| 00:01 | Good. There we go. Good campers. How are we doing |
|
| 00:06 | Aren't we? Glad we're not living Dallas where it's actually colder than this |
|
| 00:13 | freezing. Um All right. So , what we're gonna do is we're |
|
| 00:18 | to continue our discussion about the heart probably in the reading, you saw |
|
| 00:22 | horrible graph, right? It was big massive graph and it had like |
|
| 00:27 | the E. K. G. it or the E. C. |
|
| 00:29 | . On it. It had pressure volume and heartbeat. And uh did |
|
| 00:33 | see that that graph show up? you guys like look at it? |
|
| 00:36 | not gonna learn this and just kind skipped on. Yeah. Uh if |
|
| 00:40 | learn that you've learned everything you need know about the heart but were afraid |
|
| 00:43 | ask. So we're going to cover today. Um as part of our |
|
| 00:47 | and we're going to stop being afraid graphs. Because graphs are awesome. |
|
| 00:52 | tell us everything we need to know it makes life a lot easier for |
|
| 00:56 | . But before we do that, we're gonna do is we're gonna start |
|
| 00:59 | understanding what's going on with regard to electrical activity. We started or we |
|
| 01:04 | on thursday today is Tuesday. Okay. I don't never know what |
|
| 01:11 | it is. All right. On . We talked about these action |
|
| 01:16 | Right? And these action potentials are electrical initiators of the contraction, lack |
|
| 01:22 | a better term. So we had two different types of action potential. |
|
| 01:26 | had action potential that was for the rhythmic cell and that is what serves |
|
| 01:31 | the electrical signal to activate the action in the contract. I'll sell and |
|
| 01:36 | the contract. I'll sell that contract make the heart go thump thump. |
|
| 01:39 | , Well, good with that. right. So, what we're gonna |
|
| 01:42 | now is we're going to take that example because when we talk about an |
|
| 01:45 | potential, we're really talking about what's on inside one little cell and your |
|
| 01:50 | isn't one little cell. It's how cells? The answer is lots. |
|
| 01:55 | . And so, what we are is we're now looking at the heart |
|
| 01:58 | a whole. And what we're gonna is we're going to see that there's |
|
| 02:02 | conduction system, basically a bunch of wiring. All right now, it's |
|
| 02:07 | electrical wiring. 1 2. This not a nerve system. This is |
|
| 02:12 | muscular conduction system. Alright, whenever you look at any sort of |
|
| 02:17 | textbook, you're gonna see three different . We've talked about red and |
|
| 02:21 | right? Red is oxygenated blood. represents deoxygenated blood, except in certain |
|
| 02:26 | when the author gets all funky and , but usually you'll see a third |
|
| 02:30 | , which is yellow and yellow usually nerves. And so when we talk |
|
| 02:34 | the conduction system, they draw yellow throw this to talk about this conduction |
|
| 02:40 | . It is not nerves. All . These are the auto rhythmic cells |
|
| 02:46 | to each other, creating this network looks kind of like a nervous |
|
| 02:51 | And it's not all right. And we're seeing in this particular picture is |
|
| 02:55 | four basic areas that are part of conduction system. Alright. The first |
|
| 03:01 | called this, the sino atrial Then we have the atrial ventricular |
|
| 03:08 | And then we have the bundle of named after the guy that discovered |
|
| 03:12 | And then finally we have the per fibers. And those are the four |
|
| 03:16 | that serve as this conduction system. so what we're going to see in |
|
| 03:20 | rhythmic cells using this as a way tell each other it's time to |
|
| 03:25 | And then that when that's electrical passes all the terrific cells and they're passed |
|
| 03:30 | to the contract. I'll cells that up the rest of the heart. |
|
| 03:33 | can see in the picture what the of the heart looks like. |
|
| 03:36 | So the essay notes, these are specialized region found in the upper right |
|
| 03:43 | wall. Alright. And what we're to see here is that's there and |
|
| 03:48 | connected to the next one in The A. V. Node. |
|
| 03:51 | A. V. Note or atrial node is located at the cross. |
|
| 03:56 | when remember we drew the heart? our artistic endeavor how perfect and beautiful |
|
| 04:00 | heart was right where that cross where it separates the two hr from |
|
| 04:04 | two ventricles that septum. Remember we service between the atria and ventricles as |
|
| 04:10 | dividing line to prevent the electrical activity the atria to affect the electrical |
|
| 04:15 | The ventricles. The A. Note sits at that juncture so that |
|
| 04:19 | electrical activity of the atria can pass and down to the ventricles. So |
|
| 04:25 | the only point of of electrical conduction the two areas and then down through |
|
| 04:31 | middle of the ventricular septa. That where you're gonna see the bundle of |
|
| 04:35 | . And it actually divides into two . Because what we're gonna do is |
|
| 04:39 | gonna work our way down to the . And then we divide into a |
|
| 04:42 | bunch of bundles that then spread around outside walls of the ventricles. And |
|
| 04:47 | last little bit are the perkin gee . Right? So S. A |
|
| 04:52 | , a B node bundle of and then on the edges per kenji |
|
| 04:56 | . That's the anatomy of this. right. So if you remember that |
|
| 05:00 | , you're probably in good shape. right. So of all these the |
|
| 05:05 | important in terms of governing the electrical through the heart is the S. |
|
| 05:10 | . Node. Now each of these . Remember our auto rhythmic cells. |
|
| 05:15 | it doesn't matter if you look at A. V. Note, kenji |
|
| 05:18 | is a bundle of hiss or the . A note. I notice how |
|
| 05:20 | put them all out of order. each contain auto rhythmic cells and auto |
|
| 05:25 | cells naturally D polarized, going you down to that bottom and slowly d |
|
| 05:32 | de polarizing faster, Get to that and come right back down and just |
|
| 05:37 | . So they are a natural pacemaker . But of all of these four |
|
| 05:43 | , it's the S. A node governs the rate of electrical conduction through |
|
| 05:48 | system. Alright, So each of have their own rate. And the |
|
| 05:53 | that most books kind of explain is think of a train, a big |
|
| 05:56 | train. And the big long train engines at the front of the train |
|
| 06:00 | engines all work together to pull the train. But if the first engine |
|
| 06:05 | , you still have three other engines pull the train. And so each |
|
| 06:09 | can do the job of the A. Node. But because the |
|
| 06:11 | notes on the front end, it's for governing at all. That kind |
|
| 06:15 | makes sense, sort of terrible illusion it doesn't explain some of the weird |
|
| 06:22 | that are going on the heart. that's the idea. All right. |
|
| 06:26 | the idea is if you somehow damage S. A. Node, |
|
| 06:30 | don't worry, you still have other , I'll cells that are responsible for |
|
| 06:37 | the heart rate and the heartbeat. ? And so the next one in |
|
| 06:42 | would take over. All right. if the S. A note fires |
|
| 06:47 | signal is then gonna be conducted down the A. V. Node which |
|
| 06:50 | fires which conducts it down to the of his which fires which conducts through |
|
| 06:55 | park in the fires which all fire the path or the pattern that we're |
|
| 06:59 | to see. So what is actually on? All right. So we |
|
| 07:06 | to follow this path from the A note down through these structures. |
|
| 07:10 | the first thing we're going to see the S. A. Node fires |
|
| 07:13 | those auto rhythmic cells are going to and send their signals in two different |
|
| 07:19 | . The first direction is going to across from the right atrium over to |
|
| 07:24 | left atrium and this is referred to the inter atrial pathway. And what |
|
| 07:29 | trying to do is we're going to to excite all those contract I'll cells |
|
| 07:33 | make up the two atrium because we them to contract at the same time |
|
| 07:38 | we said is we have a heart is a two pump system. So |
|
| 07:42 | want to pump blood from both a into both ventricles at the same |
|
| 07:47 | And so the activation of the A. Node ensures that this occurs |
|
| 07:51 | both will go thump at the same . So far. So good, |
|
| 07:55 | easy. Alright now, following atrial , we would like the ventricles to |
|
| 08:01 | and so we want our signal to from the atria to the ventricles. |
|
| 08:05 | so the second pathway is the inter pathway and hear the signal is going |
|
| 08:10 | the S. A node down to the the note is located, hence |
|
| 08:15 | name or inter nodal. So what doing is we're setting it up so |
|
| 08:19 | the both atria contract first inter atrial . And then we're sending a signal |
|
| 08:24 | that we can set up and get ventricular pathway or the ventricular muscle to |
|
| 08:29 | ready to contract. And that's what picture is trying to show you. |
|
| 08:34 | I've kind of put arrows here, of represent that we're going in this |
|
| 08:37 | to help this one contract with And we're moving the signal down to |
|
| 08:40 | A. V. Note which is in that septum so that we can |
|
| 08:43 | the signal further onward. So that in the international pathway gets down to |
|
| 08:52 | A. V. Node. Now the A V. Node responds a |
|
| 08:57 | slowly. Alright, It's what's referred as the A V nodal delay. |
|
| 09:02 | , what we're doing here is we're that the atria contract. We don't |
|
| 09:07 | the atria to contract and be in middle of contraction to start the ventricular |
|
| 09:11 | because now you're creating a path of instead of a path of reception. |
|
| 09:18 | kind of makes sense. In other , if there's pressure that's opposing the |
|
| 09:23 | of blood into the ventricle then you're gonna move blood into the ventricle and |
|
| 09:28 | a bad thing. All right. the idea here is the A. |
|
| 09:31 | . Note. The A. Node basically receives its signal and twiddled |
|
| 09:35 | thumbs for a second, right? it kind of sits there and |
|
| 09:38 | alright, I'm gonna wait for the to begin its contraction before I send |
|
| 09:45 | signal down to the next structure which be the bundle of his. |
|
| 09:50 | And so this allows for the complete polarization. So all the cells of |
|
| 09:54 | atria receive their signal and then they to contract. And that allows for |
|
| 09:59 | contraction occurs. So that blood which be in the atrial be pushed into |
|
| 10:03 | ventricle. And then that signal is go to the ventricles. So from |
|
| 10:10 | A. V. Node and there's lot of words up here. But |
|
| 10:12 | worry about that. Now, what can see is that we go from |
|
| 10:16 | A. V. Node right down bundle of hiss and there's nothing slowing |
|
| 10:19 | down now, it's just basically gets to the apex and those fibers spread |
|
| 10:23 | becomes the fibers and then the signals up and around the edges of the |
|
| 10:28 | muscle. All right now, what doing here is we're basically spreading an |
|
| 10:33 | signal as fast as we can to many cells as we can. |
|
| 10:37 | Because you remember there are more cells the ventricle than there are in the |
|
| 10:42 | in terms of muscle cells. And so we want to get that |
|
| 10:46 | as fast as we can because we so many more cells to talk to |
|
| 10:50 | we want to ensure that they're all communicated with almost simultaneously so that they |
|
| 10:54 | contract simultaneously. One the two ventricles . But we want to ensure that |
|
| 11:00 | actually get a really strong contraction because want to propel blood out of the |
|
| 11:04 | either to the system or up to lungs. All right now the the |
|
| 11:09 | are a bit more organized than what see in the inter atrial pathway or |
|
| 11:15 | the international pathway. It's they're basically bunch of of not contract I'll cells |
|
| 11:21 | the auto rhythmic cells and they're all to each other in rows. So |
|
| 11:25 | be like me passing going here, do this and then you take another |
|
| 11:29 | over here and passing over here and it starts passing to everybody. And |
|
| 11:33 | if you can imagine only 1% of cells being ought arrhythmic and the other |
|
| 11:37 | are contract. I'll eventually, everyone's get it. But if you spread |
|
| 11:42 | those pathways through everybody, then the is going to get out a lot |
|
| 11:47 | . That kind of makes sense. that's what's going on with the fibers |
|
| 11:52 | the bundle of his. So let's it down quickly and then the let's |
|
| 11:55 | it out to as many cells as possibly can. And those auto rhythmic |
|
| 11:59 | get that signal they send it off then the contract cells start receiving the |
|
| 12:03 | and then when they receive that signal produce their actual potential. Which is |
|
| 12:07 | cause both ventricular muscles, both in left and the right. To contract |
|
| 12:12 | same time so that they can push blood out. Alright. So I |
|
| 12:16 | a lot of words to explain That was pretty simple. All |
|
| 12:20 | So in terms of electrical activity, rhythmic cells are this pathway. S |
|
| 12:26 | note to a V. Node, ? S a note over to the |
|
| 12:30 | atrium so that both atria contract a nodal delay waiting for the signal to |
|
| 12:36 | a contraction down the bundle of his through the fibers. Then the ventricles |
|
| 12:42 | . Alright, pretty straightforward. I believe I spent that much time talking |
|
| 12:47 | it. All right now you're probably familiar when we talk about electrical activity |
|
| 12:54 | this picture. If you've watched enough of tv shows you've seen the machine |
|
| 13:00 | goes peeing. All right. That's what monty python referred to it |
|
| 13:04 | the machine that goes ping beep, , beep beep beep beep. Somebody |
|
| 13:08 | there with an intubation tube in their . All these doctors with worried faces |
|
| 13:13 | them saying horrible things and then beep in the background. And you see |
|
| 13:17 | little dude. Alright. For those you who are planning on this |
|
| 13:23 | you will never see a picture as as what you see in the |
|
| 13:27 | All right. What you're looking at is the E. C. |
|
| 13:30 | Alright. It stands for electro Alright. And what this is is |
|
| 13:36 | recording of the electrical activity of all muscle cells in the body. Or |
|
| 13:42 | the body, But in the heart now it's a representation, it's not |
|
| 13:47 | actual direct recording. Um This picture do an incredibly good job of showing |
|
| 13:53 | where the leads are. So what do is they will put leads on |
|
| 13:56 | two wrists, one on one of legs and they put like six leads |
|
| 13:59 | around the heart. And it's kind like what you would do is if |
|
| 14:04 | guys we all watch the football even if you weren't interested. Have |
|
| 14:07 | watched a football game? Yeah. you noticed like in a football game |
|
| 14:12 | you have multiple angles on the When it happens? Like for |
|
| 14:16 | if there's a controversial play, you , they stop and they go to |
|
| 14:21 | and then the announcers make all sorts inane comments because they're experts, you |
|
| 14:25 | ? And then they show you a from this side and they show you |
|
| 14:28 | view from that side. They show a view from this side. View |
|
| 14:30 | this side And people up in new are usually and they're watching up in |
|
| 14:35 | york are they are they really watching new york? Or is it just |
|
| 14:38 | randomly saying stuff? I don't But the idea is they're all watching |
|
| 14:42 | play from a different angle and you make or break a play based on |
|
| 14:49 | view, right? And so it's those views create the composite image of |
|
| 14:54 | going on. And if you watch long enough, have you seen how |
|
| 14:57 | now have these digital plays? Like it's like this is what they |
|
| 15:02 | They show this it's like watching a game where they like circle the person |
|
| 15:05 | they yeah so that's a result of composite video that they actually create and |
|
| 15:10 | can actually create what play looks Now why do I go through this |
|
| 15:14 | ? Because I like football and I to make you guys like it too |
|
| 15:17 | though it's not going to necessarily be . But number two is because this |
|
| 15:22 | what an E. C. Is like. Alright when I'm looking |
|
| 15:27 | this, what we're doing is we're two leads and we're using those two |
|
| 15:31 | as a positive and negative and we're at the activity between those two |
|
| 15:36 | And so the view from Point To Point B. Is gonna be |
|
| 15:40 | from the view from Point A. point C. Which is different from |
|
| 15:43 | view from the point B. To C. Which is different from the |
|
| 15:46 | of Point B. To point And yada yada yada yada yada. |
|
| 15:50 | so each of the views that you're see gives a different idea of what's |
|
| 15:55 | on with with regard to the electrical of the heart and then if you |
|
| 15:58 | all of that together and composite The machine puts out a picture that |
|
| 16:04 | like that thing that you see here the bottom. These little wave |
|
| 16:08 | And so, what this is is representation of the electrical activity, not |
|
| 16:13 | actual measurements of the electrical activity. . It's not a measurement of a |
|
| 16:19 | action potential either. All right. we're looking at is all the activity |
|
| 16:24 | the heart at the same time over . What's going on? Alright, |
|
| 16:30 | , I have a bunch of things , just so I make sure it |
|
| 16:32 | you the recording of the electrical activity you measure in the bodily fluids. |
|
| 16:37 | , it's in direct to its overall of the activity. So, what |
|
| 16:41 | seeing is you're seeing not the actual polarization and polarization. You're looking at |
|
| 16:46 | is the heart doing during this period time? And what does it |
|
| 16:49 | What does it kinda look like? right. So, you're not looking |
|
| 16:52 | the action potential and what you're doing you're seeing changes in voltage. All |
|
| 16:57 | . But you're not watching deep polarization re polarization. Alright, So, |
|
| 17:03 | gives you or gives the physician or is looking at this and comprehensive assessment |
|
| 17:09 | the electrical changes that are taking And so, it has parts to |
|
| 17:14 | . All right. We have three distinct wave forms. And this is |
|
| 17:18 | kind of the fun part, I . You know there's stupid little facts |
|
| 17:21 | this thing. Alright so you'll see the first wave begins with P. |
|
| 17:24 | have any idea why it begins with . You don't want to take a |
|
| 17:30 | . It's my favorite little story. my favorite but it's up there. |
|
| 17:36 | . In biology we always name things alpha or a. Or one or |
|
| 17:42 | roman numeral. So the yahoo who working on this stuff said you know |
|
| 17:47 | ? I'm tired of starting things with letter A. Or alpha or |
|
| 17:51 | I'm gonna begin in the middle of alphabet. I'm gonna pick the letter |
|
| 17:55 | . And I'm just gonna see how waves are formed. And so he |
|
| 17:58 | pee and he saw the next one was Q. And then he saw |
|
| 18:02 | and then he saw S. And he saw T. And then it |
|
| 18:04 | repeating itself. And so that's how got P. Q. R. |
|
| 18:07 | . T. It has no. it's funny I think right. I |
|
| 18:13 | scientists are always so stiff and Gotta know now stupid things fly. |
|
| 18:21 | are awesome. They name all their after jeans. What genes? All |
|
| 18:30 | so three distinct wave forms first one they all correlate with something that's going |
|
| 18:35 | in the heart. First one is P. Wave. And what it |
|
| 18:38 | is atrial de polarization. In other the contraction that you're gonna see as |
|
| 18:44 | result of all those cells. Polarizing is where you're gonna see the |
|
| 18:48 | . Wave. The Q. S. C. Goes down first |
|
| 18:51 | up and then comes back down That's referred to as the QRS |
|
| 18:55 | So it's Q. There's a Wave. There's an art wave. |
|
| 18:57 | an S. Wave. It represents deep polarization. So we have |
|
| 19:02 | L. D. Polarization that would represent the contraction ventricular re polarization that |
|
| 19:07 | ventricular contraction. And then the Wave represents ventricular re polarization. What's |
|
| 19:16 | atrial re polarization? Thank you for attention and playing my game. It's |
|
| 19:21 | hard. Very early in the morning do so. So why is it |
|
| 19:26 | ? Does the heart does the atrium re polarize? Well it's there it |
|
| 19:37 | actually there. You just can't see . But that's a good guess. |
|
| 19:41 | like oh isn't just relaxing? Well what report Ization represents. It represents |
|
| 19:45 | relaxation of the heart muscle. All . I'm gonna tell you why this |
|
| 19:49 | is getting harder and harder every year I've got if you don't know I |
|
| 19:52 | two sets of twins which is always to tell people because they always kind |
|
| 19:56 | freak out. All right. I three boys out of those two sets |
|
| 19:59 | twins. Alright so all my boys like me. I'm basically I've cloned |
|
| 20:07 | and you guys are all in trouble we're taking over the world. All |
|
| 20:10 | now it was a lot better when were small and cute. But now |
|
| 20:14 | all in junior high and higher so not quite as cute anymore. |
|
| 20:20 | They're not little kid cute. That's it that way. All right. |
|
| 20:24 | youngest of all my boys. So second twin of the second couple, |
|
| 20:29 | mean, he's spot on, looks me at that age, right? |
|
| 20:34 | he's also a little bit shy. so when he was like five and |
|
| 20:38 | years old, if I had brought into this classroom, he would have |
|
| 20:41 | out here at all of y'all and would have been like and he would |
|
| 20:44 | just run right behind me. And then there's nothing I could do |
|
| 20:48 | like, you know, show if turned like this, he would just |
|
| 20:50 | behind me all the time. Well, that's what atrial re polarization |
|
| 20:56 | done. All right. It's in . You just can't see it because |
|
| 21:00 | have this Q. R. Wave which is massive. And so |
|
| 21:04 | re polarization sits at the exact same . It's just masked. Sorry, |
|
| 21:10 | should do it that way. It's by that massive Q. R. |
|
| 21:12 | . Wave. All right. you can see that we have eight |
|
| 21:17 | old deep polarization somewhere around where QRS . That's where you'd see atrial re |
|
| 21:23 | but you can't see it. You ventricular deep polarization through the Q. |
|
| 21:27 | . S. And then over here you see that t. I should |
|
| 21:30 | it the other way T. Represents deep polarization or re polarization. All |
|
| 21:36 | . So what these are supposed to you is the activity that's going on |
|
| 21:42 | that heart. All right now remember is not specifically referring to action |
|
| 21:49 | Alright. So you can't see the note actually firing right? That that |
|
| 21:56 | potential that's a result that creates this of electrical activity is not observable. |
|
| 22:01 | you see is you see all the that make up the atria coming together |
|
| 22:08 | contracting or race basically the electrical activity over the muscle cells that are going |
|
| 22:13 | result in the contraction that are gonna place and cause the contraction of the |
|
| 22:18 | . Right? So that's what you're seeing here is you're seeing not only |
|
| 22:22 | a note, but you're seeing all contract I'll cells. And the current |
|
| 22:25 | trial cells really are what are represented there. All right now, notice |
|
| 22:30 | not very big relative to the And the reason for that again, |
|
| 22:33 | to do with the volume of muscle the concentration of muscle. The atria |
|
| 22:38 | have a lot of muscle. They have to do a lot of |
|
| 22:40 | All they've got to do is squeeze the last bit of blood out of |
|
| 22:44 | atria and squeeze it into the And we're gonna see what that means |
|
| 22:47 | in just a moment. Right Not literally filling up and then squeezing |
|
| 22:52 | the blood in the atrium to the , blood literally just kind of passes |
|
| 22:57 | the atrium going, oh this is nice place. I'm heading over to |
|
| 22:59 | ventricle because of the way that these work. All right. So the |
|
| 23:08 | note fires. Um and what you is you see that spread across all |
|
| 23:13 | muscle, that's what that p wave . And then shortly thereafter about 0.1 |
|
| 23:18 | after that. That's when the contraction to occur. So this represents the |
|
| 23:24 | of deep polarization and then the contraction going to take place on that. |
|
| 23:27 | have a really good picture that's going show that here in just a |
|
| 23:31 | And if you look at this this if you look down here at the |
|
| 23:35 | , it's just showing you this is it represents. You can see the |
|
| 23:39 | occurring and it's spreading to both So the curious is the trick Euler |
|
| 23:47 | polarization. I said it masks that re polarization. It has this weird |
|
| 23:53 | down thing. And the reason has weird up down thing is because of |
|
| 23:56 | direction that the that the electrical activity to follow. Remember just looking at |
|
| 24:01 | the A. V. Know down the bundle of history of the fibers |
|
| 24:04 | go down and then back up and and each of those fibers are |
|
| 24:09 | And so the down up down activity a result of the direction in which |
|
| 24:15 | that wave of electrical activity flows before get the contraction. And I don't |
|
| 24:22 | if you guys remember but on thursday kind of pointed out this kind of |
|
| 24:26 | act uh kind of spiral shape of heart muscle. Do you remember that |
|
| 24:31 | ? I kind of pointed out and threw it out to the side. |
|
| 24:34 | was like oh yeah you can see how the muscle kind of does this |
|
| 24:37 | eight thing and then I just kind ignored it and kind of went on |
|
| 24:39 | way. Do you guys remember that sort of one person? Okay because |
|
| 24:44 | way that the heart works it actually like so when it contracts and so |
|
| 24:50 | contraction wave is a function of the of that heart muscle and how it |
|
| 24:55 | of creates his ringing action. Now interesting. I have a friend who's |
|
| 25:00 | pharmacist um who has, he was the military and he said oh my |
|
| 25:08 | wave is upside down. What do mean it's upside down? So it's |
|
| 25:12 | down, it doesn't go down up it goes up down and then up |
|
| 25:18 | before it levels out said how does happen? He says it's because my |
|
| 25:22 | when it developed flipped around the other so the muscles are backwards, it |
|
| 25:28 | contracts the right way, right? still rings instead of ringing this way |
|
| 25:32 | rings that way. That makes sense ? And so because of the shape |
|
| 25:38 | his heart muscle it creates a weird . Right? So that's what this |
|
| 25:42 | . Why is because of the weird in which the muscle is arranged in |
|
| 25:47 | heart. And finally you get to T. Wave which I even put |
|
| 25:54 | on the last slide. No, don't. So I don't know why |
|
| 25:57 | didn't put the T. Wave but T. Wave represents that period where |
|
| 26:00 | get the ventricular muscle relaxing again. you've gone through the contraction and so |
|
| 26:05 | you're gonna see relaxation taking place. it's the loss of the electrical |
|
| 26:11 | So if you look at this this kind of interesting. Alright. We |
|
| 26:17 | some areas where there's not gonna be sort of current, any sort of |
|
| 26:21 | activity. Alright. We have this of space. This one showing PQ |
|
| 26:26 | but it's basically from P. To . That's the A. V. |
|
| 26:29 | delay. All right. What's going ? The A. B. No |
|
| 26:33 | . Sitting around waiting right, waiting the signal. Go from the atrium |
|
| 26:37 | the ventricle. I have this long of time from Q. To |
|
| 26:40 | They're calling it the S. There. It is the intervals right |
|
| 26:44 | . So there to there. What's on that represents the period of time |
|
| 26:48 | I'm getting the ventricular contract. I'll in their plateau phase. So remember |
|
| 26:53 | drew the picture we said here we the contract ourselves. They're going along |
|
| 26:58 | rest. They get activated. And they kind of sit there in a |
|
| 27:02 | and then they get go through re . Remember that that that contraction is |
|
| 27:09 | in that deep polarized state allows the to go through a period of |
|
| 27:15 | All right. And you can actually those down. So it's showing you |
|
| 27:19 | , like look here's the contract. cells of the atria. And you're |
|
| 27:23 | P. And that Q. And in the plateau phase. And so |
|
| 27:29 | other thing that sits on top of this, I was like, oh |
|
| 27:33 | not gonna get my pen today, it back in there. So the |
|
| 27:38 | you can look at this is you think about like this this is my |
|
| 27:47 | . Sorry, I'm trying to make nice and smooth. That would be |
|
| 27:50 | contraction of the atria right there. the contraction of the ventricle. Did |
|
| 27:59 | see that soapy initiates the electrical activity goes through the auto rhythmic cells under |
|
| 28:07 | conducting cells. Or the contract. cells contract. I'll cells fire. |
|
| 28:12 | you can see there action potential drawn top of this is not the actual |
|
| 28:17 | itself. It's just saying this is can imagine if you put them all |
|
| 28:20 | this is where that action potential would . And so your contraction made by |
|
| 28:25 | little red here is represented in this right here. And then you get |
|
| 28:30 | a v nodal delay that causes uh the A. V. No |
|
| 28:34 | the signal goes down the bundle of along to the park in the fibers |
|
| 28:37 | activates all the contract ourselves of the . And then the contract ourselves. |
|
| 28:42 | the ventricles are get that ax potential in your plateau phase. The plateau |
|
| 28:46 | represents a period of time where you through a contraction. So the ventricles |
|
| 28:51 | . That's what you're seeing during this of time. And then finally I'm |
|
| 28:56 | gonna look here because we got two them side by side. We have |
|
| 28:59 | space in there and that's the space between when your heart is at |
|
| 29:05 | Okay? The T. P. . Alright, so think about the |
|
| 29:10 | that a heart makes, thump, , rest, thump, thump, |
|
| 29:17 | , thump, thump rest. That is the T. P. |
|
| 29:24 | All right, think about when you're or you see the cute person that |
|
| 29:28 | have a secret crush on. And is your heart? Do the rest |
|
| 29:33 | , rest, rest. The rest what gets smaller right that period of |
|
| 29:42 | here. That is the rest. does the E. C. |
|
| 29:48 | Make sense a little bit as a point. Okay, so this is |
|
| 29:54 | lot of physiology here and I understand an mp class but the idea here |
|
| 29:58 | to introduce you to this idea that have this pump that is going through |
|
| 30:02 | period of contraction relaxation. To push into your uh pulmonary system and blood |
|
| 30:08 | your systemic circulation simultaneously using these two . And the electrical activity of the |
|
| 30:14 | is what allows that to happen. we can measure it by putting all |
|
| 30:17 | leads on your body and looking at movement of that electrical activity which is |
|
| 30:22 | by the CCG. And so if heart is going through a period of |
|
| 30:26 | and relaxation, right, What we do is we can divide your heart |
|
| 30:30 | into these periods of activity and non . Alright. We have names for |
|
| 30:37 | . All right, When the heart in the process of contracting, we |
|
| 30:41 | it sisterly. Alright, if a is going through a period of |
|
| 30:48 | we call it die Estili You all your blood pressure taken at one point |
|
| 30:53 | your life. They give you two , right? What's the normal number |
|
| 30:57 | what's the number you hope for? you wanna know? 1 20/80? |
|
| 31:02 | like please let it be 1 You go in and it's like you're |
|
| 31:05 | , it's like 1 80 over 120 like, oh no, I'm |
|
| 31:08 | No, no, no, that's okay. When you're panicking, your |
|
| 31:11 | pressure is up because of anger Every time I go to the doctor's |
|
| 31:16 | I get angry. So my blood is always up in the doctor's |
|
| 31:19 | They have to take my blood pressure when I'm sitting. I hate wait |
|
| 31:23 | the waiting room sucks right? so I'm always ready to fight people |
|
| 31:26 | the waiting room and then I get there 20 minutes later it's like now |
|
| 31:29 | like okay can we take your blood now? Sure sure. I don't |
|
| 31:32 | now I'm in a better mood But anyway so the obvious thing about |
|
| 31:36 | heart is we're going to go through of contraction and relaxation called systolic and |
|
| 31:42 | . But the thing we don't always about is that remember the atria are |
|
| 31:46 | through a contraction relaxation cycle. So has its own system and die a |
|
| 31:52 | and the ventricles go through a contraction relaxation. So it has its own |
|
| 31:58 | and diastolic. And when you hear terms, if someone says you know |
|
| 32:02 | is the systolic pressure. Usually what referring to is the activity of the |
|
| 32:08 | , right? And they're measuring the in the aorta. Usually really they're |
|
| 32:12 | it way down here and making some . But but the idea here is |
|
| 32:18 | when you hear the word systolic we're usually referring to the ventricles but |
|
| 32:22 | need to understand both chambers have this but typically we're going to focus on |
|
| 32:30 | ventricle. So if you hear system I actually think oh I'm dealing with |
|
| 32:33 | ventricle if we're not dealing with the we will always always 100% preceded with |
|
| 32:41 | alright. But if it's the ventricle lazy and so we just leave it |
|
| 32:46 | , that makes sense. Okay, that mind we've already mentioned heart |
|
| 32:53 | There's two that are very familiar. is what you're most familiar with. |
|
| 32:56 | Love and the duck. That sound and sound to what they refer to |
|
| 33:00 | represent is the closure of the And I believe I mentioned this on |
|
| 33:04 | on thursday last week. So that sound the S. One sound which |
|
| 33:09 | the love. That's the closing of A. V. Valves. Those |
|
| 33:13 | shut and then when blood goes in the ventricles begin contracting, that's when |
|
| 33:19 | valve slams shut because the blood doesn't don't want the blood to go backward |
|
| 33:22 | the atrium. So that slamming is result. I like to think of |
|
| 33:26 | as you can think of it as your blood is an angry teenager and |
|
| 33:31 | you can't tell me what to do and it slams the door shut and |
|
| 33:34 | why you can hear it all And then when the blood is |
|
| 33:39 | the semi lunar valves open and when vehicle begins to relax Then the pressure |
|
| 33:45 | to go backwards into the ventricles and causes a similar balance to slam |
|
| 33:50 | And that's that doesn't sound, that's S- two sound. Now there are |
|
| 33:54 | sounds as well, there's you can a galloping sound which is S. |
|
| 33:58 | and S. Four, we're not to deal with those. Alright, |
|
| 34:02 | I don't have a good example of is primarily but we all can do |
|
| 34:06 | up. Right, loved up is bump bump bump bump. The love |
|
| 34:11 | the dope. All right. All . So, as a clinician in |
|
| 34:17 | future, you can use that to is the heart behaving the way that |
|
| 34:21 | should? All right. Now, flowing through the valves and flowing through |
|
| 34:30 | vessels and flowing through your heart does in what is called a laminar |
|
| 34:35 | and that's what you're seeing in this . Right here. Okay. It |
|
| 34:39 | flows in straight lines. All And when fluid flows like that, |
|
| 34:47 | doesn't make sound alright, It makes when fluid makes sound, it's because |
|
| 34:53 | created turbulence within that flow. So if you live on the first |
|
| 34:59 | apartment, you've probably heard the people flushing toilets, right? You've probably |
|
| 35:06 | showers or whenever they turn on water usually you're not you have old |
|
| 35:14 | I mean, I lived in an complex below somebody and I swear the |
|
| 35:18 | for like 40 years old and you hear everything flowing through those pipes, |
|
| 35:24 | ? Especially toilet. That's gross. can just think all the stuff that's |
|
| 35:27 | the pipes underneath the toilet. And so you hear that? I |
|
| 35:31 | about like when you hear a babbling . Why is the book brook |
|
| 35:38 | Because you have turbulence, right? going over the rocks, that's where |
|
| 35:42 | sound comes from. So this is . So if your blood is making |
|
| 35:48 | and the example of a noise would a murmur if you have a heart |
|
| 35:52 | , what that's representation representing is non flow because of some sort of |
|
| 36:01 | So there's different types of murmurs that can have. So basically it's an |
|
| 36:06 | , Usually these are valve malfunctions. if the valve becomes stiff, |
|
| 36:12 | So in other words, when you open it real well, right? |
|
| 36:17 | when blood flows through you now have resistance and so what's what's blood gonna |
|
| 36:22 | ? It's gonna push through. So like it's like steam being pushed through |
|
| 36:27 | kettle and it whistles. I can't the noise because I don't know like |
|
| 36:35 | . So if you're listening and you kind of a sound, oh that's |
|
| 36:40 | representation that the valves are stiff, not opening properly. So blood has |
|
| 36:45 | wash through in a way to get the other side and the heart has |
|
| 36:49 | work harder. The other is valvular and that's when the valve doesn't close |
|
| 36:55 | . When the valve doesn't close What happens is instead of creating a |
|
| 37:00 | it creates an opening and so now can leak through backwards into the chamber |
|
| 37:06 | it was formerly in. And so you kind of get a swishing noise |
|
| 37:10 | opposed to a whistling noise and then upon where you hear that sound, |
|
| 37:16 | it's a whistler or swish and you it between S. One and |
|
| 37:20 | Two or between S. Two and . One tells you which valve it's |
|
| 37:24 | all right. Yeah. No. because the doctor on a regular |
|
| 37:34 | let's say wait a second. I'm something strange happens. You notice when |
|
| 37:36 | go to the doctor, one of things he does is puts that nasty |
|
| 37:40 | thing on you and says, alright , breathe in deep. They're listening |
|
| 37:44 | tuberculosis right? Because they're looking to how hard is it to bring in |
|
| 37:48 | back and forth. Right? Is something in the lines? But they're |
|
| 37:51 | listening to your heart and whether or there's these weird sounds taking place. |
|
| 37:55 | I think in the previous picture, , it's very easy to overlook |
|
| 38:02 | right? It's like there's a I'll come back to another time. |
|
| 38:05 | look what this picture is showing These little yellow dots are telling you |
|
| 38:11 | the best place to listen to the ? Right? So again, when |
|
| 38:17 | go on to your professional schools and your professional things, this is one |
|
| 38:21 | the professional things they teach you. do you put that colt 1st 1st |
|
| 38:26 | it in the ice and then once dipped it in the ice then you |
|
| 38:30 | it on them and this is the where you put it. All |
|
| 38:34 | so that you can hear best. right? So like I said depending |
|
| 38:41 | when you hear it, and I'm gonna ask you where is the systolic |
|
| 38:44 | thing because this is something that's experiential it's something that you do when you |
|
| 38:49 | off to the professional schools. All . What I want to deal with |
|
| 38:52 | the is the cardiac cycle itself. . We said we go through this |
|
| 38:57 | of contraction and relaxation, both in atria and the ventricles. Alright. |
|
| 39:02 | what we're trying to do is we're to move blood from circulation into the |
|
| 39:05 | and back out to circulation. we'll be going from systemic Into the |
|
| 39:10 | , out to pulmonary or from pulmonary the heart out to systemic. |
|
| 39:15 | And there are at least depending on textbook you look like. There's at |
|
| 39:19 | four cardio stages of the cardiac Your book chose five a book I've |
|
| 39:24 | previously for this class had nine. know it's it's just the author. |
|
| 39:29 | , I'm going to slice the pie and thinner and thinner so I can |
|
| 39:31 | it confusing for you. All So, I think five is |
|
| 39:35 | I think four is the easiest. wish that your book would have done |
|
| 39:38 | , but I'm not gonna teach you your book talks five. Alright. |
|
| 39:42 | what I want to understand here is we're going to look at something that's |
|
| 39:45 | to seem very, very scary and , but I don't want you to |
|
| 39:49 | afraid of it. All right. all we're doing is we're breaking down |
|
| 39:53 | information in the categories so that we look and see what's going on |
|
| 39:57 | What's going on here? What's going here? What's going on here? |
|
| 40:00 | right. So, if you look this this cycle here, I've just |
|
| 40:02 | to look at we have atrial then we have ventricular sisterly. We |
|
| 40:07 | late ventricular system. So, we early and late. So, what |
|
| 40:09 | done is they've taken this and they've into two halves. Then we have |
|
| 40:13 | late ventricular diastolic and then we have ventricular diastolic. So, this whole |
|
| 40:20 | is being broken down around which structure , the ventricle. Alright, |
|
| 40:27 | really what they're saying is, what we're gonna do is instead of |
|
| 40:30 | at the whole heart, we're gonna the heart in half and we're gonna |
|
| 40:33 | at one side. Now. Which are we probably gonna look at? |
|
| 40:36 | typically look at the right side of heart because it's easy to think of |
|
| 40:40 | blood going into the systemic circulation than is to think about going into the |
|
| 40:43 | circulation. Right? So, we focus on the right side and really |
|
| 40:48 | gonna be looking at both chambers. it's really all the focus is let's |
|
| 40:53 | in on what the ventricle is doing that's what we care about is where's |
|
| 40:57 | blood coming from and where is it to? And the ventricle serves as |
|
| 41:01 | pump to push it to. That sense. Alright, are you ready |
|
| 41:07 | the scary graph scary graph? All . This is called the wickers |
|
| 41:13 | I'm not gonna ask you its It's just nice to know what it's |
|
| 41:17 | called because we teach this over and and over again. And if you |
|
| 41:20 | at this you can see we have ? 1234 different things here. |
|
| 41:26 | sometimes you'll have 1/5 thing down at bottom which shows you what's going on |
|
| 41:29 | the heart as well. And what looking at is up at the |
|
| 41:33 | We have the E. C. . Is the BCG scary. |
|
| 41:37 | Okay so we don't have to worry that one. It's just we're lining |
|
| 41:40 | up to the electoral cardio gram. so what we're gonna ask is we're |
|
| 41:44 | ask actually there should be another one here that they don't have. But |
|
| 41:48 | we have in the middle that read purple and blue represent the pressures in |
|
| 41:54 | different places. The red pressure represents pressure inside the aorta. So which |
|
| 41:59 | of the heart are we on the side? Okay. Alright. We're |
|
| 42:05 | at the pressure inside the ventricle. said the right side. I'm so |
|
| 42:10 | my brain is putting what side of heart of my on which side is |
|
| 42:15 | ? My left. Thank you. you guys aren't paying attention. You |
|
| 42:19 | have all just shook your head and you're an idiot? Turn your body |
|
| 42:24 | ? That's yeah. Alright. And you can see over here that we |
|
| 42:29 | the purple is the ventricle and then blue represents the left atrium. |
|
| 42:34 | I gotta get my caffeine going. next step down deals with volume and |
|
| 42:41 | volume of blood inside the ventricle. right. Now, what they're not |
|
| 42:46 | you here is they're not showing you state of the valves. So that's |
|
| 42:51 | you usually will see in the But this one isn't showing. But |
|
| 42:54 | it does show you. It shows the sounds. Where do the sounds |
|
| 42:58 | ? Alright, So that kind of you a hint of of where you're |
|
| 43:02 | because the sounds represent valves closing. ? So that's what you're seeing in |
|
| 43:07 | diagram. Now, the easiest thing do if we have these five stages |
|
| 43:11 | ask these different questions. Alright. are we with regard to the |
|
| 43:17 | C. G. Alright. Where we with regard to pressure? Where |
|
| 43:22 | the pressure? All right. And is a function of volume. |
|
| 43:28 | what is the volume in the ventricle a result of the pressures that we're |
|
| 43:33 | ? All right. What is the of the valve? Is the valve |
|
| 43:37 | or closed? And there's two So there's there's a valve that goes |
|
| 43:41 | the ventricle valve that goes out. we ask the question. What are |
|
| 43:44 | state of the valves in this particular ? So that's going to give us |
|
| 43:47 | sense of which direction is blood flowing is it flowing at all? And |
|
| 43:51 | last thing is um that volume and the last thing. So each of |
|
| 43:56 | slides are gonna have these five things there. Right? It's gonna be |
|
| 43:59 | are we with the E. G. Um What is the chamber |
|
| 44:04 | in terms of of the muscle activity to the E. C. |
|
| 44:08 | So what does that do? The ? What does that do to |
|
| 44:12 | What does that mean with regard to valves? All right. Now, |
|
| 44:16 | do I mean by all this? right. If a muscle contracts it's |
|
| 44:22 | pressure, right pressure drives the movement fluid. Did you guys learn that |
|
| 44:28 | time ago? I hope back in seventh grade when you took the that |
|
| 44:33 | science class. No, you don't that here. Do you guys remember |
|
| 44:39 | word Boyle's law? You may not the law, but do you remember |
|
| 44:43 | the word Boyle's law? Yeah. . It just describes the relationship between |
|
| 44:47 | and volume. All right. If increase the pressure that's gonna drive fluid |
|
| 44:54 | an area of high pressure to an of low pressure. Right? |
|
| 44:59 | Think of a balloon balloon has equal on the inside the balloon as |
|
| 45:04 | But if I take that balloon and blow into the balloon, I am |
|
| 45:09 | a pressure that drives air from my into that balloon and then the pressure |
|
| 45:15 | the balloon begins to increase decrease or the same increase right? Because now |
|
| 45:22 | more volume. And what does that wanna do? Doesn't want to leave |
|
| 45:25 | does it just want to hang out say okay I'm happy to being inside |
|
| 45:28 | bloom. It wants to leave. ? And so you gotta sit there |
|
| 45:31 | clamp onto that little tiny blow area you clamp on it because if you |
|
| 45:39 | and then you have to start all again and now it's wet on the |
|
| 45:42 | and it's even harder. Right? you understand these concepts, We're just |
|
| 45:48 | put names to it all. All ? So our starting point is going |
|
| 45:53 | be in the atrium. Remember we we're gonna look at the E. |
|
| 45:57 | . G. To figure out where going. And so here we |
|
| 46:00 | And we're pointing in our little picture here during atrial Sicily Sicily means |
|
| 46:08 | So if my a tree is what have I done with regard to |
|
| 46:12 | pressure inside the atria has gone So let's take a look at the |
|
| 46:17 | and see what's going on here. here I am. Red arrow tells |
|
| 46:23 | where we are. I'm here at P. R. Interval right? |
|
| 46:27 | sitting in there. So if I down here remember I said atrial |
|
| 46:31 | what is it doing? It's So what's happening is that the patriots |
|
| 46:37 | , right? And it's creating pressure drive blood from the atria into the |
|
| 46:42 | . Now, the only way that happen is if the valve is open |
|
| 46:47 | right. And to the pressure inside ventricle has to be less than the |
|
| 46:53 | . Does that make sense? If water can only go downhill, |
|
| 46:58 | , fluid can only move from an of high pressure to an area of |
|
| 47:01 | pressure. So if I have pressure inside the atrium, right, that |
|
| 47:09 | in order to drive blood out has be greater than the pressure to where |
|
| 47:13 | blood is going. And that would in the ventricle. And if you |
|
| 47:16 | at that graph, is that true that point? So here's the blue |
|
| 47:21 | represents atrial pressure. Purple represents ventricular which is on top of which atrial |
|
| 47:30 | is greater than than ventricular pressure. is on top of purple and notice |
|
| 47:34 | always on top of purple as we're along here. So blood should always |
|
| 47:39 | flowing into from the atrium to the during this period of time. But |
|
| 47:45 | does. So even more this graph terrible here. But it does. |
|
| 47:49 | even more. So you can see going in there and I'm getting this |
|
| 47:53 | surge of fluid. Okay, does make sense? I'm pushing blood into |
|
| 47:59 | ventricles. So the volume inside the in terms of how much blood it's |
|
| 48:02 | is increasing another way to put If I have a cup that's empty |
|
| 48:07 | I'm pouring fluid into the cup. the volume increasing? Yeah. Is |
|
| 48:13 | pressure inside the cup increasing? What you think? Yeah, it |
|
| 48:20 | What does that where does that fluid go? Want to go out of |
|
| 48:23 | cup thing is the cup has walls it can't. That's the same thing |
|
| 48:27 | going on here. So look at pressure is going on here. Is |
|
| 48:31 | pressure climbing in the graph. the same point is the ventricular pressure |
|
| 48:37 | in that graph. Yes. But is the ventricular pressure always staying |
|
| 48:40 | Atrial pressure right here. Is it underneath? Yes. Alright. So |
|
| 48:49 | blood during atrial sisterly moves from the to the ventricle, increasing the volume |
|
| 48:59 | blood inside the ventricle. The pressure in the atrium contracts and as it |
|
| 49:05 | blood into the ventricular pressure rises as due to the presence of the fluid |
|
| 49:12 | the ventricle. Okay, now, the first step, the ap valve |
|
| 49:19 | to be open and it has to open because you can't move between the |
|
| 49:22 | chambers if that door is slammed shut the purpose of the ap valve to |
|
| 49:26 | is to prevent backflow. It's not to prevent forward flow. So as |
|
| 49:31 | pressure is open, it causes or pressure is greater in the atrium to |
|
| 49:35 | ventricle, it causes the valves Alright. So this is all going |
|
| 49:40 | during atrial. Sisterly and this is starting point. All right. The |
|
| 49:47 | step is ventricular system. Alright. remember we sent the signal from the |
|
| 49:52 | . A note to the A. . Note that sat there and twiddle |
|
| 49:54 | thumbs delayed. And then we get Q. R. S. |
|
| 49:58 | R. S. Is a representation all of those contract. I'll, |
|
| 50:02 | of the ventricles contracting simultaneously. So all your muscles in your arms contracts |
|
| 50:10 | , they create tension. Right? creating tension to move something. So |
|
| 50:16 | example, I've got this big heavy . Got to put it up on |
|
| 50:21 | stage. So heavy. All come to the chair and I can |
|
| 50:30 | tension in the muscle but notice that left the chair. No. |
|
| 50:36 | what I have to do to lift chair create more attention and more attention |
|
| 50:42 | more attention to Finally, I create tension to lift the chair. Was |
|
| 50:46 | really bad angle, lift the All right. So, what we're |
|
| 50:51 | here in early ventricular sisterly is the of creating that tension boom tension |
|
| 50:59 | It reaches or or uh comes across resistance. Now, where is that |
|
| 51:07 | come from? The resistance is a of the blood inside the chamber. |
|
| 51:15 | still in your starbucks for a I'm not gonna hurt it. You |
|
| 51:20 | , you don't want me to just . All right, actually this is |
|
| 51:22 | better one right behind. I'm stealing water. Let's pretend her water |
|
| 51:30 | That water bottle is more full. let's pretend this water bowl is |
|
| 51:34 | This is like the ventricle. The ventricle, what we have is |
|
| 51:39 | create a contraction boom. It hits pressure inside the ventricle goes up. |
|
| 51:44 | at the graph. You see the go up, See how it |
|
| 51:49 | Does it cross over the atrial Boom? So when that happens, |
|
| 51:55 | A. V valve slams shut. do I want, do I want |
|
| 52:00 | going backwards? No. So it shut as a function of that. |
|
| 52:05 | does blood leave the chamber? because the other valve is slammed shut |
|
| 52:12 | well. Because the pressure out here the aorta is greater than the pressure |
|
| 52:17 | the ventricle, just like me lifting that chair, I have to create |
|
| 52:21 | tension and enough pressure to overcome the in that next area the aorta. |
|
| 52:29 | I begin squeezing. So my hand like the muscle of the ventricle surrounding |
|
| 52:34 | ventricular chamber. And I squeeze and squeeze and I squeeze and I create |
|
| 52:39 | and more and more and more And it's only until the pressure right |
|
| 52:45 | a result of the tension becomes greater here too. Cause that valve to |
|
| 52:49 | until the blood leaves. So in ventricular sisterly. Thank you. What |
|
| 52:57 | doing is we're creating that pressure and tension. So during this period of |
|
| 53:03 | the eight years relaxing. It's going its diastolic it's like I did my |
|
| 53:07 | . I squeezed everything out and now here ready to receive blood coming back |
|
| 53:12 | the system. So I'm in a state so just keep sending me |
|
| 53:15 | So it's right. But the vehicle now in the state of contraction. |
|
| 53:22 | valve slam shut. You hear a club? Right pressure begins to rise |
|
| 53:30 | that's what you're seeing here, pressure rising but there is no movement. |
|
| 53:38 | you don't see any change in the . The artist did a very poor |
|
| 53:42 | of doing that. It stays flat can't leave blood can't enter. And |
|
| 53:50 | you're doing is you're increasing and increasing the pressure more and more and more |
|
| 53:54 | more until the pressure inside the atria greater than the pressure outside in the |
|
| 54:03 | . And when that happens that's when blood will leave. Now. The |
|
| 54:08 | that we give to the volume of inside the ventricle at this time is |
|
| 54:14 | the end diastolic volume. Now it's end of ventricular diastolic. It's the |
|
| 54:20 | of ventricular sisterly and that's where he his name. The end diastolic because |
|
| 54:25 | at the end how much blood is the ventricle at the time when diacetyl |
|
| 54:29 | ends. Now this E. V. Is gonna be important here |
|
| 54:33 | a minute because we're gonna use it help calculate another value. But it |
|
| 54:37 | constant. But when the pressure gets than the aortic pressure, alright so |
|
| 54:47 | building a pressure, building up it's an isometric contraction. You guys |
|
| 54:51 | the word isometric from Mp one, it's when the muscle is getting more |
|
| 54:55 | more attention but you're not getting any of movement. What's going to happen |
|
| 54:58 | you create that tension, it becomes enough and then what it does is |
|
| 55:04 | overcomes the pressure in the aorta. simulator valve pops open. Whoosh. |
|
| 55:14 | the pressure is like over it's it's you've now overcome the hump and so |
|
| 55:19 | you don't get that isometric contraction, now getting a squeezing pressure. So |
|
| 55:24 | I squeeze, where does the fluid out? And what do we see |
|
| 55:33 | fluid leaves out? It goes as as it can and it goes out |
|
| 55:37 | the aorta. The pressure inside the increases. Why? Well because now |
|
| 55:44 | able to contract even further, I'm squeezing and squeezing and squeezing. Okay |
|
| 55:50 | . But I'm also squeezing volume of out into the aorta and the order |
|
| 55:55 | receiving a volume of fluid which causes pressure inside the aorta to go up |
|
| 55:59 | well. And that's what we're seeing . All this stuff. Alright now |
|
| 56:08 | will continue to flow down its pressure . That means the pressure inside the |
|
| 56:14 | sits higher than the pressure inside the , even though they're both climbing the |
|
| 56:19 | inside the ventricle is slightly higher than pressure inside the aorta and as long |
|
| 56:24 | we keep contracting, we're going to that process of driving the fluid |
|
| 56:31 | Now that contraction remember is a function of a it's kind of it's like |
|
| 56:36 | parabolic curve. I got contraction and I hit a peak. And then |
|
| 56:39 | happens on the other side is I relaxation and when we have relaxation that's |
|
| 56:47 | diastolic. And so here we are I think I got these two out |
|
| 56:53 | order. Here it is. Early diastolic. Sorry. And so here |
|
| 56:58 | are. And what we're going to is we're at this peak and then |
|
| 57:05 | we're still above. And just when get down to there that's when diastolic |
|
| 57:11 | . Alright. We created that We squeezed everything out and then the |
|
| 57:15 | begins to relax. And then when pressure in the aorta which is now |
|
| 57:22 | because I pushed all this fluid in now I've got a muscle a ventricle |
|
| 57:28 | relaxing, that muscle begins to relax eventually the pressure inside the ventricle gets |
|
| 57:34 | . And so which way does the want to go? He wants to |
|
| 57:38 | back to the ventricle like look there's path of least resistance it starts running |
|
| 57:42 | that causes semi lunar valve to slam . So we get our 2nd sound |
|
| 57:47 | up. Now we have two valves , the valve is closed and the |
|
| 57:55 | and the semi lunar valve is Alright the muscle is going through a |
|
| 58:00 | of relaxation. So atrial pressure is , much less. So you can |
|
| 58:10 | where the atrial pressure is. Way here, ventricular pressure is over here |
|
| 58:14 | it's less than the aortic pressure which right there as well. And what |
|
| 58:18 | going to see is that that pressure going to continue to drop as that |
|
| 58:23 | relaxes. All right. Think about the tension in a muscle, |
|
| 58:29 | Cardiac muscle the same thing and then the muscle feels good, doesn't |
|
| 58:34 | Right. Right. It's doing the thing. But blood can't enter in |
|
| 58:40 | the aorta because the semi lunar valve , blood can't enter in the |
|
| 58:44 | V valve because the pressure inside the is still greater than the pressure inside |
|
| 58:48 | atrium. And so there's no flow the ventricle. And so we end |
|
| 58:53 | with a volume of blood because we squeeze it all out. We never |
|
| 58:58 | all the blood out. All That is there at the end of |
|
| 59:04 | . That's what we call in systolic . So, I have an in |
|
| 59:08 | volume in systolic volume. And the between those two is how much the |
|
| 59:13 | pumps, which has a fancy name the stroke volume. So mathematically stroke |
|
| 59:20 | equals in diastolic volume minus in systolic . I think we'll see that in |
|
| 59:24 | second here. Alright. So early diastolic. Remember we're in a state |
|
| 59:30 | relaxation. We're not in a state reception? We're basically in a state |
|
| 59:34 | returning back to a state of And the only time we can begin |
|
| 59:38 | receive again is right here. When ventricular pressure as a result of that |
|
| 59:45 | drops below the slowly rising atrial Why is the atrial pressure rising? |
|
| 59:53 | I just pushed a whole bunch of into the systemic circulation and that's pushing |
|
| 59:56 | forward, pushing brush forward and blood returning back to the heart on the |
|
| 60:00 | side and it's just slowly filling up atrium. And as the pressure inside |
|
| 60:05 | atrium rises and the pressure inside the falls, they'll create a tipping point |
|
| 60:10 | a crossing point which results in the . V valve opening and all that |
|
| 60:15 | simply moving down its pressure gradient into ventricle. So, notice blood doesn't |
|
| 60:22 | need to be pushed into the It naturally goes there because of a |
|
| 60:26 | gradient. Can I time out for second? Just just time out gradients |
|
| 60:34 | gonna become the single most important thing you to understand. Not just pressure |
|
| 60:39 | , but just gradients in general. you deal with physiology alright. Things |
|
| 60:44 | from areas of high concentration, low things move from high pressure to low |
|
| 60:48 | . Alright, when you hear the gradient, you're jumping back to |
|
| 60:53 | When you learn things go down, ? You looking at the diver, |
|
| 60:58 | get up on top of the What is a 30 m? 32 |
|
| 61:03 | ? The how about a 10 m ? 10 m? That's 30 |
|
| 61:09 | Do you stand on your hands and that? Which way you gonna go |
|
| 61:17 | ? Always down, right? Always down. We always move down |
|
| 61:23 | Okay to go up the ladder, had to work. But when you |
|
| 61:27 | up there it's just gonna happen. that's the same thing that's gonna be |
|
| 61:32 | gradients. Alright, pressure gradients. move from the area, high pressure |
|
| 61:35 | low pressure volume. I have more . Less here, I'm gonna move |
|
| 61:40 | that gradient. And so that's what's on is as the atrial pressure |
|
| 61:44 | the blood pressure or sorry, the volume increases the pressure in here, |
|
| 61:49 | drops below that blood is gonna then go leaping forward and notice what happens |
|
| 61:57 | . And late ventricular diastolic blood leaps the ventricle is not pushed, it's |
|
| 62:06 | in simply because the pressure caused the . V valves open. When the |
|
| 62:12 | V valve opens, blood flows in then we returned back to where we |
|
| 62:21 | . Then we go to ventricular right? We have an early and |
|
| 62:25 | stage and then we're back to diastolic we just repeat it over and over |
|
| 62:30 | over again. The big thing about is if you can learn this, |
|
| 62:37 | learned how the heart works. All gotta do is just separate it |
|
| 62:40 | Make it simple for yourself. What going on at the P wave? |
|
| 62:46 | this is what pressure looks like in two chambers? What does that mean |
|
| 62:50 | regard to the valve? Is it or closed between them? Oh it's |
|
| 62:54 | . Oh it's closed. If it's , things can flow through. If |
|
| 62:58 | closed, things can't flow through. does it open? Because pressure on |
|
| 63:02 | back side is greater. The pressure the front side. Why is it |
|
| 63:06 | ? Pressure on the front side is the pressure on the back side. |
|
| 63:10 | want blood to flow in a particular . What about the volume? Volume |
|
| 63:15 | dependent upon the direction of blood If blood is moving right, you |
|
| 63:20 | all those things together, you get picture and it's easier just to kind |
|
| 63:25 | ask that question. Here I am here I am here here I am |
|
| 63:28 | here I'm here. What's going on four places? Think you can do |
|
| 63:34 | ? Everyone should nod your head and yes, I'm not an Aggie. |
|
| 63:38 | know I probably have a post back . Who's an Aggie And I'm |
|
| 63:42 | I'm not trying to make fun of . Let's make fun of people went |
|
| 63:45 | texas instead. Yeah, we're good it. two people are nodding their |
|
| 63:52 | . How about over here All right in the back, We're good people |
|
| 63:59 | their history homework. You guys You've got questions about it. Go |
|
| 64:17 | . Mhm. So so I would that this this particular poorly drunk, |
|
| 64:26 | mean, is really what is I if you there are better ones out |
|
| 64:30 | . I've seen worse than this. , the physiology textbook I use for |
|
| 64:34 | upper level students. It's even worse they don't even use color. Just |
|
| 64:39 | but I think in terms of what going on here, the picture doesn't |
|
| 64:45 | a good job. And partly it's , you know, the artist didn't |
|
| 64:49 | between the two. It should be exaggerated. So, you can see |
|
| 64:53 | just like they did down here. can see a slight exaggeration. These |
|
| 64:59 | accurate numbers, they're just points of . And they're just saying, |
|
| 65:03 | here's this difference. Okay, now swaps. And then when I get |
|
| 65:07 | here, it's like, oh, I'm gonna be like, so and |
|
| 65:11 | gonna stay like this until this one over. Now I'm I'm less and |
|
| 65:15 | just kinda how it works. Yeah, this is where bad artists |
|
| 65:23 | cause huge problems Okay with that. right. So, what I wanna |
|
| 65:30 | is I wanna I wanna move on deal with something else that with regard |
|
| 65:36 | how your heart works. And I we're uh we've got about 15 minutes |
|
| 65:41 | I think we can cover all this . So, the first thing I |
|
| 65:44 | to deal with this cardiac output, output, bite up. And it's |
|
| 65:48 | simply the amount of blood pumped by single ventricle and why we say single |
|
| 65:53 | because each side is doing the exact thing. So, the cardiac output |
|
| 65:57 | that ventricle done in one minute. so this is usually expressed in liters |
|
| 66:01 | minute. And it's determined by two , fairly simple heart rate and stroke |
|
| 66:06 | . All right now, the heart is the number of beats. |
|
| 66:09 | what you do is you can sit and count for 60 seconds to see |
|
| 66:13 | many beats you have. There you . There's your heart rate. All |
|
| 66:16 | , You can do it in 10 and multiply by 66 seconds. Multiplied |
|
| 66:20 | 10. All sorts of fun. ways that you can do the calculation |
|
| 66:22 | you want to. All right, stroke volume is the amount of volume |
|
| 66:26 | blood ejected per beat. And this measured in mils per beat. |
|
| 66:30 | if heart rate is beats per now you've got measures, you're doing |
|
| 66:34 | per beat. So, you can those two things. Thing is, |
|
| 66:38 | you really measure your stroke volume? we go out? And I |
|
| 66:41 | other than, you know, cutting big giant hole in you and doing |
|
| 66:45 | . No, we can't. here's some of the interesting. |
|
| 66:51 | so your cardiac output is gonna vary with your heart rate and or stroke |
|
| 66:55 | to meet the special demands of your . Alright, So, when you |
|
| 67:01 | , what's gonna happen? Your heart goes up, right. And the |
|
| 67:05 | it goes up is because now there's greater demand for the auction and the |
|
| 67:09 | your body is needing in order to whatever the activity is. So, |
|
| 67:15 | see your heart rate go up. you also see your stroke volume go |
|
| 67:19 | . So they kind of work hand hand to increase that cardiac output. |
|
| 67:24 | right. Now, the examples I up here are also some really, |
|
| 67:27 | interesting ones. So, for if you have a small heart, |
|
| 67:31 | a child has a small heart and you go and measure the heart rate |
|
| 67:34 | a small child, it sounds like hummingbird. Because the truth is, |
|
| 67:40 | body is trying to keep a constant output. That is equal regardless of |
|
| 67:46 | or size. It's basically like this how much fluid I need to be |
|
| 67:51 | at any given time. So, you have a small heart, it |
|
| 67:53 | to work harder to move that same . Right? So, you have |
|
| 67:58 | small stroke volume as a result of small heart because just size. And |
|
| 68:04 | to compensate for that smaller heart and smaller stroke volume, your heart rate |
|
| 68:09 | up. Right. And so you imagine her heart rate and her mother's |
|
| 68:16 | rates even faster because kids are about run on the street. All |
|
| 68:23 | Yeah, Alright, Large heart. our athlete that is an athlete. |
|
| 68:29 | type of athlete is that sumo wrestler want to mess with them. All |
|
| 68:33 | . He has a very, very heart. This is why I picked |
|
| 68:36 | picture because I think this is incredibly , Right? This is a big |
|
| 68:41 | and this person has a big So when his heart beats, he's |
|
| 68:47 | trying to maintain a cardiac output. this particular athletes heart normally beats at |
|
| 68:53 | a lot slower than the rest of . Right, would be thumb, |
|
| 68:58 | , thumb, thumb, right? you end up with a much much |
|
| 69:02 | heartbeat. Alright, And the reason is because they have a very large |
|
| 69:08 | volume, bigger heart, more blood pushed. They don't need to have |
|
| 69:13 | many heartbeats. And so that's why have a slower heart rate. All |
|
| 69:17 | now, as I said, any of physical exertion there. I like |
|
| 69:22 | one of the best example. Your rate is gonna increase to deliver blood |
|
| 69:27 | , right? Oh, my muscles blood now. So I need to |
|
| 69:31 | it there now. So, the way I can do that is if |
|
| 69:33 | start moving it quicker, Right? I also need what's in the blood |
|
| 69:41 | . I need more of it. the other half of that is I |
|
| 69:44 | going to increase my stroke volume. much blood I'm delivering to ensure that |
|
| 69:51 | particular organ gets what it needs. cardiac output. Both things are gonna |
|
| 69:57 | up. Alright, so you've probably this, your heart when you like |
|
| 70:01 | you've exerted yourself where your heart is hard, you can feel it |
|
| 70:06 | It's going thump, thump, thump, thump, thump. It's |
|
| 70:08 | fast. But you can also feel exertion because what it's doing is it's |
|
| 70:14 | and contracting and pushing more fluid at same time. All right. So |
|
| 70:21 | increase both as a function of Now there's a whole bunch of different |
|
| 70:25 | that can affect your heart rate. so these are some of the external |
|
| 70:29 | that are going to act on the . A. And the A. |
|
| 70:31 | . Node. Alright, so we autonomic innovation. We're going to have |
|
| 70:34 | types of hormones and different types of and drugs. We're going to focus |
|
| 70:38 | primarily on the on the two middle the first and the second one, |
|
| 70:41 | on the other things. Collectively these are referred to as krone tropic chrono |
|
| 70:47 | with time. So what we're doing we're affecting the timing of the |
|
| 70:52 | the rate of the heart. All . So with regard to the cardiovascular |
|
| 70:57 | , we're talking about the autonomic nervous . Keep in mind the heart beats |
|
| 71:01 | its own, it has its natural . The natural pace is regulated through |
|
| 71:05 | structure. First thing we talked about . S A node. It will |
|
| 71:12 | beat. All right. That's what does. First thing your heart does |
|
| 71:16 | it develops it produces these cells before even have muscle cells and it already |
|
| 71:21 | there and creates this beating. So what we wanna do is we |
|
| 71:27 | to either increase it or decrease it this is where the autonomic nervous system |
|
| 71:31 | into play. All right. It's be controlled through the medulla and there's |
|
| 71:40 | regions. One is called the cardio Torrey region. One is called the |
|
| 71:43 | inhibitory region. Fancy words to make heart grow faster, makes the heart |
|
| 71:47 | slower. Right? And what we're do is we're gonna respond reflexively, |
|
| 71:53 | mentally, right? We're not we control it. It's a reflex in |
|
| 71:58 | to chemicals pressure in order to maintain needs that our body has. |
|
| 72:03 | that's what homeostasis is. All And the other thing is your heart |
|
| 72:07 | knows how to respond to over filling saying no no no quit sending |
|
| 72:11 | So they're gonna control and regulate how is returning to the heart, as |
|
| 72:16 | as how the blood is pumping the . Alright. So with regard to |
|
| 72:20 | innovation, this is really, really and really simple acceleration occurs in the |
|
| 72:25 | of sympathetic activity. All right, am P. One We learned about |
|
| 72:31 | and parasympathetic autonomic nervous system, cardio is sympathetic. All right. |
|
| 72:38 | what we're using here is we're using spinal nerves. T one through |
|
| 72:42 | Five. We go to three different . S A node, the node |
|
| 72:48 | the rest of the mild cardio. ? Why would I do that? |
|
| 72:55 | , what I wanna do is I to ensure that I'm sinking up the |
|
| 73:00 | , the ventricles in order to get to work in unison. I don't |
|
| 73:04 | the atrium to start contracting faster and ventricle not keeping up. I want |
|
| 73:10 | of those things to work in So this is responsible for ensuring that |
|
| 73:16 | that is going on. So that's we increase our heart rate. We're |
|
| 73:19 | affect the control the auto rhythmic cells make them contract fast and we're gonna |
|
| 73:24 | how we do this in just a . But the other thing is the |
|
| 73:28 | cardio myocardial is represented by the contract cells and I'm stimulating the contract I'll |
|
| 73:34 | to work harder. All right. other words, I'm making them contract |
|
| 73:41 | and faster so that they create more quicker. It's beating out of your |
|
| 73:50 | like that. That's what's going All right now, there's also innovation |
|
| 73:55 | the coronary arteries and what this does it will actually induce dilation or in |
|
| 74:01 | depending on which arteries you're looking, gonna be dilation further on. You're |
|
| 74:04 | see resistance and it's actually speeds up allows for more volume and we'll deal |
|
| 74:09 | that when we deal with the blood . All right, to slow down |
|
| 74:14 | heart. This is where parasympathetic comes . It's through the vagus nerve, |
|
| 74:18 | , That's the one nerve we learned we talked about the autonomic nervous system |
|
| 74:22 | you gotta know vagus nerve because it's the big weird one. Alright. |
|
| 74:26 | what we're doing here is we're decreasing this is interesting. It's the heart |
|
| 74:32 | . We're not worried about force of . So it's not going to the |
|
| 74:37 | . Alright. It's dealing primarily with two nodes. Yes and the |
|
| 74:40 | V. Node. So we're doing we're slowing down the heart but we're |
|
| 74:45 | gonna worry about force of contraction that take care of itself because of some |
|
| 74:50 | the inherent qualities of the heart. we say something is positive a positive |
|
| 74:57 | tropic when it increases the heart All right. So sympathetic innovation is |
|
| 75:04 | chrono tropic. And what it's really here and I don't want to spend |
|
| 75:08 | too much effort on this. Is it's affecting that curve. That action |
|
| 75:13 | that we talked about. Remember we the action potential is dependent upon sodium |
|
| 75:17 | and calcium. Alright. So if want to increase the rate at which |
|
| 75:21 | climb then I want to make sure have more calcium coming into the |
|
| 75:27 | So that causes my my my curve go upward. And what I wanna |
|
| 75:32 | is I want to increase the rate which I go down but I don't |
|
| 75:36 | to go down as far as I to. Alright. So what I'm |
|
| 75:39 | do is I'm going to reduce the of potassium that is being allowed to |
|
| 75:44 | back and forth. And so what up happening is I climb fast drop |
|
| 75:48 | . But I don't go down as so I can climb fast again. |
|
| 75:51 | so that means I can get more in the same period of time as |
|
| 75:55 | did when I started. And that's this picture is. Trying to |
|
| 75:57 | You see here the gray, you see that's the normal path. Notice |
|
| 76:02 | . I don't go down as far ? So I'm allowed to return back |
|
| 76:07 | threshold quickly. Look at my slope relative to my slope there and you |
|
| 76:11 | just pick any one of those too for one of them is like this |
|
| 76:14 | for the other ones like that. I rise quicker. So that means |
|
| 76:17 | getting more heartbeats because I'm causing the fire with greater frequency. Alright, |
|
| 76:25 | increasing calcium decrease in potassium. All now, the other way we can |
|
| 76:32 | this we have hormones in our right? We can increase their |
|
| 76:39 | Right? Someone jumps out of the and go boo, fight or flight |
|
| 76:43 | . What do we do? We our body with epinephrine? What does |
|
| 76:46 | epinephrine do? It does the exact thing. It acts on these cells |
|
| 76:50 | create that and make it happen, hormone does the exact does something |
|
| 76:55 | It basically makes them more responsive to epinephrine and norepinephrine that's in circulation. |
|
| 77:01 | other drugs for example can do similar . So caffeine basically um inhibits the |
|
| 77:09 | so that this whole thing speeds There's other drugs that can do that |
|
| 77:13 | well. Not so interested in knowing . So positive. Corona tropic, |
|
| 77:19 | do they do increases heart rate, chronic topic on the other hand are |
|
| 77:26 | be through the parasympathetic, it just the opposite, it decreases calcium |
|
| 77:32 | it increases potassium permeability. And so you end up doing is you end |
|
| 77:37 | spending more time below thresholds to look the slope there versus the slope there |
|
| 77:45 | . You do know that's incredibly Alright I don't care if you guys |
|
| 77:49 | leaving. Just don't make a huge about it. All right. |
|
| 77:56 | You mean you guys are adults you choose when to get up and go |
|
| 77:59 | don't be loud about it. And then again there are other |
|
| 78:05 | So if you have probably heard beta , beta blockers block or prevent epinephrine |
|
| 78:10 | norepinephrine from binding to the receptors and you don't when you aren't able to |
|
| 78:16 | those receptors then you you end up a reduction in the activity in other |
|
| 78:21 | epinephrine or norepinephrine epinephrine and norepinephrine increase rate, blocking those receptors prevents it |
|
| 78:28 | happening. And so you decrease So krona tropic agents positive or negative |
|
| 78:34 | parasympathetic stroke volume we said is something we can calculate. We just need |
|
| 78:41 | know what the end diastolic volume is what is left at the end of |
|
| 78:45 | versus what is the end at Sicily the difference between that's how much blood |
|
| 78:50 | move from the beginning and the So that's your stroke volume. All |
|
| 78:55 | now there are three factors that affect volume and this is gonna sound a |
|
| 78:58 | scary because we use big words but already understand that these are gonna be |
|
| 79:03 | . We have things called pre We have things that's called external in |
|
| 79:07 | tropic agents, things that are going affect the ions involved. And lastly |
|
| 79:11 | load. Alright so let's deal with venus return. Alright, the pre |
|
| 79:18 | . This is one of the cool about the heart. You don't need |
|
| 79:22 | tell the heart how to behave. heart already knows how to behave. |
|
| 79:24 | actually follows something that two guys figured by just making observations whatever you give |
|
| 79:31 | heart. The heart's gonna work In other words the heart pumps what |
|
| 79:37 | give it. So if you constrict veins and push more blood into the |
|
| 79:43 | right. In other words you push blood in the heart. The heart |
|
| 79:45 | at and says okay I'll pump that so it basically responds to what you |
|
| 79:51 | it. All right? So if change how much blood I'm getting in |
|
| 79:57 | beginning of the process that's diastolic diastolic ? So I'm receiving blood during dia |
|
| 80:04 | if I increase my in diastolic What's gonna happen to my stroke |
|
| 80:09 | Mathematically says stroke volume equals in diastolic buyers E. S. V. |
|
| 80:15 | if I increase E. D. . What happens to stroke volume? |
|
| 80:20 | increases? Right. Let's make a number. E. D. |
|
| 80:23 | Is 10. E. S. . Is one. The difference between |
|
| 80:26 | two is nine. Alright if I E. D. V. And |
|
| 80:29 | it to 15 and I don't change S. V. 15 minus one |
|
| 80:33 | 14. It grows. So stroke increases so if I increase the pre |
|
| 80:40 | the amount of blood that the heart gonna pump back out is also going |
|
| 80:45 | increase. That's the stroke volume. ? That's pre load, that's venus |
|
| 80:49 | . And this is based on the Starling law. Alright. That's the |
|
| 80:53 | phrase there. The on a tropic are the external factors. So autonomic |
|
| 80:59 | stuff. We've already talked about. happens with sympathetic innovation. What does |
|
| 81:04 | innovation do, increases contract I'll So if I increase the amount of |
|
| 81:10 | I make the heart beat harder. what that does is that gives me |
|
| 81:14 | greater drive to push things outward so supports what frank Starling does. So |
|
| 81:19 | that increases calcium is going to increase volume. Anything that decreases calcium reduces |
|
| 81:25 | volume. Okay and then the last and I'm sorry I'm keeping you an |
|
| 81:30 | minute life is hard here? Right the after load? Alright? If |
|
| 81:36 | have greater pressure in the arteries, my heart have to work harder to |
|
| 81:41 | blood into the arteries? Yeah. it this way if you want to |
|
| 81:48 | this room and I'm standing in front the door, are you gonna have |
|
| 81:50 | work harder to get out of the or get through the door? Yeah |
|
| 81:54 | gotta push me so you have to harder to leave. And that's the |
|
| 81:58 | thing when there is an increase in in the periphery, that's your blood |
|
| 82:03 | . Then my heart has to work to overcome the pressure to push the |
|
| 82:08 | out. This is your after All right in other words what I'm |
|
| 82:13 | is I'm dropping my E. V. If I'm using the same |
|
| 82:16 | of work I'm not able to push as much blood and so now I |
|
| 82:20 | more blood to push out the next and the next time the next |
|
| 82:22 | So in order to do that work have to work harder at the front |
|
| 82:26 | . Come on in dr Gifford. this right here is a simple summary |
|
| 82:33 | those last four ideas. Alright so load what I give to the heart |
|
| 82:41 | load, the resistance in the blood . And lastly what's going on |
|
| 82:46 | In other words as I affect the of calcium. If I increase calcium |
|
| 82:50 | decrease calcium I'm gonna affect that stroke . Both positive and negatively. Thank |
|
| 82:55 | for being patient for the last three . I'll see you on thursday we |
|
| 83:03 | to |
|
