Characteristics of Epithelial Tissue - Video Tutorials & Practice Problems
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5 Characteristics of Epithelia
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In this video, we're going to begin our lesson on the characteristics of epithelial tissue. And so it turns out that there are five commonly recognized characteristics of epithelial tissue. Number one is polarity of the epithelial tissue. Number two is tightly pressed epithelial tissue anchored to a basement membrane. Number three is a vascular but innervated epithelial tissue. Number four is supported by connective tissue and number five, last but not least is highly regenerative and so moving forward, we're going to talk about each of these five commonly recognized characteristics of epithelial tissue in their own separate videos starting with polarity. So I'll see you all in that video.
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concept
Characteristic 1: Polarity
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In this video, we're going to talk about the first commonly recognized characteristic of epithelial tissue, which is polarity. And so, epithelial tissue is polar, which means that the epithelial tissue is sided if you will, which means that one side or one surface of the epithelial tissue is going to be structurally and functionally different than the other side or surface of the epithelial tissue. And so this leads us to two notable surfaces of epithelial tissue. The first notable surface of epithelial tissue is going to be the apical surface. And so the apical surface usually in most diagrams of epithelial tissue is going to be shown above. But more importantly, the apical surface of epithelial tissue is going to be facing the open space that's immediately adjacent to epithelial tissue. Now, the second notable surface of epithelial tissue is going to be the basal surface and usually in most diagrams of epithelial tissue, the basal surface is going to be shown below. But more importantly, the basal surface is going to be facing an extracellular structure known as the basement membrane. And so, in order to better understand these ideas, let's take a look at our diagram down below and so to orient you on this diagram. Notice that toward the top here, we're showing you epithelial tissue. And in fact, we're actually labeling an epithelial cell right here in the diagram and notice that these darker structures that you see here in these regions represent the nuclei of the epithelial cells that are coming together to form the epithelial tissue. And what you should also notice is that down below in this layer in blue, we're showing you some connective tissue, which you might recall is one of the primary types of tissue that we'll talk about later in our course. But for now, what I'd like you to notice is that the connective tissue is being separated from the epithelial tissue by this extracellular structure known as the basement membrane and the basement membrane. You can see in the diagram is right here. And so the basement membrane is separating the epithelial tissue that's shown above from the connective tissue that's being shown below. Now, in our next lesson video, we'll talk more details about the basement membrane. But for now, we want to focus on the polarity of epithelial tissue. And so once again, the polarity of epithelial tissue means that the tissue is sided one side or surface of the epithelial tissue is going to be structurally and functionally different than the other side or surface of the epithelial tissue. And so we know that the side that is facing the open space usually shown above is going to be the apical surface and the side that is usually shown below, but facing the basement membrane is going to be the basal surface. And so one thing that you should note here is that the apical surface is usually going to contain cilia or micro villa. Here in this diagram, we're showing you some cilia. And you might recall from our previous lesson videos that CIA are little tiny hair like structures that move like ores and can help to move material in the open space. And micro villa you might recall are structures that are going to be really important to maximize absorption ability, the uptake of nutrients. Now, the basal surface is not going to have CIA or micro villa. Instead, the basal surface is going to be important for anchoring the epithelial tissue to the basement membrane to make sure that the epithelial tissue is uh set in place. And so this year concludes our first commonly recognized characteristic of epithelial tissue. The fact that epithelial tissue is polar and we'll be able to talk about the second commonly recognized characteristic in our next video. So I'll see you all there.
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Characteristic 2: Tightly Pressed Tissue Anchored to Basement Membrane
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In this video, we're going to talk about the second commonly recognized characteristic of epithelial tissue, which is that epithelial tissue is tightly pressed tissue that is anchored to a basement membrane. And so, one of the key features of epithelial tissue is that the cells are held really tightly together through cell junctions. And because these epithelial tissue cells are held really tightly together that leaves very little room between the cell and that leaves very little room for the extracellular matrix or the ECM. And so epithelial tissue is going to have really tightly packed cells with very little ECM. And so the epithelial tissue is pretty much analogous to a brick wall. And that's why we're showing you a brick wall right here. And so what you'll notice is that these red bricks that are so tightly packed together represent the cells of the epithelial tissue and the cement that's holding these red bricks together here represents the extracellular matrix. And so what you'll notice is that like a brick wall, the bricks or the cells are going to be really tightly packed together with very little ECM, very little extracellular matrix. And so if we take a look at our diagram down below. What you'll notice is that we're showing you all of these different cell junctions right here. And so right here, we're showing you a tight junction. And so you might recall from some of our previous lesson videos that tight junctions are going to hold two neighboring cells really tightly together to create a leak proof barrier. And so what you'll notice is that there are plenty of tight junctions throughout this epithelial tissue, holding the epithelial tissue cells really really tightly together, creating a leakproof barrier. And so what that means is that there can be some liquid here in the open space above the epithelial tissue here and that liquid will not be able to leak through the epithelial tissue as effectively because of these tight junction creating that leak proof barrier. Now, what you'll also notice is that over here, we're showing you desmosome, which you might recall from our previous lesson, videos are more structurally complex cell junctions that are going to really firmly anchor these neighboring epithelial tissue cells together. And so we have a few desmosome throughout and that helps the epithelial tissue to remain really tightly and uh anchored firmly. Now, down below, right here, we're showing you some gap junctions which you might recall creates a gap here, essentially linking the cytoplasm of the neighboring epithelial tissue cells to allow them to exchange nutrients with each other, for example. And so you might recall from our previous lesson video that we briefly mentioned that this tightly pressed epithelial tissue is going to be anchored to an extracellular structure called the basement membrane. And so the basement membrane is really going to consist of two thin extracellular layers. The first thin extracellular layer of the basement membrane is going to be the basal lamina. And the second layer of the basement membrane is going to be the reticular lamina. Now the basal lamina is actually going to be produced by the epithelial tissue or by the epithelia for short. Whereas the reticular lamina is going to be produced by the underlying connective tissue. And so what you'll notice here is that in our brick wall analogy, our brick wall is anchored to a basement membrane that you can see down below that has those two thin extracellular layers, the basal lamina and the reticular Lana. And so let's take a look at our diagram to visualize this a little bit better. And once again in our diagram, we have the epithelial tissue up above shown here. And then down below, we have the connective tissue in a bluish color and separating the epithelial and connective tissue is this structure here that we are calling the basement membrane. And so you can see the basement membrane right here in our diagram. And what you'll notice is that this basement membrane actually consists of two thin extracellular layers. We have this uh pink extracellular layer right here and then we have this semi purpleish extracellular layer immediately beneath. And so the thin extracellular layers are going to be the basal lamina and the reticular lamina. Now, one thing that can help you remember that the basal lamina is going to be produced by the epithelial tissue. And the reticular lamina is going to be produced by the connective tissue is that uh you can notice we've uh used these bees here to help remind you of something important. And that is that the basal surface of the epithelial tissue is going to be facing the basement membrane. And you can think that the basal surface of the epithelial tissue is going to be producing that basal lamina layer of the basement membrane. And so you can see the BBB here can hopefully help remind you that the basal lamina is going to be produced by the epithelial tissue. And then of course, that means that the particular lamina must be produced by the underlying connective tissue. And so this year concludes our lesson on the second commonly recognized characteristic of epithelial tissue. And we'll get to talk about the third one in our next video. So I'll see you all there.
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concept
Characteristic 3: Avascular but Innervated
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2m
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In this video, we're going to talk about the third commonly recognized characteristic of epithelial tissue, which is that epithelial tissue is a vascular but innervated. And so the term avascular is a term that means without blood vessels or no blood vessels. And so the opposite of a vascular is just vascular without the a and so the term vascular means with blood vessels. But again, epithelial tissue is avascular, meaning it has no blood vessels. Now, the term innervated means that it contains nerves or nervous tissue. And so once again, the epithelial tissue that we're highlighting here in our diagram is going to be avascular but innervated, meaning it has no blood vessels, but it does have nerves. And so notice that the nerves are highlighted in yellow here and notice that uh the nerves that are highlighted in yellow are actually extending into the epithelial tissue. And this is a big reason for why epithelial tissue is closely connected with the function of allowing sensation. Again, epithelial tissue in most cases is going to serve as a boundary but uh adjacent to open space. And so it is going to connect us to the outside world essentially, and it can detect the initial stimulus from the outside world such as touch or pressure or temperature. And upon detecting the initial stimulus, it can go on to activate these nerve endings that it is in close connection with. And so once these nerve endings are activated, they can transmit an electrical signal for processing, allowing for the full sensation. Now, another thing to notice here in this diagram is that the underlying connective tissue here is actually vascular and innervated. Notice that it does actually have blood vessels, but again, these blood vessels are in the connective tissue, the underlying connective tissue, they're not actually in the epithelia. Uh and also notice that it does have um uh nerves which is why it is innervated. But again, uh the nerves extend into the epithelial tissue, which is why the epithelial tissue is innervated. And so this year concludes our third characteristic of epithelial tissue. And we'll be able to talk about the fourth commonly recognized characteristic of epithelial tissue in our next video. So I'll see you all there.
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concept
Characteristic 4: Supported by Connective Tissue
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In this video, we're going to talk about the fourth commonly recognized characteristic of epithelial tissue, which is that epithelial tissue is supported by connective tissue. And so recall that connective tissue is one of the four primary types of tissue found in the human body. And later in our course, we're going to talk more details about connective tissue. But for now, what we're saying is that epithelial tissue is supported by connective tissue. And so recall that the epithelial tissue is a vascular, which means that it does not have any blood vessel. And this is what allows connective tissue to support the epithelial tissue because the connective tissue that is underneath of the epithelial tissue is going to be vascular, which recall means that it does contain blood vessels. And so the vascular connective tissue with blood vessels is going to support the epithelial tissue by supplying nutrients to the epithelia and helping to remove wastes as well. And so the nutrients that can be supplied through the blood vessels of the connective tissue are things such as glucose and oxygen, for example. And the removal of waste could include removing carbon dioxide gas, for example, and So if we take a look at our diagram up above here, notice once again that the epithelial tissue is avascular but innervated with nerves. And because it is a vascular, this allows for the vascular connective tissue that's underneath to support the epithelial tissue. And so notice that the connective tissue here is going to be vascular in nature because it does have blood vessels and it's also going to be innervated with these nerves. And again, because the connective tissue is vascular with these blood vessels. It is going to allow for nutrients to diffuse from the blood and into the epithelial tissue supporting that epithelial tissue. And so this here concludes our fourth commonly recognized characteristic of epithelial tissue. And we'll be able to talk about the fifth and final characteristic in our next video. So I'll see you all there.
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concept
Characteristic 5: Highly Regenerative
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In this video, we're going to discuss the fifth and final commonly recognized characteristic of epithelial tissue, which is that epithelial tissue is highly regenerative, meaning that epithelia has the capacity to divide rapidly. And so if we take a moment to think about this, this actually makes a lot of sense. And so, recall from our previous lesson videos, that a key feature of most epithelial tissue is that it forms a boundary immediately adjacent to open space. And we know that epithelial tissue is important for covering body surfaces and organs and lining internal body cavities. And so because epithelial tissue forms this boundary, it's going to be subject to the environment and it's going to be subject to physical stresses and pressures from the environment such as friction for example. And so this can cause damage to epithelial tissue cells and it can cause epithelial tissue cells to rub off and be lost. And so these damaged or lost epithelial tissue cells need to be replaced by dividing epithelia. And so this is why epithelial tissue has the capacity to divide rapidly. Now, it turns out that it's the epithelial tissue cells that are closest to the connective tissue that underlies it, that has the highest capacity to divide. And the reason for that is pretty simple, it's because the underlying connective tissue is vast muscular. And so it has blood vessels that contain nutrients. And so the epithelial tissue cells that are closest to the underlying connective tissue are going to have more direct access to the nutrients and that is going to allow them to have a greater capacity to divide. And so as the epithelial tissue cells get further and further away from the underlying connective tissue, usually their capacity to divide also decreases. Now, because epithelial tissue cells divide rapidly. This is what makes them subject to cancer. In fact, most cancers actually develop from epithelial tissue. And so recall that cancer is a disease characterized by uncontrollable cell growth and usually mutations cause those cells to become cancers. Now, every single time a cell divides, there's a small chance of mutations occurring. And so the more that a cell divides, the greater the chance is that a mutation can occur that will lead to cancer. And so this is why most cancers develop from epithelial tissue because they have to have this ability to divide rapidly. And so this here concludes our lesson on the commonly recognized characteristic of epithelial tissue. And we'll be able to get some practice applying these concepts as we move forward. So I'll see you all in our next video
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example
Characteristics of Epithelial Tissue Example 1
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7m
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So here we have an example problem that says in the following images of epithelial tissue that we can see down below right here, identify the following features if present and the features are apical surface, basal surface basement membrane, connective tissue and CIA. And so one thing that we need to recall from our previous lesson videos is that one of the key defining features of most epithelial tissue is that it's going to consist of a sheet or multiple sheets of tightly pressed cells forming a boundary adjacent to open space. In fact, when we look at each of these micro graphs, we can identify the open space, which can be really helpful for us to identify all of these features. And so notice in the far left micrograph, the open space is going to be right over here in this highlighted region. In the next micrograph, the open space is going to be right here. And then in the third and final micrograph notice that there are multiple pockets of open space that you can see in these highlighted regions right there. And again, we know that the epithelial tissue is going to be forming tightly pressed uh it's going to have tightly pressed cells. And so notice that we have these tightly pressed cells that is surrounding and forming a boundary against this open space. Right here in this image here, we have some more tightly pressed cells forming a boundary against the open space right there. And then over here in this last micrograph, we have tightly pressed cells forming a boundary around each of these open spaces that we can see in this image. And so once again, this is going to be really helpful for us to begin to identify these features. And so uh recall that epithelial tissue is polar, meaning that the tissue is sided. And that just means that one side or surface of the tissue is going to be structurally and functionally different than the other side or the other surface of the tissue. And so recall that the apical surface of the epithelial tissue is going to be facing toward the open space. And so what we can do is we can use the letter A here to label the apical surface in each of these micro graphs. And again, the epithelial tissue here, the surface that's facing the open space is going to be the apical surface. So we can put a here and just say, hey, this surface all along here is gonna be the apical surface of the epithelial tissue. Uh Over here again, we have epithelial tissue and again, the apical surface is going to be facing toward the um open space. And then over here in each of these, again, the surface that's facing toward the open space is going to be the apical surface. So we can just go ahead and put an a uh in each of these regions to identify the apical surface. Now recall that the basal surface on the other hand is going to be facing the basement membrane. Now recall from our previous lesson videos that the basement membrane consists of two thin extracellular layers, the basal lamina which is produced by the epithelial tissue and the reticular lamina which is produced by the underlying connective tissue. Now, although the basement membrane is really important under a standard light microscope, usually the basement membrane is way too thin to actually be visualized. However, there can be some special staining techniques that allow for better visualization of the basement membrane and the basement membrane can also be visualized using more advanced microscopes like electron microscopes, for example. But in most of these standard light microscope images that we see here visualizing the basement membrane is going to be very difficult and in fact, it's really difficult to visualize the basement membrane here. However, we do know that the basement membrane is going to be separating the epithelial tissue from the underlying connective tissue. And so what we can do is we can try to identify the epithelial tissue and the underlying connective tissue. And then we know that the basement membrane will be in between the two. And so when we take a look at this micrograph over here on the far left, what you'll notice is that the epithelial tissue let's use uh yellow here is going to be basically all of this tightly pressed tissue that you see highlighted right here and uh underneath of this epithelial tissue, which I'll highlight in blue, you'll notice that the tissue changes its style. And so this uh tissue that you see here is going to be the connective tissue. And so uh what I'll do is I'll highlight this in uh this blue color and label this as the connective tissue. We'll put ad here to label it as the connective tissue. And then of course, the basement membrane is going to be separating the epithelial tissue from the um connective tissue. And so if the basement membrane were going to be included here, we know that it would be in this particular region, something like that. And then we could label this as c the basement membrane. Now, moving on to this next micrograph, the epithelial tissue, the tightly pressed epithelial tissue is going to be right here, highlighted in yellow. But then notice once again that down below, we have a change in the style of that tissue. And so uh here we're going to say that this is going to be the connective tissue. So once again, we'll label this as d here uh to label the connected tissue, put this right over here and put an arrow in. Uh and then of course, we know that the basement membrane is going to be separating the epithelial tissue from the connective tissue. So the basement membrane, if we were to be able to see it, it would be right here in this region. So we could label that as c right there, the basement for the basement membrane uh moving on to this final one over here. What you'll notice is that the epithelial tissue is going to be this tissue that is immediately surrounding the open space, as you see right here, highlighted in these regions. This is the epithelial tissue and the connective tissue is actually all of this other tissue that you see all around it like. So and so, uh we can label the connective tissue d here right over here as so and again, the basement membrane would be separating the epithelial tissue from the connective tissue. So there we would expect there to be a basement membrane around each of these uh as we see right here. And so we could label these as the basement membrane uh like. So and so uh what you'll notice is that over here in this micrograph, uh it's uh you'll see these tiny little hair like structures that are right over here and those tiny little hair like structures that you see there that represents the CIA, those are the CIA and recall that the CIA are these tiny hair like structures that move like ores that can help to move material through the open space um there. And so uh what we can do is we can take the CIA here and we can label the CIA here. We'll put an E and we'll label the cilia like. So and then uh what we'll do is we'll just color and the silly like. So, yeah. And so this was uh a really interesting example problem. Hopefully this was helpful for you and uh we'll be able to get some practice applying a lot of these concepts as we move forward. So I'll see you all in our next video.
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Problem
Problem
Most cancers develop in epithelial tissues. Which epithelial tissue characteristic makes them prone to cancer?
A
Epithelial cells have polarity.
B
Epithelial tissue is avascular but innervated.
C
Epithelial tissue is supported by connective tissue.
D
Epithelial cells divide regularly.
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Problem
Problem
Together the basal lamina and the reticular lamina make up the _____________________. The basal lamina is produced by the _________________, while the reticular lamina is produced by the ____________________.
A student scratched herself accidentally. What piece of evidence would suggest the scratch went through the epithelium (outermost layers of her skin) and reached the underlying connective tissue?
A
She started bleeding.
B
She felt pain.
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Problem
Problem
The epithelial tissue in the small intestine is specialized to absorb nutrients. Why would tight junctions be important in this function?
A
Tight junctions allow the cells to transmit ions between cells, allowing the cells of the epithelium to coordinate.
B
Tight junctions ensure all nutrients are absorbed through epithelial cells, allowing for selective permeabilty.
C
Tight junctions allow specific molecules such as nutrients to enter the cell more easily.
D
Tight junctions allow the epithelial cells to sense and recognize specific molecules.
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