You know – sometimes we forget how different the cells in the body can be – we kind of imagine them as all as little circle blobs when in reality, there is so much body cell diversity. Parietal cells in the stomach as part of the digestive system – they can make stomach acid! Thankfully, cells in other systems do not. Mast cells as part of the immune system – they contain substances like histamine that they can release which is critical for the inflammatory response. Skeletal muscle cells -which are also called muscle fibers – as part of the muscular system, they’re shaped like cylinders with multiple nuclei – and their structure includes thin and thick filaments which are essential for muscle contraction. We could on with all the specialized cells in all the body systems and the cells themselves structurally sure are different – specialized for their function. And if I had to pick my favorite specialized body cell – it’d be a neuron –a cell that is part of the nervous system. The system that is the topic of this video. But before we talk about neurons or other cells in the nervous system because it’s not just neurons – let’s give a little general tour of the nervous system. Then we’ll get to cells of the nervous system and briefly mention the action potential! First, structure wise, you can divide the nervous system into 2 very general regions: the central nervous system (CNS) – which consists of the brain and spinal cord - and peripheral nervous system (PNS) –which consists of all other components of the nervous system -such as nerves throughout the body. The PNS can provide sensory information for the CNS while the CNS can process that information and act as a command center – the CNS can execute motor responses or regulate body mechanisms. So, we said the CNS consisted of the spinal cord and brain. Let’s talk a bit about the amazing human brain – although realize we are being very general here – as we are going to divide it into 3 general regions: the hindbrain, midbrain, and forebrain. Let’s look at the hindbrain first. It includes the medulla, pons, and cerebellum. The medulla has many regulation functions such as the regulation of breathing, blood pressure, and heart rate. The pons is involved with some of these type of functions as well and also coordinating signals with this area to the rest of the brain. And the cerebellum? Balance and movement coordination are some functions of the cerebellum. The midbrain: deep in the brain, this area is involved in alertness and the sleep/wake cycle, motor activity, and more. If you’ve heard the term “brainstem,” this includes some of the structures we just mentioned: the medulla, pons, and midbrain specifically. Finally, the forebrain. Most notably, this includes the cerebrum, which itself is divided into two hemispheres: right and left. So many functions are done by our amazing cerebrum depending on specific location whether it’s our speech, our thinking and reasoning, our sensing, our emotions – check out the further reading to explore this! The forebrain also technically includes some structures in it like the thalamus – which is involved with sensory and motor information- and hypothalamus – which if you remember from our endocrine system video, has major control of the endocrine system. There are a lot of myths about the brain. One quick myth I heard all the time as a kid that I’d like to put to rest. It’s the myth that “humans only use 10% of their brain” – it’s not correct. We have a great reading suggestion on that as well as some others that circulate around. Now, that was all the central nervous system (CNS). What about the peripheral nervous system or PNS? Functionally speaking, we can further divide the PNS based on what it does. The somatic nervous system (SNS) and autonomic nervous system (ANS). The SNS is involved with motor functions of skeletal muscle. This will include voluntary actions under conscious control but also somatic reflexes that involve skeletal muscle. The ANS is all about what’s going on in the internal environment in regard to gastrointestinal or excretory or endocrine or smooth and cardiac muscle and it also includes autonomic reflexes. And the ANS itself can be further divided – I know, I know, there’s a lot of dividing but stay with me – the ANS can be divided into the sympathetic and parasympathetic systems. The sympathetic system – the shorter word of the two– helps me remember it’s part of the quick fight or flight response. I know the whole running from a bear is a very popular example. For me, it’d be more realistic if I was face to face with my personal nemesis: the copy machine which I may or may not have had some very bad experiences with before – and the warning bell just rang so you now know you have 60 seconds to get your copies – but it’s making crazy machine noises and giving you vague warnings– this also could activate your fight or flight response. A response that can cause your heart to race and breathing rate to increase and some things to not be active: like the digestive system. Because if you’re desperately trying to run from a bear or take on the copy machine, you don’t really need to be digesting your food at that very moment…right? The parasympathetic system – longer word – this is often called rest and digest. Heart rate will decrease, digestion will occur – again, rest and digest. Many times, these two systems can therefore have opposite effects on the same organ. So let’s talk about two major types of cells in the nervous system that makes up nervous tissue. That means these are cells that you’ll find in the central nervous system and the peripheral nervous system. Most of the time, neurons are what come to mind. There are different types of neurons but to focus on general neuron structure: you have the cell body – the nucleus and most other organelles are here. There are dendrites, generally these branched structures are where signals are received. And you have an axon – I like to think away axon! – because axons are the fiber where normally a signal will be carried away to some other cell. The junction area where the neuron will be communicating with another cell is called a synapse. And the other major cell type? Glial cells. Or you can call them glia. When I was a student and read that they were supporting cells – I don’t think the word “supporting” emphasized to me at the time how essential they really are. Structurally, there was a lot of emphasis on how they actually help the neurons connect in place – the word “glia” comes from a Greek word that means glue. But glia have huge roles and they are SO much more than that. Some glial cells keep a balance of certain chemicals in the space between cells – essential for signaling – and maintain the blood-brain barrier which keeps a lot of substances in the body from getting into the nervous system. Some glial cells make myelin – which goes around the axons of neurons as something called a myelin sheath - insulates the axon and transferring of the signal. Some glial cells produce cerebrospinal fluid which is protective to the brain and essential for homeostasis - as well as many other critical functions. Some glial cells have important immune function in the nervous system. These are all just a few examples. As amazing as glial cells are, it’s time to move on to the action potential. Generally, action potentials are recognized as something neurons do – but we did link some interesting reads about certain glial cell types and action potentials. We’re just going to touch on what an action potential is but we may have a future video to go into more detailed steps. The main idea is that neurons need to be able to communicate with each other. And to do that they’ve got to be able to receive a signal in the dendrite and carry it down the axon. And they need to do that fast – like less than 2 milliseconds fast. The action potential makes that possible. We can’t talk about an action potential without talking about when the neuron is at rest – meaning when there is no signal being carried – at rest, a neuron has something called a resting potential. The resting potential of a neuron is more negative than its surroundings – in fact it can be measured – it generally is around -70 mv. Yes, mv, which is millivolts- it has an electrical charge. That’s because there are ions involved inside and outside of the cell: ions like chloride (Cl-), sodium (Na+), potassium (K+), certain anions (A-). Specifically, sodium (Na+) and potassium (K+) play huge roles in keeping the resting potential – they should sound familiar because we talk about the sodium potassium pump in another video and that is a pump that helps maintain a neuron at resting potential. At rest, generally the sodium (Na+) concentration is higher outside of the cell and the potassium (K+) concentration is higher inside the cell. How can we remember that? How about it’s Kool to be K+ resting in the cell. But overall, at rest, the neuron is more negative inside compared to its surroundings. So let’s say the dendrite of the neuron receives a signal. This can generate an action potential along the axon. An action potential is going to rapidly change the charge in the neuron along the axon - the signal carries from one area of the axon to the next. Ion channels open allowing Na+ to flood inside the first region of the axon. Recall Na+ is a positive ion. This event is called depolarization – as the electric charge is becoming more positive in the axon as Na+ floods in and most K+ channels at that moment stay closed. This spreads to the next region of the axon and carries along. But as the action potential spreads to a new region of the axon, the old region where the action potential already occurred will start to be restored back - to learn more about the different channels that open and close to achieve this amazing feat – or specific events like the undershoot or refractory period- check out the further reading links in the video description. Eventually we hope to have an entire video on this process. Two things to point out about this action potential. 1. If neurons are myelinated – meaning they have myelin sheaths that insulate the axon and assist with the transfer of the signal – the action potential can actually jump from node to node – the nodes being areas of where it’s not myelinated. 2. Important to realize, the action potential is considered an “all or none” thing. What we mean by that is that it either happens or it doesn’t – like a light switch it’s either on or off – there isn’t a dimmer switch, there aren’t different levels, it’s either off or it reaches a threshold of when it’s on and if it’s on, it’s going. So that’s all good but what happens next? Let’s say you have an action potential and it’s going to signal another neuron – how? Well that’s one way to introduce neurotransmitters. So the action potential goes down the axon and gets to the axon terminals – the ends of the axon. We had mentioned there is this space called a synapse which consists of the area between the two neurons. The action potential can signal synaptic vesicles in that neuron to release something called neurotransmitters. There are different types of neurotransmitters and they can be derived from different substances: for example, amino acids or amino acid precursors. Or even a gas such as nitric oxide although the release is different than other neurotransmitters. Generally, when neurotransmitters are released from the synaptic vesicles, the neurotransmitters only need to travel a small space between the neurons specified as the synaptic cleft. Then they can bind specific receptors of the next neuron – specific receptors to the type of neurotransmitter that binds it. The dendrite area of the other neuron receives the signal and can start an action potential across its axon. When we cover a lot of things, we think it’s important to recap: so, we’ve talked about the peripheral nervous system (PNS) and the central nervous system (CNS). Since the CNS includes the spinal cord and brain, we also talked some about major areas of the brain. Then we focused on the PNS- how it can be divided into the somatic nervous system (SNS) and autonomic nervous system (ANS) and then how the autonomic nervous system (ANS) can be divided into the sympathetic and parasympathetic system. We then explored major cell types in the nervous system: glial cells and neurons. And since neurons can communicate with each other using an action potential, we gave a brief overview of the action potential. We then mentioned that once the action potential occurs, this can signal the release of neurotransmitters in the synapse between neurons. Those neurotransmitters bind specific receptors of a neighboring neuron. Phew! So, with such a complex system that could be so many videos long –there continues to be a lot of research done to help diseases and conditions of the nervous system. If you have an interest in this field– there are many careers involved in neurology to explore. Well that’s it for the Amoeba Sisters, and we remind you to stay curious.