Neurology and Special Senses - First Aid

Question 1

Neural Development

Answer 1

• Notochord induces overlying ectoderm to differentiate into neuroectoderm and form neural plate.
• Neural plate gives rise to neural tube and neural crest cells.
• Notochord becomes nucleus pulposus of intervertebral disc in adults.
• same orientation as spinal cord:
  
  • Alar plate (dorsal): sensory
  • Basal plate (ventral): motor

Question 2

Regional Specification of Developing Brain

Answer 2

• Telencephalon is the 1st part.
• Diencephalon is the 2nd part.
• The rest are arranged alphabetically:
  
  • Mesencephalon
  • Metencephalon
  • Myelencephalon

Question 3

Central and Peripheral Nervous Systems Origins:

• CNS Neurons
• Ependymal Cells
  
  • inner lining of ventricles
  • make CSF
• Oligodendrocytes
• Astrocytes

Answer 3

Neuroepithelia in Neural Tube

Question 4

Central and Peripheral Nervous Systems Origins:

• PNS Neurons
• Schwann Cells

Answer 4

Neural Crest

Question 5

Central and Peripheral Nervous Systems Origins:

Microglia (like macrophages)

Answer 5

Mesoderm

Question 6

Neural Tube Defects

Answer 6

• Neuropores fail to fuse (4th week) → persistent connection between amniotic cavity and spinal canal.
• Associated with maternal diabetes as well as low folic acid intake before conception and during pregnancy.
• ↑ α-fetoprotein (AFP) in amniotic fluid and maternal serum (except spina bifida occulta = normal AFP).
• ↑ acetylcholinesterase (AChE) in amniotic fluid is a helpful confirmatory test.

Question 7

Neural Tube Defects:

• failure of caudal neuropore to close, but no herniation
• usually seen at lower vertebral levels
• dura is intact
• associated with tuft of hair or skin dimple at level of bony defect

Answer 7

Spina Bifida Occulta

Question 8

Neural Tube Defects:

• meninges (but no neural tissue) herniate through bony defect
• associated with spina bifida cystica

Answer 8

Meningocele

Question 9

Neural Tube Defects:

meninges and neural tissue (eg. cauda equina) herniate through bony defect

Answer 9

Meningomyelocele

Question 10

Neural Tube Defects:

• also known as rachischisis
• exposed unfused neural tissue without skin/meningeal covering

Answer 10

Myeloschisis

Question 11

Neural Tube Defects:

• failure of rostral neuropore to close → no forebrain, open calvarium
• Clinical Findings: polyhydramnios (no swallowing center in brain)

Answer 11

Anencephaly

Question 12

Neurologic Defects:

• failure of left and right hemispheres to separate
• usually occurs during weeks 5–6
• may be related to mutations in sonic hedgehog signaling pathway
• moderate form has cleft lip/palate, most severe form results in cyclopia
• seen in trisomy 13 and fetal alcohol syndrome
• MRI reveals monoventricle and fusion of basal ganglia

Answer 12

Holoprosencephaly

Question 13

Posterior Fossa Malformations:

• ectopia of cerebellar tonsils (1 structure)
• congenital
• usually asymptomatic in childhood
• manifests in adulthood with headaches and cerebellar symptoms
• associated with spinal cavitations (eg. syringomyelia)

Answer 13

Chiari I Malformation

Question 14

Posterior Fossa Malformations:

• herniation of low-lying cerebellar vermis and tonsils (2 structures) through foramen magnum with aqueductal stenosis → hydrocephalus
• usually associated with lumbosacral meningomyelocele (may present as paralysis/sensory loss at and below the level of the lesion)

Answer 14

Chiari II malformation

Question 15

Posterior Fossa Malformations:

• agenesis of cerebellar vermis leads to cystic enlargement of 4th ventricle that fills the enlarged posterior fossa
• associated with noncommunicating hydrocephalus, spina bifida

Answer 15

Dandy-Walker Syndrome

Question 16

Neurologic Defects:

• cystic cavity (syrinx) within central canal of spinal cord
• fibers crossing in anterior white commissure (spinothalamic tract) are typically damaged first
• results in a “cape-like,” bilateral symmetrical loss of pain and temperature sensation in upper extremities (fine touch sensation is preserved)
• associated with Chiari malformations and other congenital malformations
• acquired causes include trauma and tumors
• most common at C8–T1

Answer 16

Syringomyelia

syrinx = tube, as in syringe

Question 17

Tongue Development

Answer 17

• 1st and 2nd branchial arches form anterior 2/3 (thus sensation via CN V3, taste via CN VII).
• 3rd and 4th branchial arches form posterior 1/3 (thus sensation and taste mainly via CN IX, extreme posterior via CN X).
• Motor innervation is via CN XII to hyoglossus (retracts and depresses tongue), genioglossus (protrudes tongue, “the genie sticks out his tongue”), and styloglossus (draws sides of tongue upward to create a trough for swallowing).
• Motor innervation is via CN X to palatoglossus (elevates posterior tongue during swallowing).
• Taste—CN VII, IX, X (solitary nucleus)
• Pain—CN V3, IX, X
• Motor—CN X, XII

Question 18

Neuroanatomy:

• signal-transmitting cells of the nervous system
• permanent cells—do not divide in adulthood
• signal-relaying cells with dendrites (receive input), cell bodies, and axons (send output)
• cell bodies and dendrites can be seen on Nissl staining (stains RER)
• RER is not present in the axon
• injury to axon → Wallerian degeneration—degeneration of axon distal to site of injury and axonal retraction proximally; allows for potential regeneration of axon (if in PNS)
• macrophages remove debris and myelin

Answer 18

Neurons

Question 19

Neuroanatomy:

• most common glial cell type in CNS
• physical support, repair, extracellular K⁺ buffer, removal of excess neurotransmitter, component of blood-brain barrier, glycogen fuel reserve buffer
• reactive gliosis in response to neural injury
• derived from neuroectoderm
• GFAP—marker

Answer 19

Astrocytes

Question 20

Neuroanatomy:

• phagocytic scavenger cells of CNS (mesodermal, mononuclear origin)
• activated in response to tissue damage
• not readily discernible by Nissl stain
• HIV-infected cells fuse to form multinucleated giant cells in CNS

Answer 20

Microglia

Question 21

Neuroanatomy:

• glial cells with a ciliated simple columnar form that line the ventricles and central canal of spinal cord
• apical surfaces are covered in cilia (which circulate CSF) and microvilli (which help in CSF absorption)

Answer 21

Ependymal Cells

Question 22

Neuroanatomy:

• ↑ conduction velocity of signals transmitted down axons → saltatory conduction of action potential at the nodes of Ranvier, where there are high concentrations of Na⁺ channels
• synthesized by oligodendrocytes in CNS (including CN I and II) and Schwann cells in PNS (including CN III-XII)
• wraps and insulates axons: ↑ space constant and ↑ conduction velocity

Answer 22

Myelin

COPS:

• CNS = Oligodendrocytes
• PNS = Schwann cells

Question 23

Neuroanatomy:

• myelinates only 1 PNS axon
• also promote axonal regeneration
• derived from neural crest
• injured in Guillain-Barré syndrome

Answer 23

Schwann Cells

Question 24

Neuroanatomy:

• myelinates axons of neurons in CNS
• can myelinate many axons (∼ 30)
• predominant type of glial cell in white matter
• derived from neuroectoderm
• “fried egg” appearance histologically
• injured in multiple sclerosis, progressive multifocal leukoencephalopathy (PML), and leukodystrophies

Answer 24

Oligodendrocytes

Question 25

Sensory Receptors:

• C—slow, unmyelinated fibers
• Aδ—fAst, myelinated fibers
• all skin, epidermis, some viscera
• pain, temperature

Answer 25

Free Nerve Endings

Question 26

Sensory Receptors:

• large, myelinated fibers
• adapt quickly
• glabrous (hairless) skin
• dynamic, fine/light touch, position sense

Answer 26

Meissner Corpuscles

Question 27

Sensory Receptors:

• large, myelinated fibers
• adapt quickly
• deep skin layers, ligaments, joints
• vibration, pressure

Answer 27

Pacinian Corpuscles

Question 28

Sensory Receptors:

• large, myelinated fibers
• adapt slowly
• finger tips, superficial skin
• pressure, deep static touch (eg. shapes, edges), position sense

Answer 28

Merkel Discs

Question 29

Sensory Receptors:

• dendritic endings with capsule
• adapt slowly
• finger tips, joints
• pressure, slippage of objects along surface of skin, joint angle change

Answer 29

Ruffini Corpuscles

Question 30

Peripheral Nerve

Answer 30

• Endoneurium
  
  • invests single nerve fiber layers (inflammatory infiltrate in Guillain-Barré syndrome)
• Perineurium
  
  • blood-nerve permeability barrier
  • surrounds a fascicle of nerve fibers
  • must be rejoined in microsurgery for limb reattachment
• Epineurium
  
  • dense connective tissue that surrounds entire nerve (fascicles and blood vessels)

Question 31

Neuropathology:

• reaction of neuronal cell body to axonal injury
• changes reflect ↑ protein synthesis in effort to repair the damaged axon
• characterized by:
  
  • round cellular swelling
  • displacement of the nucleus to the periphery
  • dispersion of Nissl substance throughout cytoplasm
• concurrent with Wallerian degeneration

Answer 31

Chromatolysis

Question 32

Neurotransmitter Changes with Disease

Answer 32

Question 33

Meninges

Answer 33

• Three membranes that surround and protect the brain and spinal cord:
  
  • Dura Mater
    
    • thick outer layer closest to skull
    • derived from mesoderm
  • Arachnoid Mater
    
    • middle layer
    • contains web-like connections
    • derived from neural crest
  • Pia Mater
    
    • thin, fibrous inner layer that firmly adheres to brain and spinal cord
    • derived from neural crest
• CSF flows in the subarachnoid space, located between arachnoid and pia mater
• Epidural Space—a potential space between the dura mater and skull containing fat and blood vessels

Question 34

Blood-Brain Barrier

Answer 34

• Prevents circulating blood substances (eg. bacteria, drugs) from reaching the CSF/CNS.
• Formed by 3 structures:
  
  • Tight Junctions between nonfenestrated capillary endothelial cells
  • Basement Membrane
  • Astrocyte Foot Processes
• Glucose and amino acids cross slowly by carrier-mediated transport mechanisms.
• Nonpolar/lipid-soluble substances cross rapidly via diffusion.
• A few specialized brain regions with fenestrated capillaries and no blood-brain barrier allow molecules in blood to affect brain function (eg. area postrema—vomiting after chemo; OVLT [organum vasculosum lamina terminalis]—osmotic sensing) or neurosecretory products to enter circulation (eg. neurohypophysis—ADH release).
• Infarction and/or neoplasm destroys endothelial cell tight junctions → vasogenic edema.
• Other notable barriers include:
  
  • Blood-Testis Barrier
  • Maternal-Fetal Bood Barrier of Placenta

Question 35

Neuroanatomy:

• Maintains homeostasis by:
  
  • regulating yhirst and water balance
  • controlling Adenohypophysis (anterior pituitary) and Neurohypophysis (posterior pituitary) release of hormones produced in the hypothalamus
  • regulating hunger, Autonomic nervous system, temperature, and sexual urges
• areas not protected by blood-brain barrier:
  
  • OVLT (senses change in osmolarity)
  • Area Postrema (found in medulla, responds to emetics)

Answer 35

Hypothalamus

TAN HATS:

• Thirst and water balance
• Adenohypophysis
• Neurohypophysis
• Hunger
• Autonomic nervous system
• Temperature
• Sexual urges

Question 36

Hypothalamus:

• hunger
• destruction → anorexia, failure to thrive (infants)
• stimulated by Ghrelin
• inhibited by Leptin

Answer 36

Lateral Nucleus

Lateral injury makes you Lean.

Question 37

Hypothalamus:

• satiety
• destruction (eg. craniopharyngioma) → hyperphagia
• stimulated by Leptin

Answer 37

Ventromedial Nucleus

VentroMedial injury makes you Very Massive.

Question 38

Hypothalamus:

• cooling
• parasympathetic

Answer 38

Anterior Nucleus

A/C = Anterior Cooling

Question 39

Hypothalamus:

• heating
• sympathetic

Answer 39

Posterior Nucleus

• Heating controlled by Posterior hypothalamus (“Hot Pot”).
• If you zap your posterior hypothalamus, you become a poikilotherm (cold-blooded, like a snake).

Question 40

Hypothalamus:

circadian rhythm

Answer 40

Suprachiasmatic Nucleus

You need sleep to be charismatic (chiasmatic).

Question 41

Hypothalamus:

• synthesize ADH and Oxytocin
• ADH and Oxytocin are carried by Neurophysins down axons to posterior pituitary, where these hormones are stored and released

Answer 41

Supraoptic and Paraventricular Nuclei

Question 42

Hypothalamus:

• thermoregulation, sexual behavior
• releases GnRH
• failure of GnRH-producing neurons to migrate from olfactory pit → Kallmann Syndrome

Answer 42

Preoptic Nucleus

Question 43

Vomiting Center

Answer 43

• Coordinated by Nucleus Tractus Solitarius (NTS) in the medulla, which receives information from the Chemoreceptor Trigger Zone (CTZ, located within area postrema in 4th ventricle), GI tract (via vagus nerve), vestibular system, and CNS.
• CTZ and adjacent vomiting center nuclei receive input from 5 major receptors:
  
  • Muscarinic (M1)
  • Dopamine (D2)
  • Histamine (H1)
  • Serotonin (5-HT3)
  • Neurokinin (NK-1)
• 5-HT3, D2, and NK-1 antagonists used to treat chemotherapy-induced vomiting.
• M1 and H1 antagonists used to treat motion sickness and hyperemesis gravidarum.

Question 44

Sleep Physiology

Answer 44

• Sleep cycle is regulated by the circadian rhythm, which is driven by Suprachiasmatic Nucleus (SCN) of hypothalamus.
• Circadian rhythm controls nocturnal release of ACTH, Prolactin, Melatonin, Norepinephrine: SCN → Norepinephrine release → Pineal Gland → Melatonin
• SCN is regulated by environment (eg. light).
• Two Stages:
  
  • Rapid-Eye Movement (REM)
  • Non-REM
• Alcohol, benzodiazepines, and barbiturates are associated with ↓ REM sleep and delta wave sleep.
• Norepinephrine also ↓ REM sleep.
• Benzodiazepines are useful for night terrors and sleepwalking by ↓ N3 and REM sleep.

Question 45

Sleep Physiology

Answer 45

Question 46

Neuroanatomy:

major relay for all ascending sensory information except olfaction

Answer 46

Thalamus

Question 47

Thalamus:

• Input:
  
  • spinothalamic and dorsal columns/medial lemniscus
• Senses:
  
  • vibration
  • pain
  • pressure
  • proprioception
  • light touch
  • temperature
• Destination:
  
  • 1° Somatosensory Cortex

Answer 47

Ventral PosteroLateral Nucleus

• Senses:
  
  • Vibration
  • Pain
  • Pressure
  • Proprioception
  • Light Touch
  • Temperature

Question 48

Thalamus:

• Input:
  
  • trigeminal and gustatory pathway
• Senses:
  
  • face sensation
  • taste
• Destination:
  
  • 1° Somatosensory Cortex

Answer 48

Ventral PosteroMedial Nucleus

Makeup goes on the face.

Question 49

Thalamus:

• Input:
  
  • CN II
  • optic chiasm
  • optic tract
• Senses:
  
  • vision
• Destination:
  
  • Calcarine Sulcus

Answer 49

​Lateral Geniculate Nucleus

Lateral = Light

Question 50

Thalamus:

• Input:
  
  • superior olive and inferior colliculus of tectum optic chiasm
• Senses:
  
  • hearing
• Destination:
  
  • Auditory Cortex of Temporal Lobe

Answer 50

Medial Geniculate Nucleus

Medial = Music

Question 51

Thalamus:

• Input:
  
  • basal ganglia
  • cerebellum
• Senses:
  
  • motor
• Destination:
  
  • Motor Cortex

Answer 51

Ventral Lateral Nucleus

Question 52

Neuroanatomy:

• collection of neural structures involved in emotion, long-term memory, olfaction, behavior modulation, and ANS function
• Consists of:
  
  • Hippocampus
  • Amygdalae
  • Mammillary Bodies
  • Anterior Thalamic Nuclei
  • Cingulate Gyrus
  • Entorhinal Cortex
• Responsible for:
  
  • feeding
  • fleeing
  • fighting
  • feeling
  • sex

Answer 52

Limbic System

5 F’s:

• Feeding
• Fleeing
• Fighting
• Feeling
• Fucking

Question 53

Neuroanatomy:

commonly altered by drugs (eg. antipsychotics) and movement disorders (eg. Parkinson disease)

Answer 53

Dopaminergic Pathways

Question 54

Dopaminergic Pathways:

• ↓ activity → “negative” symptoms (eg. anergia, apathy, lack of spontaneity)
• antipsychotic drugs have limited effect

Answer 54

Mesocortical

Question 55

Dopaminergic Pathways:

• ↑ activity → “positive” symptoms (eg. delusions, hallucinations)
• 1° therapeutic target of antipsychotic drugs → ↓ positive symptoms (eg. in schizophrenia)

Answer 55

Mesolimbic

Question 56

Dopaminergic Pathways:

• ↓ activity → extrapyramidal symptoms (eg. dystonia, akathisia, parkinsonism, tardive dyskinesia)
• major dopaminergic pathway in brain
• significantly affected by movement disorders and antipsychotic drugs

Answer 56

Nigrostriatal

Question 57

Dopaminergic Pathways:

↓ activity → ↑ prolactin → ↓ libido, sexual
dysfunction, galactorrhea, gynecomastia (in
men).

Answer 57

Tuberoinfundibular

Question 58

Neuroanatomy:

• modulates movement
• aids in coordination and balance

Answer 58

Cerebellum

Question 59

Cerebellum Input

Answer 59

• Contralateral Cortex via Middle Cerebellar Peduncle
• ipsilateral proprioceptive information via Inferior Cerebellar Peduncle from spinal cord

Question 60

Cerebellum Output:

Answer 60

• Purkinje Cells (always inhibitory) → Deep Nuclei of Cerebellum → Contralateral Cortex via Superior Cerebellar Peduncle
• Deep Nuclei (lateral → medial)
  
  • Dentate
  • Emboliform
  • Globose
  • Fastigial

Don’t Eat Greasy Foods.

Question 61

Neuroanatomy:

• important in voluntary movements and making postural adjustments
• receives cortical input, provides negative feedback to cortex to modulate movement

Answer 61

Basal Ganglia

• *D1-R**eceptor = D1Rect Pathway
• *I**ndirect (D2) = Inhibitory

Question 62

Basal Ganglia:

Putamen (motor) + Caudate (cognitive)

Answer 62

Striatum

Question 63

Basal Ganglia:

Putamen + Globus Pallidus

Answer 63

Lentiform

Question 64

Basal Ganglia

Answer 64

• Direct (Excitatory) Pathway
  
  • SNc input stimulates the striatum, stimulating the release of GABA, which inhibits GABA release from the GPi, disinhibiting the thalamus via the GPi (↑ motion)
• Indirect (Inhibitory) Pathway
  
  • SNc input stimulates the striatum, releasing GABA that disinhibits STN via GPe inhibition, and STN stimulates GPi to inhibit the thalamus (↓ motion).
• Dopamine binds to D1, stimulating the excitatory pathway, and to D2, inhibiting the inhibitory pathway → ↑ motion.

Question 65

Cerebral Cortex Regions

Answer 65

Question 66

Homunculus

Answer 66

• Topographic representation of motor (shown) and sensory areas in the cerebral cortex.
• Distorted appearance is due to certain body regions being more richly innervated and thus having ↑ cortical representation.

Question 67

Cerebral Perfusion

Answer 67

• Brain perfusion relies on tight autoregulation.
• Cerebral perfusion is primarily driven by
• Pco2 (Po2 also modulates perfusion in severe
• hypoxia).
• Cerebral perfusion relies on a pressure gradient between mean arterial pressure (MAP) and ICP.
• ↓ blood pressure or ↑ ICP → ↓ cerebral perfusion pressure (CPP)
• therapeutic hyperventilation → ↓ Pco₂ → vasoconstriction → ↓ cerebral blood flow → ↓ intracranial pressure (ICP)
• May be used to treat acute cerebral edema (eg. 2° to stroke) unresponsive to other interventions.
• CPP = MAP – ICP
• If CPP = 0, there is no cerebral perfusion → brain death.
• Hypoxemia increases CPP only if Po₂ < 50 mm Hg.
• CPP is directly proportional to Pco₂ until Pco₂ > 90 mm Hg.

Question 68

Cerebral Arteries—Cortical Distribution

Answer 68

Question 69

Watershed Zones

Answer 69

• Between anterior cerebral/middle cerebral, posterior cerebral/middle cerebral arteries (cortical border zones); or may also occur between the superficial and deep vascular territories of the middle cerebral artery (internal border zones).
• Damage by severe hypotension → proximal upper and lower extremity weakness (if internal border zone stroke), higher order visual dysfunction (if posterior cerebral/middle cerebral cortical border zone stroke).

Question 70

Circle of Willis

Answer 70

System of anastomoses between anterior and posterior blood supplies to brain.

Question 71

Dural Venous Sinuses

Answer 71

• Large venous channels that run through the periosteal and meningeal layers of the dura mater.
• Drain blood from cerebral veins (arrow) and receive CSF from arachnoid granulations.
• Empty into internal jugular vein.

Question 72

Neuropathology:

• presents with signs/symptoms of ↑ ICP (eg. headache, seizures, focal neurologic deficits)
• may lead to venous hemorrhage
• associated with hypercoagulable states (eg. pregnancy, OCP use, factor V Leiden)

Answer 72

Venous Sinus Thrombosis

Question 73

Ventricular System

Answer 73

• Lateral Ventricles → 3rd Ventricle via right and left Interventricular Foramina of Monro
• 3rd ventricle → 4th ventricle via Cerebral Aqueduct of Sylvius
• 4th ventricle → subarachnoid space via:
  
  • Foramina of Luschka = Lateral
  • Foramen of Magendie = Medial
• CSF made by ependymal cells of choroid plexus.
• Travels to subarachnoid space via foramina of Luschka and Magendie, is reabsorbed by arachnoid granulations, and then drains into dural venous sinuses.

Question 74

Brain Stem—Ventral View

Answer 74

• 4 CN are above pons (I, II, III, IV)
• 4 CN exit the pons (V, VI, VII, VIII)
• 4 CN are in medulla (IX, X, XI, XII)
• 4 CN nuclei are medial (III, IV, VI, XII)
  
  • “Factors of 12, except 1 and 2.”

Question 75

Brain Stem—Dorsal View

(cerebellum removed)

Answer 75

• Pineal Gland
  
  • melatonin secretion, circadian rhythms
• Superior Colliculi
  
  • direct eye movements to stimuli (noise/movements) or objects of interest
• Inferior Colliculi
  
  • auditory
• Your eyes are above your ears, and the superior colliculus (visual) is above the inferior colliculus (auditory).

Question 76

Cranial Nerve Nuclei

Answer 76

• Located in tegmentum portion of brain stem (between dorsal and ventral portions):
  
  • Midbrain—nuclei of CN III, IV
  • Pons—nuclei of CN V, VI, VII, VIII
  • Medulla—nuclei of CN IX, X, XII
  • Spinal cord—nucleus of CN XI
• Lateral Nuclei = sensory (aLar plate)
• Medial Nuclei = Motor (basal plate)
• Sulcus Limitans—separates the cranial nerve motor nuclei from the sensory nuclei

Question 77

Cranial Nerve and Vessel Pathways

Answer 77

Question 78

Cranial Nerves

Answer 78

Oh, Oh, Oh, To Touch And Feel A Girl’s Vagina, Simply Heaven!

• Olfactory
• Optic
• Oculomotor
• Trochlear
• Trigeminal
• Abducens
• Facial
• Auditory/Vestibulocochlear
• Glossopharyngeal
• Vagus
• Accessory
• Hypoglossal

Some Say Marry Money, But My Brother Says Big Brains Matter Most.

• Sensory
• Motor
• Both

Question 79

Cranial Nerves:

• smell
• only CN without thalamic relay to cortex
• sensory

Answer 79

Olfactory I

Question 80

Cranial Nerves:

• sight
• sensory

Answer 80

Optic II

Question 81

Cranial Nerves:

• eye movement (SR, IR, MR, IO)
• pupillary constriction (sphincter pupillae: Edinger-Westphal nucleus, muscarinic receptors)
• accommodation
• eyelid opening (levator palpebrae)
• motor

Answer 81

Oculomotor III

Question 82

Cranial Nerves:

• eye movement (SO)
• motor

Answer 82

Trochlear IV

Question 83

Cranial Nerves:

• mastication
• facial sensation (ophthalmic, maxillary, mandibular divisions)
• somatosensation from anterior 2/3 of tongue
• both sensory and motor

Answer 83

Trigeminal V

Question 84

Cranial Nerves:

• eye movement (LR)
• motor

Answer 84

Abducens VI

Question 85

Cranial Nerves:

• facial movement
• taste from anterior 2/3 of tongue (chorda tympani)
• lacrimation
• salivation (submandibular and sublingual glands)
• eyelid closing (orbicularis oculi)
• auditory volume modulation (stapedius)
• both sensory and motor

Answer 85

Facial VII

Question 86

Cranial Nerves:

• hearing
• balance
• sensory

Answer 86

Vestibulocochlear VIII

Question 87

Cranial Nerves:

• taste and sensation from posterior 1/3 of tongue
• swallowing
• salivation (parotid gland)
• monitoring carotid body and sinus chemo- and baroreceptors
• elevation of pharynx/larynx (stylopharyngeus)
• both sensory and motor

Answer 87

Glossopharyngeal IX

Question 88

Cranial Nerves:

• taste from supraglottic region
• swallowing
• soft palate elevation
• midline uvula
• talking
• cough reflex
• parasympathetics to thoracoabdominal viscera
• monitoring aortic arch chemo- and baroreceptors
• both sensory and motor

Answer 88

Vagus X

Question 89

Cranial Nerves:

• head turning
• shoulder shrugging (SCM, trapezius)
• motor

Answer 89

Accessory XI

Question 90

Cranial Nerves:

• tongue movement
• motor

Answer 90

Hypoglossal XII

Question 91

Vagal Nuclei:

• visceral sensory information (eg. taste, baroreceptors, gut distention)
• CN VII, IX, X

Answer 91

Nucleus Solitarius

Solitarius = Sensory

Question 92

Vagal Nuclei:

• motor innervation of pharynx, larynx, and upper esophagus (eg, swallowing, palate elevation)
• CN IX, X, XI (cranial portion)

Answer 92

Nucleus Ambiguus

AMbiguus = Motor

Question 93

Vagal Nuclei:

• sends autonomic (parasympathetic) fibers to heart, lungs, and upper GI
• CN X

Answer 93

Dorsal Motor Nucleus

Question 94

Cranial Nerve Reflexes:

• Afferent:
  
  • V1 ophthalmic (nasociliary branch)
• Efferent:
  
  • bilateral VII (temporal branch: orbicularis oculi)

Answer 94

Corneal

Question 95

Cranial Nerve Reflexes:

• Afferent:
  
  • V1 (loss of reflex does not preclude emotional tears)
• Efferent:
  
  • VII

Answer 95

Lacrimation

Question 96

Cranial Nerve Reflexes:

• Afferent:
  
  • V3 (sensory—muscle spindle from masseter)
• Efferent:
  
  • V3 (motor—masseter)

Answer 96

Jaw Jerk

Question 97

Cranial Nerve Reflexes:

• Afferent:
  
  • II
• Efferent:
  
  • III

Answer 97

Pupillary

Question 98

Cranial Nerve Reflexes:

• Afferent:
  
  • IX
• Efferent:
  
  • X

Answer 98

Gag

Question 99

Mastication Muscles

Answer 99

• 3 muscles close the jaw:
  
  • Masseter
  • TeMporalis
  • Medial Pterygoid

M’s Munch

• 1 muscle opens the jaw:
  
  • Lateral Pterygoid

Lateral Lowers (when speaking of pterygoids with respect to jaw motion)

• All are innervated by trigeminal nerve (V3).
• “It takes more muscle to keep your mouth shut.”

Question 100

Spinal Nerves

Answer 100

• There are 31 pairs of spinal nerves in total:
  
  • 8 cervical
  • 12 thoracic
  • 5 lumbar
  • 5 sacral
  • 1 coccygeal
• Nerves C1–C7 exit above the corresponding vertebra. C8 spinal nerve exits below C7 and above T1.
• All other nerves exit below (eg. C3 exits above the 3rd cervical vertebra; L2 exits below the 2nd lumbar vertebra).

Question 101

Neuropathology:

• nucleus pulposus (soft central disc) herniates through annulus fibrosus (outer ring)
• usually occurs posterolaterally at L4–L5 or L5–S1
• nerve usually affected is below the level of herniation (eg. L3–L4 disc spares L3 nerve and involves L4 nerve)
• compression of S1 nerve root → absent ankle reflex

Answer 101

Vertebral Disc Herniation

Question 102

Spinal Cord—Lower Extent

Answer 102

• In adults, spinal cord ends at lower border of L1–L2 vertebrae.
• Subarachnoid Space (which contains the CSF) extends to lower border of S2 vertebra.
• Lumbar puncture is usually performed between L3–L4 or L4–L5 (level of cauda equina).
• “To keep the cord alive, keep the spinal needle between L3 and L5.”
• Goal of lumbar puncture is to obtain sample of CSF without damaging spinal cord.

Question 103

Spinal Cord and Associated Tracts

Answer 103

• Legs (Lumbosacral) are Lateral in Lateral corticospinal, spinothalamic tracts.
• Dorsal columns are organized as you are, with hands at sides.
• “Arms outside, legs inside.”

Question 104

_____ tracts synapse and then cross.

Answer 104

Ascending

Question 105

Spinal Tract Anatomy and Functions:

• ascending tract
• Function:
  
  • pressure
  • vibration
  • fine touch
  • proprioception
• 1st Order Neuron:
  
  • sensory nerve ending → bypass pseudounipolar cell body in dorsal root ganglion → enter spinal cord → ascend ipsilaterally in dorsal columns
• Synapse 1:
  
  • Nucleus Gracilis
  • Nucleus Cuneatus (ipsilateral medulla)
• 2nd-Order Neurons:
  
  • decussates in medulla → ascends contralaterally as the medial lemniscus
• Synapse 2 + Projections:
  
  • VPL (thalamus) → sensory cortex

Answer 105

Dorsal Column

Question 106

Spinal Tract Anatomy and Functions:

• ascending tract
• Function:
  
  • Lateral: pain, temperature
  • Anterior: crude touch, pressure
• 1st Order Neuron:
  
  • sensory nerve ending (Aδ and C fibers) → bypass pseudounipolar cell body in dorsal root ganglion → enter spinal cord
• Synapse 1:
  
  • ipsilateral gray matter (spinal cord)
• 2nd-Order Neurons:
  
  • decussates in spinal cord as the anterior white commissure → ascends contralaterally
• Synapse 2 + Projections:
  
  • VPL (thalamus) → sensory cortex

Answer 106

Spinothalamic Tract

Question 107

Spinal Tract Anatomy and Functions:

• descending tract
• Function:
  
  • voluntary movement of contralateral limbs
• 1st Order Neuron:
  
  • UMN: cell body in 1° motor cortex → descends ipsilaterally (through posterior limb of internal capsule), most fibers decussate at caudal medulla (pyramidal decussation) → descends contralaterally
• Synapse 1:
  
  • cell body of anterior horn (spinal cord)
• 2nd-Order Neurons:
  
  • LMN: leaves spinal cord
• Synapse 2 + Projections:
  
  • NMJ → muscle fibers

Answer 107

Lateral Corticospinal Tract

Question 108

Clinical Reflexes

Answer 108

Reflexes count up in order (main nerve root in bold):

• Achilles reflex = S1, S2 (“buckle my shoe”)
• Patellar reflex = L3, L4 (“kick the door”)
• Biceps and Brachioradialis reflexes = C5, C6 (“pick up sticks”)
• Triceps reflex = C7, C8 (“lay them straight”)

Additional reflexes:

• Cremasteric reflex = L1, L2 (“testicles move”)
• Anal Wink reflex = S3, S4 (“winks galore”)

Question 109

Primitive Reflexes

Answer 109

• CNS reflexes that are present in a healthy infant, but are absent in a neurologically intact adult.
• Normally disappear within 1st year of life.
• These “primitive” reflexes are inhibited by a mature/developing frontal lobe.
• They may reemerge in adults following frontal lobe lesions → loss of inhibition of these reflexes.

Question 110

Primitive Reflexes:

• “hang on for life”
• abduct/extend arms when startled, and then draw together

Answer 110

Moro Reflex

Question 111

Primitive Reflexes:

movement of head toward one side if cheek or mouth is stroked (nipple seeking)

Answer 111

Rooting Reflex

Question 112

Primitive Reflexes:

sucking response when roof of mouth is touched

Answer 112

Sucking Reflex

Question 113

Primitive Reflexes:

curling of fingers if palm is stroked

Answer 113

Palmar Reflex

Question 114

Primitive Reflexes:

• dorsiflexion of large toe and fanning of other toes with plantar stimulation
• Babinski Sign—presence of this reflex in an adult, which may signify a UMN lesion

Answer 114

Plantar Reflex

Question 115

Primitive Reflexes:

stroking along one side of the spine while newborn is in ventral suspension (face down) causes lateral flexion of lower body toward stimulated side

Answer 115

Galant Reflex

Question 116

Landmark Dermatomes:

posterior half of skull

Answer 116

C2

Question 117

Landmark Dermatomes:

• high turtleneck shirt
• diaphragm and gallbladder pain referred to the right shoulder via phrenic nerve

Answer 117

C3

C3, 4, 5 keeps the diaphragm alive.

Question 118

Landmark Dermatomes:

low-collar shirt

Answer 118

C4

Question 119

Landmark Dermatomes:

includes thumbs

Answer 119

C6

Thumbs up sign on left hand looks like a 6.

Question 120

Landmark Dermatomes:

at the nipple

Answer 120

T4

T4 at the teat pore.

Question 121

Landmark Dermatomes:

at the xiphoid process

Answer 121

T7

Question 122

Landmark Dermatomes:

• at the umbilicus
• important point of referred pain in early appendicitis

Answer 122

T10

belly butten

Question 123

Landmark Dermatomes:

at the inguinal ligament

Answer 123

L1

Inguinal Ligament

Question 124

Landmark Dermatomes:

includes the kneecaps

Answer 124

L4

down on ALL 4’s

Question 125

Landmark Dermatomes:

sensation of penile and anal zones

Answer 125

S2, S3, S4

S2, 3, 4 keep the penis off the floor

Question 126

Common Brain Lesions:

• disinhibition and deficits in concentration, orientation, and judgment
• may have reemergence of primitive reflexes

Answer 126

Frontal Lobe

Question 127

Common Brain Lesions:

• eyes look toward (destructive) side of lesion
• in seizures (irritative), eyes look away from side of the lesion

Answer 127

Frontal Eye Fields

Question 128

Common Brain Lesions:

• eyes look away from side of lesion
• ipsilateral gaze palsy (inability to look toward side of lesion)

Answer 128

Paramedian Pontine Reticular Formation

Question 129

Common Brain Lesions:

• internuclear ophthalmoplegia (impaired adduction of ipsilateral eye; nystagmus of contralateral eye with abduction)
• Multiple Sclerosis

Answer 129

Medial Longitudinal Fasciculus

Question 130

Common Brain Lesions:

• agraphia, acalculia, finger agnosia, left-right disorientation
• Gerstmann Syndrome

Answer 130

Dominant Parietal Cortex

Question 131

Common Brain Lesions:

• agnosia of the contralateral side of the world
• Hemispatial Neglect Syndrome

Answer 131

Nondominant Parietal Cortex

Question 132

Common Brain Lesions:

Anterograde Amnesia—inability to make new memories

Answer 132

Hippocampus (bilateral)

Question 133

Common Brain Lesions:

• may result in tremor at rest, chorea, and athetosis
• Parkinson Disease
• Huntington Disease

Answer 133

Basal Ganglia

Question 134

Common Brain Lesions:

contralateral hemiballismus

Answer 134

Subthalamic Nucleus

Question 135

Common Brain Lesions:

Wernicke-Korsakoff Syndrome

• confusion
• ataxia
• nystagmus
• ophthalmoplegia
• memory loss (anterograde and retrograde amnesia)
• confabulation
• personality changes

Answer 135

Mammillary Bodies (bilateral)

Wernicke problems come in a CAN O’ beer.

• Confusion
• Ataxia
• Nystagmus
• Ophthalmoplegia

Question 136

Common Brain Lesions:

• Klüver-Bucy Syndrome
  
  • disinhibited behavior
    
    • hyperphagia
    • hypersexuality
    • hyperorality
• HSV-1 Encephalitis

Answer 136

Amygdala (bilateral)

Question 137

Common Brain Lesions:

• Parinaud Syndrome
  
  • vertical gaze palsy
  • pupillary light-near dissociation
  • lid retraction
  • convergence-retraction nystagmus
• stroke, hydrocephalus, pinealoma

Answer 137

Dorsal Midbrain

Question 138

Common Brain Lesions:

reduced levels of arousal and wakefulness (eg. coma)

Answer 138

Reticular Activating System (midbrain)

Question 139

Common Brain Lesions:

• intention tremor, limb ataxia, loss of balance
• ipsilateral deficits
• fall toward side of lesion

Answer 139

Cerebellar Hemisphere

Cerebellar hemispheres are laterally located—affect lateral limbs.

Question 140

Common Brain Lesions:

• Decorticate (flexor) Posturing
  
  • lesion above
  • presents with flexion of upper extremities and extension of lower extremities
• Decerebrate (extensor) Posturing
  
  • lesion at or below
  • presents with extension of upper and lower extremities
  • worse prognosis

Answer 140

Red Nucleus

Question 141

Common Brain Lesions:

• truncal ataxia (wide-based, “drunken sailor” gait), dysarthria
• degeneration associated with chronic alcohol use

Answer 141

Cerebellar Vermis

Vermis is centrally located—affects central body.

Question 142

Ischemic Brain Disease/Stroke

Answer 142

• Irreversible damage begins after 5 minutes of hypoxia.
• Most vulnerable: hippocampus, neocortex, cerebellum (Purkinje cells), watershed areas. Irreversible neuronal injury.
• Hippocampus is most vulnerable to ischemic hypoxia (“vulnerable hippos”).
• Stroke Imaging:
  
  • CT Scan
    
    • Noncontrast CT to exclude hemorrhage (before tPA can be given)
    • CT detects ischemic changes in 6–24 hr
  • MRI
    
    • Diffusion-Weighted MRI can detect ischemia within 3–30 min

Question 143

Histologic Features of Stroke:

12-24 hours

Answer 143

eosinophilic cytoplasm + pyknotic nuclei (red neurons)

Question 144

Histologic Features of Stroke:

24-72 hours

Answer 144

necrosis + neutrophils

Question 145

Histologic Features of Stroke:

3-5 days

Answer 145

macrophages (microglia)

Question 146

Histologic Features of Stroke:

1-2 weeks

Answer 146

reactive gliosis (astrocytes + vascular proliferation

Question 147

Histologic Features of Stroke:

> 2 weeks

Answer 147

glial scar

Question 148

Neuropathology:

acute blockage of vessels → disruption of blood flow and subsequent ischemia → liquefactive necrosis

Answer 148

Ischemic Stroke

Question 149

Ischemic Stroke:

• due to a clot forming directly at site of infarction (commonly the MCA)
• usually over an atherosclerotic plaque

Answer 149

Thrombotic

Question 150

Ischemic Stroke:

• embolus from another part of the body obstructs vessel
• can affect multiple vascular territories
• Examples:
  
  • atrial fibrillation
  • carotid artery stenosis
  • DVT with patent foramen ovale

Answer 150

Embolic

Question 151

Ischemic Stroke:

• due to hypoperfusion or hypoxemia
• common during cardiovascular surgeries
• tends to affect watershed areas

Answer 151

Hypoxic

Question 152

Ischemic Stroke:

Treatment

Answer 152

• tPA (if within 3–4.5 hr of onset and no hemorrhage/risk of hemorrhage).
• Reduce risk with medical therapy (eg. Aspirin, Clopidogrel); optimum control of blood pressure, blood sugars, lipids; and treat conditions that ↑ risk (eg. atrial fibrillation, carotid artery stenosis).

Question 153

Neuropathology:

• brief, reversible episode of focal neurologic dysfunction without acute infarction (⊝ MRI), with the majority resolving in < 15 minutes
• deficits due to focal ischemia

Answer 153

Transient Ischemic Attack

Question 154

Neuropathology:

• bleeding into ventricles
• increased risk in premature and low-birth-weight infants
• originates in germinal matrix, a highly vascularized layer within the subventricular zone
• due to reduced glial fiber support and impaired autoregulation of BP in premature infants
• can present with altered level of consciousness, bulging fontanelle, hypotension, seizures, and coma

Answer 154

Neonatal Intraventricular Hemorrhage

Question 155

Intracranial Hemorrhage:

• rupture of middle meningeal artery (branch of maxillary artery), often 2° to skull fracture (circle in A) involving the pterion (thinnest area of the lateral skull)
• lucid interval
• scalp hematoma (arrows in A) and rapid intracranial expansion (arrows in B) under systemic arterial pressure → transtentorial herniation, CN III palsy
• CT shows biconvex (lentiform), hyperdense blood collection (B) not crossing suture lines

Answer 155

Epidural Hematoma

Question 156

Intracranial Hemorrhage:

• rupture of bridging veins
• can be acute (traumatic, high-energy impact → hyperdense on CT) or chronic (associated with mild trauma, cerebral atrophy, elderly, alcoholism → hypodense on CT)
• also seen in shaken babies
• Predisposing Factors:
  
  • brain atrophy
  • trauma
• crescent-shaped hemorrhage (red arrows in C and D) that crosses suture lines
• can cause midline shift (yellow arrow in C)
• findings of “acute on chronic” hemorrhage (blue arrows in D)

Answer 156

Subdural Hematoma

Question 157

Intracranial Hemorrhage:

• bleeding (E, F) due to trauma, or rupture of an aneurysm (such as a saccular aneurysm E) or arteriovenous malformation
• rapid time course
• patients complain of “worst headache of my life”
• bloody or yellow (xanthochromic) spinal tap
• vasospasm can occur due to blood breakdown or rebleed 3–10 days after hemorrhage → ischemic infarct
• Nimodipine is used to prevent/reduce vasospasm
• ↑ risk of developing communicating and/or obstructive hydrocephalus

Answer 157

Subarachnoid Hemorrhage

Question 158

Intracranial Hemorrhage:

• most commonly caused by systemic hypertension
• also seen with amyloid angiopathy (recurrent lobar hemorrhagic stroke in elderly), vasculitis, and neoplasm
• may be 2º to reperfusion injury in ischemic stroke
• hypertensive hemorrhages (Charcot-Bouchard microaneurysm) most often occur in the putamen of the basal ganglia (lenticulostriate vessels G), followed by thalamus, pons, and cerebellum (H)

Answer 158

Intraparenchymal Hemorrhage

Question 159

Effects of Strokes:

Anterior Circulation

Answer 159

Question 160

Effects of Strokes:

Posterior Circulation

Answer 160

Question 161

Neuropathology:

• neuropathic pain due to thalamic lesions
• initial paresthesias followed in weeks to months by allodynia (ordinarily painless stimuli cause pain) and dysesthesia on the contralateral side
• occurs in 10% of stroke patients

Answer 161

Central Post-Stroke Pain Syndrome

Question 162

Neuropathology:

• caused by traumatic shearing forces during rapid acceleration and/or deceleration of the brain (eg. motor vehicle accident)
• usually results in devastating neurologic injury, often causing coma or persistent vegetative state

Answer 162

Diffuse Axonal Injury

Question 163

Neuropathology:

• higher-order language deficit (inability to understand/produce/use language appropriately)
• caused by pathology in dominant cerebral hemisphere (usually left)

Answer 163

Aphasia

Question 164

Neuropathology:

motor inability to speak (movement deficit)

Answer 164

Dysarthria

Question 165

Aphasia:

• repetition impaired
• nonfluent speech
• intact comprehension
• patient appears frustrated
• insight intact

Answer 165

Broca (Expressive)

• Broca Area in inferior frontal gyrus of frontal lobe

Broca = Broken

Question 166

Aphasia:

• repetition impaired
• fluent speech
• impaired comprehension
• patients do not have insight

Answer 166

Wernicke (Receptive)

• Wernicke Area in superior temporal gyrus of tempora lobe

Wernicke = Wordy

Question 167

Aphasia:

• repetition impaired
• fluent speech
• intact comprehension
• can be caused by damage to arcuate fasciculus

Answer 167

Conduction (Associative)

arCuate fasciculus

Question 168

Aphasia:

• repetition impaired
• nonfluent speech
• impaired comprehension
• Arcuate Fasciculus, Broca and Wernicke areas affected

Answer 168

Global

Question 169

Aphasia:

• repetition intact
• nonfluent speech
• intact comprehension
• affects frontal lobe around Broca area, but Broca area is spared

Answer 169

Transcortical Motor

Question 170

Aphasia:

• repetition intact
• fluent speech
• impaired comprehension
• affects temporal lobe around Wernicke area, but Wernicke area is spared

Answer 170

Transcortical Sensory

Question 171

Aphasia:

• repetition intact
• nonfluent speech
• impaired comprehension
• Broca and Wernicke areas and arcuate fasciculus remain intact
• surrounding watershed areas affected

Answer 171

Transcortical, Mixed

Question 172

Neuropathology:

abnormal dilation of an artery due to weakening of vessel wall

Answer 172

Aneurysms

Question 173

Aneurysms:

• also known as berry aneurysm
• occurs at bifurcations in the Circle of Willis
• most common site is the junction of ACom and ACA
• associated with ADPKD and Ehlers-Danlos syndrome
• Risk Factors:
  
  • advanced age
  • hypertension
  • smoking
  • race (↑ risk in African-Americans)
• usually clinically silent until rupture (most common complication) → subarachnoid hemorrhage
• (“worst headache of my life” or “thunderclap headache”) → focal neurologic deficits. Can also
• cause symptoms via direct compression of surrounding structures by growing aneurysm.

Answer 173

Saccular Aneurysm

Question 174

Saccular Aneurysms:

• compression → bitemporal hemianopia (compression of optic chiasm)
• visual acuity deficits
• rupture → ischemia in ACA distribution → contralateral lower extremity hemiparesis, sensory deficits

Answer 174

ACom

Question 175

Saccular Aneurysms:

rupture → ischemia in MCA distribution → contralateral upper extremity and lower facial hemiparesis, sensory deficits

Answer 175

MCA

Question 176

Saccular Aneurysms:

• compression → ipsilateral CN III palsy → mydriasis (“blown pupil”)
• may also see ptosis, “down and out” eye

Answer 176

PCom

Question 177

Aneurysms:

• common
• associated with chronic hypertension
• affects small vessels (eg. lenticulostriate arteries in basal ganglia, thalamus) and can cause lacunar strokes
• not visible on angiography

Answer 177

Charcot-Bouchard Microaneurysm

Question 178

Neuropathology:

• characterized by synchronized, high-frequency neuronal firing
• variety of forms

Answer 178

Seizures

Question 179

Seizures:

• affect single area of the brain
• most commonly originate in medial temporal lobe

Answer 179

Partial (Focal) Seizures

Question 180

Seizures:

• partial
• consciousness intact
• motor, sensory, autonomic, psychic

Answer 180

Simple Partial

Question 181

Seizures:

• partial
• impaired consciousness
• automatisms

Answer 181

Complex Partial

Question 182

Seizures:

diffuse

Answer 182

Generalized Seizures

Question 183

Seizures:

• diffuse
• 3 Hz spike-and-wave discharges
• no postictal confusion
• blank stare

Answer 183

Absence (petit mal)

Question 184

Seizures:

• diffuse
• quick, repetitive jerks

Answer 184

Myoclonic

Question 185

Seizures:

• diffuse
• alternating stiffening and movement

Answer 185

Tonic-Clonic (grand mal)

Question 186

Seizures:

• diffuse
• stiffening

Answer 186

Tonic

Question 187

Seizures:

• diffuse
• “drop” seizures (falls to floor)
• commonly mistaken for fainting

Answer 187

Atonic

Question 188

Seizures:

a disorder of recurrent seizures

Answer 188

Epilepsy

Question 189

Seizures:

continuous (≥ 5 min) or recurring seizures that may result in brain injury

Answer 189

Status epEilepticus

Question 190

Causes of Seizures by Age:

Children

Answer 190

• genetic
• infection (febrile)
• trauma
• congenital
• metabolic

Question 191

Causes of Seizures by Age:

Adults

Answer 191

• tumor
• trauma
• stroke
• infection

Question 192

Causes of Seizures by Age:

Elderly

Answer 192

• stroke
• tumor
• trauma
• metabolic
• infection

Question 193

Neuropathology:

• pain due to irritation of structures such as the dura, cranial nerves, or extracranial structures
• more common in females, except cluster

Answer 193

Headaches

Question 194

Headaches:

• unilateral
• 15 min–3 hr
• repetitive
• excruciating periorbital pain (“suicide headache”) with lacrimation and rhinorrhea
• may present with Horner syndrome
• more common in males

Answer 194

Cluster

Question 195

Headaches:

• bilateral
• > 30 min (typically 4–6 hr)
• constant
• steady, “band-like” pain
• no photophobia or phonophobia
• no aura

Answer 195

Tension

Question 196

Headaches:

• unilateral
• 4–72 hr
• pulsating pain with nausea, photophobia, or phonophobia
• may have “aura”
• due to irritation of CN V, meninges, or blood vessels (release of substance P, calcitonin gene-related peptide, vasoactive peptides)

Answer 196

Migraine

POUND:

• Pulsatile
• One-day duration
• Unilateral
• Nausea
• Disabling

Question 197

Headache Treatment:

Cluster

Answer 197

• Acute:
  
  • Sumatriptan
  • 100% O₂
• Prophylaxis:
  
  • Verapamil

Question 198

Headache Treatment:

Tension

Answer 198

• Analgesics
• NSAIDs
• Acetaminophen
• Amitriptyline for chronic pain

Question 199

Headache Treatment:

Migraine

Answer 199

• Acute:
  
  • NSAIDs
  • Triptans
  • Dihydroergotamine
• Prophylaxis:
  
  • lifestyle changes (eg. sleep, exercise, diet)
  • β-Blockers
  • Amitriptyline
  • Topiramate
  • Valproate

Question 200

Causes of Headache

Answer 200

• Subarachnoid Hemorrhage
  
  • “worst headache of my life”
• Meningitis
• Hydrocephalus
• Neoplasia
• Giant Cell (Temporal) Arteritis

Question 201

Neuropathology:

• produces repetitive, unilateral, shooting pain in the distribution of CN V
• triggered by chewing, talking, touching certain parts of the face
• lasts (typically) for seconds to minutes, but episodes often increase in intensity and frequency over time
• Treatment: Carbamazepine

Answer 201

Trigeminal Neuralgia

Question 202

Movement Disorders:

• restlessness and intense urge to move
• can be seen with neuroleptic use or as a side-effect of Parkinson treatment

Answer 202

Akathisia

Question 203

Movement Disorders:

• extension of wrists causes “flapping” motion
• associated with hepatic encephalopathy, Wilson disease, and other metabolic derangements

Answer 203

Asterixis

Question 204

Movement Disorders:

• slow, snake-like, writhing movements
• especially seen in the fingers
• basal ganglia lesion

Answer 204

Athetosis

Question 205

Movement Disorders:

• sudden, jerky, purposeless movements
• basal ganglia lesion
• seen in Huntington disease and in acute rheumatic fever

Answer 205

Chorea

Question 206

Movement Disorders:

• sustained, involuntary muscle contractions
• writer’s cramp, blepharospasm, torticollis

Answer 206

Dystonia

Question 207

Movement Disorders:

• high-frequency tremor with sustained posture (eg. outstretched arms)
• worsened with movement or when anxious
• often familial
• patients often self-medicate with alcohol, which ↓ tremor amplitude.
• Treatment:
  
  • Nonselective β-Blockers (eg. Propranolol)
  • Primidone

Answer 207

Essential Tremor

Question 208

Movement Disorders:

• sudden, wild flailing of 1 arm +/− ipsilateral leg
• contralateral subthalamic nucleus lesion (eg. lacunar stroke)
• contralateral lesion

Answer 208

Hemiballismus

Question 209

Movement Disorders:

• slow, zigzag motion when pointing/extending toward a target
• cerebellar dysfunction

Answer 209

Intention Tremor

Question 210

Movement Disorders:

• sudden, brief, uncontrolled muscle contraction
• jerks, hiccups
• common in metabolic abnormalities such as renal and liver failure

Answer 210

Myoclonus

Question 211

Movement Disorders:

• uncontrolled movement of distal appendages (most noticeable in hands)
• tremor alleviated by intentional movement
• substantia nigra lesion (Parkinson disease)
• occurs at rest
• “pill-rolling tremor” of Parkinson disease

Answer 211

Resting Tremor

Question 212

Movement Disorders:

• worse at rest/nighttime
• relieved by movement
• associated with iron deficiency and CKD
• Treatment:
  
  • Dopamine Agonists
    
    • Pramipexole
    • Ropinirole

Answer 212

Restless Legs Syndrome

Question 213

Neuropathology:

• ↓ in cognitive ability, memory, or function with intact consciousness
• must rule out depression as cause of dementia (known as pseudodementia)

Answer 213

Neurodegenerative Disorders

Question 214

Neurodegenerative Disorders:

• pill-rolling tremor at rest
• cogwheel rigidity
• akinesia or bradykinesia
• postural instability
• shuffling gait
• MPTP, a contaminant in illegal drugs, is metabolized to MPP+, which is toxic to substantia nigra
• loss of dopaminergic neurons (ie. depigmentation) of substantia nigra pars compacta
• Lewy Bodies:
  
  • composed of α-synuclein (intracellular eosinophilic inclusions)

Answer 214

Parkinson Disease

Parkinson TRAPS your body:

• Tremor (pill-rolling tremor at rest)
• Rigidity (cogwheel)
• Akinesia (or bradykinesia)
• Postural instability
• Shuffling gait

Question 215

Neurodegenerative Disorders:

• autosomal dominant trinucleotide (CAG)_n repeat expansion in the huntingtin (HTT) gene on chromosome 4
• symptoms manifest between ages 20 and 50:
  
  • chorea
  • athetosis
  • aggression
  • depression
  • dementia
• sometimes initially mistaken for substance abuse)
• anticipation results from expansion of CAG repeats
• caudate loses ACh and GABA
• atrophy of caudate and putamen with ex vacuo ventriculomegaly
• ↑ dopamine, ↓ GABA, ↓ ACh in brain
• neuronal death via NMDA-R binding and glutamate excitotoxicity

Answer 215

Huntington Disease

huntingtin = chromosome 4 (4 letters)

CAG repeats = Caudate loses ACh and GABA

Question 216

Neurodegenerative Disorders:

• most common cause of dementia in elderly
• Down syndrome patients have ↑ risk
• APP is located on chromosome 21
• ↓ ACh
• associated with the following altered proteins:
  
  • ApoE-2: ↓ risk of sporadic form
  • ApoE-4: ↑ risk of sporadic form
  • APP, presenilin-1, presenilin-2: familial forms (10%) with earlier onset
• widespread cortical atrophy, especially hippocampus
• narrowing of gyri and widening of sulci
• senile plaques in gray matter:
  
  • extracellular β-amyloid core
  • may cause amyloid angiopathy → intracranial hemorrhage
  • Aβ (amyloid-β) synthesized by cleaving amyloid precursor protein (APP)
• Neurofibrillary Tangles
  
  • intracellular, hyperphosphorylated tau protein = insoluble cytoskeletal elements
  • number of tangles correlates with degree of dementia

Answer 216

Alzheimer Disease

Question 217

Neurodegenerative Disorders:

• also known as Pick disease
• early changes in personality and behavior (behavioral variant), or aphasia (primary progressive aphasia)
• may have associated movement disorders (eg. parkinsonism)
• frontotemporal lobe degeneration
• inclusions of hyperphosphorylated tau (round Pick bodies) or ubiquitinated TDP-43

Answer 217

Frontotemporal Dementia

Question 218

Neurodegenerative Disorders:

• visual hallucinations
• dementia with fluctuating cognition/alertness, REM sleep behavior disorder, and parkinsonism
• cognitive and motor symptom onset < 1 year apart, otherwise considered dementia 2° to Parkinson disease
• intracellular Lewy bodies primarily in cortex

Answer 218

Lewy Body Dementia

“haLewycinations”

Question 219

Neurodegenerative Disorders:

• result of multiple arterial infarcts and/or chronic ischemia
• step-wise decline in cognitive ability with late-onset memory impairment
• 2nd most common cause of dementia in elderly
• MRI or CT shows multiple cortical and/or subcortical infarcts

Answer 219

Vascular Dementia

Question 220

Neurodegenerative Disorders:

• rapidly progressive (weeks to months) dementia with myoclonus (“startle myoclonus”) and ataxia
• commonly see periodic sharp waves on EEG and ↑ 14-3-3 protein in CSF
• spongiform cortex
• prions (PrPc → PrPsc sheet [β-pleated sheet resistant to proteases])

Answer 220

Creutzfeldt-Jakob Disease

Question 221

Neuropathology:

• also known as pseudotumor cerebri
• ↑ ICP with no apparent cause on imaging (eg. hydrocephalus, obstruction of CSF outflow)
• risk factors include female gender, tetracyclines, besity, vitamin A excess, and Danazol
• headache, tinnitus, diplopia (usually from CN VI palsy), no change in mental status
• impaired optic nerve axoplasmic flow → papilledema
• visual field testing shows enlarged blind spot and peripheral constriction
• lumbar puncture reveals ↑ opening pressure and provides temporary headache relief
• Treatment:
  
  • weight loss
  • Acetazolamide
  • invasive procedures for refractory cases (eg. CSF shunt placement, optic nerve sheath fenestration surgery for visual loss)

Answer 221

Idiopathic Intracranial Hypertension

Female TOAD:

• Female
• Tetracyclines
• Obesity
• Vitamin A excess
• Danazol

Question 222

Neuropathology:

↑ CSF volume → ventricular dilation +/− ↑ ICP

Answer 222

Hydrocephalus

Question 223

Hydrocephalus:

↓ CSF absorption by arachnoid granulations (eg. arachnoid scarring post-meningitis) → ↑ ICP, papilledema, herniation

Answer 223

Communicating Hydrocephalus

Question 224

Hydrocephalus:

• communicating
• affects the elderly
• idiopathic
• CSF pressure elevated only episodically
• does not result in increased subarachnoid space volume
• expansion of ventricles distorts the fibers of the corona radiata → triad of urinary incontinence, gait apraxia (magnetic gait), and cognitive dysfunction (sometimes reversible)
• symptoms potentially reversible with CSF shunt placement

Answer 224

Normal Pressure Hydrocephalus

“Wet, wobbly, and wacky.”

• urinary incontinence
• gait apraxia (magnetic gait)
• cognitive dysfunction

Question 225

Hydrocephalus:

caused by structural blockage of CSF circulation within ventricular system (eg. stenosis of aqueduct of Sylvius; colloid cyst blocking foramen of Monro; tumor)

Answer 225

Noncommunicating Hydrocephalus

Question 226

Hydrocephalus:

• appearance of ↑ CSF on imaging, but is actually due to ↓ brain tissue and neuronal atrophy (eg. Alzheimer disease, advanced HIV, Pick disease, Huntington disease)
• normal pressure hydrocephalus triad is not seen

Answer 226

Ex Vacuo Ventriculomegaly

Question 227

Neuropathology:

• autoimmune inflammation and demyelination of CNS (brain and spinal cord) with subsequent axonal damage
• Findings:
  
  • acute optic neuritis (painful unilateral visual loss associated with Marcus Gunn pupil)
  • brain stem/cerebellar syndromes (eg. diplopia, ataxia, scanning speech, intention tremor, nystagmus/INO (bilateral > unilateral)
  • pyramidal tract weakness
  • spinal cord syndromes (eg. electric shock-like sensation along spine on neck flexion [Lhermitte phenomenon], neurogenic bladder, paraparesis, sensory manifestations affecting the trunk or one or more extremity)
• symptoms may exacerbate with increased body temperature (eg. hot bath, exercise)
• relapsing and remitting is most common clinical course
• most often affects women in their 20s and 30s
• more common in Caucasians living farther from equator

Answer 227

Multiple Sclerosis

Question 228

Neuropathology:

• ↑ IgG level and myelin basic protein in CSF
• oligoclonal bands are diagnostic
• MRI is the gold standard
• periventricular plaques (areas of oligodendrocyte loss and reactive gliosis)
• multiple white matter lesions disseminated in space and time

Answer 228

Multiple Sclerosis

Question 229

Multiple Sclerosis:

Treatment

Answer 229

• Stop relapses and halt/slow progression with disease-modifying therapies (eg. β-interferon, glatiramer, natalizumab).
• Treat acute flares with IV steroids.
• Symptomatic treatment for neurogenic bladder (catheterization, muscarinic antagonists), spasticity (baclofen, GABA_B receptor agonists), and pain (TCAs, anticonvulsants).

Question 230

Demyelinating and Dysmyelinating Disorders:

• also known as Central Pontine Myelinolysis
• massive axonal demyelination in pontine white matter 2° to rapid osmotic changes, most commonly iatrogenic correction of hyponatremia but also rapid shifts of other osmolytes (eg. glucose)
• acute paralysis, dysarthria, dysphagia, diplopia, and loss of consciousness
• can cause “locked-in syndrome”

Answer 230

Osmotic Demyelination Syndrome

Fast Serum Na+ Correction:

• “from low to high, your pons will die” (Osmotic Demyelination Syndrome)
• “From high to low, your brains will blow” (Cerebral Edema/Herniation)

Question 231

Demyelinating and Dysmyelinating Disorders:

• most common subtype of Guillain-Barré syndrome
• autoimmune condition associated with infections (eg. Campylobacter jejuni, viruses [eg. Zika]) that destroys Schwann cells by inflammation and demyelination of peripheral nerves (including cranial nerves III-XII) and motor fibers likely due to molecular mimicry, inoculations, and stress, but no definitive link to pathogens
• results in symmetric ascending muscle weakness/paralysis and depressed/absent DTRs beginning in lower extremities
• facial paralysis (usually bilateral) and respiratory failure are common
• may see autonomic dysregulation (eg. cardiac irregularities, hypertension, hypotension) or sensory abnormalities
• almost all patients survive
• majority recover completely after weeks to months
• ↑ CSF protein with normal cell count (albuminocytologic dissociation)
• respiratory support is critical until recovery
• Disease-Modifying Treatment:
  
  • plasmapheresis
  • IV immunoglobulins
  • no role for steroids

Answer 231

Acute Inflammatory Demyelinating Polyradiculopathy

Question 232

Demyelinating and Dysmyelinating Disorders:

• multifocal inflammation and demyelination after infection or vaccination
• presents with rapidly progressive multifocal neurologic symptoms and altered mental status

Answer 232

Acute Disseminated (Postinfectious) Encephalomyelitis

Question 233

Demyelinating and Dysmyelinating Disorders:

• also known as Hereditary Motor and Sensory Neuropathy
• group of progressive hereditary nerve disorders related to the defective production of proteins involved in the structure and function of peripheral nerves or the myelin sheath
• typically autosomal dominant inheritance pattern and associated with foot deformities (eg. pes cavus, hammer toe), lower extremity weakness (eg. foot drop), and sensory deficits
• most common type, CMT1A, is caused by PMP22 gene duplication

Answer 233

Charcot-Marie-Tooth Disease

Question 234

Demyelinating and Dysmyelinating Disorders:

• demyelination of CNS due to destruction of oligodendrocytes (2° to reactivation of latent JC virus infection)
• seen in 2–4% of patients with AIDS
• rapidly progressive, usually fatal
• predominantly involves parietal and occipital areas
• visual symptoms are common
• ↑ risk associated with Natalizumab and Rituximab

Answer 234

Progressive Multifocal Leukoencephalopathy

Question 235

Neurocutaneous Disorders:

• also known as Encephalotrigeminal Angiomatosis
• congenital, noninherited (sporadic), developmental anomaly of neural crest derivatives due to somatic mosaicism for an activating mutation in one copy of the GNAQ gene
• affects small (capillary-sized) blood vessels → port-wine stain of the face (nevus flammeus, a non-neoplastic “birthmark” in CN V1/V2 distribution)
• ipsilateral leptomeningeal angioma → seizures/epilepsy
• intellectual disability
• episcleral hemangioma → ↑ IOP → early-onset glaucoma

Answer 235

Sturge-Weber Syndrome

STURGE-Weber:

• Sporadic
• port-wine Stain
• Tram track calcifications (opposing gyri)
• Unilateral
• Retardation (intellectual disability)
• Glaucoma
• GNAQ gene
• Epilepsy

Question 236

Neurocutaneous Disorders:

• TSC1 mutation on chromosome 9 or TSC2 mutation on chromosome 16
• tumor suppressor genes
• autosomal dominant, variable expression
• hamartomas in CNS and skin
• angiofibromas
• mitral regurgitation
• ash-leaf spots
• cardiac rhabdomyoma
• autosomal dominant
• mental retardation (intellectual disability)
• renal angiomyolipoma
• seizures
• Shagreen patches
• ↑ incidence of subependymal giant cell astrocytomas and ungual fibromas

Answer 236

Tuberous Sclerosis

HAMARTOMAS:

• Hamartomas in CNS and skin
• Angiofibromas
• Mitral regurgitation
• Ash-leaf spots
• cardiac Rhabdomyoma
• Tuberous sclerosis
• autosomal dOminant
• Mental retardation
• renal Angiomyolipoma
• Seizures
• Shagreen patches

Question 237

Neurocutaneous Disorders:

• also known as von Recklinghausen disease
• mutation in NF1 tumor suppressor gene on chromosome 17, which normally codes for neurofibromin, a negative regulator of RAS
• autosomal dominant, 100% penetrance
• café-au-lait spots ,cutaneous neurofibromas, optic gliomas, pheochromocytomas, Lisch nodules (pigmented iris hamartomas)

Answer 237

Neurofibromatosis Type I

Chromosome 17 = 17 letters in “von Recklinghausen”

Question 238

Neurocutaneous Disorders:

• mutation in NF2 tumor suppressor gene on chromosome 22
• autosomal dominant
• Findings:
  
  • bilateral acoustic schwannomas
  • juvenile cataracts
  • meningiomas
  • ependymomas

Answer 238

Neurofibromatosis Type II

NF2 affects 2 ears, 2 eyes, and 2 parts of the brain.

Question 239

Neurocutaneous Disorders:

• deletion of VHL gene on chromosome 3p
• autosomal dominant
• pVHL ubiquitinates hypoxia-inducible factor 1a
• characterized by development of numerous tumors, both benign and malignant
• hemangioblastomas (high vascularity with hyperchromatic nuclei) in retina, brain stem, cerebellum, and spine
• angiomatosis (eg. cavernous hemangiomas in skin, mucosa, organs)
• bilateral renal cell carcinomas
• pheochromocytomas

Answer 239

von Hippel-Lindau Disease

Chromosome 3p = VHL has 3 letters

HARP:

• Hemangioblastomas
• Angiomatosis
• bilateral Renal cell carcinomas
• Pheochromocytomas

Question 240

Adult Primary Brain Tumors:

• grade IV astrocytoma
• common, highly malignant 1° brain tumor with ~ 1-year median survival
• found in cerebral hemispheres
• can cross corpus callosum (“butterfly glioma”)
• astrocyte origin
• GFAP ⊕
• “pseudopalisading” pleomorphic tumor cells border central areas of necrosis, hemorrhage, and/or microvascular proliferation

Answer 240

Glioblastoma Multiforme

Question 241

Adult Primary Brain Tumors:

• relatively rare
• slow growing
• most often in frontal lobes
• “chicken-wire” capillary pattern
• oligodendrocyte origin
• “Fried Egg” Cells
  
  • round nuclei with clear cytoplasm
  • often calcified

Answer 241

Oligodendroglioma

Question 242

Adult Primary Brain Tumors:

• common, typically benign
• females > males
• most often occurs near surfaces of brain and in parasagittal region
• extra-axial (external to brain parenchyma) and may have a dural attachment (“tail”)
• often asymptomatic
• may present with seizures or focal neurologic signs
• treated with resection and/or radiosurgery
• arachnoid cell origin
• spindle cells concentrically arranged in a whorled pattern
• psammoma bodies (laminated calcifications)

Answer 242

Meningioma

Question 243

Adult Primary Brain Tumors:

• most often cerebellar
• associated with von Hippel-Lindau syndrome when found with retinal angiomas
• can produce erythropoietin → 2° polycythemia
• blood vessel origin
• closely arranged, thin-walled capillaries with minimal intervening parenchyma

Answer 243

Hemangioblastoma

Question 244

Adult Primary Brain Tumors:

• may be nonfunctioning (silent) or hyperfunctioning (hormone producing)
• most commonly from lactotrophs (prolactinoma) → hyperprolactinemia
• less commonly adenoma of somatotrophs (GH) → acromegaly/gigantism
• corticotrophs (ACTH) → Cushing disease
• rarely, adenoma of thyrotrophs (TSH) and gonadotroph (FSH, LH)
• nonfunctional tumors present with mass effect (bitemporal hemianopia, hypopituitarism, headache)
• bitemporal hemianopia due to pressure on optic chiasm
• sequelae include hyper- or hypopituitarism, which may be caused by pituitary apoplexy
• hyperplasia of only one type of endocrine cells found in pituitary (ie. lactotroph, gonadotroph, somatotroph, corticotroph)
• prolactinoma in women classically presents as galactorrhea, amenorrhea, and ↓ bone density due to suppression of estrogen
• prolactinoma in men classically presents as low libido and infertility
• Treatment:
  
  • Dopamine Agonists (eg. Bromocriptine, Cabergoline)
  • transsphenoidal resection

Answer 244

Pituitary Adenoma

Question 245

Adult Primary Brain Tumors:

• classically at the cerebellopontine angle involving both CNs VII and VIII, but can be along any peripheral nerve
• often localized to CN VIII in internal acoustic meatus → vestibular _____
• bilateral vestibular _____ found in NF-2
• treated with resection or stereotactic radiosurgery
• Schwann cell origin, S-100 ⊕
• biphasic
• dense, hypercellular areas containing spindle cells alternating with hypocellular, myxoid areas

Answer 245

Schwannoma

Question 246

Childhood Primary Brain Tumors:

• low-grade astrocytoma
• most common 1° brain tumor in childhood
• usually well circumscribed
• in children, most often found in posterior fossa (eg. cerebellum)
• may be supratentorial
• benign, good prognosis.
• glial cell origin, GFAP ⊕
• Rosenthal fibers—eosinophilic, corkscrew fibers
• cystic + solid (gross)

Answer 246

Pilocytic Astrocytoma

Question 247

Childhood Primary Brain Tumors:

• most common malignant brain tumor in childhood
• commonly involves cerebellum
• can compress 4th ventricle, causing noncommunicating hydrocephalus → headaches, papilledema
• can send “drop metastases” to the spinal cord
• form of primitive neuroectodermal tumor (PNET)
• Homer-Wright rosettes, small blue cells

Answer 247

Medulloblastoma

Question 248

Childhood Primary Brain Tumors:

• most commonly found in 4th ventricle
• can cause hydrocephalus
• poor prognosis
• ependymal cell origin
• characteristic perivascular pseudorosettes
• rod-shaped blepharoplasts (basal ciliary bodies) found near the nucleus

Answer 248

Ependymoma

Question 249

Childhood Primary Brain Tumors:

• most common childhood supratentorial tumor
• may be confused with pituitary adenoma (both cause bitemporal hemianopia)
• derived from remnants of Rathke pouch (ectoderm)
• calcification is common
• cholesterol crystals found in “motor oil”-like fluid within tumor

Answer 249

Craniopharyngioma

Question 250

Childhood Primary Brain Tumors:

• tumor of the pineal gland
• can cause Parinaud syndrome (compression of tectum → vertical gaze palsy)
• obstructive hydrocephalus (compression of cerebral aqueduct)
• precocious puberty in males (β-hCG production)
• similar to germ cell tumors (eg. testicular seminoma)

Answer 250

Pinealoma

Question 251

Herniation Syndromes

Answer 251

① Cingulate (subfalcine)

• herniation under falx cerebri
• can compress anterior cerebral artery

② Transtentorial (central/downward)

• caudal displacement of brain stem → rupture of paramedian basilar artery branches → Duret hemorrhages
• usually fatal

③ Uncal

• uncus = medial temporal lobe
• compresses ipsilateral CN III and contralateral crus cerebri against Kernohan notch (causes contralateral CN III palsy and/or ipsilateral hemiparesis, ie. a false localizing sign)

④ Cerebellar Tonsillar

• herniation into the foramen magnum
• coma and death result when these herniations compress the brain stem

Question 252

Motor Neuron Signs:

• Weakness +
• Reflexes ↑
• Tone ↑
• Babinski +
• Spastic Paresis +
• Clasp Knife Spasticity +

Answer 252

Upper Motor Neuron

• everything up (tone, DTRs, toes)

Question 253

Motor Neuron Signs:

• Weakness +
• Atrophy +
• Fasciculations +
• Reflexes ↓
• Tone ↓
• Flaccid Paralysis +

Answer 253

Lower Motor Neuron

• everything lowered (less muscle mass, ↓ muscle tone, ↓ reflexes, downgoing toes)

Question 254

Spinal Cord Lesions:

• congenital degeneration of anterior horns of spinal cord
• LMN lesions only, symmetric weakness
• “floppy baby” with marked hypotonia (flaccid paralysis) and tongue fasciculations
• autosomal recessive inheritance of mutation in SMN1
• type 1 is called Werdnig-Hoffmann disease

Answer 254

Spinal Muscular Atrophy

3 F’s:

• “Floppy baby”
• Flaccid paralysis
• tongue Fasciculations

Question 255

Spinal Cord Lesions:

• combined UMN (corticobulbar/corticospinal) and LMN (medullary and spinal cord) degeneration
• no sensory or bowel/bladder deficits
• can be caused by defect in Superoxide Dismutase 1
• LMN deficits due to anterior horn cell involvement (eg. dysarthria, dysphagia, asymmetric limb weakness, fasciculations, atrophy) and UMN deficits (pseudobulbar palsy, eg. dysarthria, dysphagia, emotional lability, spastic gait, clonus)
• fatal
• commonly known as Lou Gehrig disease
• Treatment: Riluzole

Answer 255

Amyotrophic Lateral Sclerosis

Question 256

Spinal Cord Lesions:

• spares dorsal columns and Lissauer tract
• midthoracic ASA territory is watershed area, as artery of Adamkiewicz supplies ASA below T8
• can be caused by aortic aneurysm repair
• presents with UMN deficit below the lesion (corticospinal tract), LMN deficit at the level of the lesion (anterior horn), and loss of pain and temperature sensation below the lesion (spinothalamic tract

Answer 256

Complete Occlusion of Anterior Spinal Artery

Question 257

Spinal Cord Lesions:

• caused by 3° syphilis
• results from degeneration (demyelination) of dorsal columns and roots → progressive sensory ataxia (impaired proprioception → poor coordination)
• ⊕ Romberg sign and absent DTRs
• associated with Charcot joints, shooting pain, and Argyll Robertson pupils

Answer 257

Tabes Dorsalis

Question 258

Spinal Cord Lesions:

• syrinx expands and damages anterior white commissure of spinothalamic tract (2nd-order neurons) → bilateral symmetrical loss of pain and temperature sensation in cape-like distribution
• seen with Chiari I malformation
• can affect other tracts

Answer 258

Syringomyelia

Question 259

Spinal Cord Lesions:

• Subacute Combined Degeneration (SCD)
• demyelination of spinocerebellar tracts, lateral corticospinal tracts, and dorsal columns
• ataxic gait, paresthesia, and impaired position/vibration sense

Answer 259

Vitamin B12 Deficiency

Subacute Combined Degeneration:

• Spinocerebellar tracts
• lateral Corticospinal tracts
• Dorsal columns

Question 260

Spinal Cord Lesions:

• compression of spinal roots L2 and below, often due to intervertebral disc herniation or tumor
• unilateral radicular pain, absent knee and ankle reflex, loss of bladder and anal sphincter control, saddle anesthesia
• Treatment:
  
  • emergent surgery
  • steroids

Answer 260

Cauda Equina Syndrome

Question 261

Neuropathology:

• caused by poliovirus (fecal-oral transmission)
• replicates in oropharynx and small intestine before spreading via bloodstream to CNS
• infection causes destruction of cells in anterior horn of spinal cord (LMN death)
• Signs of LMN Lesion:
  
  • asymmetric weakness
  • hypotonia
  • flaccid paralysis
  • fasciculations
  • hyporeflexia
  • muscle atrophy
• respiratory muscle involvement leads to respiratory failure
• Signs of Infection:
  
  • malaise, headache, fever, nausea, etc.
• CSF shows ↑ WBCs (lymphocytic pleocytosis) and slight ↑ of protein (with no change in CSF glucose)
• virus recovered from stool or throat

Answer 261

Poliomyelitis

Question 262

Brown-Séquard Syndrome

Answer 262

Hemisection of spinal cord.:

① ipsilateral loss of all sensation at level of lesion
② ipsilateral LMN signs (eg, flaccid paralysis) at level of lesion
③ ipsilateral UMN signs below level of lesion (due to corticospinal tract damage)
④ ipsilateral loss of proprioception, vibration, light (2-point discrimination) touch, and tactile sense below level of lesion (due to dorsal column damage)
⑤ contralateral loss of pain, temperature, and crude (nonadiscriminative) touch below level of lesion (due to spinothalamic tract damage)

If lesion occurs above T1, patient may present
with ipsilateral Horner syndrome due to
damage of oculosympathetic pathway.

Question 263

Neuropathology:

• autosomal recessive trinucleotide repeat disorder (GAA)_n on chromosome 9 in gene that encodes frataxin (iron binding protein)
• leads to impairment in mitochondrial functioning
• degeneration of lateral corticospinal tract (spastic paralysis), spinocerebellar tract (ataxia), dorsal columns (↓ vibratory sense, proprioception), and dorsal root ganglia (loss of DTRs)
• staggering gait, frequent falling, nystagmus, dysarthria, pes cavus, hammer toes, diabetes mellitus, hypertrophic cardiomyopathy (cause of death)
• presents in childhood with kyphoscoliosis

Answer 263

Friedreich Ataxia

Friedreich is Fratastic (frataxin): he’s your
favorite frat brother, always staggering and
falling but has a sweet, big heart.

Ataxic GAAit

Question 264

Common Cranial Nerve Lesions:

jaw deviates toward side of lesion due to unopposed force from the opposite pterygoid muscle

Answer 264

CN V Motor

Question 265

Common Cranial Nerve Lesions:

• uvula deviates away from side of lesion
• weak side collapses and uvula points away

Answer 265

CN X

Question 266

Common Cranial Nerve Lesions:

• weakness turning head to contralateral side of lesion (SCM)
• shoulder droop on side of lesion (trapezius)
• the left SCM contracts to help turn the head to the right

Answer 266

CN XI

Question 267

Common Cranial Nerve Lesions:

• LMN lesion
• tongue deviates toward side of lesion (“lick your wounds”) due to weakened tongue muscles on affected side

Answer 267

CN XII

Question 268

Neuropathology:

• most common cause of peripheral facial palsy
• usually develops after HSV reactivation
• Treatment: Corticosteroids ± Acyclovir
• most patients gradually recover function, but aberrant regeneration can occur
• other causes of peripheral facial palsy:
  
  • include Lyme disease
  • herpes zoster (Ramsay Hunt syndrome)
  • sarcoidosis
  • tumors (eg. parotid gland)
  • diabetes mellitus

Answer 268

Bell Palsy

Question 269

Facial Nerve Lesions:

• Location:
  
  • motor cortex
  • connection from motor cortex to facial nucleus in pons
• Affected Side:
  
  • contralateral
• Muscles Involved:
  
  • lower muscles of facial expression
• Forehead:
  
  • spared, due to bilateral UMN innervation

Answer 269

Upper Motor Neuron Lesion

Question 270

Facial Nerve Lesions:

• Location:
  
  • facial nucleus
  • anywhere along CN VII
• Affected Side:
  
  • ipsilateral
• Muscles Involved:
  
  • upper and lower muscles of facial expression
• Forehead:
  
  • affected
• Other Symptoms:
  
  • incomplete eye closure (dry eyes, corneal ulceration)
  • hyperacusis
  • loss of taste sensation to anterior tongue

Answer 270

Lower Motor Neuron Lesion

Question 271

Auditory Physiology:

• visible portion of ear (pinna)
• includes auditory canal and tympanic membrane
• transfers sound waves via vibration of tympanic membrane

Answer 271

Outer Ear

Question 272

Auditory Physiology:

• air-filled space with three bones called the ossicles (malleus, incus, stapes)
• ossicles conduct and amplify sound from tympanic membrane to inner ear

Answer 272

Middle Ear

Question 273

Auditory Physiology:

• snail-shaped, fluid-filled cochlea
• contains basilar membrane that vibrates 2° to sound waves
• vibration transduced via specialized hair cells → auditory nerve signaling → brain stem
• each frequency leads to vibration at specific location on basilar membrane (tonotopy):
  
  • low frequency heard at apex near helicotrema (wide and flexible)
  • high frequency heard best at base of cochlea (thin and rigid)

Answer 273

Inner Ear

Question 274

Hearing Loss:

• Weber Test: localizes to affected ear
• Rinne Test: abnormal (bone > air)

Answer 274

Conductive Hearing Loss

Question 275

Hearing Loss:

• Weber Test: localizes to unaffected ear
• Rinne Test: normal (air > bone)

Answer 275

Sensorineural Hearing Loss

Question 276

Hearing Loss:

• damage to stereociliated cells in organ of Corti
• loss of high-frequency hearing first
• sudden extremely loud noises can produce hearing loss due to tympanic membrane rupture

Answer 276

Noise-Induced Hearing Loss

Question 277

Hearing Loss:

• aging-related progressive bilateral/symmetric sensorineural hearing loss (often of higher frequencies)
• due to destruction of hair cells at the cochlear base (preserved low-frequency hearing at apex)

Answer 277

Presbycusis

Question 278

ORL Pathology:

• overgrowth of desquamated keratin debris within the middle ear space
• may erode ossicles and mastoid air cells → conductive hearing loss
• often presents with painless otorrhea

Answer 278

Cholesteatoma

Question 279

ORL Pathology:

• sensation of spinning while actually stationary
• subtype of “dizziness,” but distinct from “lightheadedness”

Answer 279

Vertigo

Question 280

Vertigo:

• more common
• inner ear etiology (eg. semicircular canal debris, vestibular nerve infection, Ménière disease [triad: sensorineural hearing loss, vertigo, tinnitus], benign paroxysmal positional vertigo [BPPV])
• Treatment:
  
  • antihistamines
  • anticholinergics
  • antiemetics (symptomatic relief)
  • low-salt diet ± diuretics (Ménière disease)
  • Epley maneuver (BPPV)

Answer 280

Peripheral Vertigo

Question 281

Vertigo:

• brain stem or cerebellar lesion (eg. stroke affecting vestibular nuclei or posterior fossa tumor)
• Findings:
  
  • directional or purely vertical nystagmus
  • skew deviation
  • diplopia
  • dysmetria
  • focal neurologic findings

Answer 281

Central Vertigo

Question 282

Eye Anatomy

Answer 282

Question 283

Ophthalmic Pathology:

• inflammation of the conjunctiva → red eye
• Allergic
  
  • itchy eyes
  • bilateral
• Bacterial
  
  • pus
  • treat with antibiotics
• Viral
  
  • most common
  • often adenovirus
  • sparse mucous discharge
  • swollen preauricular node
  • self-resolving

Answer 283

Conjunctivitis

Question 284

Ophthalmic Pathology:

• common cause of impaired vision
• correctable with glasses

Answer 284

Refractive Errors

Question 285

Refractive Errors:

• also known as “farsightedness”
• eye too short for refractive power of cornea and lens → light focused behind retina
• correct with convex (converging) lenses

Answer 285

Hyperopia

Question 286

Refractive Errors:

• also known as “nearsightedness”
• eye too long for refractive power of cornea and lens → light focused in front of retina
• correct with concave (diverging) lens

Answer 286

Myopia

Question 287

Refractive Errors:

• abnormal curvature of cornea → different refractive power at different axes
• correct with cylindrical lens

Answer 287

Astigmatism

Question 288

Refractive Errors:

• aging-related impaired accommodation (focusing on near objects), primarily due to ↓ lens elasticity, changes in lens curvature, ↓ strength of the ciliary muscle
• patients often need “reading glasses” (magnifiers)

Answer 288

Presbyopia

Question 289

Ophthalmic Pathology:

• painless, often bilateral, opacification of lens , often resulting in glare and ↓ vision, especially at night
• Acquired Risk Factors:
  
  • ↑ age
  • smoking
  • excessive alcohol use
  • excessive sunlight
  • prolonged corticosteroid use
  • diabetes mellitus
  • trauma
  • infection
• Congenital Risk Factors:
  
  • Classic Galactosemia
  • Galactokinase Deficiency
  • Trisomies (13, 18, 21)
  • ToRCHeS Infections (eg. rubella)
  • Marfan Syndrome
  • Alport Syndrome
  • Myotonic Dystrophy
  • Neurofibromatosis 2

Answer 289

Cataract

Question 290

Aqueous Humor Pathway

Answer 290

Question 291

Ophthalmic Pathology:

• optic disc atrophy with characteristic cupping (thinning of outer rim of optic nerve head versus normal), usually with elevated intraocular pressure (IOP) and progressive peripheral visual field loss if untreated
• treatment is through pharmacologic or surgical lowering of IOP

Answer 291

Glaucoma

Question 292

Glaucoma:

• associated with ↑ age, African-American race, and family history
• painless
• more common in US
• Primary—cause unclear
• Secondary—blocked trabecular meshwork from WBCs (eg. uveitis), RBCs (eg. vitreous hemorrhage), retinal elements (eg. retinal detachment)

Answer 292

Open-Angle Glaucoma

Question 293

Glaucoma:

• Primary
  
  • enlargement or anterior movement of lens against central iris (pupil margin) → obstruction of normal aqueous flow through pupil → fluid builds up behind iris, pushing peripheral iris against cornea and impeding flow through trabecular meshwork
• Secondary
  
  • hypoxia from retinal disease (eg. diabetes mellitus, vein occlusion) induces vasoproliferation in iris that contracts angle

Answer 293

Closed- or Narrow-Angle Glaucoma

Question 294

Closed- or Narrow-Angle Glaucoma:

often asymptomatic with damage to optic nerve and peripheral vision

Answer 294

Chronic Closure

Question 295

Closed- or Narrow-Angle Glaucoma:

• true ophthalmic emergency
• ↑ IOP pushes iris forward → angle closes abruptly
• very painful, red eye, sudden vision loss, halos around lights, frontal headache, fixed and mid‑dilated pupil
• mydriatic agents contraindicated

Answer 295

Acute Closure

Question 296

Ophthalmic Pathology:

• inflammation of uvea
• specific name based on location within affected eye
• anterior = Iritis
• posterior = Choroiditis and/or Retinitis
• may have hypopyon (accumulation of pus in anterior chamber) or conjunctival redness
• associated with systemic inflammatory disorders (eg. sarcoidosis, rheumatoid arthritis, juvenile idiopathic arthritis, HLA-B27–associated conditions)

Answer 296

Uveitis

Question 297

Ophthalmic Pathology:

• degeneration of macula (central area of retina)
• causes distortion (metamorphopsia) and eventual loss of central vision (scotomas)

Answer 297

Age-Related Macular Degeneration

Question 298

Age-Related Macular Degeneration:

• > 80%
• deposition of yellowish extracellular material in between Bruch membrane and retinal pigment epithelium (“Drusen”) with gradual ↓ in vision
• prevent progression with multivitamin and antioxidant supplements

Answer 298

Dry (Nonexudative)

Question 299

Age-Related Macular Degeneration:

• 10–15%
• rapid loss of vision due to bleeding 2° to choroidal neovascularization
• treat with anti-VEGF (vascular endothelial growth factor) injections (eg. Bevacizumab, Ranibizumab)

Answer 299

Wet (Exudative)

Question 300

Ophthalmic Pathology:

retinal damage due to chronic hyperglycemia

Answer 300

Diabetic Retinopathy

Question 301

Diabetic Retinopathy:

• damaged capillaries leak blood → lipids and fluid seep into retina → hemorrhages and macular edema
• Treatment: blood sugar control

Answer 301

Nonproliferative

Question 302

Diabetic Retinopathy:

• chronic hypoxia results in new blood vessel formation with resultant traction on retina
• Treatment:
  
  • peripheral retinal photocoagulation
  • surgery
  • anti-VEGF

Answer 302

Proliferative

Question 303

Ophthalmic Pathology:

• retinal damage due to chronic uncontrolled HTN
• flame-shaped retinal hemorrhages, arteriovenous nicking, microaneurysms, macular star (exudate), cotton-wool spots
• presence of papilledema requires immediate lowering of BP
• associated with ↑ risk of stroke, CAD, and kidney disease

Answer 303

Hypertensive Retinopathy

Question 304

Ophthalmic Pathology:

• blockage of central or branch retinal vein due to compression from nearby arterial atherosclerosis
• retinal hemorrhage and venous engorgement (“blood and thunder appearance”)
• edema in affected area

Answer 304

Retinal Vein Occlusion

Question 305

Ophthalmic Pathology:

• separation of neurosensory layer of retina (photoreceptor layer with rods and cones) from outermost pigmented epithelium (normally shields excess light, supports retina) → degeneration of photoreceptors → vision loss
• may be 2° to retinal breaks, diabetic traction, inflammatory effusions
• visualized on fundoscopy as crinkling of retinal tissue and changes in vessel direction
• breaks more common in patients with high myopia and/or history of head trauma
• often preceded by posterior vitreous detachment (“flashes” and “floaters”) and eventual monocular loss of vision like a “curtain drawn down”
• surgical emergency

Answer 305

Retinal Detachment

Question 306

Ophthalmic Pathology:

• acute, painless monocular vision loss
• retina cloudy with attenuated vessels and “cherry-red” spot at fovea (center of macula)
• evaluate for embolic source (eg. carotid artery atherosclerosis, cardiac vegetations, patent foramen ovale)

Answer 306

Central Retinal Artery Occlusion

Question 307

Ophthalmic Pathology:

• inherited retinal degeneration
• painless, progressive vision loss beginning with night blindness (rods affected first)
• bone spicule-shaped deposits around macula

Answer 307

Retinitis Pigmentosa

Question 308

Ophthalmic Pathology:

• retinal edema and necrosis leading to scar
• often viral (CMV, HSV, VZV), but can be bacterial or parasitic
• may be associated with immunosuppression

Answer 308

Retinitis

Question 309

Ophthalmic Pathology:

• optic disc swelling (usually bilateral) due to ↑ ICP (eg. 2° to mass effect)
• enlarged blind spot and elevated optic disc with blurred margins

Answer 309

Papilledema

Question 310

Pupillary Control:

Miosis

Answer 310

• constriction
• Parasympathetic:
  
  • 1st neuron: Edinger-Westphal nucleus to ciliary ganglion via CN III
  • 2nd neuron: short ciliary nerves to sphincter pupillae muscles
• Short ciliary nerves shorten the pupil diameter.

Question 311

Pupillary Control:

Pupillary Light Reflex

Answer 311

• Light in either retina sends a signal via CN II to pretectal nuclei (dashed lines in image) in midbrain that activates bilateral Edinger-Westphal nuclei.
• Pupils constrict bilaterally (direct and consensual reflex).
• Result: illumination of 1 eye results in bilateral pupillary constriction.

Question 312

Pupillary Control:

Mydriasis

Answer 312

• dilation
• Sympathetic:
  
  • 1st neuron: hypothalamus to ciliospinal center of Budge (C8–T2)
  • 2nd neuron: exit at T1 to superior cervical ganglion (travels along cervical sympathetic chain near lung apex, subclavian vessels)
  • 3rd neuron: plexus along internal carotid, through cavernous sinus; enters orbit as long ciliary nerve to pupillary dilator muscles. Sympathetic fibers also innervate smooth muscle of eyelids (minor retractors) and sweat glands of forehead and face.
• Long ciliary nerves make the pupil diameter longer.

Question 313

Ophthalmic Pathology:

• When the light shines into a normal eye, constriction of the ipsilateral (direct reflex) and contralateral eye (consensual reflex) is observed.
• When the light is then swung to the affected eye, both pupils dilate instead of constrict due to impaired conduction of light signal along the injured optic nerve.

Answer 313

Marcus Gunn Pupil

Question 314

Horner Syndrome

Answer 314

• Sympathetic denervation of face (PAM is horny.):
  
  • Ptosis (slight drooping of eyelid: superior tarsal muscle)
  • Anhidrosis (absence of sweating) and flushing of affected side of face
  • Miosis (pupil constriction)
• Associated with lesions along the sympathetic chain:
  
  • 1st neuron: pontine hemorrhage, lateral medullary syndrome, spinal cord lesion above T1 (eg. Brown-Séquard syndrome, late-stage syringomyelia)
  • 2nd neuron (stellate ganglion): Pancoast tumor
  • 3rd neuron: carotid dissection (painful)

Question 315

Ocular Motility

Answer 315

• The “chemical formula” LR₆SO₄R₃.
  
  • CN VI innervates the Lateral Rectus
  • CN IV innervates the Superior Oblique
  • CN III innervates the Rest
• The strongest action of the superior oblique is depression when the eye is adducted. The further the eye is abducted, the more the superior oblique acts to intort the eye toward the nose.
• Obliques go Opposite (left SO and IO tested with patient looking right).
• IOU: IO tested looking Up

Question 316

CN III, IV, VI Palsies:

• has both motor (central) and parasympathetic (peripheral) components.
• Common Causes:
  
  • ischemia → pupil sparing
  • uncal herniation → coma
  • PCA aneurysm → sudden-onset headache
  • cavernous sinus thrombosis → proptosis, involvement of CNs IV, V1/V2, VI
  • midbrain stroke → contralateral hemiplegia

Answer 316

CN III damage

Question 317

CN III, IV, VI Palsies:

eye moves upward, particularly with contralateral gaze (→ going down stairs, head may tilt in the opposite direction to compensate)

Answer 317

CN IV damage

Can’t see the floor with CN IV damage.

Question 318

CN III, IV, VI Palsies:

affected eye unable to abduct and is displaced medially in primary position of gaze

Answer 318

CN VI damage

Question 319

Visual Field Defects

Answer 319

1. Right Anopia
2. Bitemporal Hemianopia (pituitary lesion, chiasm)
3. Left Homonymous Hemianopia
4. Left Upper Quadrantanopia (right temporal lesion, MCA)
5. Left Lower Quadrantanopia (right parietal lesion, MCA)
6. Left Hemianopia with Macular Sparing (PCA infarct)
7. Central Scotoma (eg. macular degeneration)

• Meyer Loop
  
  • Lower retina
  • Loops around inferior horn of Lateral ventricle
• Dorsal Optic Radiation
  
  • superior retina
  • takes shortest path via internal capsule

Question 320

Cavernous Sinus

Answer 320

• collection of venous sinuses on either side of the pituitary
• blood from eye and superficial cortex → cavernous sinus → internal jugular vein
• CNs III, IV, V1, VI, and V2 plus postganglionic sympathetic pupillary fibers en route to orbit all pass through cavernous sinus
• cavernous portion of internal carotid artery is also here

Question 321

Ophthalmic Pathology:

• presents with variable ophthalmoplegia, ↓ corneal sensation, Horner syndrome and occasional decreased maxillary sensation
• 2° to pituitary tumor mass effect, carotid-cavernous fistula, or cavernous sinus thrombosis related to infection
• CN VI is most susceptible to injury

Answer 321

Cavernous Sinus Syndrome

Question 322

Internuclear Ophthalmoplegia

Answer 322

Medial Longitudinal Fasciculus (MLF):

• pair of tracts that allows for crosstalk between CN VI and CN III nuclei
• coordinates both eyes to move in same horizontal direction
• highly myelinated (must communicate quickly so eyes move at same time)
• lesions may be unilateral or bilateral (latter classically seen in multiple sclerosis)

Internuclear Ophthalmoplegia (INO)

• lesion in MLF
• a conjugate horizontal gaze palsy
• lack of communication such that when CN VI nucleus activates ipsilateral lateral rectus, contralateral CN III nucleus does not stimulate medial rectus to contract
• abducting eye gets nystagmus (CN VI overfires to stimulate CN III)
• convergence normal
• when looking left, the left nucleus of CN VI fires, which contracts the left lateral rectus and stimulates the contralateral (right) nucleus of CN III via the right MLF to contract the right medial rectus
• directional term (eg. right INO, left INO) refers to which eye is paralyzed
• INO = Ipsilateral adduction failure, Nystagmus Opposite

Question 323

Epilepsy Drugs:

• used for Status Epilepticus
• 1st line for recurrent seizure prophylaxis
• ↑ GABA_A action
• causes sedation, tolerance, dependence, respiratory depression
• also for eclampsia seizures (1st line is MgSO₄)

Answer 323

Benzodiazepines

Question 324

Epilepsy Drugs:

• commonly used for partial (focal) seizures
• used for GTC
• blocks Na⁺ channels
• causes diplopia, ataxia, blood dyscrasias (agranulocytosis, aplastic anemia), liver toxicity, teratogenesis (cleft lip/palate, spina bifida), induction of cytochrome P-450, SIADH, Stevens- Johnson syndrome
• 1st line for trigeminal neuralgia

Answer 324

Carbamazepine

Question 325

Epilepsy Drugs:

• commonly used for absence seizures
• blocks thalamic T-type Ca²⁺ channels
• causes fatigue, GI distress, headache, itching (and urticaria), and Stevens-Johnson syndrome

Answer 325

Ethosuximide

EFGHIJ:

Ethosuximide causes Fatigue, GI distress, Headache, Itching (and urticaria), and Stevens-Johnson syndrome.

Question 326

Epilepsy Drugs:

• used for partial (focal) seizures
• primarily inhibits high-voltage-activated Ca²⁺ channels
• designed as GABA analog
• causes sedation and ataxia
• also used for peripheral neuropathy and postherpetic neuralgia

Answer 326

Gabapentin

Question 327

Epilepsy Drugs:

• used for partial (focal), absence and GTC seizures
• blocks voltage-gated Na⁺ channels
• inhibits the release of glutamate
• causes Stevens-Johnson syndrome (must be titrated slowly)

Answer 327

Lamotrigine

Question 328

Epilepsy Drugs:

• used for partial (focal) and GTC seizures
• unknown MOA
• may modulate GABA and glutamate release
• causes neuropsychiatric symptoms (eg. personality change), fatigue, drowsiness, and headache

Answer 328

Levetiracetam

Question 329

Epilepsy Drugs:

• used for partial (focal) seizures, GTC seizures and status epilepticus
• ↑ GABA_A action
• causes sedation, tolerance, dependence, induction of cytochrome P-450, and cardiorespiratory depression
• 1st line in neonates

Answer 329

Phenobarbital

Question 330

Epilepsy Drugs:

• commonly used for GTC
• used for partial (focal) seizures and status epilepticus
• 1st line for recurrent seizure prophylaxis
• blocks Na⁺ channels
• zero-order kinetics
• causes P450 induction, hirsutism, enlarged gums, nystagmus, yellow-brown skin, teratogenicity (fetal hydantoin syndrome), osteopenia, inhibited folate absorption, neuropathy
• rare adverse reactions include Stevens-Johnson syndrome, DRESS syndrome, and SLE-like syndrome
• toxicity leads to diplopia, ataxia, and sedation

Answer 330

• Phenytoin
• Fosphenytoin

PHENYTOIN:

• P450 induction
• Hirsutism
• Enlarged gums
• Nystagmus
• Yellow-brown skin
• Teratogenicity
• Osteopenia
• Inhibited folate absorption
• Neuropathy

Question 331

Epilepsy Drugs:

• used for partial (focal) seizures
• ↑ GABA by inhibiting reuptake

Answer 331

Tiagabine

Question 332

Epilepsy Drugs:

• used for partial (focal and GTC seizures)
• blocks Na⁺ channels
• ↑ GABA action
• causes sedation, mental dulling, word-finding difficulty, kidney stones, weight loss, and glaucoma
• also used for migraine prevention

Answer 332

Topiramate

Question 333

Epilepsy Drugs:

• commonly used for GTC seizures
• used for partial (focal) and absence seizures
• ↑ Na⁺ channel inactivation
• ↑ GABA concentration by inhibiting GABA transaminase
• causes GI distress, rare but fatal hepatotoxicity (measure LFTs), pancreatitis, neural tube defects, tremor, and weight gain
• contraindicated in pregnancy
• also used for myoclonic seizures, bipolar disorder, and migraine prophylaxis

Answer 333

Valproic Acid

Question 334

Epilepsy Drugs:

• used for partial (focal) seizures
• ↑ GABA
• irreversible GABA transaminase inhibitor
• causes permanent visual loss (black box warning)

Answer 334

Vigabatrin

Question 335

Neurologic Drugs:

Barbiturates

Answer 335

• Phenobarbital
• Pentobarbital
• Thiopental
• Secobarbital

Question 336

Neurologic Drugs:

• facilitate GABA_A action by ↑ duration of Cl⁻ channel opening, thus ↑ neuron firing
• used for sedation for anxiety, seizures, insomnia, and induction of anesthesia (thiopental)
• causes respiratory and cardiovascular depression (can be fatal), CNS depression (can be exacerbated by alcohol use), dependence, and drug interactions (induces cytochrome P-450)
• overdose treatment is supportive (assist respiration and maintain BP)
• contraindicated in porphyria

Answer 336

Barbiturates

Barbidurates = ↑ duration

Question 337

Neurologic Drugs:

Benzodiazepines

Answer 337

• Diazepam
• Lorazepam
• Triazolam
• Temazepam
• Oxazepam
• Midazolam
• Chlordiazepoxide
• Alprazolam

Question 338

Neurologic Drugs:

• facilitate GABA_A action by ↑ frequency of Cl⁻ channel opening. ↓ REM sleep
• most have long half-lives and active metabolites (exceptions [ATOM]: Alprazolam, Triazolam, Oxazepam, and Midazolam are short acting → higher addictive potential).
• used for anxiety, spasticity, status epilepticus (Lorazepam, Diazepam, Midazolam), eclampsia, detoxification (especially alcohol withdrawal–DTs), night terrors, sleepwalking, and general anesthesia (amnesia, muscle relaxation), hypnotic (insomnia)
• causes ependence and additive CNS depression effects with alcohol
• less risk of respiratory depression and coma than with barbiturates
• treat overdose with Flumazenil (competitive antagonist at GABA benzodiazepine receptor)
• can precipitate seizures by causing acute withdrawal

Answer 338

Benzodiazepines

• Frenzodiazepines = ↑ frequency
• Benzos, barbs, and alcohol all bind the GABA_A receptor, which is a ligand-gated Cl⁻ channel.
• Oxazepam, Temazepam, and Lorazepam are OK for Terrible Livers: they can be used to treat alcohol withdrawal in patients with liver disease due to minimal first-pass metabolism.

Question 339

Neurologic Drugs:

Nonbenzodiazepine Hypnotics

Answer 339

These ZZZs put you to sleep.

• Zolpidem
• Zaleplon
• EsZopiclone

Question 340

Neurologic Drugs:

• act via the BZ1 subtype of the GABA receptor
• effects reversed by Flumazenil
• sleep cycle less affected as compared with benzodiazepine hypnotics
• used for insomnia
• causes ataxia, headaches, and confusion
• short duration because of rapid metabolism by liver enzymes
• unlike older sedative-hypnotics, cause only modest day-after psychomotor depression and few amnestic effects
• ↓ dependence risk than benzodiazepines

Answer 340

Nonbenzodiazepine Hypnotics

Question 341

Neurologic Drugs:

• orexin (hypocretin) receptor antagonist.
• used for insomnia
• causes CNS depression, headache, dizziness, abnormal dreams, and upper respiratory tract infection
• contraindicated in patients with narcolepsy
• not recommended in patients with liver disease
• no or low physical dependence
• contraindicated with strong CYP3A4 inhibitors

Answer 341

Suvorexant

Question 342

Neurologic Drugs:

• melatonin receptor agonist
• binds MT1 and MT2 in suprachiasmatic nucleus
• used for insomnia
• causes dizziness, nausea, fatigue, and headache
• no dependence (not a controlled substance)

Answer 342

Ramelteon

Question 343

Neurologic Drugs:

• 5-HT1B/1D agonists
• inhibit trigeminal nerve activation
• prevent vasoactive peptide release
• induce vasoconstriction
• used for acute migraine and cluster headache attacks
• causes coronary vasospasm (contraindicated in patients with CAD or Prinzmetal angina), mild paresthesia, serotonin syndrome (in combination with other 5-HT agonists)

Answer 343

Triptans (Sumatriptan)

A sumo wrestler trips and falls on your head.

Question 344

Parkinson Disease Drugs

Answer 344

Parkinsonism is due to loss of dopaminergic neurons and excess cholinergic activity.

BALSA:

• Bromocriptine
• Amantadine
• Levodopa (with Carbidopa)
• Selegiline (and COMT Inhibitors)
• Antimuscarinics

Question 345

Parkinson Disease Drugs:

Dopamine Agonists

Answer 345

• Ergot
  
  • Bromocriptine
• Non-Ergot (preferred)
  
  • Pramipexole and Ropinirole
  • toxicity includes impulse control disorder (eg. gambling), postural hypotension, and hallucinations/confusion

Question 346

Parkinson Disease Drugs:

↑ dopamine availability

Answer 346

Amantadine

• ↑ dopamine release and ↓ dopamine reuptake
• toxicity = ataxia, livedo reticularis

Question 347

Parkinson Disease Drugs:

↑ L-DOPA availability

Answer 347

Agents prevent peripheral (pre-BBB) l-DOPA degradation → ↑ L-DOPA entering CNS → ↑ central L-DOPA available for conversion to dopamine

• Levodopa (L-DOPA)/Carbidopa
  
  • Carbidopa blocks peripheral conversion of L-DOPA to dopamine by inhibiting DOPA decarboxylase.
  • Also reduces side effects of peripheral L-DOPA conversion into dopamine (eg. nausea, vomiting).
• Entacapone
  
  • Prevents peripheral L-DOPA degradation to 3-O-methyldopa (3‑OMD) by inhibiting COMT.
  • Used in conjunction with Levodopa.

Question 348

Parkinson Disease Drugs:

prevent dopamine breakdown

Answer 348

Agents act centrally (post-BBB) to inhibit breakdown of dopamine.

• Selegiline and Rasagiline
  
  • Block conversion of dopamine into DOPAC by selectively inhibiting MAO-B.
• Entacapone
  
  • Blocks conversion of dopamine to 3-methoxytyramine (3-MT) by inhibiting central COMT.

Question 349

Parkinson Disease Drugs:

curb excess cholinergic activity

Answer 349

Benztropine and Trihexyphenidyl

• antimuscarinic
• improves tremor and rigidity but has little effect on bradykinesia in Parkinson disease

Park your Mercedes-Benz.

Question 350

Neurologic Drugs:

• ↑ level of dopamine in brain
• unlike dopamine, L-DOPA can cross blood-brain barrier and is converted by dopa decarboxylase in the CNS to dopamine
• used for Parkinson disease
• causes nausea, hallucinations, and postural hypotension from ↑ peripheral formation of catecholamines
• long-term use can lead to dyskinesia following administration (“on-off” phenomenon) and akinesia between doses

Answer 350

Levodopa/Carbidopa

• Carbidopa, a peripheral DOPA decarboxylase inhibitor, is given with L-DOPA to ↑ the bioavailability of L-DOPA in the brain and to limit peripheral side effects.

Question 351

Neurologic Drugs:

• selectively inhibit MAO-B (metabolize dopamine) → ↑ dopamine availability
• adjunctive agent to L-DOPA in treatment of Parkinson disease
• may enhance adverse effects of L-DOPA

Answer 351

• Selegiline
• Rasagiline

Question 352

Neurologic Drugs:

• inhibit vesicular monoamine transporter (VMAT) dopamine → ↓ vesicle packaging and release
• used for Huntington chorea and tardive dyskinesia

Answer 352

• Tetrabenazine
• Reserpine

Question 353

Neurologic Drugs:

• ↓ neuron glutamate excitotoxicity
• used for ALS
• ↑ survival

Answer 353

Riluzole

For Lou Gehrig disease, give Rilouzole.

Question 354

Alzheimer Disease Drugs:

• NMDA receptor antagonist
• helps prevent excitotoxicity (mediated by Ca²⁺)
• causes dizziness, confusion, hallucinations

Answer 354

Memantine

Question 355

Alzheimer Disease Drugs:

• AChE inhibitors
• causes nausea, dizziness, and insomnia

Answer 355

Dona Riva dances at the gala.

• Donepezil
• Rivastigmine
• Galantamine

Question 356

Anesthetics—General Principles

Answer 356

• CNS drugs must be lipid soluble (cross the blood-brain barrier) or be actively transported.
• drugs with ↓ solubility in blood = rapid induction and recovery times
• drugs with ↑ solubility in lipids = ↑ potency = 1/MAC
• MAC = Minimal Alveolar Concentration
  
  • inhaled anesthetic required to prevent 50% of subjects from moving in response to noxious stimulus (eg. skin incision)
• Nitrous oxide (N₂O) has ↓ blood and lipid solubility, and thus fast induction and low potency.
• Halothane, Propofol, and Thiopental, in contrast, have ↑ lipid and blood solubility, and thus high potency and slow induction.

Question 357

Inhaled Anesthetics

Answer 357

• Desflurane
• Halothane
• Enflurane
• Isoflurane
• Sevoflurane
• Methoxyflurane
• N₂O

Question 358

Anesthetics:

• mechanism unknown
• causes myocardial depression, respiratory depression, nausea/emesis, ↑ cerebral blood flow (↓ cerebral metabolic demand)
• causes hepatotoxicity (Halothane), nephrotoxicity (Methoxyflurane), proconvulsant (Enflurane, epileptogenic), expansion of trapped gas in a body cavity (N₂O)

Answer 358

Inhaled Anesthetics

Question 359

Neuropathology:

• rare, life-threatening condition in which inhaled anesthetics or Succinylcholine induce fever and severe muscle contractions
• susceptibility is often inherited as autosomal dominant with variable penetrance
• mutations in voltage-sensitive ryanodine receptor (RYR1 gene) cause ↑ Ca²⁺ release from sarcoplasmic reticulum
• Treatment:
  
  • Dantrolene—ryanodine receptor antagonist

Answer 359

Malignant Hyperthermia

Question 360

Intravenous Anesthetics:

• facilitate GABA_A (barbiturate)
• induction of anesthesia
• short surgical procedures
• ↓ cerebral blood flow
• high lipid solubility
• effect terminated by rapid redistribution into tissue and fat

Answer 360

Thiopental

Question 361

Intravenous Anesthetics:

• facilitate GABA_A (benzodiazepine)
• procedural sedation (eg. endoscopy)
• anesthesia induction
• may cause severe postoperative respiratory depression, ↓ BP, and anterograde amnesia

Answer 361

Midazolam

Question 362

Intravenous Anesthetics:

• potentiates GABA_A
• rapid anesthesia induction
• short procedures
• ICU sedation

Answer 362

Propofol

Question 363

Intravenous Anesthetics:

• NMDA receptor antagonist
• causes dissociative anesthesia
• sympathomimetic
• ↑ cerebral blood flow
• emergence reaction possible with disorientation, hallucination, and vivid dreams

Answer 363

Ketamine

Question 364

Local Anesthetics

Answer 364

• Esters
  
  • Procaine
  • Tetracaine
  • Benzocaine
  • Chloroprocaine
• Amides (2 I’s in name)
  
  • LIdocaIne
  • MepIvacaIne
  • BupIvacaIne
  • RopIvacaIne

Question 365

Anesthetics:

• block Na⁺ channels by binding to specific receptors on inner portion of channel
• most effective in rapidly firing neurons
• 3° amine anesthetics penetrate membrane in uncharged form, then bind to ion channels as charged form
• can be given with vasoconstrictors (usually epinephrine) to enhance local action—↓ bleeding, ↑ anesthesia by ↓ systemic concentration
• in infected (acidic) tissue, alkaline anesthetics are charged and cannot penetrate membrane effectively → need more anesthetic
• Order of Nerve Blockade:
  
  • small-diameter fibers > large diameter
  • myelinated fibers > unmyelinated fibers
• overall, size factor predominates over myelination such that small myelinated fibers > small unmyelinated fibers > large myelinated fibers > large unmyelinated fibers
• Order of Loss:

1. pain
2. temperature
3. touch
4. pressure

• used for minor surgical procedures and spinal anesthesia
• if allergic to esters, give amides
• causes CNS excitation, severe cardiovascular toxicity (Bupivacaine), hypertension, hypotension, arrhythmias (Cocaine), methemoglobinemia (Benzocaine)

Answer 365

Local Anesthetics

Question 366

Neurologic Drugs:

• used for muscle paralysis in surgery or mechanical ventilation
• selective for Nm nicotinic receptors at neuromuscular junction but not autonomic Nn receptors

Answer 366

Neuromuscular Blocking Drugs

Question 367

Neuromuscular Blocking Drugs:

• strong ACh receptor agonist
• produces sustained depolarization and prevents muscle contraction
• Reversal of Blockade:
  
  • Phase I
    
    • prolonged depolarization
    • no antidote
    • block potentiated by cholinesterase inhibitors
  • Phase II
    
    • repolarized but blocked
    • ACh receptors are available, but desensitized
    • may be reversed with cholinesterase inhibitors
• complications include hypercalcemia, hyperkalemia, and malignant hyperthermia

Answer 367

Depolarizing Neuromuscular Blocking Drugs

• Succinylcholine

Question 368

Neuromuscular Blocking Drugs:

• competitive with ACh for receptors
• Reversal of Blockade:
  
  • Neostigmine
    
    • must be given with atropine or glycopyrrolate to prevent muscarinic effects such as bradycardia
  • Edrophonium

Answer 368

Nondepolarizing Neuromuscular Blocking Drugs

• Atracurium
• Cisatracurium
• Pancuronium
• Rocuronium
• Tubocurarine
• Vecuronium

Question 369

Neurologic Drugs:

• prevents release of Ca²⁺ from the sarcoplasmic reticulum of skeletal muscle by binding to the ryanodine receptor
• used for malignant hyperthermia (a toxicity of inhaled anesthetics and succinylcholine) and neuroleptic malignant syndrome (a toxicity of antipsychotic drugs)

Answer 369

Dantrolene

Question 370

Neurologic Drugs:

• skeletal muscle relaxant
• GABA_B receptor agonist in spinal cord
• used for muscle spasticity, dystonia, and multiple sclerosis

Answer 370

Baclofen

Question 371

Neurologic Drugs:

• skeletal muscle relaxant
• acts within CNS
• used for muscle spasms
• anticholinergic side effects
• causes sedation

Answer 371

Cyclobenzaprine

Question 372

Analgesics:

• act as agonists at opioid receptors (μ = β-endorphin, δ = enkephalin, κ = dynorphin) to modulate synaptic transmission—close presynaptic Ca²⁺ channel, open postsynaptic K⁺ channels → ↓ synaptic transmission
• inhibit release of ACh, norepinephrine, 5-HT, glutamate, and substance P
• used for moderate to severe or refractory pain, cough suppression (Dextromethorphan), diarrhea (Loperamide, Diphenoxylate), acute pulmonary edema, maintenance programs for heroin addicts (Methadone, Buprenorphine + Naloxone)
• causes nausea, vomiting, pruritus, addiction, respiratory depression, constipation, sphincter of Oddi spasm, miosis (except Meperidine → mydriasis), and additive CNS depression with other drugs
• tolerance does not develop to miosis and constipation
• toxicity is treated with Naloxone (_____ receptor antagonist) and relapse prevention with Naltrexone once detoxified

Answer 372

Opioid Analgesics

• Full Agonists:
  
  • Morphine
  • Heroin
  • Meperidine
  • Methadone
  • Codeine
• Partial Agonist:
  
  • Buprenorphine
• Mixed Agonist/Antagonist:
  
  • Nalbuphine
  • Pentazocine
• Antagonist:
  
  • Naloxone
  • Naltrexone
  • Methylnaltrexone

Question 373

Neurologic Drugs:

• κ-opioid receptor agonist and μ-opioid receptor weak antagonist or partial agonist
• analgesia for moderate to severe pain.
• can cause opioid withdrawal symptoms if patient is also taking full opioid agonist (due to competition for opioid receptors)

Answer 373

Pentazocine

Question 374

Neurologic Drugs:

• κ-opioid receptor agonist and μ-opioid receptor partial agonist
• used for evere pain (eg. migraine, labor)
• causes less respiratory depression than full opioid agonists
• use with full opioid agonist can precipitate withdrawal
• not easily reversed with Naloxone

Answer 374

Butorphanol

Question 375

Neurologic Drugs:

• very weak opioid agonist
• also inhibits 5-HT receptors
• used for chronic pain
• adverse effects are similar to opioids
• decreases seizure threshold
• causes serotonin syndrome

Answer 375

Tramadol

Question 376

Ophthalmic Pathology:

↓ IOP via ↓ amount of aqueous humor (inhibit synthesis/secretion or ↑ drainage)

Answer 376

Glaucoma Drugs

Question 377

Glaucoma Drugs

Answer 377

BAD humor may not be Politically Correct.

• β-Blockers
• α-Agonists
• Diuretics
• Prostaglandins
• Cholinomimetics (M3)

Question 378

Glaucoma Drugs:

• ↓ aqueous humor synthesis
• no pupillary or vision changes

Answer 378

β-Blockers

• Timolol
• Betaxolol
• Carteolol

Question 379

Glaucoma Drugs:

• ↓ aqueous humor synthesis via vasoconstriction (Epinephrine)
• ↓ aqueous humor synthesis (Apraclonidine, Brimonidine)
• causes mydriasis (α1)
• do not use in closed-angle glaucoma
• causes blurry vision, ocular hyperemia, foreign body sensation, ocular allergic reactions, and ocular pruritus

Answer 379

α-Agonists

• Epinephrine (α1)
• Apraclonidine
• Brimonidine (α2)

Question 380

Glaucoma Drugs:

• ↓ aqueous humor synthesis via inhibition of carbonic anhydrase
• no pupillary or vision changes

Answer 380

Diuretics

• Acetazolamide

Question 381

Glaucoma Drugs:

• ↑ outflow of aqueous humor via ↓ resistance of flow through uveoscleral pathway
• darkens color of iris (browning)
• causes eyelash growth

Answer 381

Prostaglandins (PGF2α)

• Bimatoprost
• Latanoprost

Question 382

Glaucoma Drugs:

• ↑ outflow of aqueous humor via contraction of ciliary muscle and opening of trabecular meshwork
• use Pilocarpine in acute angle closure glaucoma—very effective at opening meshwork into canal of Schlemm
• causes miosis (contraction of pupillary sphincter muscles) and cyclospasm (contraction of ciliary muscle)

Answer 382

Cholinomimetics (M3)

• Direct:
  
  • Pilocarpine
  • Carbachol
• Indirect:
  
  • Physostigmine
  • Echothiophate