Goljy 26: Nervous System and Special Sensory Disorders

Question 1

intracellular edema

Answer 1

water moves into cells
caused by:
1. dysfunctional Na+/K+-ATPase pump
2. Hyponatremia causing osmotic shift

Question 2

extracellular edema

Answer 2

d/t increased vessel permeability
caused by:
1. acute inflammation
2. metastasis, trauma, lead poisoning

Question 3

Why is a person with head trauma purposely hyperventilated?

Answer 3

• to produce respiratory alkalosis –> cerebral vessel constriction
• decreases risk of increased vessel permeability and edema

Question 4

What effect do respiratory acidosis and hypoxemia have on cerebral vessels?

Answer 4

• vasodilation –> increased vessel permeability –> edema

Question 5

Signs of increased intracranial pressure

Answer 5

1. papilledema
2. headache, projectile vomiting w/o nausea
3. sinus bradycardia, hypertension
4. potential for herniation

Question 6

pseudotumor cerebri

Answer 6

• increased intracranial pressure without evidence of tumor/obstruction d/t decreased CSF resorption in arachnoid villi (equilibration in inflow/outflow eventually occurs)
• papilledema is present, no mental status change/focal neurologic signs
• MC young obese women, other risks: ATRA used for APML, hypothyroid, Cushing disease, BC pills, isotretinoin, tamoxifen

Question 7

pseudotumor cerebri Sx, Dx, Tx

Answer 7

Sx: headache, rhythmic sound in one/both ears, diplopia, blurry vision

Dx: MRI - flattening of posterior globe
CSF pressure increased, decreased CSF protein

Tx: carbonic anhydrase inhibitor or systemic corticosteroids if visual disturbances present, lumboperitoneal shunt, optic nerve sheath fenestration

Question 8

cerebral herniation

Answer 8

a complication of intracranial hypertension where portions of the skull become displaced through either openings in the dural partitions or openings of the skull

Question 9

subfalcine herniation

Answer 9

• cingulate gyrus herniates under the falx cerebri

- herniation causes compression of the anterior cerebral artery

Question 10

uncal herniation

Answer 10

• medial portion of the temporal lobe herniates through the tentorium cerebelli
• Can cause:
  1. Compression of the midbrain –> Duret hemorrhage
  2. Compression of CN III –> eye deviates down and out, pupil is dilated d/t compression of parasympathetic postganglionic fibers
  3. compression of posterior cerebral artery –> hemorrhagic infarction of occipital lobe

Question 11

tonsillar herniation

Answer 11

• cerebellar tonsils herniate into foramen magnum
• “coning” of cerebellar tonsils
• cardiorespiratory arrest

Question 12

hydrocephalus

Answer 12

increase in CSF volume –> enlargement of ventricles

Question 13

production and movement of CSF

Answer 13

• produced by choroid plexus in ventricles
• exists fourth ventricle thru foramina of Luschka and Magendia and enters subarachnoid space
• reabsorbed by arachnoid villus into dural venous sinuses

Question 14

Communicating hydrocephalus

Answer 14

• open communication btwn ventricles and subarachnoid space
• Causes:
  1. increased CSF production
  2. obstruction in reabsorption of CSF by arachnoid villi

Question 15

Noncommunicating hydrocephalus

Answer 15

• obstruction of CSF flow out of ventricles
• Causes:
  1. stricture of aqueduct of Sylvius
• MCC in newborns –>paralysis of upward gaze
• pineal gland tumor
  2. Tumor in fourth ventricle
  3. scarring at base of brain
  4. colloid cyst in 3rd ventricle
  5. various developmental disorders

Question 16

Clinical findings in hydrocephalus

Answer 16

Newborns: ventricles dilate and enlarge head circumference

Adults: ventricles enlarge but NO increase in head circumference

Question 17

hydrocephalus ex vacuo

Answer 17

• dilated appearance of the ventricles when the brain mass is decreased from cerebral atrophy, eg. Alzheimer’s

Question 18

Normal pressure hydrocephalus

Answer 18

Dilated ventricles and “wet wide and wacky” sx:

• urinary incontinence
• wide based gait
• dementia

Causes:
idiopathic
secondary to subarachnoid hemorrhage, intracranial surgery, trauma

Question 19

Pathogenesis of normal pressure hydrocephalus

Answer 19

• subarachnoid space volume is increased
• ventricular dilation is out of proportion to sulcal atrophy
• wide based gait and urinary incontinence d/t stretching of sacral nerve fibers near dilated ventricle
• dementia d/t stretching of limbic fibers near dilated ventricle

Question 20

normal pressure hydrocephalus dx and tx

Answer 20

Dx: MRI shows ventriculomegaly, sulcal atrophy
Large volume of CSF is removed at lumbar puncture, symptoms improve w/ removal of fluid

Tx: ventriculoperitoneal or ventriculoatrial shunt

Question 21

Neural tube defect

Answer 21

• Failure of the fusion of the lateral folds of the neural plate
• Rupture of a previously closed neural tube
• Maternal folic acid levels must be adequate BEFORE pregnancy to prevent open neural tube defects

Question 22

Maternal findings in neural tube defect

Answer 22

Increased maternal AFP in serum and/or amniotic fluid in anancephaly, meningocele, or myelomeningocele but NOT spina bifida occulta

Question 23

Anancephaly

Answer 23

• complete absence of the brain
• frog-like appearance
• open spinal canal
• maternal polyhydramnios

Question 24

Spina bifida occulta

Answer 24

• defect in closure of the posterior vertebral arch

- dimple or tuft of hair in the skin overlying L5-S1

Question 25

meningocele

Answer 25

• spina bifida with cystic mass containing meninges

- MC in lumbosacral region

Question 26

meningomyelocele

Answer 26

• spina bifida with cystic mass containing meninges and spinal cord
• MC in lumbosacral region

Question 27

Arnold-Chiara malformation

Answer 27

• caudal extension of the medulla and cerebellar vermis through foramen magnum
• noncommunicating hydrocephalus
• platybasia
• a/w meningomyelocele, syringomyelia
• Tx: decrompression surgery

Question 28

Dandy-Walker malformation

Answer 28

• partial or complete absence of the cerebellar vermis
• cystic dilation of the fourth ventricle
• noncommunicating hydrocephalus
• Tx: shunt to treat hydrocephalus

Question 29

syringomyelia

Answer 29

• degenerative disease of the spinal cord
• Sx usually appear in 3rd of 4rd decade
• fluid-filled cavity (syrinx) within cervical spinal cord
• produces cervical cord enlargement
• cavity expands and causes degeneration of spinal tracts

Question 30

Pathogenesis of syringomyelia

Answer 30

• obstruction of outflow from fourth ventricle

- birth injury

Question 31

Clinical findings in syringomyelia

Answer 31

• disruption of the crossed lateral spinothalamic tracts –> pain and temp lost in the hands, tactile sense preserved
• destruction of anterior horn cells –> atrophy of intrinsic muscle of the hands, often confused with ALS
• Charcot joint in shoulder, elbow, or wrist

Question 32

Dx and Tx of syringomyelia

Answer 32

Dx: MRI shows enlarged cervical cord and a cystic cavity

Tx: drainage of syrinx slows progression

Question 33

Phakomatoses

Answer 33

• neurocutaneous syndromes including:
  1. disordered growth of ectodermal tissue
  2. malformationf or tumors of the CNS

Question 34

Neurofibromatosis

Answer 34

AD w/ incomplete penetrance, no gender predominance

• Type 1: MC, mutation on chromosome 17 coding for neurofibromin
• Type 2: mutation on chromosome 22 coding for merlin

Question 35

NF1

Answer 35

• cafe au lait spots
• optic gliomas
• Lisch nodules
• axillary and inguinal freckling
• mild scoliosis
• pigmented plexiform neurofibromas
• pigmented cutaneous/subcutaneous neurofibromas

a/w: pheochromocytoma, Wilms tumor, juvenile CML

Question 36

NF2

Answer 36

a/w bilateral acoustic neuromas (CN8 benign tumor –> hearing loss, tinnitis), meningiomas, spinal schwannomas, juvenile cataracts

Question 37

Tuberous sclerosis

Answer 37

AD, mental retardation and seizures beginning in infancy

• angiofibromas on the face
• hypopigmented skin lesions called shagreen patches/ash leaf spots
• subungal or periungal fibromas
• hamartomas: astrocyte proliferations, angiomyolipomas in kidneys, rhabdomyoma in the heart

Question 38

Sturge- Weber syndrome

Answer 38

• somatic mosacism or sporadic
• vascular malformation on the face in trigem nerve distribution
• some patients have ipsilateral AV malformation in meninges

Question 39

cerebral contusion

Answer 39

permanent damage to small blood vessels and the surface of the brain, most often secondary to an acceleration-deceleration injury

Question 40

Coup injury

Answer 40

occurs at site of impact

Question 41

Contrcoup injury

Answer 41

occurs opposite the site of impact, MC tips of frontal and temporal lobes

Question 42

epidural hematoma

Answer 42

• arterial bleed creates a blood-filled space between the bone and dura
• caused by a fracture of the temporoparietal bone –> severance of the middle meningeal artery
• increased ICP –> herniation and death
• Dx: CT
• hematoma rarely crosses suture line
• Tx: burr holes to relieve pressure

Question 43

subdural hematoma

Answer 43

• venous bleeding between the dura and arachnoid membranes
• MC d/t blunt trauma, also: medical anticoagulation, hemophilia, child abuse, spontaneous
• Risk factors: old people and alcoholics with brain atrophy
• tear in bridging veins between brain and dural sinuses are torn, causes venous blood clot
• herniation and death, chronic: dementia
• Tx: burr holes to relieve pressure

Question 44

3 categories of cerebrovasular diseases:

Answer 44

1. thrombosis
2. infarction
3. hemorrhage

Question 45

Causes of cerebrovascular disease:

Answer 45

• Reduced blood supply and O2 of tissue

- CNS hemorrhage from rupture of cerebral vessels

Question 46

Global hypoxic injury

Answer 46

Causes: cardiac arrest, hypovolemic shock, septic shock, CO poisoning

Complications: cerebral atrophy (necrosis of neurons in layers 3, 5, 6 of cerebral cortex), Watershed infarcts at the junctions of arterial territories, stroke

Question 47

Stroke

Answer 47

sudden loss of blood circulation to an area of the brain resulting in a loss of neurologic function
- risk increases w/ age

Question 48

Atherosclerotic stroke

Answer 48

MC type of stroke

• ischemic type of stroke caused by a platelet thrombosis that develops over a disrupted atherosclerotic plaque
• Common locations: MCA, internal carotid artery near bifurfaction, basilar artery
• Prevention: aspirin, clopidogrel

Question 49

Gross/microscopic findings in atherosclerotic stroke

Answer 49

1. Develops at the periphery of the cerebral cortex –> pale infarct
2. Swelling of the brain, loss of demarcation btwn grey and white matter, myelin breakdown
3. Gliosis
4. Cystic area develops after 10 days-3 weeks d/t liquefactive necrosis

Question 50

Transient ischemic attack

Answer 50

Transient episode of neurologic dysfunction caused by focal brain/spinal cord/retinal ischemia without infarction

Question 51

amaurosis fugax

Answer 51

a retinal TIA caused by microembolization of atherosclerotic material to a bifurcation of the retinal arteries

Question 52

Tx of TIA

Answer 52

• Antithrombic therapy
• Antiplately therapy
• possible carotid endarectomy/stenting

Question 53

Strokes involving MCA

Answer 53

• contralateral hemiparesis and sensory loss in the face and upper extremity
• expressive aphasia if Broca’s area is involved in L hemisphere
• visual field defects
• head and eyes deviate toward site of lesion

Question 54

Strokes involving ACA

Answer 54

Contralateral hemiparesis and sensory loss in lower extremity

Question 55

Strokes involving vertebrobasilar arterial system

Answer 55

• vertigo, ataxia
• ipsilateral sensory loss in the face
• contralateral hemiparesis and sensory loss in trunk and limbs

Question 56

Embolic stroke

Answer 56

• Ischemic type of stroke due to embolization
• Emboli MC originate from L side of heart
• produces a hemorrhagic infarction (MC in MCA, reperfusion after lysis of embolic material –> hemorrhage)

Question 57

Sources of emboli

Answer 57

1. Mural thrombi in LV after AMI, aortic/mitral valve vegetations, L. atrium in a fib
2. A fib d/t thrombus formation in LA from stasis of blood
3. “Shower” embolization (emboli blocking numerous small vessels)

Question 58

Intracerebral hemorrhage

Answer 58

Most often d/t stress imposed on vessels by hypertension

• branches of lenticulostriate vessels develop Charcot-Bouchard microaneurysms
• rupture of aneurysms –> intracerebral hemorrhage

Question 59

Common sites of intracerebral hemorrahage

Answer 59

Basal ganglia, thalamus, pons and cerebellar hemispheres

Question 60

Slit hemorrhage

Answer 60

A/w hypertension
Rupture of small caliber penetrating vessels, producing hemorrhages that resorb blood, leaving slit-like spaces with a brownish-red pigment

Question 61

Subarachnoid hemorrhage

Answer 61

• Majority secondary to rupture of berry aneurysm

- Can also be d/t bleeding from an AV malformation

Question 62

Berry aneurysm

Answer 62

yum yum berries

Risk factors: normal hemodynamic stress, hypertension, coarctation of aorta, atherosclerosis, smoking

Most develop at junctions of communicating branches with main cerebral artery - junctions lack internal elastic lamina and smooth muscle

MC site is junction of the anterior communicating branch with ACA

Rupture releases blood into subarachnoid space

Blood in CSF is broken down into bilirubin pigment –> xanthochromia

Question 63

Clinical findings in subarachnoid hemorrhage

Answer 63

“Worst headache ever”
Nuchal rigidity from blood irritating meninges
50% mortality
Complications: further hemorrhage, hydrocephalus, neurologic defects

Question 64

Lacunar infarct

Answer 64

• Cystic area of microinfarction

Question 65

Dx of stroke

Answer 65

CT scan without contrast, distinguishes hemorrhage from nonhemorrhagic stroke

Question 66

Tx of stroke

Answer 66

Acute: Thrombolytic therapy in thromboembolic strokes (

Question 67

Pathogenesis of CNS infections

Answer 67

1. Hematogenous (MC)
2. Traumatic implantation
3. Local extension from nearby infection
4. Ascent via peripheral nerve

Question 68

Meningitis

Answer 68

• Inflammation of pia mater covering the brain

- Usually d/t hematogenous spread

Question 69

Pathogenesis of bacterial meningitis

Answer 69

Adherence of bacteria to mucosa of nasopharynx >
Bacteremia >
Translocation through the BBB using bacterial lysins >
Bacterial in the subarachnoid space attract neutrophils >
Acute meningitis

Question 70

Risk factors for bacterial meningitis in kids

Answer 70

1. undernutrition, otitis media
2. pneumonia, immunodeficiency
3. viral infection, sickle cell
4. craniofacial abnormality

Question 71

Viral meningitis

Answer 71

Mostly fecal-oral, respiratory less common

Question 72

Clinical findings and complications of meningitis

Answer 72

Clinical: Fever, nuchal rigidity, headache

Complications: Seizures, focal neurolog deficits, cranial nerve palsies, sensorineural hearing loss, communicating and noncommunicating hydrocephalus

Question 73

Lab findings in viral meningitis

Answer 73

1. Increased CSF protein
2. Increased total CSF leukocyte count (lymphocytes)
3. Normal CSF glucose

Question 74

Lab findings in bacterial meningitis

Answer 74

1. Increased CSF protein
2. Increased total CSF leukocyte count (neutrophils)
3. Decreased CSF glucose

Question 75

Lab findings in fungal meningitis

Answer 75

1. Increased CSF protein
2. Increased total CSF leukocyte count (lymphocytes)
3. Decreased CSF glucose

Question 76

Encephalitis

Answer 76

• Inflammation of the brain
• Fever, headache, impaired mental status, drowsiness
• Meningoencephalitis

Question 77

Cerebral abscess

Answer 77

• Either spreads from an adjacent focus of infection OR hematogenous spread
• Single or multiple lesions

Question 78

Demyelinating disorders pathogenesis

Answer 78

1. Destruction of normal myelin
2. Production of abnormal myelin
3. Destruction of oligodendrocytes

Question 79

Multiple sclerosis

Answer 79

• MC demyelinating disease, MC in females 20-40

- An autoimmune disease with genetic (HLA-DR2) and environmental (microbial pathogens, vitamin D, sun exposure) factors

Question 80

Pathogenesis of MS

Answer 80

1. CD4+ TH1 cells and TH17 cells react against self myelin antigens (type IV hypersensitivity)
2. CD4+ TH1 cells secrete IFN-gamma–> activates macrophages, TH17 releases cytokines to recruit neutrophils + monocytes
3. Leukocytes + TNFa attack myelin sheath and oligodendrocytes –> demyelination
4. Antibodies produced by autoreactive B cells are directed towards myelin sheath and oligodendrocytes as well (type II hypersensitivity)

Question 81

Gross and microscopic findings in MS

Answer 81

• Demyelinating plaques in white matter of brain/spinal cord, white matter looks like grey matter
• Inflammatory infiltrate in plaques is composed of CD4+ T-cells, monocytes, and microglial cells w/ phagocytosed lipid

Question 82

Clinical findings in MS

Answer 82

1. Episodic course w/ acute relapses and remissions
2. Sensory dysfunction: paresthesias, loss of pain, temp, vibratory sensation
3. UMN dysfunction: spasticity, increased DTRs, muscle spasms, Babinski, weakness
4. Autonomic dysfunction: urge incontinence, sexual dysfunction, bowel motility probs
5. Optic neuritis
6. Cerebellar ataxia
7. Scanning speech
8. Intention tremor, nystagmus
9. Bilateral internuclear opthalmoplegia (demyelinated MLF)
10. Flexion of neck –> electrical sensation down spine

Question 83

Lab findings in MS

Answer 83

1. Increased CSF leukocyte count
2. Increased CSF protein
3. Increased CSF MBP
4. Normal CSF glucose
5. High-res electrophoresis: oligoclonal bands (sign of demyelination)
6. MRI sensitive to demyelinating plaques

Question 84

Dx and Tx of MS

Answer 84

Dx: spinal tap, MRI with gadolinium

Tx: Acute relapse: high dose methylprednisolone
Chronic: DMARDs, monoclonal antibody, cytotoxic drugs

Question 85

Central pontine myelinolysis

Answer 85

• MC in alcoholics w/ hyponatremia
• Rapid IV correction causes demyelination in basis pontis
• Tx: supportive

Question 86

Group B strep neonatal meningitis

Answer 86

• Gram + coccus
• MCC neonatal meningitis
• Spreads from focus of infxn in maternal vagina
• Tx: penicillin G or ampicillin

Question 87

E. coli neonatal meningitis

Answer 87

• Gram - rod
• 2nd MCC neonatal meningiti
• Tx: ceftazidime + gentamicin

Question 88

Listeria neonatal meningitis

Answer 88

• Gram + rod, tumbling motility, actin rockets
• Soft cheese and hot dogs
• Tx: ampicillin + gentamicin

Question 89

Strep pneumoniae meningitis

Answer 89

• Gram + diplococcus
• MCC meningitis in patients over 18
• Tx: ceftriaxone + vanc + dexamethasone

Question 90

Neisseria meningitidis meningitis

Answer 90

• Gram - diplococcus found in posterior nasopharynx
• MCC meningitis in people under 18
• Tx: ceftriaxone
• prophylaxis: cipro/rifampin/ceftriaxone

Question 91

Mycobacterium tuberculosis meningitis

Answer 91

• Complication of primary TB
• Involves base of brain
• Vasculitis and scarring
• Tx: isoniazid, rifampin, ethambutol, pyrazinamide, dexamethasone

Question 92

Trepona pallidium meningitis, encephalitis, myelitis

Answer 92

• Gram - spirochete
• Types of neurosyphilis: Meningovascular, General paresis, Tabes dorsalis
  Tx: penicillin G

Question 93

Cryptococcus neoformans meningitis, encephalitis

Answer 93

• Immunocompromised host
• MC fungal infxn in AIDS
• Budding yeasts visible with India ink
  Tx: fluconazole non-AIDS, amphotericin + flucytosine

Question 94

Mucor species frontal lobe abscess

Answer 94

Occurs in DKA, spreads from frontal sinuses

Tx: amphotericin B

Question 95

Naegleria fowleri meningoencephalitis

Answer 95

• Protozoa
• Involves frontal lobes
• Contracted by swimming in freshwater lakes
• Tx: amphotericin B

Question 96

T. brucei encephalitis

Answer 96

• Protozoa
• Transmission from bite of tsetse fly
• Diffuse encephalitis, starvation MC death
• Dx: trypanosomes in blood, CSF; blood test
• Tx: pentamidine early, melarsoprol in encephalitis stage

Question 97

Taenia solium cystericercosis

Answer 97

• Helminth transmitted by pigs
• Patient eats food or water containing eggs –> larval form invades brain –> calcified cysts cause seizures and hydrocephalus
• Tx: albenzadole + dexamethasone

Question 98

T. gondii encephalitis

Answer 98

• Protozoa
• MC CNS space-occupying lesion in AIDS, ring-enhancing lesions on CT
• Congenital toxoplasmosis produces basal ganglia calcification
• Tx: pyrimethamine + sulfadiazine + leucovorin

Question 99

Leukodystrophies

Answer 99

Inborn errors of metabolism

Question 100

Adrenoleukodystrophy

Answer 100

• XR disorder
• Enzyme deficiency in B-oxidation of fatty acids in peroxisomes –> accumulation of long chain fatty acids
• generalized loss of myelin in brain, adrenal insufficiency

Question 101

Metachromatic leukodystrophy

Answer 101

AR lysosomal storage disease

- deficiency of arylsulfatase A resuls in accumulation of sulfatides

Question 102

Krabbe disease

Answer 102

• AR LSD
• Galactocerebroside B-galactocerebrosidase deficiency, leads to accumulation of galactocerebroside
• Brain shows large multinucleated histiocytic globoid cells

Question 103

Alzheimer disease epidemiology

Answer 103

• MCC dementia, 3 types:
  1. sporadic late onset type (MC)
  2. sporadic early onset type (related to apolipoprotein E)
  3. familial early onset type (mutations of APP on chromosome 21, presenilin 1 on chromosome 14, presenilin 2 on chromosome 1)
• Prevalence increases with age
• Down syndrome has strong a/w Alzheimers

Question 104

Where does B amyloid damage neurons?

Answer 104

• medial temporal lobe
• frontal cortex esp. entorhinal cortex, hippocampus
• occipital lobe spared

Question 105

Role of activated glycogen synthase kinase-3B in neurotoxicity of B amyloid

Answer 105

1. Activation of GSK causes phosphylation of AB –> neurotoxic
2. Phosphorylated AB has positive feedback on GSK
3. Initial activation of GSK traced to dysfunction within Wnt
4. Normal Wnt signaling pathway inactivates GSK, preventing phosphorylation of AB
5. When Wnt is dysfunctional, GSK stays activated –> phosphorylation of AB –> neurotoxicity

Question 106

How does AB stain?

Answer 106

Stains positive with Congo red, has apple-green birefringence with polarization

Question 107

What is AB a metabolic product of?

Answer 107

• APP
• APP normally coded for on chromosome 21
• Defects in metabolism of APP –> increase in AB
• a-secretases cleave APP into fragments that cannot produce AB
• B- secretases followed by g-secretases cleave APP into fradments that are converted to AB

Question 108

Insulin degrading enzyme

Answer 108

• involved in the clearance of AB

- insulin resistance syndromes have increased risk for Alzheimers

Question 109

Role of tau protein in Alzheimers

Answer 109

• Normal fxn is to main microtubules in neurons

- Activated GSK enhances hyperphosphorylation of tau protein –> protein changes shape into NF tangles in cytoplasm

Question 110

How are NF tangles visualized?

Answer 110

Silver stain

Question 111

What do NF tangles do?

Answer 111

Produce neuronal dysfunction including death of the neuron

Question 112

PIN1 enzyme

Answer 112

Strips excess phosphate molecules from NF, restoring it to its original shape
- Deficient in some cases of Alzheimers

Question 113

Gross and microscopic findings in Alzheimers

Answer 113

1. Cerebral atrophy with dilation of ventricles
2. NF tangles in cytoplasm of neurons
3. Senile plaques
4. Amyloid angiopathy
5. Confirmation of AD requires postmortem exam of brain

Question 114

Clinical findings in Alzheimers

Answer 114

• Decline in short term memory
• loss of smell
• Reduced ability for self care
• No focal neurologic deficits early in disease
• pts usually die from infxn

Question 115

Dx, Tx of Alzheimers

Answer 115

• presumptive dx made with mental status testing
• PET used for DDx of dementia

Tx: Cholinesterase inhibitors, Memantine

Question 116

Parkinsonism

Answer 116

• a group of disorders that alter dopaminergic pathways involved in voluntary muscle movement

Question 117

What part of the brain is involved in voluntary muscle movement?

Answer 117

The striatal system, includes: substantia nigra, caudate, putamen, globus pallidus, subthalamus, thalamus

Question 118

What is the principal NT of the nigrostriatal tract?

Answer 118

DOPAMINE

- connects the substantia nigra with the caudate and putamen

Question 119

Causes of Parkinsonism

Answer 119

1. idiopathic (MC)
2. encephalitis, ischemia
3. Chronic CO poisoning
4. Wilson disease
5. Addiction to MPTP
6. Antipsychotic drugs

Question 120

Pathophys of Parkinson disease

Answer 120

1. Degeneration/depigmentation of neurons in the substantia nigra
2. Causes deficiency of dopamine
3. Most cases are sporadic

Question 121

Clinical findings in Parkinson disease

Answer 121

1. Muscle rigidity (bradykinesia, cogwheel rigidity)
2. Resting tremor (“pill rolling”, illegible handwriting)
3. Expressionless face, stooped posture
4. Difficulty in initiating first step, shuffling gait
5. Blepharospasm, postural instability
6. Commonly have severe seborrheic dermatitis
7. Dementia in some cases

Question 122

Tx for Parkinson disease

Answer 122

• avoid drugs that worsen Parkinsonism (neuroleptics, antiemetics, MAOIs)
• Levodopa
• Carbidopa, benserazide - dopa decarboxylase inhibitor
• Bromocriptine, pergolide - dopamine agonist
• Selegiline, rasagiline - inhibit MAO-B
• Surgical procedures

Question 123

Huntington disease

Answer 123

• AD trinucleotide repeat disorder (CAG) involving chromosome 4
• delayed appearance of Sx until age 30-40
• no gender difference
• Atrophy/loss of striatal neurons (caudate, putamen, globus pallidus)

Question 124

Clinical findings in Huntingtons

Answer 124

• Chorea
• Oculomotor abnormalities
• Parkinsonism in later stages
• Depression

Question 125

Dx and Tx of Huntingtons

Answer 125

Dx: genetic testing, imaging studies show atrophy of caudate and putamen

Tx: supportive :(

Question 126

Friedreich ataxia

Answer 126

• AR trinucleotide repeat disorder (GAA)
• Frataxin deficiency –> impaired mitochondrial iron homeostasis –> cells more prone to apoptosis
• Sites of degeneration: dorsal root ganglia, posterior columns, spinocerebellar tract, lateral corticospinal tracts, large sensory peripheral neurons
• Hypertrophic cardiomegaly
• T1DM

Question 127

Clinical findings in Friedreich ataxia

Answer 127

• Progressive gait ataxia
• Loss of deep tendon reflexes, initially at ankles
• Loss of vibratory sensation and proprioception
• Muscle weakness in legs

Question 128

Dx and Tx of Friedreich ataxia

Answer 128

Dx: Genetic testing, MRI shows spinal cord atrophy

Tx: supportive :(

Question 129

ALS

Answer 129

• degenerative disease involving loss of upper and lower motor neurons
• Sx usually appear between age 40-60
• Most cases are sporadic
• Possibly d/t mutated or misfolded superoxide dismutase 1 or misfolded leading to apoptosis of neurons

Question 130

Clinical findings in ALS

Answer 130

• UMN signs: Spasticity, Babinski
• LMN signs: Muscle weakness beginning with atrophy of intrinsic muscles of hands, eventual paralysis of respiratory muscles
• no sensory changes
• preservation of bowel and bladder fxn

Question 131

ALS Dx and Tx

Answer 131

Dx: electromyography and nerve conduction studies

Tx: Riluzole (glutamate antagonist), average survival time is 3-5 years

Question 132

Werdnig-Hoffman disease

Answer 132

Lower motor neuron disease that occurs in children

Question 133

Wilson disease

Answer 133

• AR defect of copper excretion in bile
• Defect in incorporation of copper into ceruloplasmin –> liver cirrhosis, excess free copper in blood
• CNS findings: atrophy and cavitation of basal ganglia, esp globus pallidus + putamen
• parkinsonism, chorea, dementia

Question 134

Acute intermittent porphyria

Answer 134

• AD defect in porphyrin metabolism
• Deficiency of uroporphyrinogen synthase
• Proximal increase in porphobilinogen and ALA
• Heme has a negative feedback relationship with ALA synthase, so decrease in heme –> porphyric attack!!!

Question 135

What is super spooky about pee in acute intermittent porphyria

Answer 135

When you first void, urine is COLORLESS
Exposure to light oxidizes PBG to porphobilin producing PORT-WINE COLOR
Classic “window sill test”

Question 136

Clinical findings in acute intermittent porphyria

Answer 136

• Recurrent severe abdominal pain simulating acute abdomen –> patient has “bellyful of scars” (wut)
• Psychosis, peripheral neuropathy, dementia

Question 137

Dx, Tx of acute intermittent porphyria

Answer 137

Dx: Enzyme assay in RBCs

Tx: Avoid drugs that precipitate attacks, carbo loading with glucose to inhibit ALA synthase

Question 138

Vitamin B12 deficiency

Answer 138

Subacute combined degeneration of the spinal cord (posterior column and lateral corticospinal tract demyelination)
- dementia, peripheral neuropathy

Question 139

CNS findings in alcohol abuse

Answer 139

1. Cortical and cerebellar atrophy
2. Central pontine myelinolysis
3. Wernicke-Korsakoff syndrome
4. Tx: Thiamine supplement

Question 140

Wernicke-Korsakoff syndrome

Answer 140

• MC d/t thiamine deficiency
• Hemorrhages of small vessels w// hermosiderin deposits in the mammillary bodies and walls of 3rd and 4rd ventricles
• Neuronal loss, gliosis
• Wernicke encephalopathy (reversible)
• Korsakoff psychosis

Question 141

Wernicke encephalopathy

Answer 141

Reversible: confusion, ataxia, nystagmus, opthalmoplegia

Question 142

Korsakoff psychosis

Answer 142

• Advanced irreversible stage of Wernicke encephalopathy targeting limbic system
• Anterograde amnesia
• Retrograde amnesia
• Confabulation, hallucinations

Question 143

Primary brain tumors in adults

Answer 143

• Most ABOVE tentorium cerebelli

- In order from greatest freq to least: GBM, meningioma, ependymoma

Question 144

Primary brain tumors in children

Answer 144

• 2nd MC cancer in kids
• Most BELOW tentorium cerebelli
• In order from greatest freq to least: Cystic cerebellar astrocytoma, medulloblastoma, brainstem glioma

Question 145

Risk factors for brain tumors

Answer 145

Turcot syndrome, neurofibromatosis, cigarette smoking

Question 146

General clinical findings in brain tumor

Answer 146

• Headache: worse during night, a/w nausea + vomiting
• Seizures
• Signs/Sx intracranial HTN

Question 147

Imaging studies for brain tumor

Answer 147

• MRI w/ gadolinium enhancement
• CT if calcium or hemorrhage is present
• fMRI for lesions in vital areas
• PET

Question 148

Tx for brain tumors

Answer 148

Surgery, irradiation, chemo

Question 149

Astrocytoma

Answer 149

• Accounts for ~70% of all neuroglial tumors
• Usually involves frontal lobe in adults, cerebellum in kids
• Grades I and II are low grade, III and IV are high grade

Question 150

Glioblastoma multiforme

Answer 150

• High grade astrocytoma, may arise de novo OR from dedifferentiation of a low-grade astrocytoma
• Hemorrhagic tumor: multifocal areas of necrosis and cystic degeneration, commonly crosses corpus callosum
• May seed neuraxis via CSF, rarely mets outside CNS
• Generally shit prognosis

Question 151

Meningioma

Answer 151

• MC benign brain tumor in adults
• MC in females (tumor has estrogen and progesterone receptors), some have androgen receptors
• Derived from meningothelial cell within arachnoid membrane that lines but is not adherent to the dura: MC has parasagittal location; other sites are olfactory groove and lesser wing of sphenoid
• A/W NF2, history of radiation
• Firm tumors that may indent surface of brain, causes increased bone density
• swirling masses of meningothelial cells encompass psammoma bodies
• New-onset focal seizures

Question 152

Enpendymoma

Answer 152

• Benign tumor derived from ependymal cells

- Arises in cauda equina in adults, 4th ventricle in kids (can produce non-communicating hydrocephalus)

Question 153

Medulloblastoma

Answer 153

• Malignant small cell tumor, primarily in kids
• Arises from external granular cell layer of cerebellum
• Often seeds neuraxis and invades 4th ventricle

Question 154

Oligodendroglioma

Answer 154

• Benign tumor derived from oligodendrocytes, primarily in adults
• Frontal lobe tumor that frequently calcifies

Question 155

CNS lymphoma

Answer 155

• Majority are metastatic high grade B-cell non Hodgkins lymphomas
• Primary CNS lymphomas: MC a/w AIDS, also: EBV-mediated B-cell lymphomas

Question 156

Most common cancer in the brain

Answer 156

• Metastasis!

- In order of decreasing frequency: lung, breast, skin, kidney

Question 157

Peripheral neuropathy

Answer 157

• Associated with demyelination and axonal degeneration
• Demyelination is often segmental –> sensory change often in “glove and stocking” distibution
• Axonal degenerations –> muscle fasciculations, atrophy

Question 158

Charcot-Marie-Tooth Disease

Answer 158

• MC hereditary neuropathy, AD
• Peroneal nerve neuropathy –> causes atrophy of muscles in lower legs, legs have “inverted bottle” appearance
• Tx: supportive

Question 159

Guillain-Barré Disease

Answer 159

• MC acute peripheral neuropathy
• MCC acute flaccid paralysis
• Predominantly motor involvement
• Autoimmune demyelination syndrome involving nerve roots and peripheral nerves
• Common preceding infections: M. pneumoniae pneumonia, Campylobacter jejuni enteritis, viral infections

Question 160

Sx of Guillain-Barré

Answer 160

• Rapidly progressive ascending motor weakness usually starting at proximal muscles and moving distally
• Danger of respiratory muscle paralysis and death
• Depressed or absent deep tendon reflexes in arms and legs
• Glove and stocking paresthesias/anesthesia

Question 161

Lab findings in Guillain-Barré

Answer 161

• Increased CSF protein, oligoclonal bands present on hi-res electrophoresis
• CSF glucose, cell count normal

Question 162

Dx, Tx, Prognosis of Guillain-Barré

Answer 162

Dx: Spinal tap w/ increased CSF protein, electromyography + nerve conduction studies

Tx: Infusion IVIG or plasma exchange, mechanical vent if necessary

Prognosis: 5-10% mortality, full recovery 60%, residual weakness 15% (these numbers don’t add up wtf)

Question 163

Diabetes mellitus neuropathy

Answer 163

• MCC peripheral neuropathy, d/w osmotic damage of Schwann cells

Question 164

Idiopathic Bell Palsy

Answer 164

• LMN palsy causing unilateral facial paralysis
• Inflammatory reaction of facial nerve
• May be associated w/ HSV, HIV, sarcoidosis, Lyme disease (often bilateral), pregnancy

Question 165

Sx of LMN Bell palsy

Answer 165

• ipsilateral upper and lower face involvement
• drooping of corner of mouth
• difficulty speaking
• inability to close eye
• inability to wrinkle forehead
• hyperacusis in some cases

Question 166

Sx of UMN Bell Palsy

Answer 166

• Contralateral lower face involved

- Contralateral upper face spared

Question 167

Drugs that cause peripheral neuropathy

Answer 167

Vincristine, hydralazine, phenytoin

Question 168

Vitamin deficiencies that cause peripheral neuropathy

Answer 168

Deficiency of thiamine, B12, pyridoxine

Question 169

Tx of peripheral neuropathies

Answer 169

• Antiseizure meds: gabapentin, carbamazepine
• Lidocaine patch
• Tricyclic antidepressants: amitriptyline, nortriptyline

Question 170

Schwannoma

Answer 170

• Benign tumor derived form Schwann cells
• CN V and VIII may be involved
• Spinal nerve roots, peripheral nerves may be involved

Question 171

Acoustic neuroma

Answer 171

• Schwannoma of CN VIII
• MC located in cerebellopontine angle
• Encapsulated tumors, usually unilateral, alternating dark + light areas under microscope
• Sx: associated w/ NF2 (bilateral), tinnitus, sensorineural deafness, sensory changes in CN V d/t nerve impingemtn
• Tx: surgery

Question 172

Arcus senilis

Answer 172

• MC in elderly
• Grey-opaque ring at corneal margin
• Cholesterol deposits in corneal stroma, may indicate hypercholesterolemia if under

Question 173

Opthalmia neonatorum

Answer 173

COnjunctivitis in newborn
Pathogens: Gonorrhea (first week), Chlamydia (2nd week)
Tx: ceftriaxone (gon), erythromycin (chlam), erythromycin eye drops for irritation

Question 174

Bacterial conjunvtivitis

Answer 174

• Purulent conjunctivitis, pain but no blurry vision
• Pathogens: Staph aureus, Strep pneumoniae, Haemophilus influenzae
• Tx: gatifloxacin drops

Question 175

Viral conjunctivitis

Answer 175

• Watery exudate
• Adenovirus: viral cause of pinkeye, painful periauricular adenopathy, no tx
• HSV1: keratoconjunctivitis with dendritic ulcers noted with fluorescein staining, tx: trifluridine opthalmic

Question 176

Allergic conjunctivitis

Answer 176

• Seasonal itching of eyes

- Tx: antihistamine opthalmic solutions, olopatadine

Question 177

Acanthamoeba infection

Answer 177

• Severe keratoconjunctivitis in patients who do not clean their contacts properly
• Tx: propamidine + polymyxin/neomycin/granmicidin opthalmic

Question 178

Stye

Answer 178

• Infection of the eyelid most commonly d/t staph aureus

- Tx: hot packs, dicloxacillin

Question 179

Chalazion

Answer 179

• Granulomatous inflammation involving the meibomian gland in the eyelid; usually disappears on its own w/in 2 months
• Tx: if it doesn’t go away on its own, intralesional corticosteroid injection or surgical removal

Question 180

Orbital cellulitis

Answer 180

• Periorbital redness and swelling often secondary to sinusitis
• Pathogens: S. pneumoniae, H. influenzae
• Fever, proptosis, periorbital swelling, opthalmoplegia, normal retinal exam
• Tx: nafcillin + ceftriaxone + metronidazole

Question 181

Orbital fracture

Answer 181

• MC a/w blunt trauma to eye that produces orbital floor fracture
• Often a/w edema and ecchymoses of eyelids and periorbital region
• Vertical diplopia, prolapse of orbital contents into maxillary sinus, damage to infraorbital nerve
• Tx: varies w/ severity

Question 182

Pterygium

Answer 182

• Raised, triangular encroachment of thickened conjunctiva on the nasal side of conjunctiva, may grow onto cornea
• D/t excessive exposure to wind, sun, sand
• Tx: surgical removal

Question 183

Pinguecula

Answer 183

• Yellow-white conjunctival degeneration at the junction of the cornea and sclera on the temporal side of the conjunctiva
• Does NOT grow onto the cornea like pterygium does
• Usually doesn’t require tx

Question 184

Optic neuritis

Answer 184

• Inflammation of optic nerve
• Causes: MS, methanol poisoning
• Blurry vision or loss of vision, may cause optic atrophy
• Tx: corticosteroids

Question 185

Central retinal artery occlusion

Answer 185

Causes: embolization of plaque from ipsilateral carotid or opthalmic artery, giant cell temporal arteritis involving opthalmic artery

Sx: Sudden, painless, complete loss of vision in one eye, pallor of optic disk d/t narrowed arteries, “boxcar” segmentation of blood in retinal veins, cherry red macula

Tx: acetazolamide to lower intraocular pressure, carbogen, hyperbaric O2 therapy

Question 186

Central retinal vein occlusion

Answer 186

• Causes: hypercoagulable state

Sx: Sudden painless unilateral loss of vision, swelling of optic disk, engorged retinal veins w/ hemorrhage

Tx: intravitreal injections, laser photocoagulation

Question 187

Chronic open angle glaucoma

Answer 187

• Decreased rate of aqueous outflow into canal of Schlemm
• Common in persons with severe near-sightedness
• Bilateral aching eyes, pathologic cupping of the optic disks, night blindness and gradual loss of peripheral vision leading to tunnel vision and blindness
• Tx: 1st: Beta blockers, 2nd: prostaglandins, a-adrenergic agonists, pilocarpine, carbonic anhydrase inhibitors, laser trabeculoplasty

Question 188

Acute closed angle glaucoma

Answer 188

• Narrowing of the anterior chamber angle
• Medical emergency
• Precipitated by mydriatic agent
• Uveitis, lens dislocation, severe pain a/w photophobia and blurry vision
• Red eye with steamy cornea (wut), pupil fixed and nonreactive to light
• Tx: pilocarpine + systemic carbonic anhydrase inhibitor to lower pressure to allow for laser surgery

Question 189

Optic nerve atrophy

Answer 189

Pale optic disk
MC d/t optic neuritis or glaucoma
No effective treatment

Question 190

Uveitis

Answer 190

• Inflammation of the uveal tract (iris, ciliary body, choroid)
• Causes: sarcoidosis, ulcerative colitis, ankylosing spondylitis
• Pain w/ blurry vision, miotic pupil, circumcorneal ciliary body vascular congestion, normal intraocular pressure, adhesions between iris and anterior lens capsule
• Tx: corticosteroids, atropine

Question 191

Macular degeneration

Answer 191

• MCC permanent visual los in elderly
• Disruption of Bruch membrane in retina
• Dry: thinning of retina and formation of yellowish white deposits (drusen)
• Wet: extension of dry type, vessels under retina hemorrhage –> retinal cells die –> blind spots or distorted central vision
• Antioxidants may lower risk
• Tx: antiangiogenics, insertion of special lens

Question 192

CMV retinitis

Answer 192

• MCC blindness in AIDS, usually when CD4 count

Question 193

Cataracts

Answer 193

• Opacity in the lens
• Causes: advanced age, diabetes, infection
• Common in congenital infections
• Tx: cataract extraction

Question 194

Malignant eye tumors

Answer 194

• Retinoblastoma in children
• Malignant melanoma
• Tx: enucleation

Question 195

Meniere disease

Answer 195

• Increased endolymph in inner ear and loss of cochlear hairs
• Dizziness, vertigo, tinnitus, sensorineural hearing loss
• Tx: HCTZ + triamterene, surgery

Question 196

Sensorineural defect

Answer 196

Weber test: lateralizes to normal ear

Question 197

Conduction defect

Answer 197

Weber test: lateralizes to affected ear

• D/t degeneration of cochlear hairs
• Tx: amplification devices, cochlear implants

Question 198

Otosclerosis

Answer 198

• MCC conduction deafness in elderly
• D/t fusion of ossicles
• Tx: amplification devices, surgery

Question 199

Otitis media

Answer 199

• MCC conduction deafness in children
• Usually d/t Strep pneumoniae
• Tx: antipyrine and benzocaine drops for pain, controversy over use of abx

Question 200

External otitis

Answer 200

• Inflammation of outer ear canal
• Swimmers ear –> tx: ear drops – polymixin B + neomycin + hydrocortisone + selenium sulfide shampoo
• Malignant external otitis: severe infection of outer ear canal in patients w/ diabetes, tx: imipenem-cilastatin