Exam 5: February 13 - February 17 Flashcards

Question 1

Q

what are the parts of the central nervous system?

Answer

A

brain and spinal cord

Question 2

Q

what are the parts of the brain?

Answer

A

cerebellum, diencephalon, and cerebrum

Question 3

Q

what does the cerebellum look like?

Answer

A

like coral or a ball of yarn

Question 4

Q

what are the functions of the cerebellum?

Answer

A

1) balance and coordination of muscle activities

2) muscle tone

Question 5

Q

how does the cerebellum help with balance and coordination of muscle activities?

Answer

A

so complex activities instead of having to individually work, the cerebellum kind of sorta does a feedforward type process and is proactive about the idea that if I have to stand up the same sort of muscles need to work

knows which muscles need to be involved and gets them involved

Question 6

Q

how does the cerebellum help with muscle tone?

Answer

A

if there’s damage to the cerebellum, muscles don’t get engaged as much as they would so muscle tone gets lost

Question 7

Q

what is the diencephalon?

Answer

A

it’s a two part brain component that is one area but has two distinct parts that each have their own functions as well

Question 8

Q

what are the two parts of the diencephalon?

Answer

A

thalamus and hypothalamus

Question 9

Q

what does the thalamus do?

Answer

A

part of the diencephalon that controls your movements

major relay station for motor control to get messages off to the muscles

also a major relay station for crude level sensation

Question 10

Q

how does the thalamus help with crude level sensation?

Answer

A

your thalamus is a major relay station for crude level sensation

visual goes through your thalamus so it registers big things about your visual like is there something moving in my field of vision? Is there something moving that could attack me or is there something I could eat?

Another crude sensation it picks up on is sound so really loud sound or high pitched sound

Question 11

Q

where is the hypothalamus located?

Answer

A

it’s located below the thalamus

“hypo”

Question 12

Q

what is the function of the hypothalamus? how does it accomplish it?

Answer

A

part of the diencephalon that maintains homeostatic regulation

helps get the appropriate things activated to get us back to steady state

it does this by being the link between the nervous system, registering those change, realizing we’ve moved away from steady state and realizing we need to activate the endocrine system to get us back to steady state

Question 13

Q

what is the cerebrum? what are the components of the cerebrum?

Answer

A

cerebral cortex

it’s 80% of your brain by weight and volume

Question 14

Q

what is the cerebral cortex? what does it look like?

Answer

A

often times it will get equated to be the cerebrum but this isn’t exactly true – it’s an outer shell (cortex)

it’s highly convoluted, it’s not a smooth surface, it’s ridged like how you imagine the brain, it’s coral looking – convoluted shape gives us more surface area which gives us more function since it’s the outer layer – high function within space

Question 15

Q

what are the parts of the cerebral cortex?

Answer

A

1) matters
2) corpus callosum
3) ventricles
4) basil nuclei

Question 16

Q

what are the types of matter in the cerebral cortex?

Answer

A

grey and white matter

if you crack open your skull your brain looks grey on the outside and the white is deeper inside

axons are insulated with myelin to increase speed of communication – white parts of steak are lipids so there are probably going to be more cell bodies that don’t have a lot of oligodendricites – there’s going to be more myelin on the inside

Question 17

Q

what is the corpus callosum?

Answer

A

when you look at your cerebral cortex it’s actually two groupings brought together which is your left and right hemisphere – your corpus callosum is a massive bundle of axon that helps your two

it’s white matter and it’s in the middle of your brain

Question 18

Q

what are ventricles?

Answer

A

4 fluid filled chambers

when you get a headache it’s because n has changed. Since V is constant, P must increase to accommodate for the decrease in n which is what gives you a headache. drinking water helps because you can restore the number of molecules of water in the ventricles and decrease the temperature

Question 19

Q

what are the functions of the cerebral cortex?

Answer

A

1) perception
2) voluntary movement
3) language and learning

Question 20

Q

how does the cerebral cortex help with voluntary movement?

Answer

A

the ability to control where your skeletal muscles are in space

when you have a stroke it damages the cells of the cerebral cortex which is why a lot of people lose the ability to move

Question 21

Q

how does the cerebral cortex help with language?

Answer

A

another function is language so again after a stroke people can’t understand things or lose the ability to talk

Question 22

Q

how does the cerebral cortex help with learning and memory?

Answer

A

the cc is what makes you you!

if you damage this area you take away features that define you and differentiate you from the person next to you

so when people say they’re brain-dead they aren’t actually, it’s because their cc is no longer functioning

Question 23

Q

what are the components of the forebrain?

Answer

A

cerebrum + diencephalon

aka thalamus + hypothalamus + cerebrum

Question 24

Q

how is the spinal cord protected?

Answer

A

vertebrae and processes

the spinal cord needs protection because we don’t want to damage it and lose our ability to gather and send information

Question 25

Q

what do vertebrae do?

Answer

A

they are the main bone and are on the ventral side relative to the spinal cord aka they’re on the belly side

so they’re actually protecting us more on the inside more than the outside – this is because the biggest threat to our spine is internal movement

Question 26

Q

what are processes?

Answer

A

processes are what protect the spinal cord on the outside by surrounding the spinal cord and they are on the dorsal side

Question 27

Q

what is the composition of the spinal cord?

Answer

A

grey and white matter just like the cerebral cortex

Question 28

Q

what is in the grey matter of the spinal cord?

Answer

A

interneurons, part of efferent and afferent neurons within the CNS, glial cells are also within this area

Question 29

Q

what is the white matter of the spinal cord? what is it made up of?

Answer

A

white because of myelination

made up of axons

axons associated with afferent neurons are always dorsal to the axons associated with our efferent neurons which are on the ventral side

Question 30

Q

where are the afferent and efferent neurons in the spinal cord located?

Answer

A

axons associated with afferent neurons are always dorsal to the axons associated with our efferent neurons which are on the dorsal side

DAVE = dorsal afferent ventral efferent

Question 31

Q

why is position of ventral vs. dorsal axons in the spinal cord important?

Answer

A

It’s important because of protection. If one was going to get cut and damaged would you rather give up incoming or outgoing information? You’re more likely to see damage on the dorsal side so we protect our efferent pathway more so that we can react

Question 32

Q

what is the most used neurotransmitter in the body?

Answer

A

acetylcholide (ACh)

Question 33

Q

what destroys acetylcholine?

Answer

A

gets rapidly destroyed by ACh-esterase

this is to remind you that astrocytes clean up neurotransmitters because you don’t want the neurotransmitter to keep doing the task after it’s already done it

Question 34

Q

what does acetylcholine do?

Answer

A

cognition, behavior, how we interact and do things, control of glands and organs

Question 35

Q

what are the key neurotransmitters in the body?

Answer

A

1) acetylcholine
2) biogenic amines
3) amino acids
4) neuropeptides

Question 36

Q

what are examples of biogenic amines?

Answer

A

dopamine, norepinephrine, epinephrine, serotonin, histamine

Question 37

Q

what are biogenic amines?

Answer

A

they are a type of key neurotransmitters that control consciousness, mood and endocrine regulation

have a similar chemical structure which is why they’re grouped together

control a lot of our consciousness which is why antihistamine warning is drowsiness aka reducing consciousness

Question 38

Q

what are amino acids?

Answer

A

key type of neurotransmitter

some AA act as excitatory pre-synaptic potential creates so they depolarize

other ones act as inhibitory pre-synaptic potentials so they hyper polarize the potential and make it harder to reach the threshold component

Question 39

Q

what are neuropeptides?

Answer

A

peptides just mean a small chain of AA that’s not quite a protein yet

this category tells us that they got named neuropeptides because they don’t just act as neurotransmitters, they also sometimes as paracrine and endocrines so they can be released and removed in different ways aka they don’t have to stay as a neurotransmitter all the time

Question 40

Q

what are the components of the peripheral nervous system?

Answer

A

efferent (action) and afferent (sensory)

Question 41

Q

what are the components of the efferent PNS?

Answer

A

autonomic and somatic nervous system

our brain can use one of both of those systems if it decides we need to take action

Question 42

Q

what is the similarity between autonomic and somatic nervous systems?

Answer

A

both send signals from the CNS to effectors

they’re outgoing messages

Question 43

Q

what are the differences between the autonomic and somatic components of the efferent PNS?

Answer

A

1) # of neurons it takes to reach our effector
2) what gets innervated
3) actions

Question 44

Q

what is the difference between autonomic and somatic in the # of neurons it takes to reach our effector?

Answer

A

our autonomic requires 2 neurons to get to our effector while somatic only takes a single neuron to get to our effector = spinal cord

Question 45

Q

what is the difference in what gets innervated between the autonomic and somatic nervous systems?

Answer

A

what effectors can be controlled by our autonomic vs. somatic?

somatic only controls one category of things, your skeletal muscles

however to control basically everything else like to control your breathing, heart rate, smooth muscles, cardiac muscles, glands, digestive system is all autonomic

Question 46

Q

what is the difference between autonomic and somatic in the actions that they can perform?

Answer

A

how we can do things with our effectors

somatic can only excite our skeletal muscles – we can basically only get it to squeeze and we can’t force it to not squeeze, we just stop sending it signals to squeeze to get it to relax

autonomic can excite and inhibit: we can increase heart rate and decrease heart rate so we can impact in both directions

Question 47

Q

what does the autonomic components of the efferent PNS do?

Answer

A

regulates automatic/visceral responses

this system controls how things are going on in the background, you don’t have to think about these things like digestion or increasing your heart rate if you’re exercising

Question 48

Q

what are the components of the autonomic nervous system?

Answer

A

sympathic and parasympathetic

Question 49

Q

what analogy can be used to describe the autonomic nervous system?

Answer

A

the sympathetic nervous system is the gas in the car to speed you up while the parasympathetic nervous system is the breaks to slow you down

some effectors need to be slowed down and sped up so they’re effected by both systems

Question 50

Q

how many neurons does it take the autonomic nervous system to get to the effector?

Answer

A

2

because the two neurons are in series you end up seeing clustering of the second cell body outside, in our CNS

they’re called ganglia

Question 51

Q

what are ganglia?

Answer

A

a cluster of neurons in our autonomic nervous system

because the autonomic nervous system requires two neurons to reach the effector, you end up with a clustering of the second cell body outside in our CNS

Question 52

Q

what types of ganglia are there? what do they do?

Answer

A

pre-ganglionic and post-ganglionic neurons

pre-ganglionic releases neurotransmitters to post-ganglionic neurons

post-ganglionic neurons release its neurotransmitters to the effectors

Question 53

Q

what is your sympathy nervous system?

Answer

A

fight or flight response (efferent pathway)

it’s job is to make sure you’re alive 10 minutes from now

something has been registered as life threatening and we need to do something right now by either fighting it or get out of the way and dodge it

Question 54

Q

what is your parasympathetic nervous system?

Answer

A

rest or group (efferent pathway)

you don’t want to waste energy so instead take a chill pill instead of continuously gunning the engine and wasting gas

Question 55

Q

what are the possible locations of the ganglia?

Answer

A

ganglia for the sympathetic nervous system are closer to our spine

parasympathetic ganglia are closer to our effector

if they were near each other then NTs would intermix

Question 56

Q

what pre-ganglionic neurotransmitters does the efferent pathway use? (sympathetic and parasympathetic)

Answer

A

both use acetylcholine

Question 57

Q

what post-ganglionic neurotransmitters does the efferent pathway use? (sympathetic and parasympathetic)

Answer

A

parasympathetic still uses acetylcholine

sympathetic uses epinephrine and norepinephrine for its neurotransmitter

you can’t just use Ach everywhere because you need to differentiate the responses!

Question 58

Q

what is the adrenal medulla?

Answer

A

part of our sympathetic nervous system

it’s the inner part of the adrenal gland like the inner part of an orange

Question 59

Q

what does the adrenal medulla do?

Answer

A

it’s a special case of the sympathetic nervous system that doesn’t release signal to an effector but instead puts them directly in the plasma which no longer makes them neurotransmitters they’re now endocrines!

Question 60

Q

what is the relationship between epinephrine and adrenaline?

Answer

A

they’re the same thing!

Question 61

Q

what problem do action potentials have? why?

Answer

A

a distance problem because they rely on diffusion

Question 62

Q

do action potentials move?

Answer

A

action potentials do not move

we triggers the next one, it is not all only one action potential it is multiple

one action potential like dominos can trigger another action potential to occur- each domino looks like every other one- the last one falls the exact same way the first one does)

no decrease with signal in distance

Question 63

Q

how do action potentials cover a large distance?

Answer

A

AP cover a large distance by triggering a series of action potentials to cover that distance, it’s not one action potential going that distance

there’s no movement of individual action potentials - it’s like doing the wave in the stadium

Question 64

Q

how do action potentials solve their problem?

Answer

A

We convert the original graded potential into an action potential that can trigger multiple action potentials allowing the signal to travel large distances

a single graded potential or a single action potential decreases with distance but because we’re triggering a new one next to the old one, we keep them all the same size

the first AP looks exactly like the last one

Answer 65

A

unidirectional!

it will take less time to go in the same direction rather than changing direction like weeble wobbles

Answer 66

A

An action potential creates a hyperpolarization that seemed bad at the time but it’s actually is a good thing when this hyperpolarization happens because now the next one at rest is easier to get to threshold potential, now the one that just had an action potential and is hyperpolarized

the one that’s hyper polarized from the current AP has closed Na channels and needs to get back to rest then up to the threshold so we need a much bigger depolarization to get a hyperpolarization to get to the threshold

the Na ions moving backwars couldn’t trigger an action potential even if they wanted to because the Na channel open but is still inactivated from the AP

Answer 67

A

without sodium influx there’s no AP!

so if you hit a current AP with another graded potential because we get to our hyper polarization, nothing will happen because the Na channel is still inactivated

Answer 68

A

Schwann cells in the PNS

oligodendrocytes in the CNS

Answer 69

A

myelin is insulation so is it going to allow movement of Na and K in and out cell? No!

myelin aids graded potentials and completely blocks action potentials

Answer 70

A

it takes 1-2 milliseconds for a single AP to happen but then there are tons of APs in one neuron

it still takes time to cover the 1 m distance and for all the influx and outflux to happen so yes we can cover distance but it takes 1-2 milliseconds per AP so it’ll take longer to cover a larger distance

Answer 71

A

eh you can’t really but what happens is that if we could make the AP system go faster we could make the system better

so what myelin does is it allows us to have a faster conduction velocity so we can cover a set distance faster if myelin is there

neurons that need speed are myelinated but ones that don’t necessarily need speed aren’t

Answer 72

A

it takes out some of our action potentials

if we can cover that distance with a graded potential and avoided the number of AP that would be in that area it would go faster because a graded potential that is protected by myelin moves faster than the number of AP it would take to cover that distance

Answer 73

A

it aids them by increasing the conduction velocity but it doesn’t make graded potentials perfect…

there’s still a little bit of a decrease in the signal

we can’t have a myelin too big though because we have an AP on one side of the myelin that makes a graded potential but then on the other side of the myelin the graded potential still needs to be big enough to be a partial potential to trigger the AP on the other side of the myelin

AP –> myelin –> graded potential –> no myelin –> AP

Answer 74

A

how fast we can get from one end to the other of our axon

Answer 75

A

saltatory conduction

because of the myelin, it looks like there’s an AP then it disappears where there’s myelin, then it pops up again

Bronson would rather it be called burrowing conduction

Answer 76

A

the nodes of ranveir! aka the un-myelinated sections of the neuron

AP only happen at the nodes!

Answer 77

A

everywhere! AP are graded potentials

but when it comes to the myelinated parts, the graded potential moves underneath the myelin that creates a threshold potential so that the AP can occur at the next node

like whack a mole

Answer 78

A

yes they decrease with distance but not as much as it would without myelin

Answer 79

A

cells that can experience an action potential aka have Na/K channels and an inactivator

Answer 80

A

there are two types of input that affect the likelihood of an action potential occurring

it can either depolarize or hyper polarize the cell

Answer 81

A

EPSP = excitatory pre-synaptic potential = depolarizing = more likely to have an AP = stimulatory

IPSP = inhibitory pre-synaptic potential = hyper polarizing = less likely to have an AP because we now have to have a bigger graded potential to get back up to a threshold potential

Answer 82

A

temporal summation and spatial summation

Answer 83

A

summing over time

a SINGLE presynapatic neuron is sending multiple signals

they’re smaller signals but you send multiple in quick succession so that they build on each other and they eventually reach threshold potential to trigger an action potential

star trek

Answer 84

A

NO

this is one pre-synaptic to one post-synaptic whereas convergence is multiple pre to multiple post

you’re summing over the same pre-synaptic close in time hitting that same postsynaptic cell

Answer 85

A

different presynaptic in different areas at the same time

they use their small impacts all at the same time to reach the threshold potential

each one of these signals is not very big on their own but putting them all together at the same time gives you a much bigger response

it’s spatial because we’re summing over space, not time

Answer 86

A

yes!

multiple pre-synaptic to one post-synaptic

Answer 87

A

yes! they aren’t isolated

we can combine them and do some summation over time and some over space

as we increase the number of synapses/raise the level of convergence, increase the potential ways that we can combine these to reach threshold potential- you can combine different numbers of temporal and spatial - the number of these possible summations increases astronomically

Answer 88

A

increasing the number of synapses or increasing the level of convergence

Answer 89

A

chemical synapses

Answer 90

A

how likely/what is going to successfully impact cell A to cause the message to be passed on to cell B

Answer 91

A

1) Ca availability in the interstitial fluid around the axon terminal
2) neurotransmitter availability
3) receptor availability
4) Vm

Answer 92

A

Ca is needed for exocytosis/release of neurotransmitters

we steal Ca from our bones to make sure our nervous system has enough!

it’s key for development and communication

Answer 93

A

need to have the NT available to release a message

neurotransmitter gets made in the cell body and then it got transported within our axon to the axon terminal waiting to get exocytosed

Answer 94

A

this is because our pre-synaptic neurons were most likely a post-synaptic for another cell

Answer 95

A

hyperpolarization vs. depolarization (impacts Ca^+2 entry)

what’s the membrane potential going on in this particular cell? If we hyperpolarize the axon of neuron A, it’s not likely that our AP are actually going to reach the end of the axon because we might not be able to reach the threshold potential so boom we’re done

Answer 96

A

1) receptor availability
2) Vm
3) Other presynaptic inputs

Answer 97

A

receptor availability to bind neurotransmitters released by presynaptic

Answer 98

A

Vm impacts reaching threshold potential

we know that we have other pre-synaptic signals that we can sum with this post-synaptic signals and they can either hyperpolarize or depolarize

Answer 99

A

other presynaptic inputs = combos of summations

are we having convergence on this post-synaptic, and if so what are the summations that are happening?

are we having this particular pre-synaptic hitting it multiple times then it’s temporal summation or if we have A and D hitting it at the same time that’s called spatial summation

synapses are gaps between two neurons where they communicate by releasing neurotransmitters. Increasing the level of convergence would be increasing the number of presynaptic neurons compared to the number of postsynaptic neurons. Summations are the sum of all of the signals acting on a postsynaptic neuron. So if you increase the number of presynaptic neurons acting on a postsynaptic neuron (convergence) , they will collectively release more signals causing an increase in summations which can be temporal (multiple signals from one neuron at one time) or spatial (multiple signals from multiple neurons at one time) or a combination of both.

Answer 100

A

brain stem

the end of the spinal cord

it’s what keeps us alive and is needed for basic life

referred to as the out pocketing at the end of the spinal cord in animals without a developed brain

Answer 101

A

1) respiration
2) circulation
3) digestion

Answer 102

A

tied to respiration

choking/ swallowing- we need to make sure that what we eat to digest goes down esophagus instead of into lungs into the trachea

shove a snickers bar into someone’s mouth during CPR

first thing you do during CPR is clear the airway

Answer 103

A

1) medulla
2) pons
3) midbrain

Answer 104

A

the medulla is the lowest part closest to the spinal cord

pons are in the middle

midbrain is at the top closest to the rest of our brain

Answer 105

A

sodium channels become inactivated and by the time they reset the ions are too far away down the neuron

also there’s a greater outflow of K and the cell is very hyperpolarized

Answer 106

A

short then long

Answer 107

A

long them short

Answer 108

A

they’re different lengths so that diffusion doesn’t happen between the systems and there isn’t any cross talk or confusion

it’s okay that the second neurons line up because there are different neurotransmittesr are released at the end

S: –< ————–<
P: ————–< –

Answer 109

A

post-ganglionic cell

Answer 110

A

cerebral cortex, ventricles, basil nuclei, and corpus collasum

Answer 111

A

brain stem and hypothalamus

Answer 112

A

it links the endocrine and nervous system?

Answer 113

A

two hemispheres

Answer 114

A

grey and white

the grey matter is on the outside and it includes the nuclei of the neurons

the white parts are white because of the myelin

Answer 115

A

corpus callosum

Answer 116

A

perception, memory, language and learning, and voluntary movement

Answer 117

A

cerebrum and diencephalon

Answer 118

A

processes on the dorsal side

vertebrae on the ventral side

Answer 119

A

it’s made up of interneurons

it includes glial cells

it has both efferent and afferent components

Answer 120

A

their cell body is in the grey matter

Answer 121

A

axon terminals are in the grey matter

Answer 122

A

dopamine and histamien

Answer 123

A

acetylcholine

Answer 124

A

it’s typically found in between neurons in order to destroy acetylcholine

Answer 125

A

two or more amino acids

Answer 126

A

skeletal muscles

Answer 127

A

somatic system is considered excitatory

autonomic nervous system is excitatory and inhibitory

Answer 128

A

sympathetic and parasympathetic

Answer 129

A

ganglia of the sympathetic neuron is located closer to the spine and receives acetylcholine as the NT

Answer 130

A

postganglionic of the sympathetic

Answer 131

A

postganglionic neurons which release epinephrine to the plasma

the effects of the epinephrine released by the adrenal medulla are long lasting

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Exam 5: February 13 - February 17 Flashcards

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