Cumulative Review

Question 1

[Synaptic transmission] Mechanism of NT release at the presynaptic cell

Answer 1

• AP reaches the end of the cell (“active zone”)
  
  • Active zone E_Ca = +120mV b/c the concentration of Ca²⁺ is significantly higher outside the cell
• Ca²⁺ channels open ==> Ca²⁺ flows in quickly
• Ca²⁺ attaches to vesicles containing NTs via SNARE proteins ==> fusion of vesicle to cell
• NTs escape into the synaptic cleft

Question 2

[Synaptic transmission} Mechanism of SNARE-mediated vesicle fusion

Answer 2

• Ca²⁺ attaches to synaptotagmin (located on vesicle)
• Synaptobrevin, syntaxin, and SNAP-25 form a super-helix used to fuse with the membrane
• Vesicle fuses with membrane and NTs are released into the synaptic cleft

Question 3

[Synaptic transmission} Major function of motor nerve terminal

Answer 3

• AP from CNS ==> enough ACh to depolarize muscle fiber to threshold for AP
• Muscle fiber resting = -80mV & threshold = -50mV ==> enough ACh to depolarize muscle by at least 30mV

Question 4

[Synaptic transmission} Myasthenic syndrome characteristics

Answer 4

• Ab againsts Ca²⁺ channels
• Characteristically weak, but can fire APs @ muscle & improve strength with effort
  
  • relies on facilitation to build up enough Ca²⁺ to release enough NTs to generate APs @ muscle

Question 5

[Synaptic transmission} Myasthenia gravis characteristics

Answer 5

• Disease w/Abs against AChR ==> initial strength is good, but tire very quickly
  
  • With fewer postsynaptic AChR, M.G. people generally need to release more quanta to fire APs
  • Due to synaptic depression (reduction of 10% of available quanta/AP), M.G. people quickly fall below the required number of quanta to fire APs @ muscle

Question 6

[Anterior Horn/Peripheral/NMJ Disorders] Signs/symptoms of upper motor neuron disorders

Answer 6

• spastic tone
• hyperactive tendon reflexes
  
  • pathologic reflexes (Babinski)
• emotional lability (inappropriate laughing and crying)

Question 7

[Anterior Horn/Peripheral/NMJ Disorders] Signs/symptoms of lower motor neuron disorders

Answer 7

• muscle atrophy
• fasciculation
• diminished tone (flaccidity)
• reduced or absent reflexes

Question 8

[Anterior Horn/Peripheral/NMJ Disorders] Signs/symptoms of non-motor (sensory or autonomic) peripheral nerve disorders

Answer 8

• sensory
  
  • numbness
  • pain
  • altered sensation
• autonomic
  
  • bowel, bladder disturbance
  • altered sweating, HR, BP

Question 9

[Anterior Horn/Peripheral/NMJ Disorders] Conditions w/rapidly developing muscle weakness

Answer 9

• NMJ disorders
  
  • myasthenia gravis
  • botulism
  • organophosphate poisoning
• acute demyelination
  
  • Guillain Barre
• electrolyte disturbance
• toxic myopathies

Question 10

[Anterior Horn/Peripheral/NMJ Disorders] Anterior Horn cell disorders (examples)

Answer 10

Amyotrophic lateral sclerosis*

Spinal muscular atrophy

Poliomyelitis and West Nile virus

Question 11

[Anterior Horn/Peripheral/NMJ Disorders] Peripheral neuropathies (polyneuropathy examples)

Answer 11

Hereditary – Charcot Marie Tooth disease*

Systemic disease – diabetes*, immune disorders etc

Vitamin deficiency – B12 deficiency, etc.

Exogenous toxins – alcohol, chemotherapy, etc.

Question 12

[Anterior Horn/Peripheral/NMJ Disorders] NMJ disorders

Answer 12

Myasthenia gravis*

Botulism

Organophosphate poisoning

Question 13

[Anterior Horn/Peripheral/NMJ Disorders] Myopathies examples

Answer 13

Muscular dystrophies – Duchenne/Becker*

Myotonic disorders

Inflammatory myopathies – polymyosits, dermatomyositis

Metabolic myopathies – glycogen storage, lipid myopathy

Endocrine/toxic myopathies

Question 14

[Anterior Horn/Peripheral/NMJ Disorders] ALS signs/symptoms

Answer 14

• progressive weakness & wasting
• coexisting: spasticity & hyperreflexia
• asymmetric limb weakness + fasciculations
• foot drop or hand deformity possible
• speech may be slurred/spastic
• diaphragm weakness ==> decreased breathing capacity + impaired swalling ==> aspiration pneumo or respiratory insufficiency

Question 15

[Anterior Horn/Peripheral/NMJ Disorders] Most common type of diabetic neuropathy + presentation

Answer 15

• distal sensory or sensorimotor polyneuropathy
• initial numbness and burning dysesthesias in feet ==> legs & hands
• weakness of foot dorsiflexor ==> foot drop gait
• diminished grip strength/hand dexterity

Question 16

[Anterior Horn/Peripheral/NMJ Disorders] Sensation in diabetic neuropathy

Answer 16

• loss of pin sensation in stocking glove distribution (often asymmetric)
• “Large fiber pattern”
  
  • loss of position, vibration and light touch
  • decreased reflexes
• “Small fiber injury”
  
  • prounounced loss of pain and temperature sensation
  • w/pain (dull aching; distal burning @ night)
  • NCVs may be near normal
• autonomic dysfunction

Question 17

[Anterior Horn/Peripheral/NMJ Disorders] Myasthenia Gravis presentation (signs/symptoms)

Answer 17

• fluctuating weakness & fatigue @ cranial, limb, or trunk musculature
• ocular sx: ptosis, diplopia and blurred vision
• weak facial muscles ==> slurred/nasal/hoarse speech
  
  • ==> trouble chewing/swallowing
• weak respiratory muscles ==> SOB

Question 18

[CNS Injury] Types of forces resulting in cerebral trauma

Answer 18

• contact phenomena
• acceleration
  
  • translational
  • rotation
• penetrating
• secondary injury

Question 19

[CNS Injury] Layers of Scalp

Answer 19

• S = skin
• C = subcutaneous tissue
• A = galea
• L = loose connective tissue
• P = periosteum

Question 20

[CNS Injury] Contact phenomena head injuries cause & effects

Answer 20

• result from an object striking the head
• ==> lacerations of the scalp
• ==> fractures of skull
• ==> epidural hematomas
• ==> cerebral contusions

Question 21

[CNS Injury] Skull fracture types

Answer 21

• contact phenomenon to skull
• types: linear, depressed, basilar, diastatic, and growing
  
  • linear = indicates high-impact injury
  • depressed = comminuted bone fragments
  • basilar = base of skull ==> CSF leaks ==> meningitis
  • diastatic = separates at suture lines
  • growing = infancy; from dural tears

Question 22

[CNS Injury] Concussion definition

Answer 22

• =”mild traumatic brain injury”
• = laternation in mental status, distrubance of equilibrium caused by biomechanical forces which may/may not lead to loss of consciousness
• hallmarks = confusion & amnesia

Question 23

[CNS Injury] Common concussion symptoms

Answer 23

• headache
• dizziness
• poor attention, inability to concentrate
• fatigue, sleep disturbance
• irritability, depressed mood
• intolerance of bright light or loud noise

Question 24

[CNS Injury] Types of acceleration injuries

Answer 24

• transalational: head movement in single plane after impact
• rotational: head movement in multiple planes

Question 25

[CNS Injury] Signs of basilar skull fracture

Answer 25

•CSF rhinorrhoea •Bilateral periorbital haematomas (Racoon eyes) •Subconjunctival haemorrhage •Bleeding from external auditory meatus •CSF otorrhoea •Battle’s sign •Facial nerve palsy

Question 26

[CNS Injury] Consequences of transalation acceleration injuries

Answer 26

• stretching/tearing of veins between brain and dura ==> subdural hematoma
• brain contusion
• coup/contrecoup injuries

Question 27

[CNS Injury] Characteristics of brain contusion

Answer 27

• often due to transalational acceleration injuries
• often occurs @ frontal/temporal
• can lead to swelling, brain shift, increase in intracranial pressure, herniation
• low mortality alone

Question 28

[CNS Injury] Examples of rotational acceleration injuries

Answer 28

• MVA ejection
• motorcycle accident
• auto-pedestrian accident

Question 29

[CNS Injury] Consequences of rotational acceleration injury

Answer 29

• ==> microscopic tearing of nerve cells @ brain

Question 30

[CNS Injury] Characteristics of epidural hematomas

Answer 30

• Caused by contact phenomena
• extradural arterial hemorrhage
• Associated with skull fractures
• Classic “lucid interval” after trauma occurs
• Low mortality rate

Question 31

[CNS Injury] Characteristics of subdural hematoma

Answer 31

• caused by translational acceleration injuries
• rupture of bridging veins in subdural space
• associated with brain contusions
• high mortality rate

Question 32

[CNS Injury] Characteristics of Coup/contrecoup injury

Answer 32

• often caused by translational acceleration injury
• brain contusions + shearing forces on brain/veins in both the rostral and caudal directions due to impact and rebound

Question 33

[CNS Injury] Common consequences of rotational acceleration injury

Answer 33

• diffuse axonal injury ==> microscopic tearing of nerve cells in brain
• under a microscope = “axonal spheroids”
• patients are usually in chronic vegetative state

Question 34

[CNS Injury] Goal of treatment in head injuries

Answer 34

• save any neurons that have reversible damage
• minimize secondary effects/mitigate symptoms

Question 35

[CNS Injury] Importance of controlling ICP

Answer 35

• increased ICP ==> CSF in spinal subarachnoid space OR venoconstriction @ CNS capacitance vessels ==> blood displacement into jugular venous system
• ==> herniation of brain (which is non-compressible) ==> brain damage
• also: if ICP > MAP, then there will not be blood flow to brain ==> syncope & eventaully cell death

Question 36

[CNS Injury] Common signs/symptoms of increased ICP

Answer 36

• sudden change in neurological condition
• headache, nausea, vomiting ==> progressive lethargy and LOC

Question 37

[CNS Injury] Herniation syndromes (4)

Answer 37

• subfalcine herniation
• central herniation
• uncal transtentorial herniation
• tonsillar herniation

Question 38

[CNS Injury] Characteristics of subfalcine herniation

Answer 38

• cingulate gyrus is pushed away from the expanding mass and herniates beneath the falx cerebri.
• The anterior cerebral artery is often kinked, which may result in a stroke in distribution of this vessel.

Question 39

[CNS Injury] Characteristics of central herniation

Answer 39

• Occurs when there is downward pressure centrally
• can result in bilateral uncal herniation
• results in loss of consciousness.

Question 40

[CNS Injury] Characteristics of uncal transtentorial herniation

Answer 40

• the uncus herniates across the tentorial edge, and downward into the posterior fossa
• herniation compresses the midbrain and its ipsilateral cerebral peduncle
  
  • ==> ipsilateral third nerve palsy (test pupillary light reaction, could be fixed and dilated)
  • ==> contralateral hemiparesis (paralysis of one side of body)
• Rarely, uncal herniation can compress the opposite cerebral peduncle against the tentorial edge, resulting in a hemiparesis that is ipsilateral to the mass lesion and herniated uncus.

Question 41

[CNS Injury] Characteristics of tonsillar herniation

Answer 41

• cerebellar tonsils herniate downward into the foramen magnum (coning)
• medulla is compressed → abnormal cardiac and respiratory responses, including Cushing’s reflex (bradycardia and hypertension) in the setting of high intracranial pressure.
• Tonsillar herniation most commonly is encountered in the setting of a mass lesion in the posterior fossa.

Question 42

[CNS Injury] Critical avoidance in context of intracranial mass lesion

Answer 42

• DO NOT PERFORM A LUMBAR PUNCTURE
• lumbar punctures can precipate herniation syndromes due to pressure differentials created during the procedure

Question 44

[Delirium/Dementia] Delirium DSM definition

Answer 44

• disturbance in attention and awareness
• disturbance develops over a short period of time
  
  • change from baseline attention
  • tends to fluctuate during course of day
• additional cognitive disturbance
• evidence that disturbance is a direct consequence of another medical condition
  
  • substance intoxication/withdrawal
  • toxin
  • multifactorial

Question 45

[Delirium/Dementia] Possible underlying causes of delirium

Answer 45

• infection
• electrolyte abnormalities
• hypoglycemia
• cardiac/pulmonary/hepatic/renal failure
• endocrine
• medications
• drugs, withdrawal
• trauma
• epilepsy

Question 46

[Delirium/Dementia] Delirium mechanism

Answer 46

• Disrupted ascending activation from reticular activating system and thalamus to the cortex
  
  • both very sensitive to metabolic stress
• •Potentially involving multiple transmitter systems: dopamine, acetylcholine, norepinephrine, and serotonin

Question 47

[Delirium/Dementia] Management of delirium

Answer 47

• •Low dose Haldol; IV form
• •May use low dose atypicals if PO
• •Donepezil
• •Unless EtOH withdrawal, avoid pitfalls of benzos and paradoxical agitation
• •Physical restraints only during acute agitation and promptly removed

Question 48

[Delirium/Dementia] Dementia DSM definition

Answer 48

A.Evidence of significant cognitive decline from a prior level of performance in one or more cognitive domains

B.Cognitive deficits interfere with independence in everyday activities

C.Do not occur exclusively in context of delirium

D.Not better explained by another mental disorder (i.e., depression, schizophrenia)

Question 49

[Delirium/Dementia] General characteristics of dementia

Answer 49

• “top-down” cognitive fxnl impairment
  
  • i.e. isolated memory problems w/out attention issues
• decline from previous baseline
• changes in personality, mood, perception
• numerous causes:
  
  • neurodegenrative: Alzheimers
  • vascular
  • obstructive
  • neoplastic
  • infectious
  • trauma
• depression can present as dementia

Question 51

[Neurodegenerative] General overview/underlying cause of neurodegenerative disorders

Answer 51

• often due to spontaneous failure w/in body
• includes spontaneous death of a neuronal population
  
  • location of population ==> clinical presentation

Question 52

[Neurodegenerative] Common dementia-related problems in neurodegenerative diseases

Answer 52

• memory
• language
• executive function
• visuospatial
• depression, apathy, sociopathy

Question 53

[Neurodegenerative] Common movement disorder problems in neurodegenerative diseases

Answer 53

• bradykinesia
• rigidity
• tremor
• chorea = involuntary movement disorder

Question 54

[Neurodegenerative] Dementia could indicate…

Answer 54

• Alzheimer’s disease
• FTD
• Lewy body
• HD
• CJD

Question 55

[Neurodegenerative] Movement disorders could indicate…

Answer 55

• Parkinson’s
• PSP (progressive supranuclear palsy)
• CJD
• Huntingtons

Question 56

[Neurodegenerative] Alzheimer’s disease: Clinical Features & Transmission

Answer 56

• clinical = early memory and visuospatial problems
• transmission
  
  • most = sporadic
  • genetic
    
    • presenilin 1 mutation
    • trisomy 21

Question 57

[Neurodegenerative] Parkinson’s disease: Clinical Features & Transmission

Answer 57

• tremor, rigidity, bradykinesia
  
  • leads to slow speech and movement
• genetic and sporadic transmission

Question 58

[Neurodegenerative] Lewy Body Dementia: Clinical Features & Transmission

Answer 58

• early parkinsonian features, psychosis, fluctuating consciousness
• genetic and sporadic transmission

Question 59

[Neurodegenerative] Huntington’s disease: Clinical Features & Transmission

Answer 59

• dementia
• depression, sociopathy (aggression)
• chorea
• inherited: autosomal dominant

Question 60

[Neurodegenerative] Alzheimer’s disease: Neurochemistry & Neuropathology

Answer 60

• ACh deficit (cholinergic hypothesis)
• Amyloid plaques and neurofibrillary tangles
• diffuse atrophy globally
• cortex and hippocampus involved

Question 61

[Neurodegenerative] Parkinson’s disease: Neurochemistry & Neuropathology

Answer 61

• Chemistry
  
  • Synuclein
  • Dopamine deficit
• Pathology
  
  • Lewy bodies

Question 62

[Neurodegenerative] Lewy Body Dementia: Neurochemistry & Neuropathology

Answer 62

• ACh deficit
• Dopamine deficit
• Lewy bodies

Question 63

[Neurodegenerative] CJD: Neurochemistry & Neuropathology

Answer 63

• prion protein

Question 64

[Neurodegenerative] Huntington’s disease: Neurochemistry & Neuropathology

Answer 64

• polyglutamine
• characteristic gross changes w/out microscopic changes
• caudate nucleus atrophy
• ventricles ==> butterflies

Question 65

[Neurodegenerative] Characteristics of prion diseases

Answer 65

• can be sporadic, heritable, or transmissible/infectious
• caused by proteinaceious infectious particle w/out nucleic acid
  
  • natural protein ==> deforms to beta pleated sheet
• uniformly fatal diseases

Question 66

[Stroke} Presentiation of large vessel ischemic stroke/TIA

Answer 66

• ==> deficits in multiple systems
• e.g. @ middle cerebral ==> hemiparesis, hemisensory loss, defect in visual field contralateral to ischemic side of brain

Question 67

[Stroke} General presentation of small vessel ischemic stroke/TIA

Answer 67

• ==> isolated motor or sensory deficit in one side of the body

Question 68

[Stroke} Common non-atherosclerotic causes of stroke in young patients

Answer 68

• coagulopathy
• sickle cell anemia
• oral contraceptives, post partum
• antiphospholipid ab syndrome

Question 69

[Stroke} Rescuscitation related to stroke mechanism

Answer 69

• ischemic stroke
• resuscitation ==> break up clot and maintain volume of blood to maintain brain perfusion

Question 70

[Stroke} Prevention related to stroke mechanism

Answer 70

• keep arteries healthy ==> prevention of atherosclerosis and hypercoaguability
  *

Question 71

[Stroke} Basic principles /goals of emergency tx of stroke

Answer 71

• preserve non-infarcted areas of brain
• prevent progression of infarction
• avoid complication
• initiate evaluation for long-term therapy

Question 72

[Stroke} Tx of ischemic stroke @ ER

Answer 72

• act fast even w/normal scans
  
  • If CT scan shows hemorrhage, then you know that it is hemorrhagic.
  • If not, you know it is ischemic when combined with the story and clinical signs.
• Re-open arteries with a catheter, thrombolytics.
  
  • generally a 4 hour IV window for thrombolytics
  • Tissue Plasminogen Activator (TPA) is the drug of choice.
• Keep fluids up, maximize cardiac output, and resist the temptation to lower blood pressure (unless dangerously high)
• treat hypoglycemia when it exists.

Question 73

[Stroke} Fluids used in emergency ischemic stroke tx

Answer 73

• Avoid lowering BP
  
  • most stroke patients have HTN following a stroke that fixes itself within 7-10 days
• If they won’t decompensate into heart failure, you can give normal saline.
• If they will, give d5W unless they are having a very large stroke and at risk for cerebral edema.

Question 74

[Stroke} Clinical presentation of ruptured intracranial aneurysm

Answer 74

• sudden onset neurological deficits
• headache
  
  • “worst headache of their life”
• nausea, vomiting
• depressed level of consciousness

Question 75

[Stroke} Clinical presentation of ruptured intracerebral hemorrhage

Answer 75

• begins: mild headache, mild neuro deficits, some nausea ==(minutes - hours)==> + decreased level of consciousness
• hemiparesis ==> hemiplegia
• decreased consciousness ==> coma

Question 76

[Stroke} Clinical presentation of acute subdural hemorrhage

Answer 76

• Due to trauma or spontaneous
• confusion, lethargy, coma,
• focal neurologic symptoms, seizures
• headache, dizzines
• N/V, ataxia

Question 77

[Stroke} Clinical presentation of epidural hemorrhage

Answer 77

• trauma/injury ==> period of grogginess ==> lucid interval ==> worsening condition/consciousness
• commonly = traumatic temporal bone fracture tears middle meningeal artery

Question 78

[Stroke} Emergency treatment of hemorrhage

Answer 78

• if ischemic ==> hemorrhage then use anti-platelets/anticoagulants
• rapid dx ==> ICP monitoring device +/- drainage device
• reduce ICP via diuresis and reduction of blood pCO₂
• emergency surgery if neccessary
  
  • common in subdural and epidural hemorrhage

Question 79

[Toxic-metabolic] Clinical features of Wernicke’s encephalopathy

Answer 79

• Thiamine deficiency (vitamin B1)
• Wernicke’s encephalopathy - full triad of ataxia, nystagmus (or ophthalmoplegia) and confusion
  
  • these signs not always present
• Korsakoff’s psychosis
• Peripheral neuropathy

Question 80

[Toxic-metabolic] Etiology of Wernicke’s encephalopathy

Answer 80

• Vitamin B1 (Thiamine) deficiency
• Alcoholism = common cause
  
  • ==> poor food intake + reduced absorption
• Patients w/GI or absorbing problems are also at risk

Question 81

[Toxic-metabolic] Radiographic finding in Wernicke’s encephalopathy

Answer 81

• 50% of cases detectable by MRI
• damage to affected structures (mammillary body, ventricles, etc.)
• disruption of BBB

Question 82

[Toxic-metabolic] Characteristics of Korsakoff’s Psychosis

Answer 82

• Memory loss associated with Wernicke’s encephalopathy
• Thiamine deficiency ==> damage to dorsomedial nucleus

Question 83

[Toxic-metabolic] Etiology of Hepatic Encephalopthy

Answer 83

• often: Alcoholism ==> cirrhosis ==> reduced liver fxn ==> increased toxins
• Increased ammonia (from catabolism of proteins) ==> disturbance of amino acid balance ==> disturbance of inhibitory and excitatory NTs @ brain

Question 84

[Toxic-metabolic] Presentation of Hepatic Encephalopathy

Answer 84

• Episodes of confusion, forgetfulness ==>
• drowsiness, stupor ==>
• coma

Question 85

[Toxic-metabolic] Etiology of Cobalamin deficiency

Answer 85

• Vitamin B12 deficiency
• causes:
  
  • reduced dietary intake (e.g. of meat/dairy)
  • pernicious anemia
    
    • inability to absorb B12
  • gastric neoplasms, gastrectromy

Question 86

[Toxic-metabolic] Clinical presentation of Cobalamin deficiency

Answer 86

• Megaloblastic anemia (~70% of cases)
• disorder of dorsal column + lateral corticospinal tract ==>
  
  • diminished vibration + proprioception of lower limbs
  • abnormal reflexes
  • spacsticity
  • incontinence
  • orthostatic hypotension
• damage to cerebral hemispheric white matter ==>
  
  • psychoses
  • dementia
• damage to optic nerve (rare)
  
  • visual changes

Question 87

[Toxic-metabolic] Treatment of Colbamin deficiency

Answer 87

• parenteral administration of vitamin B12

Question 88

[Toxic-metabolic] Etiology/Presentation of Central Pontine Myelinolysis (CPM)

Answer 88

• electrolyte imbalance resulting from rapid correction/overrcorrection of hyponatremia
  
  • low serum sodium ==> water into cells ==> cytotoxic edema
  • fluid restriction + hypertonic saline ==> overcorrection ==> high blood osmolarity ==> flow across BBB
• Sx: confusion, delirium, balance issues, speech problems, difficulty swallowing

Question 89

[Toxic-metabolic] Etiology of Wilson’s Disease

Answer 89

• Autosomal recessive
• Chromosome 13 gene
• disorder of copper metabolism
• mean age of presentation = 12 years
  
  • may present w/signs of liver disease + motor/neuro signs

Question 90

[Cortical Lesions] Role of Frontal Lobe in human cognition

Answer 90

• voluntary movement
• language fluency (left)
• motor prosody (right)
• comportment
• executive fxn
• motivation

Question 91

[Cortical Lesions] Role of Parietal Lobe in human cognition

Answer 91

• tactile sensation
• visuospatial function (right)
• attention (right)
• reading (left)
• writing (left)
• calculation (left)

Question 92

[Cortical Lesions] Role of Temporal Lobe in human cognition

Answer 92

• language comprehension (left)
• sensory prosody (right)
• memory
• emotion

Question 93

[Cortical Lesions] Role of Occipital Lobe in human cognition

Answer 93

• vision
• visual perception
• visual recognition

Question 94

[Cortical Lesions] Major frontal lobe syndromes

Answer 94

• Broca’s aphasia
• orbitofrontal lesions ==> disinhibition
• dorsolateral preforntal lesions ==> executive dysfxn
• medial frontal lesions ==> apathy

Question 95

[Cortical Lesions] Temporal lobe syndromes

Answer 95

• Wernicke’s aphasia
• sensory aprosody
• amnesia
• emotional disorders

Question 96

[Cortical Lesions] Characteristics of Wernicke’s aphasia

Answer 96

• due to lesion @ posterior region of left superior temporal gyrus
• auditory comprehension of language is impaired

Question 97

[Cortical Lesions] Characteristics of amnesia

Answer 97

• due to hippocampal lesion
• amnesia = new learning deficit = inability to encode new memories

Question 98

[Cortical Lesions] Characteristics of hemineglect

Answer 98

• due to parietal lesions
• = failure to report, respond to, or orient sensory stimuli
• more common after right hemisphere lesions (dominant for attention) ==> inattention to one side of body or extrapersonal space

Question 99

Major occipital lobe syndromes

Answer 99

• visual agnosia
• visual field deficit