| 00:00 | All right. Almost ready. Just this thing going and we'll get |
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| 00:06 | Like I promised this should be a day today. Have one of those |
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| 00:13 | , aren't I? Well, we'll about it later. All right. |
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| 00:19 | , I want you to kind of about what we've talked about this |
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| 00:22 | Uh You know, I really I'm big believer in that. You do |
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| 00:27 | to kind of take that step back think about what you're trying to learn |
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| 00:30 | otherwise it's just gonna go by you then all of a sudden it's just |
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| 00:33 | bunch of stuff that you have to . And so if you think about |
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| 00:36 | big picture, what have we been this week? We started off the |
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| 00:39 | going, okay, here's some introductory about a mp. Right? What |
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| 00:44 | P is And we kind of looked , you know, some organization of |
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| 00:48 | the body is kind of organized. very general sense. Within said, |
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| 00:51 | , look, there's this this hierarchy organization. And then on that on |
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| 00:55 | Tuesday, we kind of went and , all right, we're gonna deal |
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| 00:58 | biomolecules, right? And then Wednesday thursday we spent our time talking about |
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| 01:05 | , right? And how cells kind behave the parts of the cells and |
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| 01:08 | they behave. And so this day tissue, Right? So we've basically |
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| 01:14 | walking through that organization. Just like kind of said at the beginning, |
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| 01:17 | how it's organized. And so now at this where what is tissue? |
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| 01:22 | does it look like? All And then so, that means after |
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| 01:25 | . if we get a test and we're gonna say, all right, |
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| 01:28 | gonna jump and start looking at So So it's not so much that |
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| 01:33 | got a ton of information that I've to memorize. There is an organization |
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| 01:38 | a a way to look at this . And that's why it's important to |
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| 01:41 | of kind of step back and oh, I see why this is |
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| 01:45 | . All right. Otherwise, you're gonna be spinning your wheels desperately trying |
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| 01:49 | learn stuff. You know, what do I need to know this? |
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| 01:51 | do I need to know? All . And so what we're gonna do |
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| 01:55 | we're gonna walk through those four Remember the four tissues are one head |
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| 02:00 | not in there, but what are ? Uh huh. Exactly. That's |
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| 02:07 | I heard. It was just you . Yeah. So, it's |
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| 02:10 | connective tissue, nervous tissue, and . All right. So, I'll |
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| 02:14 | let you know right now, the extent to which we're gonna talk about |
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| 02:17 | nervous is like like a word. like a slide. And the reason |
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| 02:21 | that is because we're gonna get to later where we spend a lot more |
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| 02:25 | diving in deep to that stuff, ? But epithelial and connective tissue |
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| 02:31 | you know, it's much more broadly . And so there's lots of different |
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| 02:37 | where we're going to see. And just kind of understanding more more specifically |
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| 02:41 | those tissues do and and how they it is kind of what the focus |
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| 02:45 | this lecture. And when we get the end, we're going to kind |
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| 02:48 | wrap things up and kind of well how does how does tissue repair |
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| 02:52 | ? Which kind of feels out of at the end of all this |
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| 02:54 | Because it kind of focuses in on again. But many tissues repair itself |
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| 03:00 | very similar processes. And then we're just gonna go over a couple |
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| 03:03 | little housekeeping things like what are these mean and be done with it. |
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| 03:08 | . And so our starting point here gonna be epithelium. You've already seen |
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| 03:11 | picture. And the only reason I this is because it came from your |
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| 03:14 | and it said epithelial cell. And I thought that was a a decent |
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| 03:18 | to kind of show this here. really what it says here is |
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| 03:22 | epithelium has uh some very basic uh . There are two types in |
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| 03:29 | Alright, so we have epithelium that stuff and then we have epithelium, |
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| 03:33 | street stuff. Right? And so have names where we call it covering |
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| 03:37 | or glandular epithelium. And so our here is gonna be saying what does |
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| 03:42 | covering look like And how do glands like and behave? All right |
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| 03:50 | I'm sure you can go and youtube but there, you know, there |
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| 03:54 | videos on youtube where you can watch pop zits. I know it's like |
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| 03:59 | , you know, but it's not just a little tiny ones. We're |
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| 04:02 | like, you know where the gloves out a scalpel and just keep pushing |
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| 04:09 | . All right. So when we're about glands, we're talking about structures |
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| 04:13 | are not these little tiny things on nose. We are talking about |
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| 04:17 | But we're also talking these structures that much, much larger. And so |
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| 04:22 | want you when we get there, want you to kind of go, |
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| 04:24 | yeah, these things are really And if you really want to, |
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| 04:26 | you if you're that kind of go check out some of these. |
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| 04:31 | just going to conquer his videos. mean, we're talking ounces of materials |
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| 04:37 | out of these things. So, that cover and glands all right |
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| 04:44 | they're gonna have specialized contacts. Epithelium one of these really, really unique |
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| 04:49 | of tissues in that they go through process called contact inhibition. What that |
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| 04:55 | is if I get an epithelial cell put it in a dish, for |
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| 04:59 | , a plate. What will happen that epithelial cell will start growing and |
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| 05:04 | . It will just keep dividing and will create an entire sheet until there's |
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| 05:09 | more space for it to grow. then there's a signal that basically |
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| 05:12 | I'm not going to grow anymore and basically stops growing. So it's unique |
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| 05:17 | that. It has all these specialized and some of them we've already talked |
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| 05:22 | but also has this unique kind of of communicating to tell it when to |
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| 05:27 | when not to grow. So for , if you get a cut right |
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| 05:32 | your skin splits and you now have opening. Have you noticed that it |
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| 05:36 | itself? And then it kind of itself with normal skin. That's because |
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| 05:40 | skin is no longer being contact because you basically separated out the |
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| 05:46 | And so it's going like, I've got to grow until I come |
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| 05:49 | contact with something and that's why it . So, so the primary junctions |
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| 05:55 | gonna be dealing with are the ones already learned about. And now you |
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| 05:58 | start seeing like, oh, that's we talked about these dumb things because |
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| 06:03 | face it, it was kind of , right? Because epithelium is dependent |
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| 06:08 | these types of junctions to ensure that capable of doing this type of covering |
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| 06:13 | being able to create these glandular There we go. All right, |
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| 06:22 | you look at this picture, what want you to understand, you're looking |
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| 06:24 | a slice through the skin. The pink stuff up here is where |
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| 06:30 | spending our time looking right now. , this right here is connective |
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| 06:35 | The pink stuff in the picture is tissue alright. And the reason we |
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| 06:40 | this picture up here is I want show you those those two types of |
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| 06:45 | two types of characters. 1st, why it's not doing anything. There |
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| 06:50 | go. Alright. 1st. There no blood vessels up here, you |
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| 06:54 | see blood vessels are always gonna be in anatomy books, by the red |
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| 06:57 | the blue. That's red is for , blue for veins. And |
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| 07:01 | when you see them, you can that there's blood coming and blood |
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| 07:04 | All right. And you can see the blood vessels in our little cartoon |
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| 07:07 | here, in the in the in the lower area, in the |
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| 07:11 | tissue area. But when you get here to the epithelium, there are |
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| 07:14 | blood vessels. And that's not an choice. That is trying to demonstrate |
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| 07:19 | the epithelium is a vascular meaning blood do not penetrate in them. |
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| 07:26 | blood is delivered near to them. the nutrients of the materials from the |
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| 07:31 | are gonna move through the surrounding extra fluid and reach the cells to provide |
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| 07:37 | the nutrients that they need. truth be told in your body, |
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| 07:41 | is not a cell in your body alive, That is less. That |
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| 07:44 | more than five microns away from a vessel. All right. And if |
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| 07:49 | want to know how small five microns think about a millimeter. Alright, |
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| 07:54 | you take a millimeter and take 1000s that. That's a micron. And |
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| 07:58 | five of those is the distance. , very small distance. All |
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| 08:06 | So, the molecules that are leaving blood vessels. So you can see |
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| 08:10 | got these little tiny capillary systems are penetrating through and traveling a small distance |
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| 08:16 | those into that epithelium and providing the to the living cells there. All |
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| 08:22 | now, I also mentioned that their already they have that contact responsiveness or |
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| 08:27 | inhibit. It's called contact inhibition, when they touch each other, they |
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| 08:32 | growing. When they don't touch each , they grow. And if you |
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| 08:37 | aware, for example, your skin epithelial. This is true. But |
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| 08:43 | is really, really easy to see that your skin replaces itself over and |
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| 08:47 | and over again. It's really obvious the summertime when you go get sunburned |
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| 08:51 | you then get to take off those layers of of skin off your body |
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| 08:55 | already dead. It's been dead. what you're doing is you're regenerating damaged |
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| 09:00 | below that damage cells below that. , it's pushing it up faster and |
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| 09:03 | why you're able to peel it off frequently. So we've talked about this |
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| 09:10 | , but now we're going to really of focus in on we said that |
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| 09:13 | is polar and you can see in cartoon this side looks definitely different from |
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| 09:17 | side. So this polarity helps define functionality of the cells in epithelium and |
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| 09:24 | tissue of epithelium. So, what have is we have a pickle |
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| 09:28 | The a pickle side is going to what we call the exposed side. |
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| 09:31 | if you're looking at your skin, the a pickle side, Right? |
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| 09:34 | if you're looking at a hollow say your digestive track or your lungs |
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| 09:39 | blood vessel, you now have a . The exposed side is inside that |
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| 09:45 | . Okay, so that would be a pickle side and then the side |
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| 09:49 | attached to the connective tissue. That's basil side and on the sides of |
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| 09:53 | cells touching each other. That's the side. And we just kind of |
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| 09:57 | to the basil and the lateral sides as the basal lateral side. All |
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| 10:01 | now, the A pickle side has couple of characteristics. Typically you're going |
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| 10:06 | see two unique types of features and what these little tiny bumps are. |
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| 10:09 | called micro ville. And we're going see more clearly what they are in |
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| 10:13 | next slide. But you'll see on a pickle side. That's where we're |
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| 10:16 | to be secreted materials or absorbing And so we're going to have modifications |
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| 10:21 | that surface to increase surface area or manipulate the environment around us. And |
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| 10:28 | what the purpose of the micro villi the cilia are for All right, |
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| 10:33 | the basil side because we want to to the underlying connective tissue. What |
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| 10:40 | gonna do is we're going to secrete whole bunch of different types of proteins |
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| 10:43 | create an extra cellular matrix that then with the extra cellular matrix of the |
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| 10:47 | tissue. And between the two of they kind of inter mesh and they |
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| 10:51 | what is called a basement membrane. , so we refer to it being |
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| 10:59 | by the epithelial cells as the basil . Inna. Alright, so that's |
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| 11:04 | epithelial side of the basement membrane is basil laminar. It's a series of |
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| 11:10 | that just basically are being secreted as extra cellular matrix on the connective tissue |
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| 11:17 | . They're also sells their and they're their own proteins and they're gonna contribute |
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| 11:23 | that basement membrane as well. And you're gonna have there is what is |
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| 11:27 | the reticulated lamin A. So basil mina and particular lamin A coming together |
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| 11:33 | it's kind of like velcro, You have your hooks. You guys |
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| 11:37 | , have you guys closely examined velcro or you just presume that it |
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| 11:42 | I've always wondered how it works when was a little kid. And so |
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| 11:44 | sit there and you know, it's is a bunch of little hooks and |
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| 11:47 | bunch of loops. And so the and the loops get all intertwined and |
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| 11:51 | get enough of those hooks and enough those loops and you basically hold things |
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| 11:55 | and that's kind of what the particular A and the basil laminar like it's |
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| 11:58 | hooks and loops. It's not but like that and together they form this |
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| 12:03 | membrane and now you have this connected that holds the two tissues epithelium and |
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| 12:11 | tissue together. So, this right is what a micro villas is or |
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| 12:22 | civilized plural. All right. This an actual electron micrografx showing this. |
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| 12:27 | you can see right here this would where the surface of the cell normally |
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| 12:32 | . But micro ville ir surfaces of cell. All right. What you're |
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| 12:37 | to imagine here is you have a with a finite amount of space. |
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| 12:41 | right. Let's see if I can this for you. All right. |
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| 12:47 | basically have a series of cells that next to each other. Like |
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| 12:50 | okay. And so, you can the surface area for that one little |
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| 12:54 | about that long. How long is that long? Right. If I |
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| 12:59 | to increase my surface area, I'd to make bigger cells, bigger cells |
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| 13:03 | up more space. And that's So, we don't want bigger |
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| 13:07 | We want more surface area. the best thing I can do is |
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| 13:10 | can take my surface and I can it upward and then why don't I |
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| 13:14 | keep doing that over and over And now what do I have is |
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| 13:18 | have a very very I have a size cell with a lot of surface |
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| 13:22 | . Because what I've done is I've upward and downward multiple times. I've |
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| 13:27 | these finger like structures. All So typically we do this because we |
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| 13:33 | to have this large surface area to able to absorb materials. Do you |
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| 13:37 | when we talked about the laws of ? Fixed law? We said one |
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| 13:40 | the important factors increasing the rate of or the movement of materials across the |
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| 13:46 | is to increase surface area. if I have a whole bunch of |
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| 13:50 | ville, I I basically increased surface so I can increase the rate at |
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| 13:54 | I absorb material In a. & . two. You're going to talk |
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| 14:00 | the digestive system. All right I'm looking around the room and I |
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| 14:03 | see anyone here is 30 or 40 tall. Alright. I see a |
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| 14:07 | of people who are between four ft six ft. I don't think we |
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| 14:09 | anyone here. seven ft maybe. don't know. Right. But if |
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| 14:13 | were to look at the digestive system all of us, on average, |
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| 14:17 | digestive system is roughly about 30 ft , roughly. But its effective length |
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| 14:26 | our digestive system is lined by epithelium our effect. And each of those |
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| 14:31 | have all these micro villi and there's other modifications are effective length of our |
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| 14:36 | tract is over a mile long. ? So in other words, it |
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| 14:42 | to be long to be able to all those nutrients and materials that we |
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| 14:45 | into our bodies three times plus a because we eat more than three times |
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| 14:50 | day. Right? I mean that calls me all day long. There's |
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| 15:01 | right. So micro ville are going be found on the ethical side. |
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| 15:06 | purpose is primarily found on absorptive cells that you can increase the surface area |
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| 15:11 | increase the rate of absorption. All , cilia, on the other |
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| 15:17 | are a little bit different. so, if you look at |
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| 15:20 | this is again an electron micrografx. a different type where it's you're seeing |
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| 15:25 | in three dimensions. You can see are the micro villa down here. |
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| 15:30 | tiny ups and downs and this big tuft of stuff that looks like seaweed |
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| 15:36 | cilia. Now, Celia are simply extensions of the plasma membrane within them |
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| 15:43 | a bunch of intermediate filaments that are to allow for a structure to have |
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| 15:51 | or the ability to move. And purpose for the most part is to |
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| 15:56 | materials along the surface of the Now, that's in humans. |
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| 16:01 | so if you look at your respiratory , you're gonna see cilia along those |
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| 16:06 | cells that are there and their purpose the respiratory tract is to move mucus |
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| 16:11 | or really away from the lungs and towards the oral cavity or the nasal |
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| 16:17 | . Alright, bacteria have cilia to bacteria, single cells. And so |
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| 16:21 | got these little tiny cilia to kind move themselves around. So it's |
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| 16:25 | it's moving the environment. But they're moving themselves now. Similar to |
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| 16:30 | The only reason I'm mentioning it here because there's no better place to put |
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| 16:34 | . Is there something that's similar to psyllium, psyllium is singular. Sileo |
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| 16:38 | plural same structure much much longer as flagellum. All right. The flagellum |
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| 16:46 | is a propeller that's built the exact way that a cilia does. But |
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| 16:51 | only found in humans in one cell that's the spermatozoa. All right. |
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| 16:57 | other organisms. You'll see fluid gel again, it's a propulsion mechanism and |
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| 17:01 | structurally this is kind of what it like and how they're different. Um |
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| 17:05 | can see they're structurally they're the They basically there's your central or basal |
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| 17:10 | . You have a series of Excuse me. I said, intermediate |
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| 17:13 | micro tubules in the nine plus two . And what they do is basically |
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| 17:17 | have motor proteins in there, then on the different micro tubules that causes |
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| 17:22 | cilia to move if you're full of . Um you move this one |
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| 17:26 | it's kind of like a propeller. kind of like it's like taking a |
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| 17:30 | and spinning it over your head if doing a silly um It's like rowing |
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| 17:33 | boat basically. It's more like this you're imagine being on your back in |
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| 17:40 | lake or swimming pool, your drinks on your chest doing this. It's |
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| 17:50 | . That's what I want to be . All right. In essence, |
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| 17:56 | have different structure because they're designed differently they move things differently. You can |
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| 18:00 | if I have stuff up here, am I doing? And I'm pushing |
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| 18:04 | , pushing it along. This is . But you won't see flagellum Until |
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| 18:12 | . & p. two. But you see it on the exam, |
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| 18:15 | is a possibility because I've included it . It's for propulsion. Same structure |
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| 18:21 | cilia, different function. All So, what does that to thallium |
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| 18:28 | ? All right. So, up , is that picture we've already looked |
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| 18:31 | ? This is uh just looking at epithelial cells play some very very basic |
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| 18:38 | protective. Alright. It's a protective or a protective cell. I'm just |
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| 18:46 | to use the skin for right because it's an easy one to think |
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| 18:49 | . Your skin prevents things from the world from getting into your body. |
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| 18:54 | right, The epithelium completely lines you're versus your inside. Now, what |
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| 19:02 | your outside and your inside. Truth your donut. All right, |
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| 19:07 | You have an outside. That's easy see. But you also have a |
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| 19:11 | that goes all the way through There's one side of the Donut. |
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| 19:15 | a big long track that goes all way down. I'm not showing you |
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| 19:19 | other side of the donut. But basically that is on the outside |
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| 19:24 | your body. Alright. It's exposed the external surface. Ergo it's |
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| 19:29 | Even though you can't see it. . The respiratory system where the air |
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| 19:34 | in. That's external to your Alright? Internal to your body is |
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| 19:39 | the other side of that membrane, the other side of those cells. |
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| 19:44 | that's serving as a protective barrier. not only protective, it's selective as |
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| 19:49 | what will allow to pass through. right. Again, you can think |
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| 19:53 | your skin, right? I can water on the surface of my body |
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| 19:57 | it's not gonna go absorbing through my . It's a protective barrier against water |
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| 20:02 | materials. But I can take lotion example, which is fat for the |
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| 20:07 | part and rub it onto my skin it will absorb through. Okay. |
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| 20:12 | it decides what passes through if it's soluble or water soluble epithelium can be |
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| 20:20 | in nature. In other words it materials. So we've talked about, |
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| 20:24 | know, we mentioned glandular, that's primary things, mechanisms of secretion. |
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| 20:30 | we have to create all sorts of . Alright? We secrete mucus. |
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| 20:35 | can think of your oil cavity, cavity and other cavities that secrete this |
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| 20:40 | to create lubricant. Right? Your secretes materials right? And these are |
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| 20:46 | be glands that do this for the part like sweat for example, comes |
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| 20:50 | a little tiny gland and that's water fat and other materials actually depending upon |
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| 20:55 | you're actually sweating from, sweating from skin doesn't have fat and sweat from |
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| 20:58 | pits. It has fats and materials all right. So, when you |
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| 21:03 | the word secretion, your psa creating to the surface of the body, |
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| 21:06 | you're talking about the digestive system, secreting mucus, you're secreted enzymes are |
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| 21:11 | other chemicals to drop ph down. , secretion has different meaning depending where |
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| 21:18 | are. It's always moving materials to surface. The other thing and this |
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| 21:23 | really the function of the nervous But we're including it here because there |
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| 21:27 | cells that are affiliated or associated with epithelium that are epithelial nature that can |
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| 21:34 | uh different changes in our environment. right. So, for example, |
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| 21:40 | have touch receptors that are found in skin that are associated with neurons and |
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| 21:46 | that information up to our brains to us that we're being touched or touching |
|
| 21:51 | . So, it plays a role this sensory reception. And that's not |
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| 21:54 | including the neurons that are associated with hair cells. Have you ever felt |
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| 21:58 | blood crawling across your skin? Because just moving your hairs. That's a |
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| 22:02 | that's that's feeling that or detecting that the hair is actually moving. All |
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| 22:09 | . So, really it's the neuron doing the hard lifting of sending the |
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| 22:12 | forward. But the detection of being at the level of the epithelium. |
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| 22:17 | epithelium has multiple roles now how we stuff when we're dealing with epithelium is |
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| 22:27 | straightforward. All epithelium has two It has a first name and last |
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| 22:32 | . Lack of a better term. . The first name is based on |
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| 22:36 | number of cells or excuse me, number of cell layers that you're going |
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| 22:40 | look at. Alright, So there's two types, there's two types of |
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| 22:44 | . The first name. The simple . The easy one I should say |
|
| 22:47 | simple if you have a single layer cells so you can see single |
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| 22:51 | single layer, single layer, we that simple epithelium. Alright, so |
|
| 22:56 | would be the first name if it more than one. So two or |
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| 23:02 | we call it stratified. So here can see that there's multiple layers stratified |
|
| 23:07 | . There's two layers. It's So two or more. This is |
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| 23:11 | weird one. We're gonna get to in a little bit. All |
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| 23:15 | Here's another one. This would be stratified but it has some unique |
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| 23:19 | So we give it a special name we'll deal with that in just a |
|
| 23:22 | . Alright. Typically simple epithelium is you have absorption or filtration absorption when |
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| 23:28 | taking things into the body filtration is you're moving things in the opposite |
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| 23:33 | moving into a tube. So going outside inside the body to outside the |
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| 23:39 | stratified, epithelium is typically when you multiple layers, you can imagine what |
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| 23:43 | doing is I'm creating a very thick and so this is primarily where protection |
|
| 23:47 | going to be taking place, your is going to be stratified, you |
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| 23:53 | sit there and dig at it for while and you're going to take a |
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| 23:56 | time to get down below those many layers of cells. No, |
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| 24:04 | the second name is going to be upon what those cells look like when |
|
| 24:10 | dealing with stratified epithelium, you you're gonna be dealing with that first |
|
| 24:15 | of that last name. So when deal with the stratified, that last |
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| 24:19 | is gonna be based on the most layer. So what you wanna do |
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| 24:23 | you want to look at the shape this upper layer to determine that second |
|
| 24:29 | . Right now the second names are simple. All right. Again, |
|
| 24:34 | the easy one to do this and we'll we'll kind of look at some |
|
| 24:37 | examples here. Alright, so the name is the shape of the |
|
| 24:41 | The three common shapes squamous, squamous scale like. Alright. And so |
|
| 24:47 | cells are typically flat and very very . Q. Boy Idol, if |
|
| 24:53 | look at them, they kind of this cube like shape Coloman er they're |
|
| 24:59 | than they are wide. So in little picture that I drew over |
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| 25:02 | which ones would this be Klempner? now I'm just gonna let you know |
|
| 25:08 | now this is not a histology class if you're going to nursing school, |
|
| 25:13 | you're going to medical school, you're to take histology Histology can be |
|
| 25:18 | Alright, Because you have to sit and you have to look at a |
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| 25:21 | and you have to not only determine cells are there, but then you |
|
| 25:24 | to name the tissue, it can a tough one, and it takes |
|
| 25:26 | time and effort to learn how to this. That's not the purpose of |
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| 25:30 | class. We're not going to sit and go guess the name. |
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| 25:34 | But you should be able to identify simple ones as we go along. |
|
| 25:41 | . One of the tricks to identifying type of epithelium you're looking at because |
|
| 25:48 | ever looks as pretty as it does you see here in the cartoon is |
|
| 25:52 | look at the nucleus. Alright, you're trying to guess the shape of |
|
| 25:55 | cell, kind of look at the of the cell and then look at |
|
| 25:57 | nucleus and if the two things look of the same. So if you |
|
| 26:00 | a flat cell and you have this looking nucleus, okay, that's |
|
| 26:05 | If you have this kind of squarish one, you don't have to get |
|
| 26:07 | there and measure it out, You're like, okay, it's kind |
|
| 26:10 | square looking. If you look at nucleus and it looks almost perfectly symmetrically |
|
| 26:15 | , it's like, okay, that's um a cute boy idol. And |
|
| 26:19 | I'm looking at this cell that looks of tall, I mean maybe it's |
|
| 26:23 | this tall instead of this tall, it's like, oh, and but |
|
| 26:25 | look at the nucleus and it's kind elongate in the same direction. That's |
|
| 26:30 | cute boy girl. Our, sorry boy will columnar. So looking at |
|
| 26:36 | and kind of taking that step to about, do these two things look |
|
| 26:40 | same or do they behave in the direction? Then that's probably a good |
|
| 26:46 | to figure out the nomenclature. the other thing I'd add is you |
|
| 26:51 | to know which direction the cell is going. We said we have an |
|
| 26:55 | pickle side and we have a basil , how do you define which ones |
|
| 27:01 | we'll look for, where the cell attached. Try to find the connective |
|
| 27:07 | on which that cell or group of are sitting. All right. So |
|
| 27:12 | going to help you orient yourself because when you look down a slide, |
|
| 27:16 | not gonna be oriented in this It may be oriented to the |
|
| 27:19 | It may be oriented in the wrong . So, you gotta figure |
|
| 27:23 | oh, oh, this is open a compartment. This is, this |
|
| 27:26 | attached to something down here. So I know which direction, everything is |
|
| 27:31 | right. So what I wanna do I want to first kind of define |
|
| 27:36 | they do and then we're gonna look a couple of pictures and this |
|
| 27:39 | I'm gonna show you there are a of ones you're gonna have to know |
|
| 27:41 | the test, in other words there be a picture. Everyone will get |
|
| 27:45 | picture. There's not you're not you get like three of them, you're |
|
| 27:47 | gonna get one right. And what gonna have to do is you're just |
|
| 27:50 | have to identify which one it Good news. I'm not here to |
|
| 27:54 | you. That's the easy part. students is easy. Just like you |
|
| 28:00 | me is easy. Alright. So we're trying to do is we're trying |
|
| 28:03 | test to see whether we learn the . Okay, so when it comes |
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| 28:09 | simple, remember we said it deals permeability, absorption, filtration and there's |
|
| 28:15 | be some secretion involved in other There's thin layers so that they can |
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| 28:19 | this job of of putting things out pulling things into the body. So |
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| 28:25 | have simple, simple, simple. then we look at the shape. |
|
| 28:29 | is the shape of the cell squamous or Coloman are now long before we |
|
| 28:35 | up with a standard way of naming , scientists were naming things primarily from |
|
| 28:42 | embry a logical origin. They're trying figure out where does this come |
|
| 28:45 | Or or is this unique? And they kind of gave things some simple |
|
| 28:51 | . We still use these because we fall into that trap of using the |
|
| 28:55 | language over and over again. So if you see the word empathy |
|
| 29:00 | . Alright, in the thallium is type of simple squamous epithelium. |
|
| 29:06 | And typically where you're gonna find these in the cardiovascular system and the lymphatic |
|
| 29:10 | . Alright. So, when you're at a blood vessel and they refer |
|
| 29:14 | the vasculature or the helium in the , just like, okay, |
|
| 29:17 | okay, that's simple epithelium. You , it's a squamous epithelium. I |
|
| 29:22 | it. It's just one of the you you you just learn and memorize |
|
| 29:28 | when we talked about those serious Remember the ones that prevent the friction |
|
| 29:32 | stuff? That's a type of simple as well? All right. And |
|
| 29:38 | they're very very thin sheets and that's we find light in body. Just |
|
| 29:45 | it musically. Um It refers to origin. So, here's the |
|
| 29:53 | These pictures. Now, I'm not these pictures. These specific pictures onto |
|
| 29:58 | exam. So, don't memorize the . I understand what you're looking at |
|
| 30:02 | example of the simple squamous that you're at here is going to be from |
|
| 30:06 | lungs. But you see that they from a whole bunch of different |
|
| 30:09 | Can you even see the basement membrane this in this picture? No, |
|
| 30:17 | just basically a bunch of really thin that are connected to each other. |
|
| 30:21 | basically So, when you see dark like that, that's those are those |
|
| 30:25 | blood vessels. So, we're looking here is we're looking at things like |
|
| 30:28 | and there's actually lots of cells. gonna just be the first one to |
|
| 30:31 | you these pictures suck. All If I was to write this book |
|
| 30:36 | we're trying to show you pictures of tissues, these would not be the |
|
| 30:41 | I would have picked. All So, what did that tell you |
|
| 30:45 | the test? They're going to be than these pictures. All right. |
|
| 30:49 | basically, I'm not just gonna throw picture of things. I guess. |
|
| 30:52 | I wouldn't like throw this picture and tell me what that tissue is or |
|
| 30:56 | because what are you supposed to look in that picture? The other thing |
|
| 31:01 | is like taking a picture from like miles away. Staying with that |
|
| 31:05 | I mean what you wanna do, wanna get right up in there so |
|
| 31:07 | you can see and what you have there's a bunch of cells. Here's |
|
| 31:11 | cell. Here's the cell, Here's cell, here's a cell. Here's |
|
| 31:13 | cell and they're all flat and And if you look at the nuclei |
|
| 31:16 | can see that the nuclear nuclear kind flat as well. But with this |
|
| 31:20 | , it's really hard to tell you to get up close and kind of |
|
| 31:22 | it. But you see what we here thin long cells thin nuclei simple |
|
| 31:32 | scale, like simple Que boy idol , imagine this amplified or magnified so |
|
| 31:39 | you can kind of look in here and what you see is a bunch |
|
| 31:42 | cells that look like this that kind look like squares, kinda do it |
|
| 31:54 | his side. Are they perfect No, but they kind of look |
|
| 32:06 | that and then if you come in and look at the nuclei you'll see |
|
| 32:10 | the nuclear more or less symmetrical like that would be cute boy. It'll |
|
| 32:18 | you find these in your ducks and glands, you'll see them in the |
|
| 32:24 | so they play a role in absorption filtration secretion. Again, We've taken |
|
| 32:34 | picture from 1000 miles away. What would do is we'd come up a |
|
| 32:39 | closer but you can see here this here is the basement membrane going up |
|
| 32:45 | down. Really want to kind of up there. This is a |
|
| 32:48 | It's an oblique, remember that term oblique slice. That's what you're getting |
|
| 32:53 | things down here because the glands are of moving out towards you. But |
|
| 32:58 | you're seeing here is if you look these cells, they're much more like |
|
| 33:04 | and then the nuclei or like So they're elongate something like this. |
|
| 33:20 | you might see in these cells, might see micro villi which since it's |
|
| 33:28 | picture so far away, it's really to tell. Alright, typically digestive |
|
| 33:33 | , reproductive system. These are areas you're doing a lot of absorption. |
|
| 33:42 | those three you have to know, you have to be able to look |
|
| 33:46 | the picture and say, I learned definition. If I look at this |
|
| 33:51 | , can I figure out what it this one? You only have to |
|
| 33:55 | what it means. I'm not gonna this picture up at you because it |
|
| 33:58 | be evil and wicked to do All right. This is called the |
|
| 34:03 | stratified epithelium. Sudo means eric so stratified. If you were to look |
|
| 34:12 | this, look at the cartoon, look like a bunch of Colombian |
|
| 34:15 | And they are But look at the at the Columbia ourselves. Some are |
|
| 34:19 | , some are small. They go and down and it looks like a |
|
| 34:24 | epithelium because the nuclear are all over place. But they're not All those |
|
| 34:30 | are attached to the basement membrane and give rise to false sizes and or |
|
| 34:38 | heights. All right now, these found all over the place as |
|
| 34:43 | Um reproductive system respiratory track. Some your large glands have these You can |
|
| 34:49 | see up here. You can see cilia on the surface right there. |
|
| 34:55 | . And so it's a type of epithelium but it has an appearance of |
|
| 35:02 | stratified epithelium. Alright in secretion. cilia. So when we look at |
|
| 35:14 | , we're going to have multiple layers cells. All right. The living |
|
| 35:19 | are gonna be found down here on bottom and as you move further and |
|
| 35:22 | away from the basement membrane, the move further and further away from their |
|
| 35:27 | of nutrients and they typically die Especially when you're dealing with something like |
|
| 35:32 | one that we're looking at here. what you see is basically there's a |
|
| 35:35 | of regeneration going here and you're pushing cells upward. Typically what you're going |
|
| 35:41 | see is that these types of tissues a major role in protection. This |
|
| 35:50 | you should be able to identify. right. So again, you're looking |
|
| 35:55 | this is the stratified multiple layers Now we said we're always naming these |
|
| 36:02 | upon the a pickle layer. if you look in this picture and |
|
| 36:06 | , terrible picture because you can see kind of goes off. But right |
|
| 36:09 | is the basement membrane you can see here it's really, really thick. |
|
| 36:13 | see those nuclei how happy the cells . And as you go further and |
|
| 36:17 | up, they get flatter and flatter flatter until you get up to the |
|
| 36:20 | and they look like little tiny Okay, that's why stratified multiple |
|
| 36:27 | A pickle layer, squamous and that's it gets its name. This is |
|
| 36:32 | cut through your epidermis. And so what you're looking at is the |
|
| 36:36 | Now there are two different types of squamous. And that picture is not |
|
| 36:42 | to matter. I'm not going to is it's characterized or non criticized. |
|
| 36:46 | . But your body has criticized cells non criticized. That term refers to |
|
| 36:51 | presence of keratin in those cells, . Remember what we said is a |
|
| 36:57 | of molecule that makes up these intermediate and it's a tough tissue or a |
|
| 37:04 | fiber. It's what makes up your . Your nails are made up of |
|
| 37:08 | . Your hair's keratin, your skin keratin. If you take your fingernail |
|
| 37:13 | run it across your skin it doesn't ripping off, does it? |
|
| 37:18 | You take your fingernails across the inside your mouth. You're gonna have a |
|
| 37:22 | conversation, aren't you? It's not tough on the inside of your mouth |
|
| 37:28 | . Your oral cavity, nasal anal cavity, vaginal cavity, |
|
| 37:33 | All those openings where you basically are moving into that donut portion of your |
|
| 37:41 | are covered with non christian ized They don't need to be as tough |
|
| 37:48 | the surface of your body does or skin does. Alright, so carotene |
|
| 37:54 | stratified squamous is on the surface of body. It will be a slow |
|
| 37:59 | and then eventually you get to these christianized and that's where the internal cavities |
|
| 38:04 | the same sort of appearance. But that tough protein in it. |
|
| 38:12 | The other stratified epithelium. You're not to need to identify the test. |
|
| 38:18 | need to be able to understand their . So I'm not gonna give you |
|
| 38:21 | picture of stratified columnar stratified Q. . That would be mean all |
|
| 38:29 | stratified cube oil is fairly rare. you're gonna have two layers of cube |
|
| 38:33 | cells and typically this is located in tissue. Stratified columnar is found in |
|
| 38:40 | very specific locations. And typically it's or two. I mean it's basically |
|
| 38:45 | cells stacked on top of each So you might have a kind of |
|
| 38:49 | square looking cell, but then you a tall columnar cells sitting on top |
|
| 38:53 | it. Alright, so this is to show you here. You can |
|
| 38:57 | if you look carefully, there's this structure. Can you see the round |
|
| 39:03 | ? Right? And then you can that right. There would be the |
|
| 39:06 | of that tube. And what you is 121212. These are those cute |
|
| 39:13 | idols. Same, here's another one will not have to identify but you |
|
| 39:21 | to understand what it is, transitional is a specialized type of stratified |
|
| 39:29 | Typically multiple layers of cube oil looking , but the external surface is unique |
|
| 39:37 | that those cells change their shape. you find this in the bladder. |
|
| 39:43 | your bladder is like a balloon. also kind of like a pleated |
|
| 39:48 | Guys are going, I don't know pleated skirt is but ladies, you're |
|
| 39:52 | smarter than the guys. Um And it does is as you fill the |
|
| 39:56 | , The pleated skirt kind of And then what you do now is |
|
| 40:00 | you have the bladder that needs to outward and what allows it to stretch |
|
| 40:05 | those cells because they go from a of a cube oil shape and they'll |
|
| 40:10 | out become a scream of shape and when you evacuate the bladder they go |
|
| 40:17 | into their original shape so they transition and forth between the different shapes. |
|
| 40:25 | you'll see cells that have two See if I can find one in |
|
| 40:30 | . Yeah, who knows? Probably there. Alright, so depending on |
|
| 40:35 | level of distortion of those structures and not just the bladder, but it's |
|
| 40:40 | ureter and urethra, which if you know those just yet, yuri throws |
|
| 40:44 | tube to the bathroom, from the . The your orders are the tubes |
|
| 40:48 | the kidneys to the bladder. So they're filling up, they stretch out |
|
| 40:52 | to accommodate the flow of the Yeah, clear. Yeah, |
|
| 41:02 | Yeah. Okay, so this is really good question and I don't want |
|
| 41:05 | dwell on too much. So just your hands down. I mean, |
|
| 41:07 | don't write this stuff down. so we define in very simple |
|
| 41:11 | cells have a single nucleus. Some cells, muscle cells for |
|
| 41:17 | is an example is a really good where the cells actually fused together and |
|
| 41:22 | nuclei for each of the individual cells around. And so when you see |
|
| 41:27 | by nuclear cell Mhm. If it's normal if it's a normal cell functional |
|
| 41:34 | because sometimes that would be bad, . It just basically sticks around. |
|
| 41:38 | end up with both nuclear and they contribute to the function of the |
|
| 41:42 | Other cells that do this are muscle . So every muscle in your body |
|
| 41:45 | off as a single tiny individual little . And they said, Hey, |
|
| 41:48 | know what? I think we're gonna out together and refuse. And then |
|
| 41:52 | you have two nuclear and for nuclear 50 nuclei. And so each |
|
| 41:56 | so these cells are incredibly long. my muscle cells start from here and |
|
| 42:00 | down there. So it's a very long sell. There's a fusion of |
|
| 42:04 | cells. So remember how we I'm back up even a little further |
|
| 42:09 | So remember at the beginning I said have about 300 different types of cells |
|
| 42:12 | the body. Everything we learned about . There is the basic of all |
|
| 42:18 | . But that specialization gives rise to kind of unique features like the multi |
|
| 42:23 | . Another one is the census show cells. Um and those are the |
|
| 42:29 | that when you're an embryo and your to implant in the uterus basically it |
|
| 42:34 | like a super blob that basically starts through tissue. And it's basically as |
|
| 42:39 | chews things up, it creates bigger larger cells. It's literally like the |
|
| 42:43 | . Yeah, you guys are too . You don't know what the blob |
|
| 42:45 | , 1950s movie horror movie scared the out of everybody basically. Someone film |
|
| 42:51 | going through little tiny models. It like the blob. Yeah, I |
|
| 42:59 | alive in the 50s. It's just used to have tv. We didn't |
|
| 43:03 | Youtube. So everything was in reruns the time on cable. So, |
|
| 43:07 | got to see everything. All Moving to the glands. Alright, |
|
| 43:14 | are two basic types of Glands in body. All right. Their job |
|
| 43:20 | to secrete materials. All right. , what is the secretion? It's |
|
| 43:24 | acquis fluid, meaning it's water plus . So, it will primarily contain |
|
| 43:29 | , but it can contain some other as well. An ex A Quran |
|
| 43:34 | versus an endocrine gland. Are the types. Exa Quran is I'm secrete |
|
| 43:39 | out of the body. Alright. going onto the surface of the |
|
| 43:45 | All right. So, typically what doing is we're going on the body |
|
| 43:48 | or into the cavities, right? into like the digestive track, which |
|
| 43:52 | be surface. And we're going to those based on their structure, which |
|
| 43:56 | what we're going to see here in a moment. Endocrine glands are what |
|
| 44:00 | going to ignore for right now. right. But they exist. And |
|
| 44:03 | some of them have origins from epithelial . These are the ones that produce |
|
| 44:11 | . Alright. They lacked duct So, an extra cleaning land because |
|
| 44:15 | secreted on the surface. There needs be a way to get that material |
|
| 44:18 | the surface. So it's gonna have duct endocrine glands are going into the |
|
| 44:22 | . So basically it's just a bunch cells that are associated with each other |
|
| 44:25 | they secrete into the extra cellular fluid gets picked up into the blood and |
|
| 44:30 | it goes to wherever it needs to . So, what we have with |
|
| 44:33 | endocrine gland is that we are internally into that extra cellular fluid. All |
|
| 44:39 | . Some are epithelial in nature. are neural in nature depending upon what |
|
| 44:44 | is. And it could be neural , which is where it gets kind |
|
| 44:47 | confusing. All right, We're gonna with the most simple one. And |
|
| 44:52 | gonna work to our more complex You can have glands are single |
|
| 44:56 | We call them magically uni cellular Alright, so these are scattered within |
|
| 45:03 | epithelial sheets. This is typically called goblet cell. Alright, there are |
|
| 45:09 | types, but the goblet is the common. All right. And they |
|
| 45:13 | their products simply by exhaust. Ditto . So, you can see here |
|
| 45:16 | are Colombia ourselves. Right? You see up there there's our cilia. |
|
| 45:21 | can see the mucus and the bad secreting all that mucus are those goblet |
|
| 45:28 | . Alright, so they're embedded in part of that epithelial sheet typically when |
|
| 45:35 | think of glands, we think of multicellular gland, which is more |
|
| 45:40 | Obviously if your one cell that's not complex how these multiple cellular glands form |
|
| 45:47 | basically you have your epithelium sheet or your sheet of epithelial cells. And |
|
| 45:52 | you do is you get this in nation that basically works its way down |
|
| 45:56 | forms as duct work. And then the bottom of the duct work is |
|
| 46:00 | place where the materials for that gland actually made. Alright, so here's |
|
| 46:05 | example. This is a very, complex one. This would be an |
|
| 46:08 | of a simple one. Or basically you're looking here at the bottom. |
|
| 46:13 | the simple one is just repeated multiple . It's much more complex one. |
|
| 46:18 | what you have is you have this portion and then what you'll have is |
|
| 46:22 | messiness. Okay, This is where going to be making the materials. |
|
| 46:28 | the secretary portion. The duct is how I conduct the materials out of |
|
| 46:33 | gland. When you get these larger , these larger gland works. What |
|
| 46:38 | gonna see is you'll see multiple And then at the end of each |
|
| 46:43 | the ducks are the little seen, a little tiny purple dots or whatever |
|
| 46:46 | that is. Are there at the . Alright, so the ducks are |
|
| 46:51 | and separating out each of these What you're doing is you have your |
|
| 46:55 | lobes and so that's connective tissue. you end up with like this lobe |
|
| 46:59 | structure, but the ducks are through everything is being conducted and there's some |
|
| 47:06 | that goes with this. Now I to apologize for the artist in this |
|
| 47:11 | because they apparently didn't give them really instruction. All right. And so |
|
| 47:16 | I want to point out here is terms of the nomenclature ascena versus um |
|
| 47:23 | or sorry, Al Viola versus to when you think of a tube, |
|
| 47:28 | of something that is uniform in Alright. When you think of Al |
|
| 47:32 | , I think of something that is rounded in shape. Okay, so |
|
| 47:37 | artist kind of does a good job it but in some cases he doesn't |
|
| 47:42 | quite a good job. Alright. I think it's a guy who did |
|
| 47:47 | . Maybe it was a woman. when you're classifying a gland and notice |
|
| 47:54 | we're trying to do is we're trying keep this very basic. The ducks |
|
| 47:57 | either gonna be simple or compound. what I want you to do here |
|
| 48:01 | I want you to focus in on path through which things are being |
|
| 48:06 | So here we don't really have a . Maybe you can call that the |
|
| 48:11 | here, That's the duck. They to color it differently. Alright. |
|
| 48:16 | there's a duck, there's a duck . A duck duck. I guess |
|
| 48:21 | a quack quack, but a tube . This is the duct. This |
|
| 48:27 | the duct really that should be the as well. That should be the |
|
| 48:30 | as well. So, the Right? The ducks are the path |
|
| 48:38 | which the material is going to be . The escena is what you find |
|
| 48:45 | the bottom. Okay, So that's the material is going to be |
|
| 48:51 | So you can have a simple like it doesn't branch or you can |
|
| 48:57 | a compound duct which branches and it branch multiple times. Artists did a |
|
| 49:04 | job. I can branch over there example and have multiple branches like |
|
| 49:12 | Alright, simple. No, no . When you get down to the |
|
| 49:18 | , you look at the shape of end of that tube. Is that |
|
| 49:23 | ending in a bulb? Or is ending like a straight structure? If |
|
| 49:29 | ends like a straight structure, like just the tube coming down and coming |
|
| 49:33 | an end, then that's referred to a tubular a sinus. If it's |
|
| 49:38 | to a bulb then it's referred to an Al viola Hasina's. So when |
|
| 49:44 | look at a gland, it can tubular or can be L. |
|
| 49:49 | Or in some cases if you have really, really complex glands, it |
|
| 49:53 | be two below Al Viola, meaning contains both. All right now, |
|
| 50:02 | important is that? The grand scheme things? Probably not terribly important. |
|
| 50:09 | understand that glands have different shapes and they share shapes. All right. |
|
| 50:16 | if you understand the definition when someone there goes other than the tubular al |
|
| 50:20 | complex gland, you're like okay I get it. You know its |
|
| 50:25 | Okay I get it. It's multiple where it gets interesting and weird. |
|
| 50:35 | here the method of secretion. So got these terms american african and |
|
| 50:42 | And what they refer to is how these cells secrete their materials? The |
|
| 50:46 | that's easiest, the one that's that can visualize and understand easiest is the |
|
| 50:52 | America is kind of what we've already describing basically. I make some |
|
| 50:56 | I put it in vesicles, vesicles serves as a storage depot for that |
|
| 51:01 | until it's called to be released and it moves that vehicle moves to the |
|
| 51:05 | of the cell, opens up and its material out into the surrounding |
|
| 51:09 | So whatever happened to me in that has now been secreted. That is |
|
| 51:16 | Now easy ones to think about. about your tear ducts. What are |
|
| 51:20 | tears like? Watery and slippery. ? Think about your salivary glands. |
|
| 51:27 | slippery. Yeah. Alright sweat glands like on the surface of your skin |
|
| 51:33 | here when you walk outside is your gonna become wet and moist, not |
|
| 51:38 | , It's just gonna be kind of slimy. Right? So this is |
|
| 51:43 | example of the american what the cell , it doesn't modify, it just |
|
| 51:49 | it as is The next two is it gets weird? The Quran gland |
|
| 51:56 | is basically what you see with mammary . So what do mammary glands |
|
| 52:00 | What's its secretion milk? Alright, , if you want to think about |
|
| 52:05 | cow, that's fine. But humans mammals. We produce milk. All |
|
| 52:12 | . What happens here is you make vesicles filled with materials and then when |
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| 52:18 | vesicles moves to the surface, it merge with the surface and release. |
|
| 52:22 | happens is that vesicles gets pinched off the portion of the cell that contains |
|
| 52:28 | . And so, what you end with is a larger vesicles that's basically |
|
| 52:32 | bubble containing the vesicles within it. right. And as you pinch off |
|
| 52:41 | of the cell, the cell actually itself. All right. So, |
|
| 52:45 | you're doing is you're letting go of of the cell plus the material that |
|
| 52:50 | cell is making as a broken holocron the weirdest of all. Okay. |
|
| 52:59 | now I want you to think about zits. Alright, The pores on |
|
| 53:04 | face. I want you to jump three years when it was the |
|
| 53:08 | Remember right there before the prom, big old volcano that erupted on your |
|
| 53:14 | . And you're sitting there going, can't I can't go out. I'm |
|
| 53:17 | freak. The reason that thing erupted your face is because of this type |
|
| 53:23 | cell right here. All right just in case you don't know, |
|
| 53:28 | have tons and tons of bacteria living your body. Right? I think |
|
| 53:32 | mentioned you have more bacterial cells in on your body than you actually have |
|
| 53:35 | number of cells in your body. right now living on your surface and |
|
| 53:39 | circulating, circulating around your body like is a cloud of bacteria. We're |
|
| 53:47 | clean and we go take a shower that's not gonna help. But you |
|
| 53:51 | bacteria living on your on your on skin. And the reason it's living |
|
| 53:55 | is because of the secretion of the cells. Holocron sells what they do |
|
| 54:00 | they make this material and they store up and it sits there and it |
|
| 54:05 | up and it builds up and eventually the cell produces enough of its material |
|
| 54:10 | the cell dies and it ruptures or and dies whichever way you want to |
|
| 54:15 | . And then all that material that in that cell gets released by that |
|
| 54:20 | and rupturing cell. Now typically this is very very viscous. This is |
|
| 54:26 | oil that your body is producing. the reason it produces it it's actually |
|
| 54:30 | a protective barrier of oils and waxes oils on the face to prevent bacteria |
|
| 54:39 | viruses and all sorts of things from the body. Right. But of |
|
| 54:44 | you have bacteria live on you and this is yummy. Good. And |
|
| 54:46 | what happens is is when that thing remember it's in a gland there's a |
|
| 54:51 | there and if it ruptures too much and it oxidizes or if you have |
|
| 54:55 | and stuff, you basically jam up hole, that duct and then that |
|
| 55:00 | gets stuck in there and then it of oxidizes and then it keeps other |
|
| 55:04 | keep rupturing and it fills up and up the next thing. You |
|
| 55:07 | you've got this thing that's sitting on face announcing its presence. So the |
|
| 55:17 | that produce the oils from your bodies holocron glands. They produce their material |
|
| 55:24 | then the cell dies and the new comes along and replaces it. Easiest |
|
| 55:30 | identify. Because that's kind of how think about secretion. Right? Mary |
|
| 55:37 | Quran Weird. one Location. Mammary , Holocron Gross and Disgusting. They're |
|
| 55:44 | ones that rupture themselves so far. good. All right then, that |
|
| 55:55 | us like through half the lecture. , what I want to do now |
|
| 56:00 | I want to shift gears away from . I want to move into connective |
|
| 56:04 | . Are you okay with that? guys are real quiet. I |
|
| 56:08 | I swear I need to bring something here that wakes you guys up. |
|
| 56:12 | a live possum to run through the make threats like this. I never |
|
| 56:20 | through with them. Alright, connective . Most widely abundant. Most available |
|
| 56:28 | of tissue. There's lots of different of connective tissues. Alright. So |
|
| 56:33 | you can kind of see the major . We're going to go through |
|
| 56:36 | All. All right, the primary when you think connective tissue is going |
|
| 56:40 | be protection and insulation. When we're about protection. That's a physical protection |
|
| 56:46 | it can refer to as immune Alright. They play a role in |
|
| 56:50 | and support. Which kind of makes because it's in their name. It |
|
| 56:53 | a role in storage. We'll see storage here in just a moment. |
|
| 56:57 | plays a role in transportation. it kind of has all this catch |
|
| 57:01 | . And really the truth of it is connective tissue. The reason that |
|
| 57:05 | group all these these tissues together, though they can be very very |
|
| 57:09 | is because they have a very similar biological origin came. So, it's |
|
| 57:15 | that very early on you start off as a single cell, you eventually |
|
| 57:19 | three layers of tissue and then those layers of tissues differentiate. And so |
|
| 57:24 | connective tissues come from one of those . Now, all connective tissues contained |
|
| 57:33 | it. A material called ground And it's just a fancy word to |
|
| 57:38 | say the stuff that makes up the . All right. It's basically non |
|
| 57:42 | material. It's made by the cells the connective tissue in which we're going |
|
| 57:47 | kind of focus in on and it's which it's the environment or the matrix |
|
| 57:52 | which that cell actually lives. So cell arrives and then it creates the |
|
| 57:57 | in which it's going to be found . And that's what it's That's that |
|
| 58:02 | substance. So the ground substance depending where you are and what type of |
|
| 58:06 | tissue looking at can have different Alright. It can be proteins like |
|
| 58:10 | see here. Right. And an cellular matrix that surrounds the individual |
|
| 58:16 | And these are all individual cells. right. So that's that's the most |
|
| 58:21 | type. But it can be something blood, blood. The plasma of |
|
| 58:25 | is an extra cellular matrix. It the ground substance that surrounds the blood |
|
| 58:31 | . It can be semi solid in like cartilage. We're going to see |
|
| 58:35 | this stuff or think about a A bone has is hard. And |
|
| 58:39 | it's not this squishy fiber looking It's basically a bunch of minerals plus |
|
| 58:45 | plus cells. So the environment, this extra cellular matrix is going to |
|
| 58:51 | unique for the different types of connective that you look at. Now. |
|
| 58:55 | of the characteristics is that it's going contain within it. These molecules that |
|
| 59:00 | called protease google icann's. So this the matrix. You've got these large |
|
| 59:06 | . You have these smaller fibers and protein google. I can is this |
|
| 59:11 | looking thing that hangs off the edge really what approach google icon is the |
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| 59:15 | that's bound up to a bunch of and the sugars are called gags. |
|
| 59:20 | the abbreviation glucose amino Bly. Can don't need to know it. But |
|
| 59:24 | it's a bunch of sugar and it's a charged sugar, it has a |
|
| 59:29 | of negative charges. So it attracts to it. So typically what you |
|
| 59:32 | imagine is in an environment like that you have these fibers and these pretty |
|
| 59:38 | cans with these sugars is that water gonna come to this area and it |
|
| 59:42 | this kind of spongy environment, it of holds things in place and it's |
|
| 59:50 | environment, this ground substance that holds connective tissue in place. So when |
|
| 59:56 | look at this picture right here and see this hollow space, it's not |
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| 60:02 | , it's filled with this stuff, and small proteins and sugars keeping everything |
|
| 60:09 | together. All right now with regard the cells. So we have fibers |
|
| 60:16 | we have ground substance, we're gonna to the fibers in just a moment |
|
| 60:21 | have cells. Now, every connective is going to have different types of |
|
| 60:25 | in it. But there are when dealing with many of these cells, |
|
| 60:28 | you're going to see is that there's primary cells that exist within the connective |
|
| 60:34 | . So you're going to see terms fibroblasts or fiber site whenever you see |
|
| 60:38 | at the end of a word, refers to an immature cell is a |
|
| 60:42 | that is still capable of division and become the mature cell yet. When |
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| 60:47 | see site at the end of the , then it's a cell that has |
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| 60:51 | the mature cell. So fiberglass is cell that's dividing and making a whole |
|
| 60:57 | of fibers and stuff And then when matures it becomes a fiber O site |
|
| 61:01 | it stops dividing. It still maintains matrix in which it lives. Fibroblasts |
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| 61:07 | fiber sites are finding connective tissue Condo blast contra sites are in |
|
| 61:12 | osteoblasts, osteo sites and bones. when you're looking at the connective |
|
| 61:16 | if you know what type of connective kind of know what type of cells |
|
| 61:21 | ? This primary. So if I'm at a bone, I know uh |
|
| 61:23 | primary cell found in bone is going be an osteoblasts and osteo sites. |
|
| 61:29 | right. I'm looking at connective tissue . It's like, oh, it's |
|
| 61:32 | to be fibroblasts and fiber sites. things like connective tissue proper have more |
|
| 61:38 | one type of cell on them. while the primary cell maybe fibroblast, |
|
| 61:43 | may also find parasites, parasites are the fancy word for saying fat |
|
| 61:48 | You might find mesenchymal cells. Mesenchymal are the the stem cell of all |
|
| 61:55 | of connective tissue cells you might see Eunice sites which is a fancy word |
|
| 62:00 | saying cells that are involved in the system. So lymphocytes, white blood |
|
| 62:05 | of all different types are lymphocytes. right. And these cells like immune |
|
| 62:12 | may kind of hang out for a while Or they may just be passing |
|
| 62:15 | like a cop on the beat is there anything going wrong in |
|
| 62:18 | Do I need to take care of and then it just kind of moves |
|
| 62:21 | its way. So depending on where looking, you're going to see multiple |
|
| 62:26 | of cells or you'll see a single of cell. The other thing. |
|
| 62:30 | we're gonna go back to this picture in the next slide I think is |
|
| 62:35 | going to see that the cells are in direct contact with each other. |
|
| 62:38 | when epithelial cells, all the cells jammed up against each other right |
|
| 62:43 | they're all kind of spread out and creating that matrix and they're all kind |
|
| 62:47 | hanging out together. But they're not talking to each other directly. They're |
|
| 62:51 | connected to each other. Now, might see a seller to connected to |
|
| 62:55 | other, but that's going to be a short period of time. They |
|
| 62:57 | separate themselves out from from each other , I mean by forming the |
|
| 63:04 | So we've come back to this picture I just want to show that to |
|
| 63:06 | . So here what they have a bunch of different cells that they've |
|
| 63:10 | labeled and again, you don't even which cells which because that's insignificant. |
|
| 63:14 | it's like, look, here's amazing sell, what do we have here |
|
| 63:17 | a immuno site that's a macrophage over . Those are fibroblasts. These two |
|
| 63:22 | are touching each other, but this way over here and it's not associated |
|
| 63:25 | those here we have a deep So we've got all sorts of different |
|
| 63:29 | of cells in this environment doing their little thing living within a matrix of |
|
| 63:36 | substance plus a whole bunch of Now the fibers found some basic |
|
| 63:45 | We have collagen That makes up about of your body's protein. You're mostly |
|
| 63:51 | . Lots and lots of collagen. . It's a very very long |
|
| 63:56 | It's on branch. It's very It's flexible, it's resistant to stretching |
|
| 64:01 | time. It begins to relax and start getting this stuff going on, |
|
| 64:05 | know. But when you're young and that collagen is nice and tight. |
|
| 64:12 | why you guys all look young and look old. Particular fibers are similar |
|
| 64:19 | collagen. Little cartoon draws them over . Doesn't again, doesn't matter. |
|
| 64:24 | fibers are coated with glycoprotein. So and lots of sugars. All |
|
| 64:30 | And what you do is you see these branch ing's within them. All |
|
| 64:34 | . So they create these massive networks there are many organs built solely on |
|
| 64:39 | fibers. So like your spleen for is basically a strom a a scaffolding |
|
| 64:47 | particular fibers on which cells are built they kind of just sit there and |
|
| 64:52 | you wrap them up in a little of other type of connective tissue to |
|
| 64:55 | everything into place. Particular fibers. elastic fibers. They have a specific |
|
| 65:01 | called elastin that's a shocking name for elastic protein in it. And what's |
|
| 65:07 | is is basically the stretch and You got this all over the |
|
| 65:11 | But here's an easy one. You see right bent my ear and watch |
|
| 65:16 | magic could do this all day. is just fun, right? It |
|
| 65:25 | for things to stretch and recall it . And so you'll see some of |
|
| 65:29 | stuff found in connective tissue as and which fibers are found where, |
|
| 65:34 | upon which type of connective tissue, at what its function is. Obviously |
|
| 65:39 | cartilage in my ear here has a of elastic fibers in it, |
|
| 65:45 | cartilage in my back. Not so so that gives rise to or ultimately |
|
| 65:54 | us to the different types. All . So, what we're going to |
|
| 66:00 | is we're going to see the name the group. So it's connective tissue |
|
| 66:04 | . And then we're going to see subgroup. For example, this is |
|
| 66:07 | loose connective tissue. And then we're to see the different types of loose |
|
| 66:11 | tissue. So, there's a primary kind of a subgroup. And then |
|
| 66:15 | unique type. So connective tissue When you think of connective tissue, |
|
| 66:20 | think of connective tissue proper. loose connective tissue implies. What look |
|
| 66:31 | the pictures. What do you What's unique about them? Are |
|
| 66:35 | Is everything jammed close together? Let's a look at the next picture real |
|
| 66:39 | . And then we'll come back. is dense connective tissue. Look at |
|
| 66:44 | connective tissue defense. Loose biologists are people. We name things for what |
|
| 66:53 | look like. Does it look Yeah. Okay. The first type |
|
| 66:59 | there in the top is called All right. Areola connective tissue. |
|
| 67:04 | can see It's the example that we . Alright, so connective tissue |
|
| 67:08 | Areola got all three different types of . You got a whole bunch of |
|
| 67:12 | cells, primarily fiber blasts in Alright. Its job is to support |
|
| 67:17 | surround structures and organs for the most . All right. Lots and lots |
|
| 67:22 | ground substance in their adipose tissue. think fell into this category because when |
|
| 67:26 | first start looking at adipose tissue under microscope, it looks like there's nothing |
|
| 67:32 | . Alright. But basically adipose tissue a loose connective tissue. There's a |
|
| 67:36 | of fat cells that are being pressed . So, where we had fat |
|
| 67:40 | sparsely scattered here. Adipose tissue has adipose cells. All right. And |
|
| 67:48 | can see there's this little nucleus pressed to the back that's its side of |
|
| 67:52 | . Here you have this big old vacuole in the middle of it. |
|
| 67:56 | it's mostly made up of fat and it looks like it's empty space. |
|
| 68:01 | why I think it was called Here's a particular You can see a |
|
| 68:05 | of particular fibers and little tiny cells here there and everywhere. Very, |
|
| 68:10 | loose. Looking at least the first top. And if you imagine the |
|
| 68:13 | doesn't appear there, that's why it loose again, connective tissue proper. |
|
| 68:19 | is dense connective tissue as opposed to . And you can see here we've |
|
| 68:24 | a series of fibers. All the themselves are compressed and very very close |
|
| 68:28 | is not a lot of space in everything. The cells are scattered |
|
| 68:32 | So the dark purple things you see least up here in the regular, |
|
| 68:36 | or dense regular is um they're kind scattered about. They're the ones that |
|
| 68:40 | laying down the fibers right? But very little ground substance to speak of |
|
| 68:49 | regular, dense irregular. Can you why they're named? These two things |
|
| 68:56 | are moving regularly in the same direction . It looks like someone just kind |
|
| 69:00 | scattered fibers in multiple directions but they're close together. And then the last |
|
| 69:07 | here is the elastic. And again you have here is these are elastic |
|
| 69:11 | that impressed close together. But there there's still that one type of |
|
| 69:18 | Typically you'll find the elastic um connective around things like um blood vessels. |
|
| 69:26 | So they'll be like a layer of type of connective tissue. So like |
|
| 69:30 | art. The easy one to think the aorta, it can stretch when |
|
| 69:35 | inside it is applied and then it back to its original shape naturally. |
|
| 69:44 | are three types of cartilage is so this is a type of supporting |
|
| 69:50 | tissue cartilage exists as highland elastic or cartilage. Now here you can see |
|
| 69:57 | cell is within a matrix that's semi . All right, there is the |
|
| 70:01 | and you can see here now what done is we've added in fibers. |
|
| 70:05 | the cells as well. And you see little tiny cells here as well |
|
| 70:08 | lots of fibers. So when you're with highland cartilage, you don't see |
|
| 70:13 | fibers. It's just basically the semi matrix and that the cells have created |
|
| 70:17 | themselves and they're now stuck or embedded that matrix. The cells are very |
|
| 70:22 | alive and they're doing the job of that matrix or building the matrix. |
|
| 70:29 | those are the cell types con dro to cartilage. So Condra blasts make |
|
| 70:34 | matrix and the cells are dividing and once they've made as much matrix as |
|
| 70:39 | possibly can, they become the Kandra and they hang out maintaining that |
|
| 70:45 | there's no blood vessels in this type connective tissue. All the nutrients has |
|
| 70:50 | pass through the matrix to get there cartilage has the elastin fibers, fiber |
|
| 70:57 | cartilage is have fibers. And this a little bit tougher. The idea |
|
| 71:00 | is to create support and stretch, though you don't want to have too |
|
| 71:06 | movement in it. Blood is the one. Alright. That's a fluid |
|
| 71:15 | tissue. It doesn't actually make the , The plasma is the matrix but |
|
| 71:20 | made by other things. It's water other stuff made by other things. |
|
| 71:23 | so what we have in the blood we have these things called formed elements |
|
| 71:28 | could call themselves but they're not quite cells. Rivera sights are cells that |
|
| 71:35 | been modified and removed much of their . They carry around oxygen for you |
|
| 71:42 | . So their immune insights, you see them. They're kind of marked |
|
| 71:45 | , red blood cells or all the stuff. Their job is part of |
|
| 71:48 | immune system and platelets are bits and of another type of immune cell are |
|
| 71:54 | immune cell, but another type of cell that's kind of hanging around. |
|
| 71:57 | their job is to create blood So the cells themselves have different |
|
| 72:03 | They don't make the actual plasma plasma made elsewhere. Now we'll come across |
|
| 72:09 | in A. And P. To lymph is basically the plasma of the |
|
| 72:13 | without the cells in it. And found in a different location and its |
|
| 72:18 | is far too complex to explain right , another supporting is bone or what |
|
| 72:25 | call odysseus tissue. It's very similar cartilage. The differences is that what |
|
| 72:29 | doing is we're putting uh minerals within matrix. So it makes that squishy |
|
| 72:36 | . Much much more tough, much resilient resistant to torque. And so |
|
| 72:41 | very, very strong. You can of bonus being dead but it's not |
|
| 72:47 | . It's actually very living tissue. these little dots that you see |
|
| 72:51 | those are cells that are stuck within bone matrix and they're keeping the matrix |
|
| 72:57 | . So when, what they do they sit there and they detect the |
|
| 73:01 | in the bone and they actually build as needed and when there's bone that's |
|
| 73:06 | needed, it breaks it down. your bones are being remodeled all the |
|
| 73:11 | . We're going to talk about this more detail when we talk about bones |
|
| 73:14 | the unit. So here we have . So those big circles right |
|
| 73:18 | those are canals within the bone structure these are the blood vessels and nerves |
|
| 73:22 | actually found. We're coming around the , we have a couple more slides |
|
| 73:30 | we're going to be done for the . Mhm. Any questions about the |
|
| 73:37 | tissues, You know, I think could get up here and just tell |
|
| 73:44 | guys lies and you guys are just your head. Here we go. |
|
| 73:47 | what I want. I want to a hand up. So, bone |
|
| 73:54 | is unique. It's basically the um stem cells. We're gonna talk about |
|
| 74:00 | a little bit more. There's two types of bone marrow and when we |
|
| 74:04 | about the Aussies tissue will go into lot more. Well, I'm not |
|
| 74:07 | see a lot more detail, but essence what it is, there's fat |
|
| 74:11 | there and then there are blood stem . And so the cells that make |
|
| 74:16 | become red blood cells or become the ist sites or become the mega carriers |
|
| 74:21 | , which give rise to the platelets found within that marrow. And so |
|
| 74:26 | you're younger, you have lots and of the marrow that consists of the |
|
| 74:30 | that make up the blood cells. as you get older, that gets |
|
| 74:33 | with the fat cells. And so basically stuck with less of those cells |
|
| 74:38 | you don't need them quite as You're not growing anymore. You don't |
|
| 74:41 | to make as much. And so it's not necessarily what we call connective |
|
| 74:46 | . We call it more of a a stem cell. Yeah. So |
|
| 74:52 | we talk about the hard parts of bone though, that's connective tissue. |
|
| 75:00 | , I promised you like one slide the muscles. Here's the one slide |
|
| 75:03 | the muscles. We've already seen this . And and really what I want |
|
| 75:06 | kind of show you here these are contract. I'll sell all right, |
|
| 75:11 | highly vascular rise. In other when you look at muscle, you're |
|
| 75:14 | see blood vessels go into the muscles that you can provide the nutrients of |
|
| 75:17 | materials necessary for them to do the work that they do, They produce |
|
| 75:23 | and depending on what type of cell gonna be the specific type of |
|
| 75:27 | So skeletal muscle causes local motion, muscle creates a pumping action to drive |
|
| 75:34 | forward vascular cherry also has smooth your digestive system, smooth muscle respiratory |
|
| 75:40 | and smooth muscle. And what you're there is you're creating movement of the |
|
| 75:45 | or the air in your lungs or through the digestive track. And so |
|
| 75:52 | different types of movements in different But whenever you think a muscle think |
|
| 75:56 | movement. All right. So, they contract is going to be dependent |
|
| 76:01 | the side of skeletal elements that we about When we talk about the site |
|
| 76:06 | skeleton and when we get to we'll go into more detail how it |
|
| 76:09 | happens in which elements are involved. that's the purpose of muscle movement. |
|
| 76:14 | there's three different types found in different and they do different types of |
|
| 76:24 | Half of this class is spent talking nervous tissue. All right. |
|
| 76:30 | we're only giving it a one slide right now. All right, nervous |
|
| 76:36 | or nervous tissue. Give it made of two basic types of cells We |
|
| 76:42 | . The neuron. The neuron is the quarterback of a football team. |
|
| 76:48 | pays attention to the neuron because exciting, interesting. Its job is |
|
| 76:56 | process information. It receives input and . It takes those signals and determines |
|
| 77:03 | response to the signals and then it and sends signals down to the cells |
|
| 77:08 | are responsible for creating the response. why nerves are interesting. Excuse |
|
| 77:14 | neurons are interesting. Glial cells are the rest of the football team, |
|
| 77:19 | the thing that makes the neuron look . Glial cells are the support |
|
| 77:26 | A quarterback can't throw passes if he no line blocking for him, he |
|
| 77:32 | make completions unless there's a receiver to the football. Glial cells support the |
|
| 77:37 | provide the nutrients tell the neurons which to go. They provide protection and |
|
| 77:44 | sorts of support for the neurons. , they don't actually transmit the signals |
|
| 77:52 | the nervous system is responsible for. if you didn't have these, they |
|
| 77:56 | do their job. All right. we'll break this down and go into |
|
| 78:00 | detail when we get to the nervous . Last three slides, I think |
|
| 78:08 | three sides might be four. last little bit is I want to |
|
| 78:12 | about tissue repair. Yeah, there two major ways in which tissues repair |
|
| 78:21 | . Now, these last couple of are really kind of focusing in on |
|
| 78:26 | epithelial repairs itself. But this type repair is true for all tissues. |
|
| 78:32 | ? You can either repair through a of regeneration or you can repair through |
|
| 78:36 | process of fibrosis regeneration is where you the damaged tissue and you replace it |
|
| 78:44 | the very same tissue fibrosis and in so, what you're doing is you're |
|
| 78:48 | restore the function of whatever the organ that was damaged. Fibrosis, on |
|
| 78:53 | other hand, is where connective tissue where the lost tissue was. And |
|
| 78:58 | what you end up with is that material that can't do the job that |
|
| 79:03 | organ originally did. Alright, you structural restoration but you don't get functional |
|
| 79:09 | restoration. Now again, we're gonna primarily with dealing with damage in the |
|
| 79:15 | here. But I want to give example of a student I had after |
|
| 79:19 | gave this lecture, he came up couple of years ago, he said |
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| 79:22 | wayne when I was much younger, got hit in the head with an |
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| 79:27 | . I was like dude really? like yeah, no. And I |
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| 79:31 | he said what happened to my brain that happened right because it went in |
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| 79:37 | don't know if it was like a or if it was an access but |
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| 79:40 | said what happened with that tissue Because nervous tissue is a tissue that |
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| 79:46 | regenerate very well. It can but very difficult. I said, well |
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| 79:52 | those glial cells play a role in and they basically create an environment similar |
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| 79:59 | fibrosis. What they do is they in and where all those cells |
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| 80:03 | you now have empty space, you have empty space. And so what |
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| 80:06 | cells do is they grow into it they create this fibrous tissue. And |
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| 80:10 | wherever that acts went in is now you have and then the neurons around |
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| 80:14 | kind of took over the jobs that in that space. But I tell |
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| 80:19 | that story, so that, you , it's not just the skin that |
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| 80:23 | happens if you have a heart attack , die fibers, tissue grows in |
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| 80:27 | and replaces or fills in that gap those dead cells were you no longer |
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| 80:34 | cardiac cells there. So it's struggles contracting now because it no longer |
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| 80:40 | its full um network or or structural function that used to have. But |
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| 80:48 | does play a role now, depending where you are. You know, |
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| 80:51 | going to see different types of tissue in different types of severity. |
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| 80:55 | for example, if you've ever cut , you can see that you don't |
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| 80:58 | a scar sometimes. But if you a really, really bad cut, |
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| 81:01 | end up with scars is actually That's not a real scar, I |
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| 81:08 | it was and I really looked it and it was for a movie kind |
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| 81:12 | bombed finding that out. So, on the type of tissue damage and |
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| 81:17 | type of severity is gonna depend on path you're going to use, whether |
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| 81:21 | gonna use just regeneration or you're gonna regeneration, fibrosis or just fibrosis, |
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| 81:26 | that's gonna be. So, what wanna do is I want to use |
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| 81:28 | uh this example from the epithelium to of show you what the basic steps |
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| 81:33 | wound healing looks like. Alright, this is the skin, the first |
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| 81:39 | is going to be an inflammatory response what the inflammatory response is, is |
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| 81:44 | when tissue damage occurs, the tissue starts releasing chemicals to attract in immune |
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| 81:50 | into that site. Alright, and , why are you attracting immune |
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| 81:54 | You can think of it as the or the police force going, |
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| 81:57 | we know problems are occurring here, here to deal with whatever is going |
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| 82:01 | be problematic. And so the immune are there to basically attack foreign material |
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| 82:07 | might be in where that damage has . Now, the other thing that's |
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| 82:13 | happen is that the cut comes all way down to the blood vest. |
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| 82:16 | basically what that's gonna do is blood into that wound and helps wash out |
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| 82:21 | and push things away. All And so, you can imagine here's |
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| 82:24 | cut. I want to see if shows it over here. Now, |
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| 82:27 | the cut. You can imagine blood out and it basically filled in this |
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| 82:32 | , pushed materials out, but also a cap to prevent materials from coming |
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| 82:38 | . That's what the clot serves as kind of a barrier. It's a |
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| 82:41 | band aid to say, you can't in here, we're gonna be working |
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| 82:46 | fixing the problem that just happened in space. The other thing that inflammation |
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| 82:52 | is that basically it draws fluid in so fluid is moving towards the wound |
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| 82:58 | of away from the wound instead also of traps material in that particular |
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| 83:03 | Right. So basically, if you're to swim upstream, it's a lot |
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| 83:06 | than swimming downstream. Um If the was moving away. All right. |
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| 83:12 | the clotting proteins and the stuff come as a result of the blood opening |
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| 83:17 | that wound you create that clot, now becomes step two and that basically |
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| 83:22 | the tissue. And now the immunity can start doing their work. They're |
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| 83:26 | for anything that isn't supposed to be . So damaged tissue isn't supposed to |
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| 83:30 | there. It'll start breaking down the tissue, foreign materials, bacteria. |
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| 83:34 | else? It'll start trying to break and destroy. The next step has |
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| 83:43 | do with rebuilding all right. And , what we're going to see is |
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| 83:48 | gonna start making new blood vessels penetrate that area. This is a process |
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| 83:53 | angiogenesis. Angiogenesis ensures that we can the nutrients and the materials necessary for |
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| 83:59 | rebuilding of that area. And so why we end up with this. |
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| 84:04 | angiogenesis, the cells of the connective , the fibroblasts will begin dividing and |
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| 84:11 | start creating a matrix around which things going to be built on this is |
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| 84:17 | granule ation. Alright, so granule is rebuilding the tissue in this |
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| 84:23 | Now notice we're in this picture. we're looking at the skin. So |
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| 84:25 | here, this connective tissue up there epithelium. Alright. And you can |
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| 84:31 | we got cells that are working in area as well. Have you ever |
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| 84:35 | that your scabs don't stick around for long time. Even when you don't |
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| 84:39 | at them, Let's face it, all pick out our scabs, right |
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| 84:43 | like? And then what do you ever done that? Yeah, I |
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| 84:52 | the smiles on your faces like. . Yeah, I'm guilty, |
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| 84:54 | But if you left your scab it's a short term band aid for |
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| 85:00 | problem. It will break down on own. There are actual chemical elements |
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| 85:04 | it that are designed to break it so that your skin can reform |
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| 85:11 | When we're dealing with skin we're dealing the epithelium. That's epithelial regeneration. |
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| 85:16 | the epithelium as that scab breaks down epithelium not seeing epithelial cell next. |
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| 85:22 | will continue to grow until it finds cells underneath it. The fibers tissue |
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| 85:30 | organized. So basically the you you initially create these graduations. You |
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| 85:35 | this idea and then afterwards it's okay let's make this as best we |
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| 85:39 | based upon what the original structure should like and that's what happens. That's |
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| 85:46 | of that fibrous tissue now different areas gonna have different speeds. You know |
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| 85:53 | a typically it's a pretty slow process if it's a little tiny cut, |
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| 85:56 | doesn't take all that long. You , just a couple of days it's |
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| 86:00 | deeper wound, it's gonna take longer tissues, different timescales, but those |
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| 86:06 | basically the four steps, right? simple inflammation formation of a clot that |
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| 86:11 | be internal or external. It can angiogenesis and granule ation as well as |
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| 86:16 | final regeneration and re formation of the . The fibrosis. Yes sir. |
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| 86:35 | so that's a good question, which don't really know the answer to. |
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| 86:39 | mean with with plastic surgery and us and um orthopedic surgery very often what |
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| 86:45 | doing is you're breaking things and reshaping to meet some sort of of |
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| 86:51 | right? So for example, like know, let's say you're doing a |
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| 86:57 | , you know, or a tummy . What you're doing is you're cutting |
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| 87:00 | away and creating damage. But then you're doing is you're reshaping things and |
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| 87:06 | you know, like with a tummy , you're bringing tissue that should be |
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| 87:09 | back together and saying I want you reform this way, right, let's |
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| 87:14 | for example uh rhinoplasty which would be know reshaping your nose, you're damaging |
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| 87:21 | and bone and then reshaping it and allowing the natural uh function of tissue |
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| 87:29 | to then go back and and form shape that you're trying to achieve. |
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| 87:34 | is why they're very very skilled uh know um forms of medicine I |
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| 87:43 | I mean all medicine is skilled in way, shape or form. But |
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| 87:46 | mean here it's artistry, right? saying I'm expecting this to look like |
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| 87:50 | based upon the damage that I do the first place. But think about |
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| 87:55 | cut that's that's really the more important , you know, a wound, |
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| 88:00 | ? It will naturally repair itself in way that best suits it. If |
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| 88:04 | break your arm and don't reset it's going to reform and regenerate |
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| 88:11 | If you take the bones and breaking that, it's gonna reform like |
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| 88:14 | But it's going to use these sorts processes along the way. So did |
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| 88:18 | answer the question or did I kind skirt skirt it? Okay, well |
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| 88:27 | , so in the long what you think about is we're taking advantage of |
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| 88:31 | way that the body normally repairs we're just forcing it to repair |
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| 88:35 | At least in the in the in instant that you're describing it's repairing itself |
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| 88:41 | in the best way that it can upon the conditions that we set it |
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| 88:46 | , right? It's like I'm so when we go break a |
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| 88:49 | the first thing we do is we to the doctor and they reset the |
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| 88:53 | so that it can be as best it can. My child fell at |
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| 88:57 | broke both his own and the radius actually broke through, you know, |
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| 89:02 | it was at a like this, know, I mean if you look |
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| 89:05 | his arm, it was like a right? Because the bones broke that |
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| 89:09 | We took him to the doctor and were like, Okay, we got |
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| 89:10 | within 5° of its of its normal , it will repair itself. And |
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| 89:16 | all you gotta do is as you it, then the body does takes |
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| 89:19 | and does this process of tissue repair bone is a tissue. And when |
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| 89:24 | first start off it looks pretty weird strange. But with bone which we're |
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| 89:29 | to learn about a little bit bone actually remodels itself based upon the |
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| 89:33 | that you give it. So, will work its way in such a |
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| 89:36 | so that you can do the job you're originally trying to accomplish. |
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| 89:44 | Last two slides. Sorry. I know it's the last two |
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| 89:47 | Maybe just one slide. No, slides. Sorry. All right. |
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| 89:51 | is the really easy part then. done. And I'm sorry. I |
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| 89:54 | you are sitting there going, he's keep going to the No, that's |
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| 89:57 | my job. I don't want to here the whole time. Words that |
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| 89:59 | need to know. All right, . Say it with me apoptosis. |
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| 90:04 | , so, notice how I said not apoptosis. I had a professor |
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| 90:08 | you said that in the talk, would stand up and abuse you verbally |
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| 90:14 | you did so. So, it's important to me. Apoptosis. |
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| 90:18 | Apoptosis is cell suicide. It's a . Cell death. This is when |
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| 90:22 | cell is told you're not doing what want you to do or we're done |
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| 90:27 | with you or whatever you need and need to go die in a controlled |
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| 90:31 | so that you do not cause harm the rest of the body. And |
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| 90:34 | cell says, okey dokey. And does so Alright. This is how |
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| 90:39 | body removes damage or unneeded tissues in body when you were developing. Each |
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| 90:45 | every one of us had webs between fingers notice you do not have them |
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| 90:50 | because those cells disappeared through the process apoptosis. All right, autopsy autopsy |
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| 91:00 | a process of cell eating again. is a way to break down damaged |
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| 91:06 | or other biomass or biomolecules inside the . It's a controlled way of removing |
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| 91:12 | cells so that it doesn't release its and cause harm to the cells around |
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| 91:16 | . All right. So, that's that term means. So, apoptosis |
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| 91:23 | dealing with the whole cell autopsy. is a process occurring within the cell |
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| 91:30 | three terms. Atrophy. Atrophy is an organ decreases in size as a |
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| 91:37 | of lack of normal use or Typically you can think of a muscle |
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| 91:42 | I don't use a muscle that muscle smaller and weaker. That's atrophy. |
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| 91:49 | . It's true for any organ Alright. Any organ that doesn't get |
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| 91:53 | is going to not waste time and keeping that organ the same size. |
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| 91:57 | going to shrink it down the opposite atrophy is hypertrophy. Hypertrophy is when |
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| 92:04 | gets larger in size as a result overstimulation. First Cadaver I ever dissected |
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| 92:12 | a 40 year old smoker. And we cut her open, she had |
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| 92:15 | heart that was twice her size that was. And her lungs were all |
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| 92:21 | and nasty and stuff. But they also out of shape as well as |
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| 92:26 | size of the liver. So we cardio meagley and pato mega lee and |
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| 92:32 | omega li which were the result of systems. Having to overwork because she |
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| 92:36 | a chain smoker. All right over . Now you can think if I |
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| 92:43 | work out and exercise, what am doing creating hypertrophy? That's okay. |
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| 92:48 | not a bad thing. Hypertrophy is in some situations. It's bad in |
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| 92:52 | situations. Another term hyperplasia is typically term we think of. When we |
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| 92:58 | of cancer cells, hyperplasia is accelerated rate of growth of a |
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| 93:04 | So when cells are dividing very very we call that hyperplasia, it can |
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| 93:08 | normal. So, for example, puberty, hyper plastic cells are normal |
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| 93:14 | you're 70 years old and you have tumor growing growing in you hyper plastic |
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| 93:19 | are bad, not normal. All . But it just refers to the |
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| 93:25 | or growth of the cells in terms number. This is growth size of |
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| 93:32 | cells to create that larger structure. this kind of shows you bigger |
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| 93:37 | Same number, same size sells more them one week. Done what |
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| 93:49 | No. Damn it, stem cells , stem cells very, very basic |
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| 93:57 | cells are cells that are capable of many different types of cells. They |
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| 94:01 | mitosis activity. They can divide an a symmetrical method, meaning that when |
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| 94:08 | divide to create a cell that's a that looks exactly like them. So |
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| 94:11 | can keep the process going or what and the other cell then continues on |
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| 94:16 | the pathway down to that specialized self . The other type is that you |
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| 94:22 | these daughter cells that are unique and so they can actually both go back |
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| 94:26 | or they can both go this It just depends. Alright. But |
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| 94:30 | two daughter cells look exactly the same here they don't look the same. |
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| 94:35 | why it's asymmetric. Alright. Um stem cells are just simply the cells |
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| 94:40 | give rise to the other type give to cells in the body. Um |
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| 94:45 | for example when we're talking about the at the basal layer, those are |
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| 94:50 | would be the example of the stem . They're already committed towards becoming uh |
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| 94:55 | um skin cells but they are able divide in this way. They're basically |
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| 95:04 | and on this way, whereas you're one behind to keep that pool going |
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| 95:08 | if they all went this way then would end up with no skin |
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| 95:13 | There we go anymore. Stupid slides Okay. I know. Yes |
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| 95:26 | Look out. How do you how you why do your cells get bigger |
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| 95:38 | you work out? Is that the ? Okay, so the thing is |
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| 95:47 | that your muscles r really um you actually increase the number of cells. |
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| 95:53 | as you're growing you're increasing number of that you have. But then once |
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| 95:56 | stop growing the number of cells in muscle don't necessarily increase. There can |
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| 96:02 | but that's not that's a few and between really. What you're doing is |
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| 96:07 | actually increasing the size of the So you're actually doing hyperplasia. And |
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| 96:12 | you're doing is we're gonna see when look at muscles that there's this this |
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| 96:15 | side of skeleton makes up the majority the cell. And what you're doing |
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| 96:19 | you're increasing the number of fibers so the cell gets bigger and bigger and |
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| 96:24 | , Right? So the cell itself expanding and since you have so many |
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| 96:28 | , they'll expand together. And that's you get bigger and stronger and the |
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| 96:32 | part as a result of if you of the side of skeleton as a |
|
| 96:35 | of ropes, you know? And you're pulling on one side. So |
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| 96:39 | you think if I had more I'm able to pull more with greater |
|
| 96:43 | ? Yeah. Yeah. You're Yes. So earlier you mentioned that |
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| 96:49 | , you know like this is on face or like from |
|
