions, or medical causes (such as
diabetes mellitus, hypertension,
giant cell arteritis, and herpes
zoster).
Management of cranial nerve palsies

 In recent-onset isolated  All patients with recent-
third nerve palsy, especially onset double vision should
if there is pupillary be referred urgently to a
involvement or pain, neurologist or
immediate referral is ophthalmologist,
required for neurologic
assessment and possibly particularly if there are
CT, MRI, or catheter multiple cranial nerve
angiography for intracranial dysfunctions or other
aneurysm. neurologic abnormalities.
Case

 A 56-year-old white male with a history of The most likely diagnosis is
hypertension and diabetes complains of double which of the following?
vision and pain for the past 2 days. On
examination, his vision is OD 20/50 and OS 20/25.
He has a larger pupil with a RAPD OD. A. First nerve palsy
 The lid of his right eye is slightly lower than the
left. His right eye is deviated slightly temporally
B. Fourth nerve palsy
and inferiorly, and he has difficulty adducting and
elevating the eye. C. Third nerve palsy
 The most likely diagnosis is which of the
following? D. Sixth nerve palsy
The end