Nerdfighteria Wiki - The Nervous System - CrashCourse Biology #26 (2024)

I'm going to be totally honest with you:I don't really spend a lot of time thinking about my bodily functions.For the most part. Maybe sometimes.But in the next few episodes, I'm going to be talkingabout all of the organ systems that make our lives possible,even occasionally pleasant!And to start it all off, I'm going straight to mission control:the Nervous System!

(Intro)

Pretty much every single animal, except for some really simple ones,have nervous systems, which is great,because it's what lets things do things like have behaviors.It makes you the sentient, living thing that you are.The whole set-up here: your brain, your nerves,your spinal cord, everythingis made up of specialized cells that you don't findanywhere else in the body.Most of those are neurons, which, you've seen them before,they look kind of like a tree with roots and a trunk and branches.Neurons bundle together to form nerves,pathways that transmit electrochemical signalsfrom one part of your body to another.So, when you bite into a piece of pizza-I love it when there's pizza in the videos...The receptor neurons in my taste buds recognizeI'm eating something salty and fatty and awesome.And they carry that information along a nerve pathway to my brain.And then my brain can be like "Yeah! Pizza!"and then it can respond by sending back informationthrough different nerve pathways that say:"You should eat more of that pizza!"And despite what my brain is telling me,I'm going to try to not eat any more of that pizza.You wouldn't think that it's terribly complicatedto know that pizza tastes good and to tell someone to eat more pizza but it turns out that our brainsand our nervous systems are crazy complicated.

Central Nervous System
(1:39) Your nervous system basically has a big old bureaucracy of neurons,and it's divided into two main departments:the central nervous system and the peripheral nervous system.Central and peripheral.

Peripheral Nervous System
(1:50) The central nervous system,basically your brain and your spinal cord,is responsible for analyzing and interpretingall of those data that your peripheral nervous system,all of the nerves outside of your brain and spine,collects and sends its way.Once the central nervous system makes a decision about data,it sends a signal back through to the peripheral nervous systemsaying "Do this thing!"Which the peripheral nervous system then does.

Afferent and Efferent Neurons
(2:12) Both of these systems contain two different types of neurons:afferent and efferent.Afferent and efferent are biological terms,and they're horribly confusing, and I apologizeon behalf of the entire institution of biology for them.Afferent systems carry things to a central point,and efferent systems carry things away from a central point.So afferent neurons carry information to the brainand spinal cord for analysis.In the peripheral nervous system,afferent neurons are called sensory neurons,and they're activated by external stimulilike the complex and glorious flavor of pizzaand then they convert those data into a signalfor the central system to process.The central nervous system has afferent neurons too,and there they bring information into special parts of the brain,like the part of the brain that goes, "Mmmmmm, salty!"Efferent neurons carry information out of the center.In the peripheral nervous system,they're called motor neurons because many of themcarry information from the brain or the spinal cordto muscles to make us move,but they also go to pretty much every other organ in your body,thus making them, like, work and do stuff to keep you alive.In the central system, efferent neurons carry informationfrom special parts of the brain to other partsof the brain or spinal cord.Of course if it ended there, it would be way too simpleand no good bureaucracy has just two departments.

Somatic System
(3:26) So the peripheral nervous system is actually made up oftwo different systems with two very different jobs:the somatic nervous system and the autonomic nervous system.The somatic system controls all the stuff you think about doinglike all the information coming through your senses,and the movement of your body that it makes when you want it to make movements.But here's something interesting:Since we're totally in love with our brainsas sort of the center of all being, of ourselves,we think that all the information abouteverything going on in our bodies goes to our brainsfor some kind of decision.Not so!Sometimes, like when we touch a hot stove,the afferent neurons carry the signal "HOT!"to the central nervous system, but that informationdoesn't even ever get to the brain. The spinal cord actually makes that decisionbefore it gets to the brain,sends a message directly back to the muscle saying,"Get your hand off the freakin stove, *!"This bit of fancy nerve-work lets the spinal cordmake decisions rather than the brain and it's called the reflex loop.

Autonomic System
(4:17) So, the other branch of the peripheral nervous system,the autonomic system, carries signalsfrom the central nervous system that drive all of the thingsyour body does without thinking about them:your heartbeat, your digestion, breathing,saliva production, all of your organ functions.But we're not done yet here.We need to go deeper.The autonomic nervous system has two divisions of its own:the sympathetic and the parasympathetic.And the jobs that these two perform aren't just differentthey're completely opposite, and frankly,they're always vying for control of the bodyin some kind of nervous system cage match.

Sympathetic Division
(4:48) The sympathetic division is responsible for, like,freaking out.You've probably heard this talked aboutas the fight-or-flight response, in other words, stress.But stress isn't all bad:it's what saves our lives when we're being chasedby saber toothed tigers, right?The sympathetic system prepares our body for actionby increasing the heart rate and blood pressure,enhancing our sense of smell, dilating the pupils,activating our adrenal cortex to make adrenaline,shutting down blood supply to our digestiveand reproductive systems so that there'll bemore blood available for our lungsand our muscles when we have to, like, RUN!And even though you're not in a constant state of panicat least I hope not, I kind of am,that system is running all the time, every day.

Parasympathetic Division
(5:29) But right next to it is the parasympathetic division,working hard to make sure we take it nice and easy.It dials down the heart rate and blood pressure, constricts our lungs,makes our nose run, increases blood flowto our reproductive junk, our mouths produce saliva,encourage us to poop and pee.It's basically what we have to thank for taking a nap,sitting in front of the TV, going to the bathroom and getting it on.So, consider yourself lucky you've got both the stress responseand the chill-the-heck out response working side-by-sidebecause together they create a balance, or a homeostasis.Now, that's what the nervous system does.Next we have to talk about how it does it.

Anatomy of a Neuron
(6:08) The neurons that make up our nervous systems make it possiblefor our bodies to have their very own little electric systems.So to understand how they work you have to understand their anatomy.Like I've said before, a typical neuron has branches like a tree.These are called dendrites, and they receive informationfrom other neurons.Neurons also have a single axon, the trunk of the treewhich is branched at the end and transmits signals to other neurons.The axon is also covered in fatty material called myelin,which acts as insulation.But the myelin sheath isn't continuous,there are these little bits of exposed neuron along the axon,which have the sweetest names in this whole episodethey're called the Nodes of Ranvier.Which seems like an excellent working title for the8th Harry Potter novel.Harry Potter and the Nodes of Ranvier.Anyway, these nodes allow signals to hop from node to node,which lets the signal travel down a nerve faster.This node-hopping, by the way, has a name.It's called saltatory conduction.Conduction because it's electrical conductionand saltatory because saltatory means leaping.Finally, the place where an axon's branches come in contactwith the next cell's dendrite is called a synapse,and that's where neurotransmitters pass information from one neuronto the next.Now, think back to, or just go watch the episode thatwe did on cell membranes, where we talked abouthow materials travel down concentration gradients.

Resting Potential
(7:23) Well, in much the same way, all of the neurons in your bodyhave a membrane potential, a difference in voltage,or electrical charge, between the insideand the outside of the membrane.You might also remember that this buildup of voltageis handled in part by a sexy little proteincalled the sodium-potassium pump.Basically, the pump creates a voltage differential,like charging a battery, by moving 3 positively chargedsodium ions out for every 2 potassium ions it lets in,creating a net negative charge inside the cellrelative to the outside.When a neuron is inactive, this is called its resting potential,and its voltage is about -70 millivolts.But in addition to the pumps, neurons also have ion channels. These are proteins that straddle the membrane,but they're a lot simpler and don't need ATP to power them.Each cell can have more than 300 different kinds of ion channels,each tailored to accept a specific ion.

Action Potential
(8:12) Now, don't zone out here, because all of this stuffhas got to come into play when a neuron becomes active.This happens when an input or stimulus creates a changein the neuron that eventually reaches the axon,creating what's called an action potential,a brief event where the electrical potential of a cellrapidly rises and falls.When action potential begins, like when a molecule of sugartouches one of my sweet taste buds, some ion channels openand let those positive sodium ions rush in,so that the inside starts to become less negative.With enough stimulus, the internal charge of the neuronreaches a certain threshold, which triggers more sodium channelsto respond and open the flood gates to let even more ions in.That's happening on one tiny little area of the neuron.But this change in voltage creeps over to the next bunchof sodium channels, which are also sensitive to voltage,and so they open.That exchange triggers the next batch, and the next batch,and so on down the line.So this signal of changing voltage travels downthe neuron's membrane like a wave.But remember, the myelin sheath insulates most of the neuron,and just leaves those little nodes exposed,so instead of being a steady wave, the wave jumps from node to node,speeding up the travel time of action potential down a neuron:That's your saltatory conduction at work!When the wave reaches the end of the neuron,it triggers the release of neurotransmitters from the neuronthrough exocytosis, and those neurotransmitters then floatacross the synapse to the next neuronwhere they trigger another action potential over there.Now, by this time, so many sodium ions have gotten insidethe first neuron that the difference between the outsideand the inside is actually reversed:The inside is positive and the outside negative.And it seems like neurons hate that more thanpretty much anything else, so it fixes itself.The sodium channels close and potassium channels open up.The positive potassium ions rush down both the concentrationand electrochemical gradients to get the heck out of the cell.That brings the charge inside the cell back downto negative on the inside, and positive on the outside.Notice, though, that now the sodium is on the insideof the cell and the potassium is on the outsidethey're in the opposite places of where they started so the sodium-potassium pumps get back to work,burn up some ATP to pump the sodium back outand the potassium back in, and phew!Things are now back at the resting potential again.

So, that, my friends, is how action potentialallows neurons to communicate signals down a whole chainof neurons from the outer reaches of the peripheral nervous system,all the way up the spinal cord and to the brain,and then back out agian.So, let's zoom out, and look at the broad view here.I'm gonna take a bite of this pizza.All my taste buds have neurons in them.Each of my taste buds contains between 50-100specialized taste receptor neurons.Chemicals from this beautiful pizza dissolve in the salivaand then stimulate the dendrites on the afferent neurons.This generates a bunch of action potentials that travelfrom the afferent neurons in my tongue all the way to my brain,which is like, "My goodness, I think that's pizza!Let's have another bite!"The brain then sends messages throughthe efferent nerve pathways to do all sorts of things:
1. Chew, which involves constricting the musclesin my jaw over and over again.
2. Lower my head down to catch another bite,which involves moving all kinds of neck muscles.
3. Swallowing, which involves constricting the musclesin my throat and esophagus.
4. Opening my mouth again to receive another bite.That signal is also going to my jaw.
And that's not even to mention what's going to go onwith the digestion of this bad boy,driven by the autonomic nervous system.But digestion is still a couple episodes from now.Hopefully there will be more pizza.

Thank you for watching this episode of Crash Courseand for giving me an excuse to eat more pizza.If you want to review what we learned in this episode,check out the table of contents.Thanks to everyone who put this together.If you have questions for us:Facebook, Twitter, or the comments below.We'll see you next time.