L22+23 Bioelectricity: Action Potentials and Synapses in Neurons

Question

The timing and sequence of events leading up to and when carrying out an action potential in a neuron are critical. Firstly, [blank_start]stimulus[blank_end] gated [blank_start]Na+[blank_end] channels open, and begin to [blank_start]depolarise[blank_end] the cell. If the threshold potential of [blank_start]-59mV[blank_end] is reached, the [blank_start]voltage[blank_end] gated Na+ channels open and the cell begins to rapidly depolarise (an [blank_start]excitatory[blank_end] function) as Na+ [blank_start]enters[blank_end] the cell. When the membrane potential reaches +30mV it is at it's maximum, and this is is the [blank_start]action potential[blank_end] which causes propagation along the axon without losing amplitude. At +30mV, the Na+ channels [blank_start]close[blank_end] and the [blank_start]voltage gated K+ channels[blank_end] open. [blank_start]K+[blank_end] rapidly leaves the cell, and [blank_start]repolarisation[blank_end] occurs. [blank_start]Hyperpolarisation[blank_end] beyond the RMP usually occurs. The cell is returned to RMP by pumping the ions against their gradient, which is done by Na+/K+ ATPase.

Answer 1

depolarise

Answer 2

excitatory

Answer 3

action potential

Answer 4

voltage gated K+ channels

Answer 5

repolarisation

Answer 6

Hyperpolarisation

Answer 7

There are two refractory periods.

Answer 8

The initial refractory period is the absolute refractory period.

Answer 9

The relative refractory period follows the absolute refractory period.

Answer 10

The relative refractory period is the shortest of the periods (in ms)

Answer 11

There is no response during the absolute period

Answer 12

The relative period requires a large stimulus

Answer 13

The absolute period is measured from the opening of voltage gated Na+ channels to the action potential

Answer 14

The relative period is measured from the action potential to the hyperpolarisation of the cell

Answer 15

The refractory period is an intrinsic feature of the Na+ channels

Answer 16

depends on the inactive state of K+ channels after activation

Answer 17

relies on the fact that inactive channels do not respond to the electric field

Answer 18

prevents backward movement

Answer 19

relies on an inactive but open state

Answer 20

They are linked by gap junctions.

Answer 21

There is a direct connection between neurons.

Answer 22

Charge needs to be 'stored' at the terminus of the presynaptic neuron.

Answer 23

It is the fastest method of synapsing.

Answer 24

There is no physical link between the two neurons.

Answer 25

The propagation of the action potential is direct.

Answer 26

A chemical messenger/neurotransmitter has to be 'stored' in the synaptic knob of the presynaptic neuron.

Answer 27

It is slower than electrical synapses.

Answer 28

The NMJ is an example of a specific chemical synapse.

Answer 29

Stimulus gated Na+ channels are most critical and most concentrated at the input zones of neurons.

Answer 30

Stimulus gated Ca+ channels at the presynaptic knob allow vesicle release.

Answer 31

Vesicles containing neurotransmitter reside in the postsynaptic knob.

Answer 32

Mitochondria are present at the synapse.

Answer 33

Degradation by enzymes

Answer 34

Reuptake of neurotransmitter into the knob

Answer 35

Diffusion/reuptake of neurotransmitter into glia cells

Answer 36

Mitochondrial uptake of neurotransmitter

Answer 37

Excitatory Post Synaptic Potential (Net depolarisation)

Answer 38

Excitatory Pre Synaptic Potential (Net hyperpolarisation)

Answer 39

Electric Post Synaptic Potential (Net depolarisation)

Answer 40

Electric Post Synaptic Potential (Net hyperpolarisation)

Nächster

L22+23 Bioelectricity: Action Potentials and Synapses in Neurons

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