Neuro

Question 1

Arnold-Chiari Type I

Answer 1

Adults: low-lying cerebellar tonsils below formen magnum–> vertebral canal
- Symptoms: headaches, cerebellar symptoms (ataxia), syringomyelia

Question 2

Arnold-Chiari Type II

Answer 2

Babies: Cerebellar tonsil and vermian heniation through foramen magnum

• Aqueductal stenosis and hydrocephalus
• Thoraco-lumbar myelomeningocele
• paralysis below defect

Symptoms: difficulty swallowing, dysphonia, stridor, apnea

Question 3

Dandy-Walker syndrome

Answer 3

Agenesis of cerebellar vermis with cystic enlargement of 4th ventricle (fills posterior fossa)

• hydrocephalus
• Spina bifida

Symptoms: postural instability, gait problems

Question 4

Meissner’s corpuscles

Answer 4

Large, myelinated fibers (adapt quickly)
Seen in glabrous (hairless) skin

Dynamic, fine/light touch; position sense

Question 5

Pacinian corpuscles

Answer 5

Large, myelinated A-beta fibers
- Deep skin layers, ligaments, joints

Rapid vibration, pressure sense

Question 6

Merkel’s discs

Answer 6

Large, myelinated fibers; adapt slowly
- Hair follicles

Pressure, deep static touch (shapes, edges), position sense

Question 7

Endoneurium

Answer 7

Invests single nerve fibers

- Guillain-Barre= inflammation of endoneurium

Question 8

Perineurium

Answer 8

Surrounds fasicle of nerve fibers

• Permeability layer
• Rejoined in microsurgery for limb reattachment

Question 9

Epineurium

Answer 9

Surrounds entire nerve (dense connective tissue)

Question 10

Golgi Tendon Organ

Answer 10

Sensory receptor at muscle-tendon junction
- in SERIES with extrafusal muscle fibers
- Ib innervation–> inhibitory
GTO activated with excess contraction—> relaxation

Question 11

Intrafusal muscle spindles

Answer 11

Ia and II innervation

- Sensitive to stretch (stops excess stretch force)

Question 12

Locus Ceruleus

Answer 12

Site of NE formation
- SAM required to transform NE to epi

NE= tyrosine derived (like DA, epi)

Question 13

Dopamine

Answer 13

Tyrosine-derived neurotransmitters

- Found in Ventral tegmentum, SNc (substantia nigra pars compacta)

Question 14

5-HT (serotonin)

Answer 14

Tryptophan–> BH4 (pyridoxine= B6)–> 5-hydroxytryptamine–> serotonin
- found in Raphe nucleus (pons)

Question 15

Basal nucleus of Meynert

Answer 15

ACh synthesis

• Decreased in Alzheimer’s, Huntington’s
• Increased in REM sleep

Question 16

Metencephalon

Answer 16

Pons and cerebellum
+ Upper part of 4th ventricle

Part of Hindbrain (Rhombencephalon)

Question 17

Myelencephalon

Answer 17

Medulla
+ Lower part of 4th ventricle

Part of Hindbrain (Rhombencephalon)

Question 18

Diencephalon

Answer 18

Thalamus + Third ventricle

Question 19

Mesencephalon

Answer 19

Midbrain + aqueduct

Question 20

Nucleus accumbens

Answer 20

Site of GABA synthesis
- Glutamate converted to GABA by glutamate decarboxylase

*Decreased synthesis in anxiety, Huntington’s

GABA receptor types:

• GABA(A)= Cl- influx in brain (ion channel)
• GABA(B)= K+ efflux, decreased Ca+2 influx inhibit adenylyl cyclase (G-protein)
• GABA(C)= Cl- influx in retina

*Decreased GABA(A) in long term EtOH/benzo use–> withdrawal seizures

Question 21

Cross BBB

Answer 21

Glucose and AA by carrier-mediated transport (slow)

Non-polar/lipid-soluble cross rapidly

Specialized areas with fenetrated capillaries:

• Area postrema (vomiting post-chemo)
• OVLT (osmotic sensing
• Neurosecretory products (neurohypophysis–> ADH)
• Hypothalamic inputs/outputs

Question 22

Hypothalamus areas

Answer 22

Lateral: regulates hunger

• Inhibited by leptin
• Destruction–> anorexia

Ventromedial: regulates satiety

• Stimulated by leptin
• Destruction (craniopharyngioma)–> hyerphagia

Anterior: cooling, parasympathetic

Posterior: Heating, sympathetic

Suprachiasmatic nucleus: circadian rhythm

**Posterior pituitary (neurohypophysis) recieves axonal projections from supraoptic nuclei (ADH) and paraventricular nuclei (oxytocin)

• • Anterior pituitary (adenohypophysis) recieves stimulation from hypothalamus:
• DA–> inhibits Prolactin
• GHRH–> GH release
• LHRH–> LH release, FSH release
• CRH—> ACTH release
• TRH–> TSH release

Question 23

Thalamus

Answer 23

VPL: Pain, temp, pressure, touch, vibration, proprioception

VPM: Face sensation and taste (Makeup on the face)

LGN: Vision

MGN: Hearing

VL: motor

Thalamus strok= post-stroke pain (burning/stabbing sensation)

Question 24

Cerebellar peduncles

Answer 24

Input= climbing, mossy fibers

• Inferior: ipsilateral proprioceptive info
• Middle: Contralateral cortex

Output= Purkinje fibers
- Superior: Deep nuclei to contralateral cortex

• Deep nuclei (lat–> med): Dentate, Emboliform, Globose, Fastigial (Don’t Eat Greasy Foods)

Question 25

Mesolimbic pathway

Answer 25

Dopaminergic pathway
Midbrain VTA–> Limbic nucleus accumbens

• Stimulation–> delusions, hallucinations, pleasure (Pathway to addiction)
• D3, D4 receptors, inhibited by atypical antipsychotics

Question 26

Mesocortical pathway

Answer 26

Dopaminergic pathway

Midbrain VTA–> limbic cortex (dorsolateral prefrontal)

• Cortex= cognition; defects–> negative symptoms of psychosis
• D3, D4 receptors, inhibited by atypical antipsychotics

Question 27

Nigrostriatal pathway

Answer 27

Dopaminergic pathway

Substantia nigra–> basal ganglia (striatum)

*Movement pathway (“nigrostride”); damage–> Parkinson’s

Question 28

Tubuloinfunibular pathway

Answer 28

Dopaminergic pathway

Arcuate nucleus (hypothalamus)–> anterior pituitary

• Inhibit DA–> increased prolactin productions

Question 29

Basal ganglia nuclei

Answer 29

Striatum:
- Putamen (motor) and caudate (cognitive)

Lentiform:
- Putamen and globus pallidus

Question 30

Hemiballismus

Answer 30

Contralateral subthalamic nucleus
- Lacunar stroke

Sudden, wild flailing of 1 arm +/- ipsilateral leg

Question 31

Kluver-Bucy syndrome

Answer 31

Lesion of amygdala, associated with HSV-1

Symptoms:

• Hyperorality (taste, eat anything)
• Hypersexuality
• Disinhibited behavior

Question 32

Cerebellar hemisphere lesion

Answer 32

Intention Tremor, limb ataxia, loss of balance

Damage–> ipsilateral deficits–> fall toward lesion

Question 33

Cerebellar vermis lesion

Answer 33

Truncal ataxia, dysarthria

Question 34

Paramedian pontine reticular formation lesion

Answer 34

Eyes look away from side of lesion

Question 35

Frontal eye field lesion

Answer 35

Eyes look towards lesion

Question 36

Conduction aphasia

Answer 36

Poor repetition with fluent speech, in tact comprehension
- Damage to arcuate fasciculus (connecting Wernicke’s to Broca’s)

Can’t repeat phrase: “No ifs, ands, or buts”

Question 37

Therapeutic hyperventilation and cerebral perfusion

Answer 37

Cerebral perfusion regulated by PCO2 (except in severe hypoxia= PO2 < 60)

Hyperventilation–> decreased CO2–> decreased ICP in cases of acute cerebral edema (stroke, trauma)–> decreases cerebral perfusion

Question 38

Lateral striate artery

Answer 38

Supplies striatum, internal capsule

Lesion–> contralateral hemiparesis, hemiplegia

• *Posterior internal capsule stroke has pure motor/pure sensory deficits
• • Genu of internal capsule= dysarthria-clumsy hand syndrome

Question 39

Anterior spinal artery (ASA)

Answer 39

Supplies:

• Lateral corticospinal tract
• Medial lemniscus
• Caudal medulla (hypoglossal nerve)

** Lesion= Medial medullary syndrome
Stroke: commonly bilateral
- Contralateral hemiparesis, proprioception
- Ipsilateral hypoglossal dysfunction (tongue deviates to side of lesion)

Question 40

PICA (posterior inferior cerebellar artery)

Answer 40

Supplies:
- Lateral medulla: vestibular nuclei, lateral spinothalamic tract, spinal trigeminal nucleus, nucleus ambiguus, sympathetic fibers, inferior cerebellar peduncle

Lesion= Lateral medullary (Wallenberg’s) syndrome

• Dysphagia, Hoarsenss, decreased gag reflex
• Vomiting, vertigo, nystagmus
• Decreased pain and temperature sensation to limbs/face
• ipsilateral Horner’s
• Ataxia, dysmetria

Question 41

AICA (anterior inferior cerebellar artery)

Answer 41

Supplies:

• Lateral pons (cranial nerve nuclei)
• Vestibular nuclei, facial nucleus
• Spinal trigeminal
• Cochlear nuclei
• Sympathetic fibers
• Middle and inferior cerebellar peduncles

Symptoms:

• Paralysis of face
• Decreased lacrimation, salivation, taste of anterior 2/3 of tongue, corneal reflex
• Decreased pain, temp sensation on face
• Ipsilateral decreased hearing, Horner’s syndrome
• Vomiting, vertigo, nystagmus
• Ataxia, dysmetria

Question 42

PCA (posterior cerebral artery)

Answer 42

Supplies:
- occipital cortex, visual cortex

Symptoms:
- Contralateral hemianopia with macular sparing

Question 43

Anterior communicating artery (AComm)

Answer 43

Saccular/berry aneurysm site–> impinge cranial nerves

- Visual field defects

Question 44

Posterior communicating artery (Pcomm)

Answer 44

Berry aneurysm

- CNIII palsy (eye down and out, ptosis, pupil dilation

Question 45

Charcot-Bouchard microaneurysm

Answer 45

Associated with chronic HTN (small vessels in basal ganglia, thalamus)
- Visible on CT

Question 46

Epidural hematoma

Answer 46

Accumulation of blood between cavarium and dura

• Creates high-pressure system within the skull
• Usually results from trauma to side of head

Ex: Fracture of temporal bone–> transection of middle meningeal artery

Symptoms:

• Lucid interval after trauma
• Expansion–> transtentorial herniation, CNIII palsy

CT:

• biconvex (lentiform), hyperdense blood collection
• Does not cross suture lines, but can cross falx, tentorium

Question 47

Subdural hematoma

Answer 47

Rupture of bridging veins

• Slow onset (venous blood- less pressure)
• Seen in elderly, alcoholics, blunt trauma, shaken baby (brain atrophy, shaking/whiplash)

CT:

• Crescent-shaped hemorrhage crosses suture lines
• midline shift
• Cannot cross falx, tentorium

Question 48

Subarachnoid hemorrhage

Answer 48

Rupture of aneurysm (berry) d/t Marfan’s, Ehlers-Danlos, ADPKD, or AVM

• Rapid onset
• Worst Headache of my Life (WHOML)

Bloody/yellow spinal tap

Risk of vasospasm due to blood breakdown products: avoid with nimodipine (Ca+2 channel blocker)

• • Spontaneous intracranial hemorrhage due to AVM, ruptured crerebral aneurysms, cocaine use
• Berry aneurysms associated with coarctation of aorta (HTN in branches proximal to arch–> increased pressure on cerebral arteries)

Question 49

Intraparenchymal (HTN) hemorrhage

Answer 49

Systemic hypertension, amyloid angiopathy, vasculitis, neoplasm

Occurs in bassal ganglia, internal capsule (Charcot-Bouchard aneurysm)

• *Amyloid angiopathy= recurrent hemorrhagic stroke w/o HTN (milder onset)
• Seen in cerebral hemispheres (vs basal ganglia)

Question 50

Noncommunicating hydrocephalus

Answer 50

Structural blockage of CSF circulation in ventricular system (stenosis of aqueduct of sylvius)

Due to:

• Type II Arnold-Chiari malformations (babies)
• Hereditary aqueductal stenosis
• Prenatal infections (toxoplasmosis)

Presentation:

• Irritable, poor feeding
• Periventricular pyramid tracts stretched—> UMN damage
• Hypertonic muscles, hyperreflexia

Question 51

Dorsal column

Answer 51

Tract: medial lemniscus

Function: ascending pressure, vibration, fine touch, proprioception

Synapse 1: ipsilateral nucleus cuneatus (Upper body) or gracilis (lower body)

Synapse 2: decusses in medulla –> contralateral medial lemniscus–> VPL (thalamus)

Question 52

Spinothalamic tract

Answer 52

Function:

• Lateral= pain, temperature
• Anterior= crude touch, pressure

Synapse 1: ipsilateral gray matter (spinal cord)

Synapse 2: decussates at AWC–> ascends contralaterally–> VPL (thalamus)

Question 53

Poliomyelitis, Werdnig-Hoffmann disease

Answer 53

LMN lesion: destruction of anterior horns
–> flaccid paralysis, weakness, atrophy, fasciculations, hyporeflexia, muscle atrophy

Poliomyelitis: fecal-oral transmitted Picorna virus (ssRNA+, non-enveloped)

• Replicates in oropharnx, small intestine–> bloodstream, CNS
• Diagnosis: CSF with increased WBCs with slight protein elevation (no glucose changes); recover virus from stool, throat

Werdnig-Hoffman: congenital degeneration of anterior horns of spinal cord

• -> “Floppy baby” with hypotonia, tongue fasciculations
• Autosomal recessive
• Death by 7 months

Question 54

ALS (amyotrophic lateral sclerosis)

Answer 54

UMN and LMN deficits
- No sensory, cognitive, oculomotor deficits

Defect in superoxide dismutase 1

Tx: Riluzole: decreases presynaptic Glutamate release–> increased survival

Question 55

Tabes dorsalis

Answer 55

Tertiary syphillis–> demyelination of dorsal columns, roots
–> lose sensation, proprioception, sensory ataxia

Conditions:

• Charcot’s joints
• Shooting pain
• Argyll Robertson Pupils: small bilateral pupils constrict to accomodation, not light
• Absent DTRs, positive Romberg (UMN and LMN signs)

Question 56

Syringomyelia

Answer 56

Syrinx (cyst in spinal cord) expands–> damage AWC (anterior white commisure) of spinothalamic tract

• -> bilateral loss of pain and temp (C8-T1)= Cape-like loss of sensation
• Seen in Arnold-Chiari I malformation

Question 57

Vitamin B12, Vitamin E deficiency

Answer 57

Subacute combined degeneration- demyelination of:

• Dorsal columns
• Lateral corticospinal tracts
• Spinocerebellar tracts

Symptoms:

• Ataxic gait
• Paresthesias
• Impaired position, vibration sense

Question 58

Friedreich’s Ataxia

Answer 58

Autosomal recessive trinucleotide repeat disorder (GAA on Chromosome 9)
–> mitochondrial function impaired

1. Cerebellar dysfunction–> ataxia
   - staggering gait, frequent falling, nystagmus (saccades), dysarthria
2. Degeneration of dorsal columns–> loss of position, vibration sensation
   - pes cavus, hammer toes
   - May see DM in 10%

Presents in childhood with kyphoscoliosis

Death due to hypertrophic cardiomyopathy:

• Arrhthmias
• CHF
• Bulbar dysfunction (can’t protect airway)

Question 59

Brown-Sequard Syndrome

Answer 59

Lateral hemisection of spinal cord:

• Ipsilateral UMN signs below lesion, LMN signs at lesion, loss of tactile sensation, discrimination below lesion, loss of all sensation at lesion
• Contralateral pain and temp loss (2-3 segments below where AWC knocked out)

Lesion above T1: may see Horner’s syndrome (damage sympathetic ganglion)

Question 60

Cauda equina syndrome

Answer 60

Damage to S2-S4 nerve roots

• Low back pain radiating to leg(s)
• Loss of ankle jerk reflex with plantar weakness
• Saddle anesthesia, loss of anocutaneous reflex (sphincter pinprick–> contraction)

Question 61

Conus medullaris Syndrome

Answer 61

Lesion at S2–>

• Flaccid paralysis of bladder, rectum, impotence
• S3-S5: saddle anesthesia
• Mild weakness of leg muscles if it spares cord/ roots

Question 62

Moro reflex

Answer 62

“Hang on for life” reflex:

- Abduct/extend limbs when startled, then draw together

Question 63

Parinaud syndrome

Answer 63

Lesion of brainstem superior colliculi (damage to oculomotor, trochlear nerves, Edinger-Westphal nucleus):

• Paralysis of conjugate vertical gaze
• Absent pupillary light reflex, failure to converge
• Wide-based gait
• Caused by pinealoma
• Inferior colliculi= auditory center

Question 64

Cranial nerve nuclei: location of emergence from brainstem

Answer 64

Midbrain: CN III, IV
Pons: CN V, VI, VII, VIII
Medulla: CN IX, X, XII
Spinal cord: CN XI

• • Medial nuclei= Motor (basal plate)
• • Lateral nuclei= Sensory (aLar plate)

Question 65

Vagus branches

Answer 65

Superior laryngeal nerve:

• External branch= cricothyroid m (runs with superior thyroid artery and vein)
• Internal branch: Sensory above vocal cords

Recurrent laryngeal:

• All laryngeal muscles (-ary-) except cricothyroid
• Sensory below vocal cords

Question 66

Nucleus solitarius

Answer 66

Visceral Sensory information (taste, baroreceptors, gut distention)

CN VII, IX, X

Question 67

Nucleus aMbiguus

Answer 67

Motor innervation of pharynx, larynx, upper esophagus

CN IX, X

Question 68

Dorsal motor nucleus

Answer 68

Parasympathetic (autonomic) innervation to heart, lungs, upper GI

CN X

Question 69

Cavernous sinus syndrome

Answer 69

Cavernous sinus= venous sinus around pituitary

• Blood from eye/superficial cortex–> cavernous sinus–> internal jugular vein
• Contains CN III, IV, V1, V2, VI and postganglionic sympathetic fibers

Mass effect, fistula, thrombosis:
- Decreased corneal, maxillary sensation with normal vision

Question 70

Hearing loss types

Answer 70

Conductive:

• AbnL Rinne test (Bone > air)
• Weber test localizes to affected ear (vibration>air conduction)
• Ex: middle ossicle otosclerosis; rupture of tympanic membrane d/t loud sound

Sensorineural

• normal Rinne test
• Weber localizes to unaffected ear (normal ear picks up sound/vibration, other doesn’t)

Noise-induced:

• Damage to stereocilliated cells in organ of corti (shearing forces against tectorial membrane
• Loss of high-frequency hearing 1st

Acoustic reflex: dampen effects of prolonged noise by contracting tensor tympani muscle (via chorda tympani)–> decreased ossicle responsiveness

Question 71

Muscles of mastication

Answer 71

CN V
Open mouth: Masseter, Temporalis, Medial pterygoid

Close mouth: Lateral pterygoid (Lateral Lowers jaw)

Question 72

Accomodation

Answer 72

Focus on near objects–> ciliary muscle tightens–> zonular fibers relax–> lens becomes more convex
- Occurs with convergence, miosis

• • Presbyopia= sclerosis, decreased elastility of lens–> decreased ability to focus during accomodation
• Myopes see improvement in distance vision as lens scleroses–> decreased elasticity, changes in lens curvature, decreased ciliary muscle strength

Question 73

Uveitis

Answer 73

Inflammation of uveal coat (iris, ciliary body, choroid)

• Associated with inflammatory disorders (RA, sarcoid, TB)
• HLA-B27 associated conditions

Question 74

Pupillary miosis

Answer 74

Parasympathetic constriction

1st neuron: Edinger-Westphal nucleus to ciliary ganglion (via CNIII)
2nd neuron: short ciliary nerves–> pupillary sphincter muscles

Question 75

Pupillary mydriasis

Answer 75

Sympathetic dilation

1st neuron: hypothalamus–> ciliospinal center of Budge (C8-T2)
2nd neuron: Exit T1–> superior cervical ganglion (along cervical sympathetic chain near lung apex)–> subclavian vessels
3rd neuron: plexus along internal carotid–> cavernous sinus–> orbit (long ciliary nerve)–> pupillary dilator muscles

Question 76

Pupillary light reflex

Answer 76

Light–> CNII–> pretectal nuclei–> midbrain bilateral Edinger Westphal nuclei–> bilateral contraction

Marcus Gunn pupil= afferent pupillary defect (optic nerve damage, retinal detachment)
- Decreased constriction when light shined in affected eye during “swinging flashlight test”

Question 77

CN III components

Answer 77

Motor= interior of nerve
- Vascular disease–> decreased O2, nutrients–> ptosis, down and out gaze (seen in Diabetes: glucose–> sorbitol)

Parasympathetic: outer part of nerve

• Affected first by compression (PCA aneurysm, uncal herniation)
• Diminished/absent pupillary light reflex (“blown out” pupil)

Question 78

Meyer’s loop

Answer 78

inferior retina: Carries superior visual field

• Temporal lobe
• Loops around inferior horn of lateral ventricle
• more susceptible to damage

Question 79

Dorsal optic radiation

Answer 79

Superior retina: inferior visual field

• Parietal lobe
• Shortest path via internal capsule (retrolenticular limb)
• Projects onto occipital cortex

Question 80

Internuclear ophthalmoplegia (INO)

Answer 80

MLF (medial longitudinal fasciculus)= tract communicating between CN VI (lateral rectus) and CN III (medial rectus) to coordinate horizontal gaze

Normal:
- R CN VI activates (abduct R eye)–> R nucleus of CN VI–> Left MLF–> L CN III activation (adduct L eye)

Lesion:

• R abducts–> L MLF lesioned–> no L eye adduction
• Right then develops nystagmus to compensate for Left= Left INO

** Seen in Multiple Sclerosis

Question 81

Alzheimer’s disease

Answer 81

Inheritance:

1. Down’s syndrome: increased risk due to Amyloid precursor protein (APP) expression on Chrom 21
2. Familial form: 10%:
   - Early onset: APP (chrom 21), presenilin-1 (chrom 14), presinilin-2 (chrom 1)
   - Late onset: ApoE4 (chrom 19)= protective

Pathophys:
1. Widespread cortical atrophy–> decreased Ach (deficiency of choline acetyltransferase on nucleus basalis of Meynert + hippocampal changes)

2. Plaques form first–> Neurofibrillary tangles

Amyloid plaques:

• Extracellular accumulation of A-beta (fragment of the amyloid precursor protein)
• Abnormal processing of APP critical to pathophysiology of Alzheimer’s disease

Neurofibrillary tangles:

• Intracellular, paired helical structures composed of hyperphosphorylated tau.
• Correlate well with disease severity and neuronal death.

Question 82

Neural tube defect markers

Answer 82

Low serum folate
Elevated fetal, maternal serum alpha-fetoprotein (AFP)
Elevated amniotic AchEsterase

Question 83

Epinephrine

Answer 83

Alpha-agonist used for Glaucoma
MOA: Decrease aqueous humor synthesis via vasoconstriction

Tox: Mydriasis (do NOT use in closed-angle glaucoma)

Question 84

Brimonidine

Answer 84

Alpha-2 agonist for Glaucoma

MOA: decrease aqueous humor synthesis

Tox: blurry vision, ocular hyperemia, foreign body sensation, ocular allergic reactions, ocular pruritis

Question 85

Timolol, betaxolol, carteolol

Answer 85

Beta-blockers for glaucoma

MOA: decrease aqueous humor synthesis

Question 86

Acetazolamide

Answer 86

Diuretic used for Glaucoma

MOA: Carbonic anhydrase inhibitor–> decreased aqueous humor synthesis

Question 87

Pilocarpine, carbachol

Answer 87

Direct cholinomimetics for glaucoma

MOA: Increase outflow of aqueous humor via contraction of ciliary muscle, opening meshwork
** Use pilocarpine in emergencies (opens canal of Schlemm)

Tox: miosis, cyclospasm (contraction of ciliary muscle)

Question 88

Physostigmine, echothiophate

Answer 88

Indirect cholinomimetics for glaucoma

MOA: Increase outflow of aqueous humor via contraction of ciliary muscle, opening meshwork

Tox: miosis, cyclospasm (contraction of ciliary muscle)

Question 89

Latanoprost

Answer 89

Prostaglandin for glaucoma

MOA: increases outflow of aqueous humor

Tox: darkens iris (brown)

Question 90

Opioid analgesics

Answer 90

Morphine, fentanyl, codeine, heroine, methadone, meperidine, dextromethorphan, diphenoxylate

MOA:

• Agonist at opioid receptors: Mu= morphine, delta= enkephalin, kappa= dynorphin
• Modulates synaptic transmission:
• Opens K+ channels–> hyperpolarization–> stop pain transmission
• Closes Ca+2 channels
• Inhibits cAMP formation
• Decreased synpatic transmission
• -> inhibit release of ACh, NE, 5-HT, glutamate, substance P

Use:

• Pain
• Cough suppression (dextromethorphan)
• Diarrhea (loperamide, diphenoxylate), acute pulmonary edema
• Maintenance: potent, long-acting opiate with good bioavailability (Methadone)

Tox:

• Addiction
• Respiratory depression, additive CNS depression with other drugs
• Constipation, miosis (tolerance does NOT develop)

** Overdose: Naloxone, Naltrexone)

Question 91

Butorphanol, Nalbuphine, Pentazocine

Answer 91

Mixed agonist/antagonist

• K and Mu agonist (without other opioid)
• Antagonist of Mu in presence of other opioids

Uses:

• Counteract AEs of opioids (respiratory depression, constipation)pain)
• Central Kappa effect: dysphoria
• Labor pain

Question 92

Tramadol

Answer 92

Dual action: Mu opioid receptor (weak), NE and serotonin reuptake inhibitor

Use: chronic pain

Tox: similar to opioids, decreased seizure threshold

Question 93

Phenytoin

Answer 93

Treats:

• GTC (1st line**), Focal seizures
• Status Epilepticus prophylaxis (1st line**)
• Class Ib Antiarrhythmic

MOA:
- Na+ channel block in cortical neurons (can’t recover from depolarization)

AEs:

• Purple glove
• Gingival hyperplasia
• Nystagmus, diplopia, ataxia, sedation
• Hirsutism
• Megaloblastic anemia
• Teratogenic (fetal hyantoin syndrome)
• SLE-like syndrome (slow alkylators)/ serum sickness
• Generalized lymphadenopathy
• Stevens-Johson
• Osteopenia
• Teratogenic: fetal hydantoin syndrome= microcephaly, dysmorphic craniofacial features, hypoplastic nails and distal phalanges, cardiac defects, IUGR, mental retardation

Question 94

Carbamazepine

Answer 94

Treats:

• GTC (1st line), focal seizures (1st line)
• Bipolar disorder
• Trigeminal neuralgia

MOA:
- Na+ channel block in cortical neurons (can’t recover from depolarization)

AEs:

• Reacts with everything
• Autoinducer
• Must perform HLA-typing
• DON’T use in myoclonic, absense, aclonic seizures
• SIADH
• Stevens-Johnson
• Diplopia, ataxia
• Blood dyscrasias (agranulocytosis, aplastic anemia)
• Teratogen= neural tube defects, craniofacial defects, fingernail hypoplasia, developmental delay, IUGR

Question 95

Lamotrigine

Answer 95

Treats:

• ALL seizure types
• GOOD Bipolar med

MOA:
- Na+ channel block

AEs:
- Toxic epidermal necrolysis!!

Question 96

Gabapentin

Answer 96

Treats:

• GTC, focal seizures
• pain

MOA:
- alpha-2 delta subunit of Ca+2

Tox:
- Sedation, ataxia

Question 97

Topiramate

Answer 97

Treats:

• ALL seizure but absence type
• Migraine
• Weight loss

MOA:

• Increase GABA
• Decrease NMDA (Na+ channel block)
• CA inhibitor
• Ca+2 block in hippocampus

AEs:

• Kidney stones
• Weight loss
• Sedation, mental dulling

Question 98

Phenobarbital

Answer 98

Treats:
- GTC, focal seizures in INFANTS

MOA:

• Opens Cl- channel LONGER in GABA
• In high enough dose–> binds GABA receptor directly–> opens channel w/o GABA

AEs:

• Overdose- don’t use except in children
• Sedation, tolerance, dependence
• CyP-450 induction

Question 99

Benzodiazepines

Answer 99

Treats:

• ALL seizure types
• Status epilepticus (1st line for acute**)
• EtOH withdrawal
• Anxiety
• Sleep (decreases REM sleep)
• Night terrors, sleepwalking
• General anesthetic (amnesia, muscle relaxation)

MOA:

• Increases Cl- channel opening FREQUENCY in GABA
• Long term: decreased GABA receptors

AEs:

• Withdrawal seizures
• Do not take with EtOH
• Respiratory depression

** Treat overdose with Flumazenil

Question 100

Valproic acid

Answer 100

Treats:

• ALL seizure types
• 1st line for Tonic-Clonic**
• Bipolar disorder
• Migraines

MOA:

• GABA increase
• Block NMDA receptors (K+) in hippocampus
• Na+ channel block in cortical neurons (can’t recover)

AEs:

• Thrombocytopenia
• Children: Pancreatitis, Hepatitis
• Neural tube defects (due to inhibition of folate absorption)
• Tremor, weight gain

Question 101

Ethosuximide

Answer 101

Treats:
- Absence seizures (1st line**)

MOA:
- T-type Ca+2 channels in Thalamus–> hyperpolarization

Tox:

• GI distress, Fatigue, H/A, urticaria
• Stevens-Johnson

Question 102

Tigabine

Answer 102

Treats:
- partial seizures

MOA:
- GABA increase (inhibits GABA reuptake)

Question 103

Vigabatrin

Answer 103

Treats:
- Partial seizures

MOA;
- Irreversibly inhibits GABA transaminase–> increased GABA

Question 104

Levitiracetam

Answer 104

Treats:

• GTC
• Focal epilepsy
• Myoclonic epilepsy

MOA:
- SV2A

Question 105

Zolpidem, Zaleplon, Eszopiclone

Answer 105

MOA: Act via BZ1 subunit of GABA receptor

Use: Insomnia

Tox:

• Ataxia, H/A, confusion
• Modest day-after psychomotor depression, fewer amnestic effects
• Lower dependence risk than benzos

**Reverse effects with flumazenil

Question 106

Principles of anesthetics

Answer 106

CNS drugs must be lipid soluble (cross BBB) or actively transported

• Drugs with decreased solubility in blood= rapid induction, recovery
• Increased solubility in blood= high AV concentration gradient, slow onset, slow recovery
• Drugs with increased solubility in lipid= increased potency

Potency= 1/MAC
MAC= minimal alveolar concentration at which 50% of population anesthetized
- Varies with ambient temperature and AGE (NOT surgery type, duration of administration, sex, height, weight)

Arterial tension curve:

• Depends on solubility of anaesthetic in blood
• Less soluble in blood: steeper curve (partial pressure of substance in blood increases steeply)

Question 107

Inhaled anesthetics

Answer 107

Halothane, -fluranes, NO

MOA: unknown

Effects:

• Decreased myocardial contractility–> decreased renal, hepatic blood flow
• Decreased respiratory drive
• Decreased pulmonary vascular resistance
• Decreased mucocillary reflex
• N/V
• Increased Cerebral blood flow (increased ICP)

Tox:

• Hepatotoxic (halothane)
• Nephrotoxic (methoxyflurane)
• Proconvulsant (enflurane)
• Malignant hyperthermia (all but NO)–> reverse with dantrolene sodium
• Expansion of trapped gas in body (NO–> the bends)

Question 108

Thiopental

Answer 108

IV anesthetic= Barbituate

• High potency, high lipid solubility (rapid entry into brain)
• **DECREASES CBF: used in stroke to decrease cerebral edema

Use: induction of anesthesia, short procedures
- Terminated by rapid redistribution into tissue (skeletal muscle)

Question 109

Midazolam

Answer 109

IV anesthetic= benzo

Use: endoscopy
- Used with gaseous anesthetics, narcotics

Tox: respiratory depression (post-op)

• Decreased BP (tx overdose with flumazenil)
• Amnesia

Question 110

Ketamines

Answer 110

IV anesthetic
Arylcyclohexylamines= PCP analogs
- Dissociative anesthetics
- Block NMDA receptors (via glutamate + glycine)

Tox:

• CV stimulants
• Disorientation, hallucinations, nightmares
• Increase CBF

Question 111

Propafol

Answer 111

IV anesthetic
Use: sedation in ICU
- Rapid anesthesia induction
- Short procedures

• • decreased postoperative nausea than thiopental
• Potentiates GABA(A)

Question 112

Local anesthetics

Answer 112

Esters= procaine, cocaine, tetracaine
Amides= 2 I's in name

MOA: block Na+ channels by binding receptor on inner channel

• Bind to activated Na+ channels (most effective in rapidly firing neurons
• Tertiary amines penetrate membrane uncharged and bind ion channels in charged form

Principles:

• Given with vasoconstrictors
• Acidic tissue (infected)–> charges alkaline anesthetics–> can’t penetrate membrane–> need to administer more
• Order of blockade: small myelinated > small unmyelinated (C-fibers) > large myelinated > large unmyelinated
• Lose: 1. pain, 2. temp, 3. touch. 4. pressure

Use: minor surgical procedures, spinal anesthesia

Tox: CNS excitation

• CV toxicity (bupivacaine)
• HTN, hypotension
• Arrhythmias (cocaine)

Question 113

Succinylcholine

Answer 113

Depolarizing NM blocking drug
MOA: Ach receptor agonist–> sustained depolarization, prevents muscle contraction
- Reverse blockade in 2 phases:
1. Prolonged depolarization (no antidote): block potentiated by AchE-I
2. Repolarized but blocked: Ach receptors available but desensitized
- Antidote= AchE-I (neostigmine)
“Train of 4 response”
- Slow metabolizers take longer to enter phase 2 (antidote won’t work until then)

Tox: hypercalcemia, hyperkalemia, malignant hyperthermia

Question 114

Tubocurarine, Atacurium, mivacurium, pancuronium, vecuronium, rocuronium

Answer 114

Nondepolarizing NM blocking drugs
MOA: Competitive antagonist of Ach receptors

Reversal: neostigmine, edrophonium, AchE-I

Question 115

Bromocriptine

Answer 115

Ergot dopamine agonist

Question 116

Pramipexole, Ropinerole, pergolide

Answer 116

Non-ergot dopamine agonist

- Used in treatment of Restless leg syndrome

Question 117

Amantadine

Answer 117

Increases dopamine release
- Also used as antiviral against rubella, Influenza A

Tox: ataxia

Question 118

Benzotropine

Answer 118

Antimuscarinic/anticholinergic drug used to improve tremor and rigidity associated with Parkinson’s
- Can also be used to treat EPS due to antipsychotic antagonism of DA receptors

Question 119

L-dopa

Answer 119

Increases dopamine in brain (can cross BBB)
- Converted by dopa decarboxylase to DA in CNS

Tox:

• Long term use: dyskinesia after administeration, akinesia between doses
• w/o Carbidopa: postural hypotension, N/V, Arrhythmias (increased peripheral catecholamine formation)
• Anxiety, agitation, insomnia, confusion, hallucinations (too much DA)

** Vitamin B6 (pyridoxine)= cofactor for DOPA metabolism (therefore supplements can enhance degradation)

Question 120

Carbidopa

Answer 120

Peripheral dopa decarboxylase inhibitor

• Prevents peripheral formation of dopamine
• Increases CNS levels, limits peripheral side effects

Question 121

Selegiline

Answer 121

Selective MAO-B inhibitor: decreases central DA degradation

- MAO-B= metabolizes DA over NE/serotonin

Question 122

Entacapone, Tolcapone

Answer 122

COMT inihibtors: prevent L-dopa degradation

• Entacapone= prevents peripheral breakdown
• Tolcapone= prevents peripheral and central breakdown

Question 123

Memantine

Answer 123

NMDA receptor antagonist

• Used in Alzheimer’s
• Prevents excitatoxicity (mediated by Ca+2 influx)

Tox: dizziness, confusion, hallucinations

Question 124

Donepezil, galantamine, rivastigmine

Answer 124

AchE-Inhibitors used in Alzheimer’s

Tox: Nausea, dizziness, insomnia

Question 125

Huntington’s treatments

Answer 125

Tetrabenzine, Reserpine: block VMAT: limit DA packaging and release

Haloperidol: DA receptor antagonist

Question 126

Sumatriptan

Answer 126

Serotonin 1B/1D agonist

• Inhibits trigeminal nerve activation
• Prevents Vasoactive peptide release
• Induces vasoconstriction

Use: acute migraine, cluster headache

Tox: coronary vasospasm (avoid in CAD, Prinzmetal angina), mild tingling

Question 127

Tetrodotoxan

Answer 127

Puffer fish venom

• Blocks voltage-gate Na+ channels in nerve cell membranes
• -> inhibits passive sodium transport

Question 128

Primidone

Answer 128

Antiepileptic drug

• Metabolized to phenobarbital and phenylethylmalonamide
• Used in treatment of essential tremor

Question 129

Alcohol and CNS

Answer 129

Thiamine deficiency:

• Cerebellar atrophy–> Ataxia (weeks to months)= wide-based gait, truncal instability, intention tremor, “Parkinsonian tremor”
• Loss of Purkinje cells in anterior lobes, cerebellar vermis
• Wernicke-Korsakoff syndrome= confusion, ophthalmoplegia, ataxia; memory loss (antero- and retrograde), confabulation, personality changes

Question 130

Pontine hemorrhage

Answer 130

Pinpoint pupils
Loss of horizontal gaze
Quadriparesis
Decerebrate posturing (prostrate position, lesion below red nucleus)–> coma–> death

**Decorticate posturing (bent arms) due to lesion ABOVE red nucleus

Question 131

Thalamic hemorrhage

Answer 131

Contralateral sensory loss, aphasia, temporary homonymous hemianopia (unilateral abducens palsy, pupil asymmetry, nonreactive downward gaze)

Question 132

Peripheral vertigo

Answer 132

More common type

• Inner ear etiology (semicircular canal debris, vestibular nerve infection, Meniere’s disease)
• Positional testing-> delayed horizontal nystagmus

Question 133

Central vertigo

Answer 133

Brainstem/cerebellar lesion (vestibular nuclei stroke or posterior fossa tumor)

• Directional change of nystagmus
• Skew deviation, diplopia, dysmetira
• Positional testing–> immediate nystagmus in any direction, may change directions