Section 1

Question 1

Symptoms in the head (e.g., facial weakness) usually rule out what?

Answer 1

spinal cord (Horner’s is the exception).

Question 2

Increased tone usually rules out what?

Answer 2

pathology that is strictly peripheral

Question 3

If in the brain, what level is the lesion?

Answer 3

Shift your diagnosis rostrally to accommodate additional reported symptoms. Do not shift down (caudally).

Question 4

If the symptoms occur suddenly, they are most probably caused by what?

Answer 4

a stroke, except if caused by obvious trauma.

Question 5

Strokes can be either

Answer 5

hemorrhagic or ischemic (thrombus).

Question 6

If the symptoms progress gradually over time and are unilateral, they are likely caused by a

Answer 6

tumor.

Question 7

Tumors often are accompanied by

Answer 7

increased intracranial pressure, although large hemorrhagic strokes can also present with increased intracranial pressure.

Question 8

Symptoms caused by a disease process develop gradually and are usually

Answer 8

bilateral in nature with no increased intracranial pressure.

Question 9

If the lesion is in the spinal cord:

Answer 9

All sensory and motor symptoms are on the same side as the lesion except loss of pain and temperature.

Question 10

If the lesion is in the brain stem:

Answer 10

The lesion is on the same side as the highest symptom (the one which located the level); lower symptoms will occur on the opposite side.

Question 11

If the lesion is in forebrain,

Answer 11

all sensory and motor symptoms are on the opposite side of the body (olfactory loss is the exception).

Question 12

If the lesion is in the cerebellum (or its input or output tracts)

Answer 12

all symptoms are on the same side as the lesion.

Question 13

Reduce all somatosensory words (loss of pain, position sense, temperature, joint sense, etc.) into

Answer 13

one symptom, “sensory loss of the … [e.g., left trunk and limbs].” Somewhere along its course the ascending sensory pathways have been cut.

Question 14

Reduce all motor symptoms to one of three diagnoses:

Answer 14

1) Failure to move: includes “paralysis, paresis, weakness, hypertonus, spastic, flaccid.” All of these indicate lesion of descending motor pathways (motor cortex, internal capsule, descending motor tracts, etc., motor neurons.). 2) Tremor, incoordination, usually implicate cerebellum 3) involuntary, uncontrollable movement implicates basal ganglia

Question 15

telencephalon =

Answer 15

cerebral hemispheres (cortex + white matter + basal ganglia)

Question 16

diencephalon =

Answer 16

thalamus + hypothalamus

Question 17

mesencephalon =

Answer 17

midbrain

Question 18

metencephalon =

Answer 18

cerebellum + pons

Question 19

myelencephalon =

Answer 19

medulla

Question 20

forebrain =

Answer 20

telencephalon + diencephalon

Question 21

hindbrain =

Answer 21

metencephalon + myelencephalon (i.e. cerebellum + pons + medulla)

Question 22

brainstem =

Answer 22

midbrain + pons + medulla

Question 23

The glossopharyngeal, vagus, hypoglossal, and spinal accessory nerves originate largely in the

Answer 23

medulla

Question 24

Collectively, what do the glossopharyngeal, vagus, hypoglossal, and spinal accessory nerves do?

Answer 24

they control breathing and heart rate (among other things) so that ataxic or disrupted breathing (death), or irregular heartbeats suggest that the medulla has been compromised by the patient’s illness.

Question 25

ataxic or disrupted breathing (death), or irregular heartbeats suggest that

Answer 25

the medulla has been compromised by the patient’s illness.

Question 26

Cranial nerves 5, 6 and 7 originate in the

Answer 26

pons,

Question 27

so that loss of sensation in the face, or an eye deviated medially, or weakness of the facial muscles is often indicative of

Answer 27

pontine dysfunction.

Question 28

Cranial nerve eight originates in

Answer 28

the transition between the pons and medulla, and

Question 29

CN 8 symptoms include

Answer 29

ipsilateral deficits in hearing or balance.

Question 30

Cranial nerves 3 and 4 originate from the

Answer 30

midbrain.

Question 31

Midbrain dysfunction often shows as

Answer 31

a dilated pupil or an eye whose movements are extremely restricted (Cn 3).

Question 32

Additionally, levels of consciousness are controlled by circuits in the

Answer 32

tegmentum of the midbrain so a coma usually indicates forebrain or midbrain involvement.

Question 33

Cn 1 and 2 are

Answer 33

forebrain nerves.

Question 34

Loss of smell or the more common loss of vision indicates

Answer 34

forebrain disease.

Question 35

Changes in “mental” functions, memory, language, affect also indicate

Answer 35

forebrain disease.

Question 36

The cerebral cortex

Answer 36

participates in many sensory, motor, and “cognitive” processes and is the largest component of our brain, about 85% of the brain by weight.

Question 37

The surface of the cortex is

Answer 37

highly convoluted into gyri and sulci, which are similar from person to person and define general functional regions.

Question 38

The cerebral cortex is interconnected with the other side of the brain via

Answer 38

commissures, including different parts of the corpus callosum, and the anterior commissure.

Question 39

Most of the cerebral cortex is made up of

Answer 39

neocortex

Question 40

Neocortex

Answer 40

contains neurons organized in six layers or laminae that are numbered from the surface of the brain to the deep white matter.

Question 41

Each layer (of the neocortex) has

Answer 41

neurons with distinctive morphology.

Question 42

Changes in the organization of these laminae (number of neurons, cell packing density, perikaryal size, etc.) between different cortical areas is related to

Answer 42

their functional specialization; altogether over 50 subdivisions of the cortex have been defined by these histological differences

Question 43

For instance cortical layer IV is made up of

Answer 43

small stellate neurons with locally ramifying axons.

Question 44

In sensory cortices

Answer 44

(somatosensory, visual, auditory) this layer is prominent and receives input from the thalamus.

Question 45

Layer V is

Answer 45

prominent in motor cortex and contains large pyramidal cells, whose axons leave the cortex to descend to the brainstem and spinal cord.

Question 46

Layer IV is

Answer 46

difficult to detect in motor cortex.

Question 47

In addition to this laminar organization, connections of groups of neurons between different laminae are

Answer 47

organized in a vertical or columnar fashion, so that cells with similar function tend to span all cortical layers within these columns.

Question 48

In sensory and motor regions of cortex, this columnar organization is

Answer 48

represented topographically across the surface of the cortex.

Question 49

Sensory cortex

Answer 49

(post-central gyrus) a map of the body’s surface spreads over this region such that columns of neurons representing the face is located within this gyrus in a region near the lateral fissure, the arm more superiorly, and the leg and foot representation ar

Question 50

Occipital lobe

Answer 50

Its functions are associated with the visual system and damage to it result in visual deficits.

Question 51

Visual information

Answer 51

(from the thalamus) to the cortex comes first to the primary visual cortex (often called “area V1” or “area 17”).

Question 52

V1

Answer 52

This region of the occipital cortex includes a portion of the lingual and cuneate gyri and within the deep folds of the calcarine sulcus.

Question 53

Most of the primary visual cortex is on

Answer 53

the medial surface of the hemisphere

Question 54

Visual information after the primary visual cortex

Answer 54

then spreads to other portions of the occipital cortex and to areas in the parietal and temporal lobes (e.g. areas 18 and 19).

Question 55

Lesions in the occipital lobe usually cause

Answer 55

blind spots (called “scotomas”) in the half of the visual field contralateral to the lesion.

Question 56

Each side of the visual cortex is

Answer 56

interconnected with the other side via the splenium of the corpus callosum.

Question 57

Parietal Lobe parts

Answer 57

1. Postcentral gyrus 2. Superior parietal lobule 3. Inferior parietal lobule

Question 58

1. Postcentral gyrus -

Answer 58

This area is associated with the somatosensory system.

Question 59

Post central gyrus is analogous to

Answer 59

area V1 of the occipital cortex in that it is the site where somatosensory information from the thalamus first reaches the cerebral cortex.

Question 60

Post central gyrus is also called

Answer 60

area “SI” or Brodmann’s areas 3,1, 2

Question 61

Damage to Brodmann’s area leads to

Answer 61

somatic sensory deficits (e.g. loss of touch, limb position) on the opposite side of the body.

Question 62

Because of the topographic localization of sensory information within the postcentral gyrus, damage to a portion of it (e.g. anterior cerebral artery infarct damaging the medial aspect of the cortex) will result in

Answer 62

sensory loss to only a portion of the opposite side of the body and help to localize the damage.

Question 63

Superior parietal lobule -

Answer 63

This region is associated with guiding movement.

Question 64

Lesions of the superior parietal lobule

Answer 64

will sometimes cause “apraxia”. This is an inability to bring the limb under sensory or cognitive control.

Question 65

Example of apraxia

Answer 65

a patient may not be able to point to an object when asked, even though he can see it clearly, and his limbs are not paralyzed.

Question 66

Inferior parietal lobule –

Answer 66

This region is associated with several cognitive functions.

Question 67

Inferior parietal lobule in the “dominant” hemisphere

Answer 67

(usually the left) it is concerned with language.

Question 68

The supramarginal gyrus is

Answer 68

part of “Wernicke’s area” and is needed to understand language

Question 69

The angular gyrus

Answer 69

is the gateway through which visual information reaches Wernicke’s area.

Question 70

Damage to the angular gyrus

Answer 70

area affects the ability to read.

Question 71

In the right hemisphere, pathology of this same area as the angular gyrus leads to

Answer 71

spatial disabilities; 1) The patient gets lost even in his own home. 2) He may display “neglect”, forgetting to dress or shave the left side of his body, and he may not notice anyone standing to his left. 3) In severe cases he may even deny that the left

Question 72

Corpus callosum

Answer 72

The parietal lobe and posterior parts of the frontal lobe are interconnected through the body of the corpus callosum.

Question 73

Temporal Lobe:

Answer 73

1) heschl’s gyrus / gyri 2) superior temporal gyrus 3) Middle, inferior, and occipito-temporal (fusiform) gyri 4) Parahippocampal gyrus and uncus

Question 74

Heschl’s gyrus/gyri

Answer 74

(transverse temporal gyrii, Brodmann’s areas 41 and 42) - This is primary sensory cortex for audition.

Question 75

Damage to Heschl’s

Answer 75

However, since information from both ears is processed bilaterally in the brain, damage to this area in only one hemisphere produces little deficit.

Question 76

Damage to Heschl’s in both hemispheres results in

Answer 76

an inability to understand spoken language since auditory information is cut off from Wernicke’s area.

Question 77

Superior temporal gyrus -

Answer 77

It is associated with audition and the posterior portion and superior surface lying within the lateral sulcus, called the planum temporale, (posterior to Heschl’s gyrus) makes up part of Wernicke’s area in the dominant hemisphere (for understanding langua

Question 78

Planum Temporale

Answer 78

the posterior portion and superior surface (of the superior temporal gyrus) lying within the lateral sulcus, called the planum temporale, (posterior to Heschl’s gyrus) makes up part of Wernicke’s area in the dominant hemisphere (for understanding language

Question 79

Middle, inferior, and occipito-temporal (fusiform) gyri

Answer 79

They are associated primarily with vision, particularly related to visual memory and perception.

Question 80

bilateral lesions of the inferior temporal lobe

Answer 80

limited primarily to the fusiform gyri, results in prosopagnosia - an inability to identify or recognize faces).

Question 81

Parahippocampal gyrus and uncus

Answer 81

The medial surface of the temporal lobe has a special association with memory.

Question 82

Bilateral damage to parahippocampal gyrus and uncus

Answer 82

can lead to severe amnesia.

Question 83

Anterior Commisure

Answer 83

The anterior parts of the temporal lobes and olfactory lobes (regions receiving terminations of the olfactory tract including the uncus, anterior part of the parahippocampal gyrus, and subcallosal gyrus) are interconnected via the anterior commissure

Question 84

Frontal Lobe:

Answer 84

1. Precentral gyrus 2. Superior and middle frontal gyri (posterior portions) 3. Inferior frontal gyrus (posterior portion) 4. Prefrontal cortex (rostral portions of the superior, middle and inferior frontal gyri)

Question 85

1. Precentral gyrus

Answer 85

This gyrus is called “primary motor cortex” or area 4 of Brodmann, and is a major source of axons that extend to the spinal cord (and other “motor areas”) for the control of voluntary movements.

Question 86

Damage to the precentral gyrus

Answer 86

area results in weakness (paresis) and movement deficits on the opposite side of the body.

Question 87

What helps to localize the damaged portion of the precentral gyrus?

Answer 87

because of the topographic localization of motor information within this gyrus to different parts of the opposite side of the body, specific motor loss helps to localize the damaged portion of this gyrus.

Question 88

Superior and middle frontal gyri (posterior portions) -

Answer 88

This region includes “secondary motor” and “premotor” areas that also contribute to the organization of voluntary movements, including eye movements (frontal eye fields).

Question 89

Damage to the Superior and middle frontal gyri (posterior portions)

Answer 89

can also result in forms of apraxia. If the damage is in the dominant hemisphere, the ability to write may be impaired.

Question 90

If damage to the Superior and middle frontal gyri (posterior portions) is in the dominant hemisphere, what is the result?

Answer 90

Patients ability to write may be compromised

Question 91

Inferior frontal gyrus (posterior portion) in the dominant hemisphere =

Answer 91

“Broca’s Area”

Question 92

Broca’s Area is needed for?

Answer 92

the programming of speech and writing.

Question 93

Damage to Broca’s Area

Answer 93

If it is damaged, patients lose the ability to generate fluent speech (although they can usually understand verbal or written statements).

Question 94

If Broca’s is damaged why do patients have trouble understanding statements?

Answer 94

(Trick) Usually they CAN understand (Wernicke’s function) verbal or written statements

Question 95

Prefrontal cortex

Answer 95

rostral portions of the superior, middle and inferior frontal gyri

Question 96

Prefrontal cortex in humans

Answer 96

This region is far more developed in humans than in any other species.

Question 97

What are the functions of the prefrontal cortex?

Answer 97

It’s difficult to delineate but many contribute to the make-up of a person’s personality. Others are associated with the planning and sequencing of complex tasks

Question 98

Damage to the prefrontal cortex can lead to what?

Answer 98

personality changes that may be subtle or profound. In addition, patients sometimes develop compulsive, repetitive behaviors (related to their impaired ability to plan complex behaviors).

Question 99

How are the frontal lobes interconnected?

Answer 99

via the genu of the corpus callosum.

Question 100

Language functions are centered largely in the

Answer 100

dominant (left) hemisphere and involve more than one lobe.

Question 101

How does information about speech enter the temporal cortex?

Answer 101

in Heschl’s gyrus and then spreads to Wernicke’s area which includes posterior portions of the superior temporal gyrus and the supramarginal gyrus.

Question 102

Visual information from the occipital lobe that is related to reading enters what area and how does it do this?

Answer 102

Wernicke’s area via the angular gyrus

Question 103

What happens to visual information after the it is passed through the angular gyrus?

Answer 103

language information is relayed to the frontal lobe

Question 104

Broca’s area is in the

Answer 104

inferior frontal gyrus, where the commands for speech are organized.

Question 105

“Wernicke’s aphasia”

Answer 105

(receptive or sensory aphasia) involves an inability to understand language and to speak coherently. In most cases it is associated with damage to Wernicke’s area.

Question 106

“Broca’s aphasia”

Answer 106

(expressive or motor aphasia) is associated with an impaired ability to generate speech (or writing) and usually involves damage to Broca’s area.

Question 107

CNS circulation has two major origins, what are they?

Answer 107

Vertebral Arteries and Internal Carotid Arteries

Question 108

Where does the posterior circulation arise from?

Answer 108

the Vertebral Arteries

Question 109

What are the vertebral arteries branches of?

Answer 109

they are branches of the subclavian arteries.

Question 110

Where does the anterior circulation arise from?

Answer 110

the Internal Carotid Arteries.

Question 111

What does the Posterior Communicating Arteries provide?

Answer 111

anastomoses between the two circulations. They may allow one circulation to perfuse the other if the latter occludes gradually from arterial disease.

Question 112

How does the posterior communicating artery protect the brain during a sudden stroke?

Answer 112

However, because the Posterior Communicating Arteries are often small, the anastomoses will not protect the brain from a sudden stroke in one of the two circulations.

Question 113

What does the posterior circulation supply?

Answer 113

the brainstem, cerebellum, and part of the cerebral cortex.

Question 114

In the posterior circulation, what gives rise to small arteries?

Answer 114

spinal arteries that travel down the spinal cord.

Question 115

What gives rise to the spinal arteries?

Answer 115

Vertebral arteries

Question 116

What are the spinal arteries that the vertebral arteries give rise to?

Answer 116

two Posterior Spinal Arteries and one Anterior Spinal Artery.

Question 117

What is the path of the spinal arteries and what reinforces their blood supply?

Answer 117

These arteries travel the length of the spinal cord and are reinforced by segmental branches from the Aorta.

Question 118

As the Vertebral Arteries extend along the base of the medulla, what happens?

Answer 118

each gives rise to many medial and lateral branches that penetrate the medulla.

Question 119

In addition to the medial and lateral branches that penetrate the medulla, what else happens to the vertebral arteries as it passes of the medulla?

Answer 119

They also produce prominent branches that supply the dorsolateral medulla and medial portions of the cerebellum (including the cerebellar nuclei). (PICA)

Question 120

Posterior Inferior Cerebellar Arteries.

Answer 120

prominent branches that supply the dorsolateral medulla and medial portions of the cerebellum (including the cerebellar nuclei)

Question 121

Where do the vertebral arteries join to form the Basilar arteries?

Answer 121

Near the junction of the medulla and the pons the Vertebral Arteries join to form the Basilar Artery.

Question 122

What is the first branch of the basilar artery?

Answer 122

1) Anterior inferior cerebellar artery 2)

Question 123

What is the location of the first branch off the Basilar Artery?

Answer 123

At or just beyond the junction of the medulla and pons

Question 124

What does the first branch of the Basilar Artery supply?

Answer 124

a pair of branches (AICA) which supply the undersurface of the cerebellar cortex and central areas of the pontine tegmentum

Question 125

What comes off the Basilar after AICA?

Answer 125

The basilar then gives off several small Pontine Arteries,

Question 126

What does the pontine arteries supply?

Answer 126

the medial and lateral portions of the pons.

Question 127

At the rostral end of the pons what large arteries arise off of the Basilar?

Answer 127

two more large branches, the Superior Cerebellar Arteries arise

Question 128

What do the Superior Cerebellar Arteries supply?

Answer 128

the superior surface of the cerebellar cortex and dorsolateral areas of the pontine tegmentum.

Question 129

At the rostral end of the Basilar Artery, what do those perforating branches contribute to?

Answer 129

the blood supply of the crus cerebri, posterior thalamus, and midbrain

Question 130

What does the Basilar Artery bifurcate into?

Answer 130

the Posterior Cerebral Arteries

Question 131

What is the path of the posterior cerebellar arteries?

Answer 131

travel along the medial surfaces of the temporal and occipital lobes. They also send branches to the midbrain, posterior parts of the thalamus and internal capsule (called Posterior Choroidal Arteries).

Question 132

Each Posterior Cerebral Artery gives rise to what?

Answer 132

a branch that connects the posterior circulation with the anterior.

Question 133

What is the connection between the posterior and anterior circulation?

Answer 133

Posterior communicating artery

Question 134

What is the function of the Posterior Communicating Artery perforating branches?

Answer 134

They give rise to important perforating branches to the thalamus, midbrain, and crus cerebri.

Question 135

What does the anterior circulation arise from?

Answer 135

the Internal Carotids.

Question 136

What is the first branch off of the internal carotids?

Answer 136

As each of these large arteries enters the skull, it sends a branch that follows the optic nerve into the orbit, the Ophthalmic Artery.

Question 137

As the carotids continue into the skull at what level does it meet the PCA?

Answer 137

At the level of the optic chiasm.

Question 138

After the PCA connects to the ICA, what are the two major branches that it gives off, and what does it supply?

Answer 138

two major branches that supply the surface of the cerebral cortex, the Anterior Cerebral Artery and the Middle Cerebral Artery.

Question 139

Each Anterior Cerebral supplies what?

Answer 139

the medial surface of the frontal and parietal lobes in one hemisphere

Question 140

Each Middle Cerebral supplies what?

Answer 140

the most of the lateral surface of one cerebral hemisphere including the insula

Question 141

Where does the anterior choroidal artery arise from?

Answer 141

arising at the junction between the PCA and ICA (sometimes off the Posterior Communicating Artery)

Question 142

What is the path of the Anterior Choroidal Artery?

Answer 142

runs posteriorly and then penetrates deep into the brain

Question 143

What does the anterior choroidal artery supply?

Answer 143

It supplies the anterior part of the choroid plexus and hippocampus, and continues superiorly to supply areas of the brain near more posterior parts of the internal capsule.

Question 144

A series of small branches (end arteries) that arise from the proximal portion of the Middle Cerebral Artery, what structures do these supply?

Answer 144

the basal ganglia and parts of the internal capsule. (lenticulostriate arteries)

Question 145

Lenticulostriate Arteries

Answer 145

A series of small branches (end arteries) that arise from the proximal portion of the Middle Cerebral Artery that supplies the basal ganglia and parts of the internal capsule

Question 146

The two Anterior Cerebral Arteries are joined by the

Answer 146

Anterior Communicating Artery, thus completing the arterial circle known as the Circle of Willis

Question 147

Venous blood from the cerebral cortex is collected mainly into what?

Answer 147

the superficial cerebral veins,

Question 148

What do the superficial cerebral veins drain into?

Answer 148

it drains into all of the dural sinuses

Question 149

Deep structures of the cerebrum drain largely into what structure?

Answer 149

the great cerebral vein (of Galen)

Question 150

What does the great cerebral vein of Galen drain into?

Answer 150

the straight sinus.

Question 151

Most of the blood from the dural sinuses drain into what?

Answer 151

the internal jugular vein which begins at the base of the skull

Question 152

In addition to the internal jugular vein, what else does the dural sinuses drain into?

Answer 152

there are significant drainage pathways to the facial veins, basilar venous plexus to the vertebral venous plexus and through the cavernous sinus to the pterygoid plexus and maxillary veins.

Question 153

What is the distribution of the anterior spinal artery?

Answer 153

1) ventral 2/3 of the spinal cord 2) medial medulla

Question 154

What are the major symptoms associated with the branch of the anterior spinal artery in the spinal cord?

Answer 154

Paralysis, loss of pain and temperature sense below occlusion

Question 155

What are the major symptoms associated with the branch of the anterior spinal artery in the medial medulla?

Answer 155

Contralateral sensory loss and paresis, ipsilateral tongue paralysis

Question 156

What is the distribution for the posterior inferior cerebellar artery?

Answer 156

Dorsolateral medulla and pons, medial cerebellum, cerebellar cortex

Question 157

What are the major symptoms associated with posterior inferior cerebellar artery?

Answer 157

Wallenburg’s syndrome: vertigo, loss of balance, ipsilateral cerebellar signs, loss of facial pain sensation, hoarseness

Question 158

What is the distribution for the anterior inferior cerebellar artery?

Answer 158

inferior surface of cerebellar cortex, dorsolateral pons

Question 159

What are the major symptoms associated with anterior inferior cerebellar artery?

Answer 159

ipsilateral “cerebellar signs” (tremor, ataxia), facial paralysis, ipsilateral hearing loss, loss of pain and temperature over face ipsilaterally

Question 160

What is the distribution for the basilar branches?

Answer 160

pons, anterior midbrain (crus cerebri)

Question 161

What are the major symptoms associated with basilar branches?

Answer 161

paralysis and loss of sensation in the face, body and limbs; can also affect eye movements and cause diplopia

Question 162

What is the distribution for the superior cerebellar arteries?

Answer 162

superior surface of cerebellum, dorsolateral corner of rostral pons

Question 163

What are the major symptoms associated with superior cerebellar arteries?

Answer 163

ipsilateral cerebellar signs, contralateral pain and temperature loss, Horner’s

Question 164

What is the distribution for the posterior cerebral arteries?

Answer 164

occipital lobe, medial portions of parietal and temporal lobes, anterior & posterior midbrain, crus cerebri, posterior thalamus

Question 165

What are the major symptoms associated with posterior cerebral arteries?

Answer 165

if unilateral: blindness in the visual field contralateral to the affected side, alexia (left side). if bilateral as with “top of the basilar” occlusion: bilateral blindness, memory loss, somatosensory loss, coma & death

Question 166

What is the distribution for the posterior communicating branches?

Answer 166

anterior midbrain, crus cerebri, thalamus

Question 167

What are the major symptoms associated with posterior communicating branches?

Answer 167

contralateral paresis, coma & death

Question 168

What is the distribution for the middle cerebral arteries?

Answer 168

Lateral surface of cortex, insula

Question 169

What are the major symptoms associated with middle cerebral arteries?

Answer 169

deficits can include – contralateral paralysis and sensory loss; “apraxia”; aphasia; partial blindness

Question 170

What is the distribution for the anterior cerebral arteries?

Answer 170

medial surface of parietal and frontal lobes

Question 171

What are the major symptoms associated with anterior cerebral arteries?

Answer 171

contralateral paralysis and sensory loss in leg and foot; sometimes, apraxia

Question 172

What is the distribution for the lenticulostriate arteries?

Answer 172

Basal ganglia, amygdala, internal capsule, anterior thalamus

Question 173

What are the major symptoms associated with lenticulostriate arteries?

Answer 173

Possibly, involuntary movements (basal ganglia); paralysis, sensory deficits over the entire ½ of the body, homonymous visual field deficits. (internal capsule)

Question 174

What is the distribution for the anterior choroidal arteries?

Answer 174

hippocampus, anterior choroid plexus, posterior internal capsule

Question 175

What are the major symptoms associated with the anterior choroidal arteries?

Answer 175

With hemorrhage may cause paralysis, sensory deficits, visual field defect (internal capsule)