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Course: Health and medicine > Unit 8
Lesson 3: Function of neurons and neurotransmittersOverview of neuron function
This video introduces the function and functional types of neurons. By Matt Jensen. Created by Matthew Barry Jensen.
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Wait...so action potentials happen faster with axons of a larger diameter? Is that it?(5 votes)
Resistance within an axon is inversely proportional to the axon's diameter. Because the resistance is lower, the larger the axon's diameter, the faster the action potential can be transmitted.
A good way to think about it is to imagine water flowing through a pipe with a small diameter as compared to one with a large diameter. The water that is touching the side of the pipe experiences resistance (from friction) that slows it down. The water that isn't touching the sides of the pipe (so, the water in the middle) is not in contact with the pipe surface and so it does not experience that resistance from friction. Because it doesn't experience this resistance, it can travel at a faster speed.
In a large pipe, while the water on the edges experiences the resistance, there is a lot of water in the middle that can travel at this faster pace. Contrast that with a small pipe, which has less water in the middle, and so it has less water that can travel at a faster rate. The same is true in large vs. small diameter axons, except that it is the cell membrane that is the cause of the resistance that can impede the movement of a charge down the axon.(36 votes)
Is the "trigger zone" being discussed at1:48the same as the axon hillock? If so, are those two words interchangeable? If "trigger zone" and "axon hillock" are not interchangeable, could you please explain the difference? Thanks!(13 votes)
The trigger zone is an area near the axon hillock that causes voltage gated channels within the cell to open and initiate the propagation of the cell's action potential.
The axon hillock specifically refers to an area within the cell where the axon originates. It is cone shaped and is marked by a high density of intracellular microfilaments and a lack of Nissl bodies.(13 votes)
Are one of the physical stimuli what we see? Say we are told to press a button as soon as we see a dot appear... Do neurons, in this case, carry our signal?(3 votes)
Yes; neurons would carry the sensory information to the brain that allows you to recognize the dot, and then neurons would carry the motor stimuli to the relevant muscles which would make you press the button.(6 votes)
I believe that this expression is somewhat problematic: " It is more negative inside the cell membrane whereas it is more positive outside the cell membrane". I believe that you should emphasize the fact that both outside and inside of the cell are positive(since both potassium and sodium are known as positive (+) ions). The difference is; inside the cell is LESS positive compared to outside of the cell.(3 votes)
Actually you are partially correct. The inside of the cell does experience a net loss of positive charge. However, this leaves the cell to have excess of negatively charged proteins, hence, the negative charge.(4 votes)
Is there Interneurons in the Peripheral Nervous System? If yes, why wasn't it added in the video?(4 votes)
no, interneurons are just present inside the CNS(1 vote)
Does information have to be simultaneously inputted into the axon as graded potential to create an instant release at the trigger zone, or can graded potential be stored, and once past a certain limit, is released? (What I am asking is that if graded potential must be inputted at the instant before release, or can it be charged up?)(1 vote)- Well, electrostatic spread causes the signals to dissipate after a certain distance. That's why there are 2 different types of signal summation at the axon hillock: temporal and spatial. For simplicity here I'm going to describe EPSPs and ignore the IPSPs until the end. (EPSP and IPSP stand for excitatory and inhibitory postsynaptic potential.)
Temporal summation occurs when the same excitatory fiber pulsates signals repeatedly to the same neuron. Each graded potential it produces is too small to break the threshold value, but when the charges are added together at the axon hillock, the threshold is broken and an AP is generated.
Spatial summation: Two or more excitatory nerve fibers fire EPSPs, that, through synergistic interactions, sum and break threshold. An AP is generated and fired down the axon. (AP = action potential.)
Anyway, I said I would mention IPSPs at the end. IPSPs (inhibitory postsynaptic potentials) can hyperpolarize the cell (make it more negative) which makes it much more difficult to depolarize the cell. Remember that depolarization is a rapid burst of positive charge. With inhibition, the threshold value for an AP to be fired remains the same; what changes is the "inner negativity" of the cell. It becomes much more negative than its extracellular environment. Because it's so much more negative than its environment, it would take a much larger (and likely huge) influx of positive ions to get the neuron past its threshold value.
I hope all this made sense to you. If you would like further clarification, please ask! I love neurology, and I can think of few things more enjoyable than answering questions about the nervous system!
Great questions! I realize this was a long-winded response that kind of rabbit-trailed from your direct question. So in short, no, charge is not stored up because the charges diffuse away into nothingness after a certain distance. You might enjoy Khan Academy's videos about nerve conduction and electrochemistry. I've attempted to describe the overview in short, sensible form here, but I understand it's a rather long discussion that I left here.
Anyway, cheers!(7 votes)
So, if action potentials are always the same size and duration, will neurotransmitter release always be the same in quantity/magnitude?(3 votes)- Neurotransmitters are usually stored inside vesicles in terminal end of neurons. When action potential reaches terminal end, some of those vesicles are fused to cell membrane and transmitter of those vesicles are released to synaps gap. If there is a lot of action potentials without enough recovery time for neuron, terminal end can run out of transmitter-vesciles. That means that action potentials don't make terminal end release anymore neurotransmitters.
In normal case, if neurons have time for recovery, the amount of neutrotransmitters released are functionally constant. That means, there is no functional chance between action potentials. Of course the action which neurotransmitters cause depend on many other things too. For example one neuron takes input for many other neurons and then calculates should it or should it not release action potential - one neuron doesn't command other neuron by itself.
Also the action potentials of same neuron are not always same size and duration. Elctrical enviroment of a neuron makes an effect on neuron's function.(1 vote)
- "Input information usually comes in through the dendrites. Although less often, it'll come in through the soma or the axon." In what cases could the input skip dendrites and go straight into an axon or soma?(2 votes)
- How summation of signals occurs in a Neuron?(1 vote)
- At the dendrites, a neuron will receive signals from many different axons. Some of these are excitatory (makes the membrane potential more positive) and some of them inhibitory (makes the membrane potential more negative). These signals will travel through the dendrites and the soma to the axon hillock, where they add up to one membrane potential.(2 votes)
- Where do the neurotransmitters come from, the target cell or the terminal?(1 vote)
1:48Video transcript
In this video, I want to provide
an overview of neuron function, which I think of sort of
like how a gun functions. And we'll go into
a lot more detail on how a neuron functions
in later videos. But in this video. I just want to give a
bird's eye overview of it. The function of neurons
is to process and transmit information. Without input, most neurons
have a stable electrical charge difference across
their cell membrane, where it's more negative
inside the cell membrane and more positive outside
the cell membrane. And we call this the resting
membrane potential or just resting potential for short. And this resting
potential is really how the neuron is
going to be able to be excitable and respond to input. And I think of this
as similar to loading a gun by putting a bullet in it. Neurons receive excitatory
or inhibitory input from other cells or
from physical stimuli like odorant
molecules in the nose. Input information usually
comes in through the dendrites. Although less often, it'll
come in through the soma or the axon. The information from the
inputs is transmitted through dendrites or
the soma to the axon with membrane potential changes
called graded potentials. These graded
potentials are changes to the membrane potential away
from the resting potential, which are small in size
and brief in duration, and which travel
fairly short distances. The size and the duration
of a graded potential is proportional to the size
and the duration of the input. Summation, or an adding
together of all the excitatory and inhibitory graded
potentials at any moment in time occurs at the trigger zone,
the axon initial segment right here. This summation of
graded potentials is the way neurons process
information from their inputs. If the membrane potential
at the trigger zone crosses a value called
the threshold potential, information will then
be fired down the axon. So I like to think of
this process of summation of the excitatory and
inhibitory graded potentials at the trigger zone as analogous
to the trigger of a gun. In fact, that's why it's
called the trigger zone. I think of the graded
potentials as being like the finger on the
gun, that may be squeezing a little harder or relaxing. But once the trigger of
the gun is pulled back past a certain
threshold distance, a bullet will be fired
down the barrel of the gun, just like if the membrane
potential of the trigger zone crosses a threshold
value, information will be fired down the axon. The way information
is fired down the axon is with a
different kind of change to the membrane potential
called an action potential. An action potential is usually
large in size and brief in duration. But it's usually conducted
the entire length of the axon, no matter how long it
is, so that it can travel a very long distance,
just like a bullet usually has no trouble making it
down the barrel of the gun. And like a bullet traveling
through the barrel of a gun, action potentials tend to
travel very quickly down the length of the axon. Action potentials are different
than graded potentials because they're usually
the same size and duration for any particular
neuron, as opposed to the graded potentials,
whose size and duration depends on the size and
the duration of the inputs. Action potentials are
conducted faster along larger axons, axons
with a larger diameter, and along axons that have
a myelin sheath, that I've drawn in yellow here. When an action potential
reaches the axon terminals at the end of the
axon, information will then cross,
usually a small gap, to the target cell
of the neuron. And the way this happens
for most synapses where an axon terminal makes
contact with the target cell is by release of molecules
called neurotransmitters that bind to receptors
on the target cell and which may
change its behavior. Neurotransmitter is then
removed from the synapse. So it's reset to transmit
more information. And I think of this part as
similar to the bullet leaving the gun, to hit the target. The input information
that was converted into the size and the
duration of graded potentials is then converted into the
temporal pattern of firing of action potentials
down the axon. And this information
is then converted to the amount and the temporal
pattern of neurotransmitter release at the synapse. These steps are how neurons
transmit information, often over long distances. This is the general way that
neurons usually function. But there are multiple
functional types of neurons. So let's take a look
at some of those. Here I've drawn a few
different neurons, with their somas in red,
their axons in green, and their dendrites in blue. And I've drawn a
line here to separate between the central nervous
system on this side-- so I'll just write
CNS for short-- and the peripheral nervous
system on this side-- so I'll just write
PNS for short. And there's some
different ways we can categorize functional
types of neurons. The first way is the
direction of information flow between the CNS and the PNS. If a neuron like this
pseudounipolar neuron right here brings information
from the periphery in toward the central
nervous system, we call that an afferent neuron. Afferent, meaning it's
bringing information into the central nervous system. We can also call
this type of neuron a sensory neuron
because the information it's bringing into the
central nervous system involves information
about a stimulus. And a stimulus is
anything that can be sensed in the internal or
external environment, which is to say anything
inside the body or anything outside the body. These neurons are
carrying information away from the central nervous
system out into the periphery. So instead of calling
them afferent neurons, we call them efferent neurons. And there are two main
kinds of efferent neurons. The first we call motor neurons. Motor, which means movement. These are efferent neurons
that control skeletal muscle, the main type of
muscle that's attached to our skeleton,
that moves us around. These motor neurons are also
called somatomotor neurons or neurons of the
somatic nervous system. The other type of
the efferent neurons are called autonomic neurons. And these neurons
control smooth muscle, like the muscle around
our blood vessels; cardiac muscle, the muscle of
our heart; and gland cells, the cells of our glands
that secrete hormones into the bloodstream. These autonomic neurons are
also called visceromotor neurons or neurons of the
autonomic nervous system. Most neurons of the
central nervous system aren't any of these types
of neurons, however. They're like this
neuron, in that they connect other neurons together. So these are called
interneurons, neurons between neurons. And there are many interneurons
in the central nervous system, forming very complex pathways
for information to travel. So that while an
individual neuron is processing and
transmitting information, these complex
networks of neurons in the central
nervous system are doing even more
complex processing and transmitting of information.