Unit 1 CNS Lots of info Flashcards

Question 1

Q

What are the 5 steps of Embryological development?

Answer

A

Neurulation: Formation of the neural crest and neural tube
Cell Proliferation: within neural tube
Migration and Aggregation: of cells within definitive locations
Formation of axonal and dendritic processes
Synatopgenesis: connections between nerve cell to nerve cells or muscle

Question 2

Q

In Stage 1 of Embryological Development- Neurulation, describe what is happening in Day 14?

Answer

A

In day 14 the embryo begins in a process of gastrulation that is forming the 3 cellular layers, building blocks. The embryo, called a gastrula, is made up of 3 layers of cells:
- Ectoderm
- Mesoderm
- Endoderm

The entire nervous system is derived from embryonic Ectoderm

Question 3

Q

In Stage 1 of Embryological Development- Neurulation, describe what is happening in Day 21?

Answer

A

When the embryo is around 21 days old, it measures less than 4 millimeters. It begins with the presence of a mesodermal structure called the notochord. The notochord induces the overlying dorsomedial ectoderm to differentiate into neuroectoderm.

Neuroectoderm is thicker than general ectoderm and is called the Neural Plate. The margins of the Neural plate (Neural fold) elevate and create a depression between them called the neural groove.

Question 4

Q

In Stage 1 of Embryological Development- Neurulation, describe what is happening in Day 28?
How long does it take for the neural tube to form?
What happens as the neural groove closes?

Answer

A

When the edges of the neural groove fuse, the structure is called the neural tube. The neural tube develops into the entire CNS with is cavity becoming the Ventricular system
- At the time of fusion of the neural tube, a differentiation of cells occurs at the lateral edge of each fold called the neural crest, these then develop into most of the peripheral nervous system
- Closure of the neural groove begins in the future thoracic region then it moves caudally and later cranially. It takes around one week for the neural tube to form.
- As it closes, it separates from the overlying ectoderm. The ends remain open for about 2 weeks and are called the anterior and posterior neuropores.

Question 5

Q

What are the Embryologic names for Forebrain, Midbrain, and Forebrain?

Answer

A

Prosencephalon (Forebrain)
Mesencephalon (Midbrain)
Rhombencephalon (Hindbrain)

Question 6

Q

What are the 2 subdivisions of Prosencephalon?

Answer

A

Telencephalon
Diencephalon

Question 7

Q

The Telencephalon is a subdivision of the Prosencephalon. What are the parts (Derivates) of the Telencephalon?

Answer

A

Cerebral Hemispheres
Cerebral Cortex
Subcortical White Matter
Basal Ganglion
Basal Forebrain Nuclei

Question 8

Q

The Diencephalon is a subdivision of the Prosencephalon. What are the parts (Derivates) of the Diencephalon?

Answer

A

Thalamus
Hypothalamus
Epithalamus

Question 9

Q

What are the Parts of the Mesencephalon (midbrain)?

Answer

A

In the future this connects the forebrain to the hindbrain
- Cerebral Peduncles
- Midbrain Tectum
- Midbrain Tegmentum

Question 10

Q

The Metencephalon is a subdivision of the Rhombencephalon. What are the parts (Derivates) of the Metencephalon?

Answer

A

Pons
Cerebellum

Question 11

Q

The Myelencephalon is a subdivision of the Rhombencephalon. What are the parts (Derivates) of the Myelencephalon?

Question 12

Q

During the First stage of Neurulation, there is a imbalance between the rate of the embryo expansion (growing) and the available space, this results in what?

Answer

A

This results in the development of Flexures of the brain

Question 13

Q

What are the 2 Primary Flexures of the Brain?
What is the third flexure?

Answer

A

The Two Primary Flexures are:
- Cephalic Flexure, which marks the division between the brain and the brainstem
- Cervical Flexure, which is the junction of the Spinal Cord to the Brain

The 3rd Flexure is:
- The Pontine Flexure, which is found on the dorsum and is the future site of the cerebellum

Question 14

Q

The fluid-filled cavities within the neural tube develop in to what? What do they contain?

Answer

A

Develops into the Brain Ventricles, which contain Cerebrospinal Fluid

Question 15

Q

The second stage of Embryological development is Cell Proliferation. When does this start stage start?
What are the dorsal/ventral portions called and what do they do in the future?

Answer

A

This stage starts when the neural tube starts with the appearance of the Sulcus Limitans, a bilateral furrow along the inner surface of the neural tube which divides the tube into Ventral and Dorsal portions.

The dorsal portion is called the Alar Plate, the future binding site of sensory neurons and tracts
The ventral portions is called the basal plate, the future site primarily for motor system development

Question 16

Q

In the second stage of Embryologic development (Cell Proliferation) following the closer of the neural tube, postmitotic cells are pushed externally and are divided into 3 layers. What are the 3 layers and what do they later become?

Answer

A

Germinal (Ependymal) Layer: This is the inner layer, this then becomes the lining of the central canal and ventricles- these cells develop cilia that help move Cerebral Spinal Fluid (CSF)
Mantle Layer: This becomes the GREY MATTER of the spinal cord due to the cell bodies there-The Sulcus Limitans appears, above is the Alar Plate (sensory) and below is the Basilar Plate (motor)
Marginal Layer: The outermost layer that contains most of the processes from the cell bodies of the mantle- It becomes the WHITE MATTER

Question 17

Q

In the second stage of Embryologic development (Cell Proliferation), how does the brain increase in size? (5)

Answer

A

Growth in dendrites
Growth in axons
Vascularization
Myelination
Development of synapses

Question 18

Q

In the third stage of Embryologic Development (Migration), there are 2 types of migration. What are they?

Answer

A

Radial Migration
Tangential Migration

Question 19

Q

In the third stage of Embryologic Development, where does the Radial Migration occur? What does active migration require?

Answer

A

This occurs from the Spinal cord through the Telencephalon. Active Migration requires Radial Glia Cells; transient elongated cells that serve as a template for neuroblast migration.

Question 20

Q

In the third stage of Embryologic Development, where does the Tangential Migration occur? How do the Glial cells run?

Answer

A

This occurs mostly in structures within the brainstem (Inferior to the olivary nucleus) and occurs late in the migration process. The glial cells run oblique or parallel to the neural tube and the neuroblast may use existing axons in addition to the glial cells to reach its destination. They pass from one to another tangentially.

Question 21

Q

What are some defects in the 3rd stage of embryological development?

Answer

A

Dyslexia
Lissencephaly (“Smooth brain” results in motor and mental retardation)
Microencephaly (Small brain results in mental retardation)
Macrogyria (Some folding but not normal have less gyri)

Question 22

Q

In stage 4 of Embryological development (Cell Differentiation), what happens?

Answer

A

There is the formation of axonal and dendritic processes
Development of cranial nerves

Question 23

Q

In the 5th stage of Embryological development (Synaptogenesis), what happens?

Answer

A

Development and change of synapses occurs throughout life
- Synaptogenesis is strongly correlated with changes in the patterns of transfer of information within the nervous system therefore it is correlated with all known types of permanent learning.
- The process involved in growth of neural processes and synaptogenesis are the bases for neural plasticity

Question 24

Q

Which parts of our brain controls our basic functions necessary for survival: respiration, BP, and HR?

Answer

A

Brainstem: Midbrain, Pons, Medulla

(Also the most evolutionary ancient parts of the brain)

Question 25

Q

How is Cerebral Spinal Fluid (CSF) formed?

Answer

A

Its formed by vascular tufts lying within the ventricles called Choroid Plexus

Question 26

Q

How does the CSF circulate? Where does it leave?

Answer

A

CSF circulates from the lateral ventricles to the third ventricle, and then leaves the ventricular system via foramina in the fourth ventricle to percolate around the outside surface of the brain and spinal cord.

Question 27

Q

In the brain, what are the Meninges?
MNEMONIC - PAD

Answer

A

From inside - out:
- Pia Mater
- Arachnoid Mater
- Dura Mater

Question 28

Q

In the brain there is a Dura Mater structure called the Falx Cerebri, where is it and what does it do?

Answer

A

This structure dips in-between the cerebral hemispheres between the longitudinal fissure
This is a very tough and very thick layer for the purpose of keeping the our brain from moving around in the skull

Question 29

Q

What are the differences in terms of Orientation of the Brain (Midbrain) and Spinal Cord?

Answer

A

Above the Midbrain:
- Anterior = Rostral
- Posterior = Caudal
- Superior = Dorsal
- Inferior = Ventral

Below the Midbrain (like Spinal cord)
- Anterior = Ventral
- Posterior = Dorsal
- Superior = Rostral
- Inferior = Caudal

Question 30

Q

In terms of Orientation, where is the Thalamus compared to the Frontal Lobe?

Answer

A

The Thalamus is Caudal to the Frontal Lobe

Question 31

Q

In terms of Orientation, where is the Cerebellum compared to the Pons?

Answer

A

The Cerebellum is Dorsal to the Pons

Question 32

Q

In terms of Orientation, where is the Anterior horn of the SC compared to the Posterior horn of SC?

Answer

A

The Anterior horn of SC is Ventral to Posterior horn of SC

Question 33

Q

In neurons, what do Dendrites and Axons do? What are Glia Cells?

Answer

A

Dendrites are the processes that receive information into the cell

Axons are acting to carry information away

Everything outside of the neuron or nerve-cell is considered glial cells (Support cells)

Question 34

Q

What is a Multipolar Neuron?

Answer

A

Having several dendrites and axons

Typical in most mammalian neurons

Question 35

Q

What is a Bipolar Neuron?

Answer

A

Those with single dendrite and axon

We see them in our sensory systems, vision and olfaction

Question 36

Q

What is a Unipolar Neurons?

Answer

A

When both axon and dendrite form a single process coming off a cell body

Seen in invertebrates

Question 37

Q

What is a synapses?

Answer

A

Typical communication between the neurons, from an axon terminal of one neuron to the dendrite of the next neuron

Question 38

Q

What are Chemical Synapses? Where are they stored?
Where are they released and binded?

Answer

A

They are the transmission of neurotransmitters, they are typically stored in the synaptic vesicles.

They are released from the pre-synaptic terminal of the neuron -> then they bind to the neurotransmitter receptor on the post-synaptic neuron, giving rise to either excitation or inhibition of the post-synaptic neuron.

Question 39

Q

Why are Myelin Sheath important?

Answer

A

Myeline sheath covers axons allowing for speed of transmission of action potential

Question 40

Q

What is the name of the myelin forming glial cells in the Central Nervous System?

Answer

A

Oligodendrocytes

Question 41

Q

What is the name of the myelin forming glial cells in the Peripheral Nervous System?

Question 42

Q

In the CNS, what is Glutamate?

Answer

A

Its an excitatory neurotransmitter

Question 43

Q

In the CNS, what is GABA?

Answer

A

Its an inhibitory neurotransmitter

Question 44

Q

What are the neurotransmitters used in the PNS?

Answer

A

Acetylcholine

Question 45

Q

What are the neurotransmitters in the ANS?

Answer

A

Acetylcholine
Norepinephrine

Question 46

Q

Areas in the CNS mainly made up of Myelinated axons are called what?

Answer

A

White matter

Question 47

Q

Areas in the CNS mainly made up of cell bodies are called what?

Answer

A

Gray matter

Question 48

Q

Where do most local synaptic communication occur in the CNS? What about signals over lager distances?

Answer

A

Gray Matter = local synaptic communication

White matter = signals over larger distances

Question 49

Q

In terms of White and Gray Matter, what is the difference between their location in the brain, Spinal Cord, and brainstem?

Answer

A

In the Cerebral Hemisphere, Gray matter is in the outside, white matter in in the inside
In the Spine, white matter is on the outside, gray matter is on the inside
In the brainstem, gray matter and white matter regions are found both on the inside and outside, although most of the outside is white matter.

Question 50

Q

Within the CNS, what are the structures of white matter? what do they do?

Answer

A

Tracts: white matter communication
Fascicles: Like a white matter freeway (where info comes or goes)
Lemniscus: Same as the fascicles
Bundle: Multiple white matter tracts
Commissure: white matter pathway that connects structures on the left and right sides of our brain

Question 51

Q

Within the PNS, what are the structure of white matter?

Answer

A

Peripheral Nerves

Question 52

Q

Within the PNS, what are the structures of Gray Matter?

Answer

A

Ganglia (cluster of cell bodies)

Question 53

Q

How many pairs of Cranial nerves are there?

Question 54

Q

How many pairs of Spinal nerves are there? Where do they arise?

Answer

A

31 pairs

Arise from spinal cord segments and give rise to both sensory and motor nerve roots on each side of the body.

(Motor=Efferent) ; (Sensory=Afferent)

Question 55

Q

Where does the Spinal Cord end? What is below the spinal canal?

Answer

A

The spinal cord ends at L1 or L2.

Below the spinal canal contains a collection of nerve roots known as Cauda Equina (latin for horses tail), which continues down their exit points

Question 56

Q

What is the Cervical Enlargement?

Answer

A

The brachial plexus, which is from C5-T1

Question 57

Q

What is the Lumbosacral Enlargement?

Answer

A

The lumbosacral plexus, which is from L1-S4

Question 58

Q

Based on function, in the Cervical enlargement and the Lumbosacral enlargement, would there be more gray or white matter? Why?

Answer

A

There is more Gray Matter in these segments causing the overall thickness of the cord to be greater. There is a greater amount of cell synapses also.

Question 59

Q

In the Autonomic Nervous System (ANS), what are the two major divisions? For each division what are the final neurotransmitters?

Answer

A

Sympathetic = “Fight or Flight”; Also known as the Thoracolumbar Branch of the ANS
(Involved with pupil and bronchial dilation, cardiac acceleration, etc.)
- Norepinephrine

Parasympathetic = “Rest and Digest”; Also known as Cranial Sacral Division of the ANS
- Acetylcholine

Question 60

Q

What are the definitions of Sulci, fissure, and Gyri?

Answer

A

Sulci are the crevices or infoldings
Fissure are deep sulci
Gyri are bumps and ridges between the sulci

Question 61

Q

What are the 4 major lobes of the brain? What Fissure separates them?

Answer

A

Frontal: Extends back to the Central Sulcus
Temporal: Separated from the Frontal lobe by Sylvian/lateral fissure
Parietal: Bounded anteriorly by Central Sulcus, (when viewed on medial aspect) Pareito-occipital sulcus separates the Parietal and Occipital lobe
Occipital

Question 62

Q

The 4 lobes of the brain, what are they related to? Where does this structure lie?

Answer

A

They are related to the Insular Cortex
This is the convergence of the frontal, parietal and temporal complex
This lies deep in the Sylvian Fissure and its considered an additional region to cortices (additional region of cerebral cortex)

Question 63

Q

In the Brain what are the Hemispheres separated by? What structure is within the Hemispheres?

Answer

A

Interhemispheric fissure (Sagittal or longitudinal)

Within the hemispheres, there is a white matter structure called the Corpus Callosum (Hard Body)

Question 64

Q

What is the Primary Motor Cortex also known as? What does it control?

Answer

A

Also known as the Precentral Gyrus (Located in Frontal Lobe)

Controls movement in the opposite side of body

Answer 62

A

Also known as Postcentral Gyrus (Located in Parietal Lobe)

Controls sensation in opposite side of body

Answer 63

A

The Occipital Lobe

Answer 64

A

Transverse Gyri of Heschl

Best described as 2 finger-like gyri that lies inside the Sylvian Fissure on the superior surface of the temporal lobe

Answer 65

A

A 6 cell layer structure based on looking at a component of the gray matter cerebral cortex.

This has been labeled in roman numerals
I-VI, continuing from the surface and moving in

Answer 66

A

Name: Molecular Layer

Main Connection: Dendrites and Axons from other layers

Answer 67

A

Name: Small Pyramidal Layer

Main Connection: Cortical-Cortical connection

Answer 68

A

Name: Medium Pyramidal Layer

Main Connection: Cortical-Cortical connection

Answer 69

A

Name: Granular Layer

Main Connection: Receives inputs from Thalamus

Answer 70

A

Name: Large Pyramidal Layer

Main Connection: Sends outputs to subcortical structures (Other than Thalamus)

Answer 71

A

Name: Polymorphic Layer

Main Connection: Sends outputs to Thalamus

Answer 72

A

Primary Somatosensory cortex

Answer 73

A

Post-Central Gyrus (Parietal Lobe)

Answer 74

A

Primary Motor Cortex

Answer 75

A

Pre-Central Gyrus (Frontal Lobe)

Answer 76

A

Voluntary movement control

Answer 77

A

Primary Visual Cortex

Answer 78

A

Banks of Calcarine Fissure (Occipital Lobe)

Answer 79

A

Secondary Visual Cortex

Answer 80

A

Medial and Lateral Occipital Gyri

Answer 81

A

Vision, depth

Answer 82

A

Tertiary visual cortex, middle temporal visual area

Answer 83

A

Medial and Lateral Occipital Gyri

Answer 84

A

Vision, color, motion, depth

Answer 85

A

Higher-order Auditory Cortex

Answer 86

A

Superior Temporal Gyrus

Answer 87

A

Hearing, speech

Answer 88

A

Primary Auditory Cortex

Answer 89

A

Heschl’s gyri and superior temporal gyrus

Answer 90

A

Secondary Auditory Cortex

Answer 91

A

Heschl’s gyri and superior temporal gyrus

Answer 92

A

Broca’s area; Lateral premotor cortex

Answer 93

A

Inferior Frontal gyrus (Frontal operculum)

Answer 94

A

Speech, movement, planning

Answer 95

A

A pathway of upper motor neuron from motor cortex to lower motor neuron in contralateral spinal cord

Firstly starts at the Pre-central gyrus (motor complex), then goes to the pyramidal decussation (this is where it goes contralaterally), then goes to the anterior horn

Answer 96

A

UMN: Motor neurons that project from the cortex down to spinal cord or brainstem

LMN: Located in anterior horn of gray matter of spinal cord or in brainstem motor nuclei

Answer 97

A

Folia, vermis, arbor vitae, tonsils, peduncles.
- Additionally has Anterior, Posterior, and Flocculonodualr Lobe

Answer 98

A

Caudate Nucleus
Putamen
Globus Pallidus
Subthalamic nucleus
Substantia Nigra

The Caudate Nucleus and Putamen together are called striatum
Putamen and Globus Pallidus together are called lenticular nucleus

Answer 99

A

Both act to modulate the output of the corticospinal and other descending motor systems.
- Both receive major inputs from motor cortex, they also intern project back to motor cortex via thalamus
In other words they are both feedback systems designed to refine movement

Answer 100

A

Ataxia: Disorder associated with coordination and balance

Answer 101

A

Parkinson’s: Hypokinetic movement disorder- movements are infrequent, slow and rigid

Answer 102

A

Posterior Column Pathways:
Proprioception, vibration, sense, and fine. discriminative touch
Anterolateral Pathways:
Pain, temperature sense, and crude touch

Answer 103

A

The most well studied reflex arc that provides rapid local feedback for motor control

Answer 104

A

It begins with specialized receptors-muscle spindles. This info is transmitted to the distal processes of sensory neurons and is then conveyed via the dorsal roots into the spinal cord gray matter.
- In Gray matter, multiple synapses with sensory neurons to include some direct synapse onto LMN in the anterior horn. LMNs project via the ventral roots back out to the muscle, causing it to contract.

Answer 105

A

It can cause the reflex to be diminished or absent

Answer 106

A

DTRs, results can be normal, hyper/hypoactive

Answer 107

A

This structure extends from Medulla to Midbrain.
- More caudal portions in medulla and lower pons tend to be more involved mainly in motor and autonomic functions
- Rostral portions in upper pons and midbrain plays an important role in regulating level of consciousness influencing higher areas through modulation of thalamic and cortical activity

Answer 108

A

Regulation of emotion
Memory
Appetite
Autonomic function
Neuroendocrine control
Olfaction

– Near the medial edge of the cerebral cortex, (Limbus means edge in latin)

Answer 109

A

Difficulty forming new memories
Behavioral changes
Epileptic seizures (Most commonly arise in medial temporal lobe)
–Fear
–Memory distortions
–Olfactory hallucinations

Answer 110

A

Higher-order information processing

Unimodal: For a single sensory or motor modality, usually located adjacent to primary motor or sensory are.
Heteromodal: Integrates functions from multiple sensory and/or motor modalities

Answer 111

A

Frontal Lobe

Answer 112

A

Language

Perceived first by the Primary Auditory Cortex in the temporal lobe (At the transverse gyrus heschl)
Then perceived by Primary Visual Cortex
From here we have cortical-to-cortical connections with Broca’s and Wernicke’s area

Answer 113

A

Broca’s area is found in the left frontal lobe

Wernicke’s area is found in the left or dominate hemisphere in out temporal lobe

In charge of making our language fluent, as well as having intact auditory comprehension

Answer 114

A

Wernicke’s Aphasia, (also referred to as receptive aphasia, or sensory fluent aphasia), individuals have deficits in their language comprehension. So they dont have an issue with primary hearing. Patients with Wernicke’s Aphasia dont sense their communication sound off, these patients are very pleasant.

Answer 115

A

This is referred to as motor aphasia or expressive aphasia, the patient is not able to articulate. Patients generally get frustrated, they understand what they want to say they are just unable to articulate or express themselves

Answer 116

A

Divided by intraparietal sulcus, then we get:
- Superior Parietal Lobule
- Inferior Parietal Lobule

Answer 117

A

The patient may have something referred to as Gerstmann’s Syndrome.
They would have difficulty with calculations, they would have issues with right-left confusion (within their own body), they would have issues with finger agnosia (inability to identify fingers by name), and difficulty with written language

They may also have apraxia, the inability to execute a motor plan generally upon command

Answer 118

A

The patient will lack of spatial awareness, the person will lack the perception of space and even neglect that contralateral side (right sided brain damage causes left neglect) For example, a patient may draw a clock without filling in the left side of the clock

With a more severe case, pt. can have something called Anosognisia. This is the lack of knowledge of their entire disease altogether, they may not have acknowledgement at all that their body part is their body part.

A patient may also develop extinction, this is where a tactile stimulus or a visual stimulus is perceived normally when its presented to one side of the body only, but when its presented on the side opposite of the lesion simultaneously with the normal side the patient neglects the stimulus on the side opposite the lesion

Answer 119

A

Pt. may exhibit Personality and Cognitive functioning

Frontal Release signs: Normal reflexes seen in infants (Grasp, root, suck, and snout)
Perseveration: Difficulty when asked to perform a sequence of actions or to change from 1 activity to another, instead they just repeat one action over and over
Disinhibited Behaviors: Impaired judgement, a cheerful lack of concern about one’s illness, inappropriate joking
Abulic: Loss or impairment of the ability to make decisions or act independently
Magnetic Gait: Feet in close contact to the ground
Urinary Incontinence

Answer 120

A

This is in the Parietal-Occipital Lobe as well as the Inferior Temporal Lobe.

Lesions may and could involve several impairments such as:
- Prosopagnosia: Inability to recognize faces
- Achromatopisa: Inability to recognize colors (colorblind)
- Palinopsia: Persistence or reappearance of an object viewed earlier (Deja vu)

Pt. may have seizures if their association cortex is damaged and can cause elaborate visual hallucinations

Answer 121

A

Internal Carotid arteries
Vertebral Arteries (Basilar A.)

Venous drainage is provided mainly by internal jugular veins

Answer 122

A

The Circle of Willis

The ACA and MCA branch from the ICA
The PCA brach from the Vertebrobasilar system

Answer 123

A

These arteries arise from the vertebral and basilar arteries:
- Superior Cerebellar Artery (SCA)
- Anterior Inferior Cerebellar Artery (AICA)
- Posterior Inferior Cerebellar Artery ( PICA)

Answer 124

A

Anterior Spinal Artery: which runs along the ventral surface of the cord in midline
Posterior Spinal Artery: runs along the right and left dorsal surfaces of the cord

Brainscape's Knowledge GenomeTM

Unit 1 CNS *Lots of info* Flashcards

Brainscape's Knowledge Genome^TM

Unit 1 CNS Lots of info Flashcards