Neuroanatomy|Neurons

Question 1

What are dipoles?

Answer 1

Charge distributions at the synapses that create measurable electrical potentials

Question 2

What is volume conduction?

Answer 2

How electrical currents get from the brain to the scalp. Body tissues have capacity for conduction or spread of electricity.

Question 3

What part of the neuron receives messages from other neurons?

Answer 3

Dendrites

Question 4

What part of the neuron is covered with myelin?

Answer 4

Axon

Question 5

What term refers to the cell body of a neuron?

Answer 5

Soma

Question 6

What type of cells provide maintenance and support for neurons?

Answer 6

Glial cells

Question 7

What types of neurons carry sensory information from the periphery to the central nervous system?

Answer 7

Afferent (Sensory) neurons [Afferent Arrives]

Question 8

What types of neurons carry motor signals from the CNS to the peripheral nervous system?

Answer 8

Efferent (Motor) neurons [Efferent Exits]

Question 9

What do descending nerves do?

Answer 9

Transmit motor impulses from the brain to the peripheral nervous system

Question 10

What do ascending nerves do?

Answer 10

Transmit sensory impulses to the brain

Question 11

Nerve cells produce signals that are called what?

Answer 11

Action Potentials

Question 12

What are LTP and LTD?

Answer 12

Long-Term Potentiation and Long-Term Depression

Question 13

LTP and LTD are terms that refer to what?

Answer 13

Neuroplasticity

Question 14

What do brainwaves measure?

Answer 14

EPSPs and IPSPs- not a direct measure of action potentials. These are graded potentials that occur at and near the synapses.

Question 15

What is the max rate a neuron can produce action potentials?

Answer 15

About 1000 per second

Question 16

What 2 terms define the process of making brain waves?

Answer 16

Excitatory post-synaptic potential (EPSP) and Inhibitory post-synaptic potential (IPSP)

Question 17

What does an excitatory neurotransmitter do?

Answer 17

Increases depolarization and the likelihood of an action potential

Question 18

What does an inhibitory neurotransmitter do?

Answer 18

Increases polarization and decreases the likelihood of an action potential.

Question 19

What are sensory-evoked potentials (EPs)?

Answer 19

Electric responses generated by the CNS when sensory receptors in the brain are stimulated by auditory, visual, or somatosensory activity. For example, flashes of light generate visual evoked potentials and matching brain wave frequencies.

Question 20

What are event-related potentials (ERPs)?

Answer 20

Similar to EPs but more generally reflect responses to mental, motor, or psychophysiological tasks. For example, some ERPs are triggered by novel or unexpected stimulation.

Question 21

What are slow cortical potentials (SCPs)?

Answer 21

Shifts in the DC or standing polarity of the cerebral cortex. Negative shifts occur when the brain is preparing to do a cognitive task. Positive shifts occur and can be recorded when the brain is executing a cognitive task. They are considered slow because they may continue for several seconds in a frequency range usually less than 2 hz.

Question 22

A negative slow cortical potential has what effect on cortical excitability?

Answer 22

It increases excitability

Question 23

What focal site measures the max amplitude of SCPs?

Answer 23

Cz

Question 24

What effect would the self-regulation of SCPs at Cz likely have?

Answer 24

Improved cognitive performance

Question 25

What determines whether a neuron is considered part of the central or peripheral nervous system?

Answer 25

Location of its soma (cell body)

Question 26

In what order does neural information travel through parts of a neuron?

Answer 26

Neural information flows from dendrites to the cell body, to the axon hillock, down the axon, and ends at the synaptic terminal. Synaptic terminals can send information to either the dendrites of postsynaptic cells or cell bodies, but cannot transmit information directly to axons.

Question 27

What is myelin?

Answer 27

Fatty substance that wraps around some axons and helps determine the speed at which action potentials travel along axons. Myelin wraps around the axon create areas where the signal can jump over instead of passing through the axon, which accelerates transmission.

Question 28

What effect do demyelinating diseases have on the body?

Answer 28

Demyelinating diseases can slow or entirely disrupt the transmission of information.

Question 29

What are three examples of demyelinating diseases?

Answer 29

Multiple sclerosis, Charcot-Marie-Tooth, Guillain-Barre

Question 30

What causes multiple sclerosis?

Answer 30

Failure of oligodendrocytes in the CNS to produce myelin.

Question 31

What causes Charcot-Marie-Tooth (a chronic, hereditary condition) and Guillain-Barre (an acute condition)?

Answer 31

Failure of Schwann cells in the PNS to produce myelin.

Question 32

What are the three types of glial cells?

Answer 32

1. Oligodendrocytes (CNS) and Schwann Cells (PNS)
2. Astrocytes
3. Microglia

Question 33

What are oligodendrocytes?

Answer 33

Glial cells in the CNS that produce myelin.

Question 34

What are Schwann cells?

Answer 34

Glial cells in the PNS that produce myelin.

Question 35

What cells are considered the “sanitation workers of the brain”?

Answer 35

Astrocytes, a type of glial cell

Question 36

What are astrocytes?

Answer 36

Glial cells that keep synaptic environments clean and help neurons develop and go where they need to go.

Question 37

What are microglia?

Answer 37

Glial cells that serve as medics. They are immune cells that come from the blood and repair problems, but that can cause problems if overactive.

Question 38

Oligodendrocytes/Schwann cells comprise what percentage of all glial cells?

Answer 38

75%

Question 39

Astrocytes comprise what percentage of all glial cells?

Answer 39

20%

Question 40

Microglia comprise what percentage of all glial cells?

Answer 40

5%

Question 41

What causes neurons to fire?

Answer 41

Changes in the electrical charge (ions) of cells.

Ions are molecules where the number of protons and electrons are unequal. It is the influx and efflux of positively- and negatively-charged ions that changes the electrical state or neurons and activates action potentials via the processes of depolarization and repolarization.

Question 42

Positively-charged ions contain more ______ than ______.

Answer 42

Protons; electrons.

Question 43

Negatively-charged ions contain more ______ than ______.

Answer 43

Electrons; protons.

Question 44

Cell membranes are comprised primary of ______ that is surrounded by a thin layer of ______ on the inside and outside of the cell membrane.

Answer 44

Fat; water.

Question 45

Because ions cannot pass directly across cell membranes, they require the use of _______ that work like cat/dog doors.

Answer 45

Ion channels

Question 46

What are the two different types of ion channels?

Answer 46

Ligand-gated and voltage-gated

Question 47

What activates ligand-gated ion channels?

Answer 47

Neurotransmitters

Question 48

What activates voltage-gated ion channels?

Answer 48

Changes in electrical charge.

Question 49

What is the resting membrane potential of cells in millivolts?

Answer 49

Around -65 mV

Question 50

The flow of what three ions in and out of the cell is primarily responsible for changing the polarity or charge of the cell?

Answer 50

Potassium (K+)
Sodium (Na+)
Chloride (Cl-)

Question 51

In a word, what causes a neuron to trigger an action potential?

Answer 51

Depolarization

Question 52

What causes depolarization?

Answer 52

The membrane voltage increases its positive charge and crosses a Threshold of Excitation of -55 mv.

This can occur from channels letting in more positive ions (e.g., Na+) or letting out more negative ions (e.g., Cl-). Once this threshold is reached, voltage-gated Na+ channels open and allow a flood of positively-charged Sodium ions into the cell, triggering an Action Potential.

[Sodium rushes in; chloride rushes out]

Question 53

What is repolarization?

Answer 53

Return of the cell body to its resting membrane potential

Question 54

When does repolarization occur?

Answer 54

When the cell voltage reaches a peak positive charge of +30-40 mV

Question 55

What happens during repolarization?

Answer 55

After the cell voltage reaches a peak positive charge of +30-40 mV, the sodium-channels inactivate/close. At this point, potassium (K+)-gated channels open, allowing potassium to rush out of the cell. This brings the charge of the cell back towards the resting membrane potential of -55 mV.

Question 56

What is hyperpolarization?

Answer 56

As cells repolarize (i.e., regain negative charge), potassium-gated channels remain open a little longer than necessary for the cell to reach its resting membrane potential. The voltage of the cell therefore briefly dips negatively lower than resting potential before coming back to rest. During this brief period of time the cell is considered hyperpolarized. This is considered the undershoot period.

Question 57

What are refractory periods?

Answer 57

After an action potential occurs, the cell cannot immediately fire again due to the recent inactivation of the sodium-gated channels. These inactivated sodium channels cannot open, even if the membrane potential goes above threshold. The slow closure of the voltage-gated potassium channels, which results in undershoot, also contributes to the refractory period by making it harder to depolarize the membrane (even once the voltage-gated sodium channels have returned to their active state). The refractory period ensures that action potentials will only travel forward down the axon, not backwards through the portion of the axon that just underwent an action potential.

Question 58

Communication between ______ and ______ neurons is the true driver of neuronal activity.

Answer 58

pre-synaptic; post-synaptic.

Question 59

What are Excitatory Post-Synaptic Potentials (EPSPs)?

Answer 59

Graded potentials that bring the membrane of the postsynaptic neuron closer to generating an action potential (i.e., depolarization). EPSPs bring the membrane potential of the postsynaptic membrane closer to threshold (-55 mV; the point at which the neuron can generate an action potential). EPSPs result from both IONOTROPIC (i.e., fast) and METABOTROPIC (i.e., slow; G-protein linked receptors) channels.

Question 60

What does EPSP stand for?

Answer 60

Excitatory Post-Synaptic Potential

Question 61

What does IPSP stand for?

Answer 61

Inhibitory Post-Synaptic Potentials

Question 62

What are Inhibitory Post-Synaptic Potentials (IPSPs)?

Answer 62

Graded potentials that repolarize/hyperpolarize or stabilize the membrane of the postsynaptic neuron at rest (i.e., decreases chance of action potential). IPSPs bring the membrane potential further away from threshold (make neuron more negative) and/or stabilize the membrane at its resting potential. This decreases the chances of generating an action potential. IPSPs result only from IONOTROPIC (i.e., fast) channels. IPSPs act either by opening fast potassium (K+) channels (efflux) or fast, negatively-charged chloride channels (influx).

Question 63

What word describes fast-acting ion channels?

Answer 63

Ionotropic

Question 64

What word describes slow-acting, G-protein linked ion channels?

Answer 64

Metabotropic

Question 65

IPSPs result only from what type of channels?

Answer 65

Ionotropic

Question 66

What neurotransmitter is related to mood, sleep, depression, and addictions?

Answer 66

Serotonin

Question 67

Is serotonin an excitatory or inhibitory neurotransmitter?

Answer 67

Inhibitory

Question 68

What neurotransmitter is related to the reward system, pleasure centers, and attentional networks?

Answer 68

Dopamine

Question 69

Is dopamine an excitatory or inhibitory neurotransmitter?

Answer 69

It can be either.

Question 70

What neurotransmitter is related to fight-or-flight responses to fear and stress?

Answer 70

Epinephrine

Question 71

Is epinephrine an excitatory or inhibitory neurotransmitter?

Answer 71

Excitatory

Question 72

What neurotransmitter increases heart rate and blood pressure, and is used to stimulate attention and alleviate depression?

Answer 72

Norepinephrine (precursor of epinephrine)

Question 73

Is norepinephrine an excitatory or inhibitory neurotransmitter?

Answer 73

Excitatory

Question 74

What neurotransmitter is the main neurotransmitter involved in muscle contraction and the autonomic nervous system?

Answer 74

Acetylcholine

Question 75

Is acetylcholine an excitatory or inhibitory neurotransmitter?

Answer 75

Excitatory

Question 76

Is acetylcholine an amino acid or monoamine neurotransmitter?

Answer 76

Monoamine

Question 77

Is norepinephrine an amino acid or monoamine neurotransmitter?

Answer 77

Monoamine

Question 78

Is epinephrine an amino acid or monoamine neurotransmitter?

Answer 78

Monoamine

Question 79

Is dopamine an amino acid or monoamine neurotransmitter?

Answer 79

Monoamine

Question 80

Is serotonin an amino acid or monoamine neurotransmitter?

Answer 80

Monoamine

Question 81

Is glutamate an amino acid or monoamine neurotransmitter?

Answer 81

Amino acid neurotransmitter

Question 82

Is GABA an amino acid or monoamine neurotransmitter?

Answer 82

Amino acid neurotransmitter

Question 83

Is glycine an amino acid or monoamine neurotransmitter?

Answer 83

Amino acid neurotransmitter

Question 84

Is glutamate an excitatory or inhibitory neurotransmitter?

Answer 84

Excitatory

Question 85

Is GABA an excitatory or inhibitory neurotransmitter?

Answer 85

Inhibitory

Question 86

Is glycine an excitatory or inhibitory neurotransmitter?

Answer 86

Inhibitory

Question 87

What amino acid neurotransmitter plays a key role in thinking, learning, and memory?

Answer 87

Glutamate

Question 88

What amino acid neurotransmitter regulates brain activity to prevent problems with arousal disorders (anxiety, irritability, concentration, sleep, seizures, and depression).

Answer 88

GABA

Question 89

What does GABA stand for?

Answer 89

Gamma Aminobutryic Acid

Question 90

What amino acid neurotransmitter, found in the spinal cord, is involved in hearing processing, pain transmission, and metabolism?

Answer 90

Glycine

Question 91

What three ways are neurotransmitter removed from the synaptic cleft?

Answer 91

1. Diffused away from synapse and degraded.
2. Degraded by enzymes in the synapse.
3. Reuptake

Question 92

What are the Nodes of Ranvier?

Answer 92

Spaces between myelin sheath along the axon

Question 93

The spaces between myelin sheath along the axon are called what?

Answer 93

Nodes of Ranvier

Question 94

What is saltatory conduction?

Answer 94

Jumping of electrical current across myelin sheath

Question 95

What term describes the jumping of electrical current across myelin sheath?

Answer 95

Saltatory conduction

Question 96

What is Local Field Potential (LFP)?

Answer 96

The synchronized excitation of neurons generated by the sum of postsynaptic potentials from a localized region. Greater firing synchrony produces larger field potentials on the scalp surface which in turn create electrical dipoles that are detected as EEG waves. (SYNCHRONOUS FIRING = SPIKES OF HIGHER VOLTAGE). Higher amplitude indicates larger field of synchronous firing. The EEG shows changes in local field potential (greater/lesser synchrony).

Question 97

What are Slow Cortical Potentials?

Answer 97

Slow, event-related direct-current shifts of the EEG, near to 0 Hz

Question 98

What neurotransmitter is released by sympathetic neurons to create flight-or-flight response?

Answer 98

Norepinephrine

Question 99

What neurotransmitter is released by parasympathetic neurons to regulate rest and digest functions?

Answer 99

Acetylcholine

Question 100

What is the main hormone secreted by the adrenal medulla?

Answer 100

Epinephrine

Question 101

What type of receptors transmit acetylcholine?

Answer 101

Cholinergic receptors/fibers

Question 102

What type of receptors transmit norepinphrine?

Answer 102

Adrenergic receptors/fibers

Question 103

What inhibitory neurotransmitter influences attentional networks and pleasure centers and is associated with schizophrenia, ADHD, and addictions?

Answer 103

Dopamine

Question 104

What inhibitory neurotransmitter influences mood centers and is associated with sleep cycles, depression, and addictions?

Answer 104

Serotonin

Question 105

What excitatory neurotransmitter is related to general arousal levels and attentional networks?

Answer 105

Norepinephrine

Question 106

What neurotransmitter is associated with memory networks and memory problems?

Answer 106

Acetylcholine

Question 107

What inhibitory neurotransmitter is associated with anxiety disorders?

Answer 107

GABA

Question 108

Research indicates that an increase in serotonin has what effect on EEG?

Answer 108

Hypercoupling and slowing down

Question 109

Research indicates that increases in acetylcholine, norepinephrine, and dopamine have what effect on EEG?

Answer 109

Hypocoupling and increased activity