Chapter 11- Fundamentals of nervous system and nervous tissue

Question 1

Main functions of the nervous system (3)

Answer 1

These functions can overlap or co-occur

1. Sensory input
2. Integration
3. Motor output (motor response)

Question 2

Sensory input function

Answer 2

Monitors changes that occur inside the body and outside the body. We have many receptors, usually for one specific sensation

Question 3

Integration function

Answer 3

Processing and integration of input information- the nervous system decides what response to make. The brain decides what the input means

Question 4

Motor response function

Answer 4

Nervous system activates effector organs to cause a response. The brain or spinal cord sends a message based on the input.

Question 5

Neuroglia (glial cells)

Answer 5

Provide support and maintenance to neurons

Question 6

Neurons

Answer 6

Nerve cells that can respond to stimuli and transmit electrical signals. They can change membrane potential in a fraction of a second, which creates a message.
Neurons are the functional unit of the nervous system

Question 7

What organs make up the central nervous system?

Answer 7

Brain and spinal cord

Question 8

Central nervous system function

Answer 8

Function- is responsible for interpreting sensory input and deciding motor output

Question 9

What is the peripheral nervous system composed of?

Answer 9

Composed of bundles of nerves coming from the brain/spinal cord

Question 10

Peripheral nervous system function

Answer 10

Function- spinal nerves and cranial nerves link the rest of the body to the central nervous system. If a nerve is severed, that part of the body no longer exists to your brain

Question 11

2 subdivisions of the peripheral nervous system

Answer 11

1. Afferent division

2. Efferent division

Question 12

Afferent division (PNS)

Answer 12

Carries impulses from the body to the central nervous system. Impulses allow the CNS to interpret information and send out a response.
Impulses from this division arrive at the brain

Question 13

Efferent division (PNS)

Answer 13

Carries impulses from the CNS to the effector organs. Impulses activate muscle or glands to carry out motor response.
Impulses from this division exit the brain

Question 14

Types of neuroglia (glial cells) in the CNS (4)

Answer 14

1. Astrocytes
2. Microglial cells
3. Ependymal cells
4. Oligodendrocytes

Question 15

Types of neuroglia (glial cells) in the PNS (2)

Answer 15

1. Satellite cells

2. Schwann cells

Question 16

Astrocytes

Answer 16

Most abundant and versatile of the neuroglia
Star shaped, with projections connecting to and wrapping around neurons, synaptic nerve endings, and surrounding blood capillaries. Found in the CNS.

Question 17

Major functions of the astrocytes (4)

Answer 17

1. Provide a nutrient supply for neuron cells
2. Makes the sure the neuron is growing in the correct direction
3. Allows migration of young neurons
4. “Clean up” outside neuron cells

Question 18

What do astrocytes clean up outside of neuron cells?

Answer 18

Some substances could interfere with the function of the neurons if they’re freely floating around, such as leaked K+ ions, neurotransmitter

Question 19

Microglial cells

Answer 19

Have long and thin processes that touch neurons, found in the CNS.

Question 20

Microglial cells functions (2)

Answer 20

1. Contact nearby neuron cells to monitor health - microglial cells pick up on neurons not doing what it’s supposed to do
2. Phagocytize injured neurons

Question 21

Why must microglial cells phagocytize injured neurons?

Answer 21

Microglial cells migrate toward injured neurons, where they transform into a macrophage and phagocytize the neuron (these neurons can’t send messages correctly, so they must be cleaned up).
Importance- the immune system has very limited access to the central nervous system

Question 22

Ependymal cells

Answer 22

Function- lines central cavities of the central nervous system to circulate cerebrospinal fluid (CSF) within cavities. Most cells have cilia (to move and circulate CSF). Found in the CNS.

Question 23

Oligodendrocytes

Answer 23

Associated with thicker nerve fibers in the CNS, extensions of the cells wrap around each fiber to produce a myelin sheath

Question 24

Oligodendrocytes function

Answer 24

Create an insulating covering for individual neurons of the CNS
Importance- allows for fast and efficient transmission of electrical impulses

Question 25

Satellite cells

Answer 25

Support and protect neuron cells in the PNS-cleanup duty, helps neurons get oxygen and nutrients.
Functionally similar to astrocytes, found in the PNS.

Question 26

Schwann cells

Answer 26

Surround nerve fibers of PNS to form myelin sheaths, functionally similar to oligodendrocytes

Question 27

Other than transmitting electrical impulses, what 3 characteristics do neurons have?

Answer 27

1. Longevity- neurons last a lifetime. The nervous system will not be replaced over time, in contrast to other organ systems
2. Amitotic- neurons do not reproduce
3. Metabolism- neurons are very metabolically active. A portion of oxygen and nutrients dedicated to the nervous system

Question 28

What 2 general structures do neurons have?

Answer 28

1. Cell body

2. Processes

Question 29

Cell body of neurons

Answer 29

Portion of cell containing the nucleus. Most are found in the CNS, protected by bone

Question 30

Cell body function

Answer 30

Function- plasma membrane can receive information from surrounding neurons

Question 31

Nuclei

Answer 31

Name for clusters of cell bodies in the CNS, however, ganglia is typically used as an umbrella term for all cell bodies.

Question 32

Ganglia

Answer 32

Name for clusters of cell bodies in the PNS, but is typically used as an umbrella term for all cell bodies

Question 33

Processes of neurons

Answer 33

Arm like extensions from the cell body of all neurons. There are 2 types.

Question 34

Types of processes of neurons (2)

Answer 34

1. Axons

2. Dendrites

Question 35

Dendrites

Answer 35

Main receptive region of the neuron. A single neuron can have dozens of dendrites

Question 36

Dendrites function

Answer 36

Function- provide increased surface area for incoming signals to be received, convey incoming messages toward the cell body. You want neurons to be highly sensitive to messages.

Question 37

Axon

Answer 37

Single nerve fiber coming from a cell body. The axon is the conducting region of the neuron. Axons branch at the end to form terminal branches and form axon terminals.

Question 38

Axon function

Answer 38

Function- generates and transmits nerve impulses away from the cell body

Question 39

Tracts

Answer 39

Bundles of axons in the CNS- axon bundles save space. However, nerve is typically used as an umbrella term

Question 40

Nerves

Answer 40

Bundles of axons in the PNS- axon bundles save space. However, nerve is typically used as an umbrella term for the CNS as well.

Question 41

Axon terminals

Answer 41

Axons branch at the end to form terminal branches and form axon terminals.
The axon terminal is the portion of the neuron that releases the neurotransmitter, which will be received by the dendrites

Question 42

Axon terminal function

Answer 42

Function- neurotransmitter released at the axon terminal to pass along the impulse to the next neuron

Question 43

Myelin sheath function (2)

Answer 43

1. Protects and electrically insulates long and/or large nerve fibers
2. Increases speed at which these impulses are transmitted

Question 44

Myelin sheath

Answer 44

Fatty covering, usually associated with specific types of fibers, like very long axons. Not usually found with short or thin fibers. Not all axons are myelinated.

Question 45

Myelin sheath gaps

Answer 45

There are multiple Schwann cells on the axon in the PNS, but do not make contact with one another

Question 46

How is myelination in the PNS accomplished?

Answer 46

Accomplished by Schwann cells, which wrap themselves around the axon multiple times to create layers of insulation

Question 47

How is myelination in the CNS accomplished?

Answer 47

Accomplished by oligodendrocytes- a single oligodendrocyte can cover 60+ axons with branching processes. The oligodendrocyte processes wrap around the axon in layers, covering a much larger portion than a schwann cell.
A single oligodendrocyte has multiple processes and can therefore insulate multiple neurons

Question 48

How are neurons grouped?

Answer 48

According to the direction in which nerve impulses travel relative to the central nervous system. Afferent or efferent

Question 49

Afferent neurons

Answer 49

Sensory neurons- afferent neurons transmit signals from the body to the CNS.
Receptive endings can function as actual sensory structures, or they are associated with larger sensory receptors (other cell types).
A larger sensory receptor can receive more information and send it to the brain.

Question 50

Where are the cell bodies of afferent neurons found?

Answer 50

Cell bodies are found outside the CNS

Question 51

Efferent neurons

Answer 51

Motor neurons- efferent neurons transmit motor responses from the CNS to the body.
The cell bodies found inside the CNS.
Impulses travel to effector organs (muscles and glands).

Question 52

Interneuron

Answer 52

Lie between sensory and motor neurons. Most neurons in the body are interneurons.
Mostly confined only to the CNS, make up 99% of all neurons in the body

Question 53

Interneuron function

Answer 53

Function- pass signals through CNS pathways where integration and interpretation occurs

Question 54

What is the resting membrane potential value?

Answer 54

-70 mV

Question 55

Why do cells have a resting membrane potential?

Answer 55

So the inside of the cell is more negatively charged than the outside. All cells have a resting membrane potential, but neurons can change theirs faster than other cells.

Question 56

Resting membrane potential importance in neurons

Answer 56

Neurons are able to change their resting membrane potential faster than other cell types- neuron communication occurs when the membrane potential changes. Without this quality- the nervous system loses its function. The CNS would not know what was going on. There must be a membrane potential and it must be able to change quickly.

Question 57

Voltage

Answer 57

The measure of the potential energy by separate electrical charges (measured in V or mV). The greater the difference in charge between two points (or charges), the higher the voltage.

Question 58

What creates voltage in the human body?

Answer 58

In the human body, difference in charge on either side of the cell’s plasma membrane creates voltage (also called a potential). Each side of the membrane is considered 2 points.

Question 59

Current

Answer 59

Flow of electrical charge from one point to another, can be used to do work

Question 60

What creates current in the human body?

Answer 60

In the human body, currents reflect movement of ions across a membrane along the axon

Question 61

Resistance

Answer 61

Hindrance of charge flow from substances through which charge must travel

Question 62

What creates resistance in the human body?

Answer 62

In the human body, plasma membranes provide resistance. Sodium is stopped from entering the cell entirely.

Question 63

Insulator

Answer 63

A substance with high resistance (the myelin sheath is an example).

Question 64

Conductor

Answer 64

A substance with low resistance

Question 65

What types of signals can be produced by changes in resting membrane potential? (2)

Answer 65

1. Graded potential

2. Action potential

Question 66

Graded potential

Answer 66

Signals that have variable (graded) strength. They vary directly with stimulus strength, strong stimulus= strong graded potential. Usually, they are incoming signals over short distances. Can be hyperpolarizing or depolarizing.

Question 67

Action potential

Answer 67

A very brief reversal of membrane potential (from -70 mV to +30 mV). They do occur long distance and only occur in axons. Strength does not vary- action potentials are all or nothing.

Question 68

A change in membrane potential can be produced by (2)

Answer 68

1. Anything that alters ion concentrations on two sides of the membrane- this would decrease the difference between points of charge.
2. Anything that changes membrane permeability to any ion. Only permeability changes are important for transferring information. Ions can cross in greater amounts or prevent them from moving entirely.

Question 69

Ion channels

Answer 69

Selective proteins in the plasma membrane allow passage of ions into/out of the cell.

Question 70

Types of ion channel proteins (2)

Answer 70

1. Leakage (non-gated) channels

2. Gated proteins: chemically, voltage, or mechanically gated.

Question 71

Leakage (non-gated) protein channels

Answer 71

Always open, allow free flow of ions. Function depends on the specific protein.

Question 72

Gated proteins

Answer 72

Part of protein forms a gate that must be opened before ions can move. When the channels open, ions will move across the membrane

Question 73

Chemically gated channel

Answer 73

Only open when a certain chemical (neurotransmitter) binds to a protein

Question 74

Voltage gated channel

Answer 74

Open and close in response to changing membrane potentials

Question 75

Mechanically gated channel

Answer 75

Open in response to physical deformation of the receptor, usually associated with sensory receptors for touch and pressure.

Question 76

What determines the direction of ion movement?

Answer 76

Electrochemical gradients

Question 77

Components of electrochemical gradients (2)

Answer 77

1. Concentration gradient- ions move from higher to lower concentration
2. Electrical gradient- ions move to an area of opposite charge
   These components rarely work together

Question 78

Depolarization

Answer 78

A decrease in membrane potential (charge difference). The inside of the membrane becomes less negative than resting potential (potential (mV) becomes more positive).

Question 79

Depolarization function

Answer 79

Function- depolarizing the membrane increases the probability of producing a nerve impulse, results in excitation of a neuron.

Question 80

Hyperpolarization

Answer 80

An increase in membrane potential (greater difference in charge). The inside of the membrane becomes more negative than resting potential (potential (mV) becomes more negative).

Question 81

Types of graded potentials (2)

Answer 81

1. Receptor potential

2. Postsynaptic potential

Question 82

Receptor potential

Answer 82

Produced when sensory receptor is excited by its specific stimulus- the sensory receptor is responding directly to its stimulus

Question 83

Postsynaptic potential

Answer 83

Produced when the stimulus is released by another neurotransmitter

Question 84

Why do graded potentials only occur over short distances?

Answer 84

Charge is lost quickly due to leaky channels- current dies off quickly as well

Question 85

Function of graded potentials

Answer 85

Important function- graded potentials are absolutely necessary to initiate an action potential at the axon. No graded potential= no function in neuron

Question 86

Which cells do action potentials occur in?

Answer 86

Neurons and muscle cells only

Question 87

Action potentials importance

Answer 87

Important because this is the actual message sent to or from the nervous system

Question 88

How are action potentials generated?

Answer 88

APs are generated from graded potentials, originating at the trigger point. Change in membrane potential from graded potential causes voltage gated channels to open- generation of an AP involves opening of voltage-gated ion channels in the membrane in response to changing membrane potential

Question 89

Trigger point

Answer 89

The beginning of the axon coming from the cell body where action potentials originate

Question 90

2 gates of a sodium channel

Answer 90

1. Activation gate- voltage sensitive, opens at depolarization. If the voltage of the membrane changes, the gate opens
2. Inactivation gate- blocks the ion channel once it is open

Question 91

Process of generating an action potential (4 steps)

Answer 91

1. All voltage gated channels are closed at the resting state (-70 mV)
2. Depolarization- voltage gated sodium channels open
3. Repolarization- sodium channels are inactivated and potassium channels open
4. Hyperpolarization- excess potassium leaves the cell

Question 92

What molecules does the sodium potassium pump move out and in?

Answer 92

3 Na+ out, 2 K+ in

Question 93

When can a nerve fiber send out another action potential after sending the first?

Answer 93

When the sodium and potassium concentrations outside and inside the cell have been re-established.

Question 94

Threshold point

Answer 94

Depolarization must reach a “threshold point” to generate an AP. The threshold value= -55 mV.

Question 95

What is the purpose of a threshold point?

Answer 95

Not all depolarizing events will result in an AP- sometimes, incoming graded potentials are too weak. A threshold point weeds out weak signals that shouldn’t be integrated

Question 96

How does an action potential travel the length of an axon?

Answer 96

The influx of sodium causes a local current. This change causes depolarization of adjacent areas of the membrane, and Na+ channels open in these new areas as well. Na+ channels nearer the AP origin are inactivated, so no new AP can be generated here (must be unidirectional).

Question 97

Why are action potentials unidirectional?

Answer 97

Action potentials are unidirectional- sending information in multiple directions will likely result in the nervous system either not receiving the message or taking a very long time to receive the message. An AP always propagates away from the origin.

Question 98

How does the nervous system discriminate between a strong stimulus and a weak stimulus?

Answer 98

This depends on how frequently nerve impulses are generated. For strong stimuli- impulses are sent more frequently in a given period of time. Your brain recognizes that this is something it should pay attention to. For weak stimuli- impulses are sent less frequently in a given period of time

Question 99

Refractory period

Answer 99

A period of time in which a second AP cannot be generated at an axon. Occurs when Na+ voltage gated channels are open

Question 100

Types of refractory periods (2)

Answer 100

1. Absolute refractory period

2. Relative refractory period

Question 101

Absolute refractory period

Answer 101

Begins when Na+ gated channels open and continues until Na+ channels reset to their original state. During this time, another AP cannot be generated in the area, no matter how strong the stimulus is.

Question 102

Importance of the absolute refractory period (2)

Answer 102

1. Ensures each AP is a separate, all or none event

2. Enforces one way transmission of the AP

Question 103

Relative refractory period

Answer 103

Follows the absolute refractory period, occurs after depolarization.
Stimuli that are relatively weak cannot stimulate an AP, but an exceptionally strong stimulus can- hyperpolarization causes mV to be more negative, so you need a stronger stimulus to reach threshold

Question 104

Which 2 factors does conduction speed depend on?

Answer 104

1. Axon diameter. A larger axon= faster conduction

2. Degree of myelination- more myelination= faster conduction

Question 105

How do myelin sheaths influence conduction speed (2)?

Answer 105

1. Continuous conduction

2. Saltatory conduction

Question 106

Continuous conduction

Answer 106

Propagation in unmyelinated fibers- voltage gated ion channels are adjacent. Occurs slowly- taking very small steps

Question 107

Saltatory conduction

Answer 107

Propagation in myelinated fibers. Voltage gated ion channels found in myelin sheath gaps
AP can only be generated in these gaps. Electrical signals will “jump” from gap to gap, goes much faster

Question 108

Synapse

Answer 108

Junction between 2 neurons that sends information from one neuron to the next. Signals are transmitted between neurons at synapses

Question 109

Presynaptic neurons

Answer 109

Conduct impulses toward the synapse

Question 110

Postsynaptic neurons

Answer 110

Conduct signals away from the synapse

Question 111

Synaptic cleft

Answer 111

A fluid filled space that separates neurons.

Question 112

Types of synapses (2)

Answer 112

1. Electrical synapses

2. Chemical synapses

Question 113

Electrical synapses

Answer 113

Transmit signals very quickly. They have gap junctions that connect the cytoplasm of one neuron to another, allowing ions and small molecules to travel directly between them

Question 114

Where are electrical synapses typically found?

Answer 114

Are more common in embryos than adults, found in areas of the brain associated with stereotypic (repetitive) movements.

Question 115

Chemical synapses

Answer 115

Allow release and reception of neurotransmitters. Most common synapse type in the body

Question 116

Synaptic vesicles

Answer 116

Found in chemical synapses. Presynaptic neuron releases neurotransmitter at the axon terminal via synaptic vesicles, and the postsynaptic neuron has a receptor region (dendrite/body cell) that senses the neurotransmitter.

Question 117

Process of transmission of action potentials from one neuron to another (5 steps)

Answer 117

1. Action potential arrives at the axon terminal of the presynaptic neuron
2. Voltage gated Ca2+ channels open in response to AP, and calcium flows into the axon terminal of the presynaptic neuron
3. Synaptic vesicles fuse with the membrane in response to Ca2+ influx. The neurotransmitter enters the synaptic cleft
4. Neurotransmitter crosses cleft, binds to proteins on the postsynaptic neuron
5. The binding of the neurotransmitter opens ion channels, resulting in graded potentials

Question 118

After an action potential is transmitted, how are neurotransmitter effects terminated?

Answer 118

Neurotransmitter effects are terminated by reuptake through transport proteins, enzymatic degradation, or diffusion away from the synapse. The astrocytes will take up excess neurotransmitter and bring it back to the nerve fiber so it can store it for later. Also, enzymes can break down the neurotransmitter into smaller parts so they can’t interact with synapses. The neurotransmitter could also just float away from the synaptic cleft and therefore not interact with anything

Question 119

Which aspects of the neurotransmitter can cause the graded potentials to vary in strength?

Answer 119

1. Amount of neurotransmitter released

2. How long the neurotransmitter stays in the synaptic cleft

Question 120

What determines if chemical synapses are excitatory or inhibitory?

Answer 120

Depends mostly on how membrane potential is affected

Question 121

Excitatory postsynaptic potential (EPSP)

Answer 121

If enough neurotransmitter is bound to a postsynaptic neuron, an excitatory postsynaptic potential (EPSP) occurs at the postsynaptic membrane. Depolarization of postsynaptic membrane occurs, and EPSP triggers an action potential at the beginning of the axon. If the current reaching this portion of the axon is at the threshold, an AP is generated

Question 122

Excitatory synapses

Answer 122

More likely to generate an AP, depolarizing in nature. Must be strong enough to reach threshold to trigger an AP

Question 123

Inhibitory postsynaptic potentials (IPSP)

Answer 123

Inhibitory synapses reduce ability to generate an AP by hyperpolarizing the postsynaptic membrane
K+ channels or Cl- channels are opened, making the inside of the cell more negative and pushing membrane potential farther from the threshold value. This results in inhibitory postsynaptic potentials (IPSP)

Question 124

Are EPSPs or IPSPs dominant?

Answer 124

Most neurons will receive both excitatory and inhibitory input from 1000+ other neurons. Whichever signal (EPSP or IPSP) is stronger will have greater influence on the postsynaptic neuron. If EPSP is predominant, an AP is generated.

Question 125

Types of summation (2)

Answer 125

1. Temporal summation

2. Spatial summation

Question 126

Temporal summation

Answer 126

One or more presynaptic neurons transmit impulses in rapid fire order

Question 127

Spatial summation

Answer 127

Postsynaptic neuron stimulated by a large number of terminals on multiple dendrites at the same time

Question 128

Neurotransmitters

Answer 128

Chemical signals produced in the cell body that move into the axon. Most neurons produce at least 2 types- neurons can release one or more neurotransmitters simultaneously

Question 129

Anterograde movement

Answer 129

Anterograde movement= away from cell body. This is how neurotransmitters move into the axon

Question 130

What effects do neurotransmitters have (2)?

Answer 130

1. Functional effects- can be excitatory, inhibitory, or can do either depending on the receptor type they bind
2. Action effects- can be direct or indirect

Question 131

Direct neurotransmitters

Answer 131

cause opening of ion channels directly

Question 132

Indirect neurotransmitters

Answer 132

Have longer lasting effects, act through second messenger molecules. They can increase likelihood that a direct neurotransmitter can bind

Question 133

Acetylcholine

Answer 133

Released at neuromuscular junctions (junction between nerve and muscle cells), formed from acetic acid and choline. Function- mostly stimulates skeletal muscle tissue and neurons in the autonomic nervous system (ANS).

Question 134

Acetylcholinesterase (AChE)

Answer 134

The enzyme that degrades acetylcholine. Acetylcholine is split into choline and acetic acid so it can’t interact with the muscle fiber. Do not want unwanted or prolonged muscle contraction, so it must be degraded very quickly

Question 135

Which neurotransmitters are considered biogenic amines? (5)

Answer 135

1. Dopamine
2. Norepinephrine
3. Epinephrine
4. Serotonin
5. Histamine

Question 136

What are biogenic amines synthesized from?

Answer 136

Various amino acids

Question 137

Epinephrine

Answer 137

Biogenic amine. Adrenaline- helps with mobilizing the body for action, inducing the fight or flight response. Take a while to break down- people don’t “come down” from a situation for a few hours.

Question 138

Histamine

Answer 138

Biogenic amine. Neuromodulator, involved with immune system function.

Question 139

Biogenic amine function

Answer 139

Mostly involved in emotional behavior and regulates the biological clock.

Question 140

Imbalances in biogenic amine neurotransmitters can result in (2)

Answer 140

1. Schizophrenia or hallucinations. Hallucinations can result from drug use, schizophrenia occurs when an individual’s brain reacts differently to serotonin or dopamine.
2. Low amounts of dopamine and serotonin are linked to depression and anxiety disorders

Question 141

Amino acids neurotransmitters (4)

Answer 141

1. Glutamate (excitatory)- acts in conjunction with substance P
2. Aspartate (excitatory)
3. Glycine (inhibitory)
4. Gamma-aminobutyric acid (GABA) (inhibitory)

Question 142

Peptides

Answer 142

Strings of amino acids that take on a broad spectrum of molecules, all of which having various effects. 2 types.

Question 143

Peptide neurotransmitters (2)

Answer 143

1. Substance P

2. Endorphins

Question 144

Substance P

Answer 144

Peptide, mediator for pain signaling

Question 145

Endorphins

Answer 145

Peptide. Reduce pain perception (opiates).
They are released during high stress or traumatic situations.
Endorphins take a while to break down- people don’t “come down” from a situation for a few hours.

Question 146

Purines (2)

Answer 146

One type of nitrogen containing base that make up DNA and RNA. Includes ATP and adenosine.

Question 147

ATP

Answer 147

Purine. More primitive neurotransmitter found in CNS and PNS, can produce fast and slow responses

Question 148

Adenosine

Answer 148

Purine. Inhibitor in the brain. Caffeine blocks adenosine receptors- prevents inhibition and therefore makes you more alert.

Question 149

Gases and lipids neurotransmitters

Answer 149

Different because they are not stored, they are produced by a neuron on demand. They are lipid soluble or small, so they pass through the membrane and interact with receptors inside the cell, not outside

Question 150

Gases and lipids (3)

Answer 150

1. Nitric oxide
2. Carbon monoxide
3. Hydrogen sulfide

Question 151

Nitric oxide function

Answer 151

Participates in formation of new memories by increasing synapse strength in the brain (forming a synapse)

Question 152

Endocannabinoids

Answer 152

Neurotransmitters that act on the same receptors as THC. Made on demand, not stored. Similar functions to THC- controls appetite, suppresses nausea, neuronal development, learning and memory

Question 153

Types of neurotransmitter receptors (2)

Answer 153

1. Channel linked receptors

2. G-coupled protein receptors

Question 154

In neurons, a sodium influx causes

Answer 154

Depolarization

Question 155

In neurons, a chloride influx causes

Answer 155

Hyperpolarization

Question 156

Channel linked receptors

Answer 156

These receptors mediate fast synaptic transmission. Includes ligand gated ion channels, where a ligand binds to a channel linked receptor protein. Action is immediate, but brief

Question 157

What happens when a ligand binds to a receptor protein?

Answer 157

When ligand binds to the channel linked receptor protein- the protein changes shape and the channel opens

Question 158

G-protein coupled receptors

Answer 158

Contains transmembrane protein complexes. Response is indirect on the postsynaptic neuron and is complex and longer than the effect of a channel linked receptor.
Effects tend to include widespread metabolic changes in the postsynaptic cell

Question 159

General process of a G-protein coupled receptor (3 steps)

Answer 159

1. Neurotransmitter binds to the receptor
2. G-protein is activated
3. G-protein activates adenylate cyclase- second messengers are produced

Question 160

Second messengers purpose

Answer 160

Second messengers can activate certain genes to produce proteins, can open/close ion channels, etc.