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BIOL 2301 Human Anatomy & Physiology I - 2301_lecture11_0622
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00:03 Okay, let's see how we can done today. We have a lot
00:07 do. What we're gonna do is gonna cover the smooth muscle. We're
00:10 move from smooth muscle back to skeletal . Talk about some features of skeletal
00:15 . And then when we're done with , we're gonna look at the central
00:18 system. We're gonna start looking at protections of the central nervous system.
00:21 lots of ground to cover. When look at smooth muscle, structurally,
00:27 very, very different than skeletal All the state materials is there are
00:31 But they're organized in a very, different way. And so you can
00:34 here, first off, the skeletal the smooth muscle is an individual
00:38 It's single nucleus. In other union nucleus doesn't have the multi nuclear
00:43 nuclei, it's much much smaller. think of it like little tiny cells
00:47 you'd expect. All right. It has this weird spindle shape to
00:52 There are no sorry, I'm ears it instead. What you have Or
00:54 have these structures that are dense These dense bodies are the same proteins
00:59 make up the uh uh the Z in the saarc amir, But it's
01:07 organized differently. And so what that is is that if these are the
01:11 structures these little black lines that are the cartoon represent where those Maya filaments
01:18 going to be located. All And so you still have thick
01:21 you still have thin filaments. You have some intermediate filaments that kind of
01:25 arrange things. But you can see the arrangements create this kind of weird
01:30 . Alright, so the thick and thin filaments are still there and they're
01:34 this lattice work. And so when thick and thin filaments cause a
01:40 what ends up happening is that the shrinks in this weird way?
01:44 Kind of looks like a bound of . You know what I'm talking about
01:49 ? All right now, what I'd point out is just just some features
01:52 , is that the acting doesn't have ? Alright. So, if it
01:56 have troponin, that means it's going behave slightly differently. All right.
02:03 In terms of let's see here some features that are necessary. They're gonna
02:10 connected to each other by mechanical And really what that means is that
02:15 one cell contracts, it's pulling on cell. When we look at skeletal
02:19 , all the skeletal muscle cells are moving in the same direction.
02:22 when you look at a muscle, know, the the the head of
02:26 muscle, basically what you're seeing or belly of the muscle, What you're
02:30 is all the muscle fibers moving in same direction, They're all parallel with
02:34 other. So here, what we is we have them all kind of
02:37 gathered together in this census um That's special word that just means sheet.
02:42 , since Isham And when one pulls pull on the other ones. And
02:47 you'll see these contractions that occur where cell contracts and the next sales contract
02:52 the whole sensation moves together. It have a cytoplasmic articulate, it does
02:57 calcium. But most of the calcium gonna start from uh entering into the
03:03 from the outside rather than from the particular. Um There are no T
03:07 . You don't need them. because you're getting primarily your calcium from
03:13 external environment. Now. Typically what gonna see is that you'll find smooth
03:18 located in your hollow organs. When think of hollow organs, we primarily
03:23 of the digestive tract. But you think of structures in the respiratory
03:27 You can think of structures in the . You can think of structures in
03:31 cardiovascular system that includes the blood So, basically, anything that forms
03:37 tube in the body is going to made up or have within it,
03:40 smooth muscle and typically the smooth muscle going to be in these sheets.
03:44 what they're gonna do is they're gonna arranged in two different directions. You
03:48 one group of sheets that are going the circumference of the hollow organs.
03:53 , they're basically moving around in this . Alright. The second sheet is
03:59 to be moving parallel to the length the organ. All right. So
04:04 have one coming out towards you. have one going around this and what
04:07 does is when you get a contraction you're surrounding something. What's going to
04:11 if you get a contraction, what's happen to the circumference it's gonna get
04:15 . So it's gonna see constriction when relaxes, it dilates and then when
04:20 have a contraction along the length of organ, what's gonna happen to the
04:24 of the organ it shrinks. so the smooth muscle is going to
04:31 in those two ways. Now we here, it's typically arranged in two
04:34 . There are some organs like the and the uterus that actually have three
04:39 . So they have one that's kind at an oblique angle, but we
04:42 need to worry about that until you to those structures. Alright. It's
04:46 these are the two that are we memorize them when they're weird.
04:50 . Now, where do we see ? It's going to be in terms
04:52 involuntary movement. Alright. And what gonna do is we're gonna regulate blood
04:57 , will move materials along the digestive . And so you can see for
05:01 , what am I doing when I'm ? I'm kind of making the tube
05:04 . So that kind of pushes material to one side, right? I
05:08 change resistance into the airways and with to the uterus, the uterus is
05:14 we'll see contractions during labor and So smooth muscles in all these different
05:21 of organs and the way that a is done is different than what we
05:26 in a skeletal muscle. Remember in muscle? Very, very simple.
05:30 have that neuro muscular junction action potential release of locally made locally causes an
05:36 potential in the muscle cell. So different action potentials that that act potential
05:41 along the surface of the cell, down the T. Tubules causes the
05:44 of those D. H. Receptors which causes the opening up of
05:47 ridin receptors which causes calcium to flood the cell. Right, calcium floods
05:53 the cell, binds to troponin pulls mice out of the way the thick
05:57 thin filaments can interact, thereby creating contraction as long as a T.
06:00 . Is available to break the bond them. Right. So it's a
06:06 simple thing. We spent almost two talking about something that took me less
06:10 a minute to explain. Right. is the joy of going to
06:17 All right, so those that framework just described isn't going to be the
06:24 muscle but there's parts of it that going to sound a little familiar.
06:29 going to see calcium moving into the . So as a result, an
06:33 potential is going to travel along the of the cell that's going to cause
06:35 opening of voltage gated calcium channels so so good. Alright, that sounds
06:41 calcium floods into the cell that calcium also trigger calcium being released from the
06:46 . A plasma critical. Um So say calcium goes into the cell.
06:51 . But what happens here is calcium bind a troponin. Why doesn't it
06:55 a troponin? What did I say the first slide? There is
06:58 So, we can't bind it What calcium does is it binds to
07:02 molecule that's found inside the cell called module in Now Call model is all
07:08 the place in the body. It's of the single it's one of the
07:11 common types of regulatory molecules. All . It's part of a signal transducer
07:17 cascade. So remember we learned back unit one. The signal transaction cascades
07:22 said we don't need to know what little players are. Here's one where
07:26 seeing what the players are. calcium binds cal modular. When that
07:32 that activates cal modular, modular. does a whole bunch of stuff in
07:36 cell. But one of the things it does is activates another molecule called
07:40 light chain keens. Now a keenness an enzyme that phosphor relates other
07:48 All right. And so what it's is when it becomes activated by cal
07:53 in it's gonna go and foss for another molecule and it tells you always
07:57 its name, what that kindness is . So in this case it's myosin
08:01 chain and we have a myosin we really talk about the structure of
08:07 But that little tiny head that's the chain. And what it does is
08:13 relates that and it causes that head become mobile. So remember what we
08:19 in the last case we had ATP along and activating the mice and light
08:24 so they could break and make the . So here what we have is
08:28 have a signaling cascade that does it . Now there's more complexity going on
08:34 with a D. P. That want to go into. I don't
08:36 to confuse you but I want you understand this concept. The idea is
08:40 is working through a signaling cascade that in the phosphor elation and activate ovation
08:46 the thick uh thick filament. All . And as a result what you're
08:52 do is you're gonna start getting a , right? And when calcium is
08:58 there are molecules that inactivate this and activate this. And when you inactivate
09:04 then you stop the contraction. Do you think this is a fast
09:07 slow? Slow relative to the other is kind of slow. And think
09:13 your smooth muscle. Think about when digesting food. Is it fast or
09:17 it slow? It's like very And so this is what it's doing
09:22 . Slow is a relative term. didn't say speed. What is the
09:25 ? Which is how fast is it ? It's kind of slow and blood
09:29 when you visit constrict and dilate. faster than your digestive system right?
09:34 it still uses the same sorts of . So, you're gonna get those
09:39 bridges just like we saw. And that's going to be the contraction.
09:44 remove it. Then everything is just to cause relaxation. So basically the
09:51 sort of rules apply if everything is and you're activating stuff, you're going
09:55 continue the contraction. But if you at the top, there are mechanisms
09:59 move things along the way that cause . Alright. And again, this
10:04 be a slow process. Yes, . Yes. But remember.
10:10 what we're dealing with is we're dealing that head interacting with a thin
10:14 Right? So, what we're doing we're making the bond we're pulling We're
10:18 the bond. Yeah, That's that's we're referring to. That's what that
10:21 relation is doing. Now. The is there is a TPS activity and
10:26 other stuff in there. Please do write that down because I don't want
10:29 confuse you with the difficulties that that along with that little thing. The
10:35 thing here is that we're using a signaling cascade as opposed to the one
10:41 we learned in the skeletal muscle. right. So, some unique features
10:49 smooth muscles. One is that has stress relaxation response. How many guys
10:54 thanksgiving and eating. Thanksgiving. All right. How many plates can
10:58 go for you stop it too? . Four proper thanksgiving. Play
11:09 Right. I mean, you just going and going. It's like the
11:11 you're you know, you can just expanding basically what it is. Is
11:15 when when smooth muscle gets stretched it goes through relaxation response. In other
11:21 , what it does is it accommodates stress as opposed to resisting against
11:26 All right. And so in the example, the digestive system, it
11:31 for greater volume. So this allows to put a lot of food into
11:34 stomach until you're like, I can't it anymore. Then you unbutton your
11:38 if you didn't properly wear your stretchy right now, the reason this is
11:44 , remember we talked about that that tension relationship and skeletal muscle. We
11:50 said there's a there's an ideal right? We said we don't care
11:54 the edges are. It's just like this ideal length for muscle to work
11:59 , smooth muscle doesn't care so It can actually be still efficient if
12:03 stretch it even further. Right? or compress it down. And
12:09 it has to be a little bit do with the structure. The other
12:13 that's really interesting is that some smooth in the body is hyper plastic.
12:18 hyper plastic means they have an ability multiply and divide. Now the easy
12:24 to think about that does this is uterus. All right, everyone hold
12:28 your fist. That's the ladies. the size of your uterus before you
12:33 get pregnant. It's actually little bit than that. Alright. And then
12:38 about full term pregnancy. We're talking , I don't know a £9
12:44 That's on the big side, write £9 child plus about £13 of placenta
12:50 amniotic fluid. Alright, so we're like two basketballs worth of size.
12:55 , so that's the size of your . After nine months you give birth
13:00 then you actually go through a process bringing your orders back down to the
13:05 and it takes about two weeks. the smooth muscle accommodates that because it's
13:11 of being hyper plastic table will Yeah. Two. That's exactly
13:28 Just because it's right. So because the arrangement of how those thick and
13:36 filaments are using those dense bodies as to the Z lines, right?
13:40 allows for these cells to actually be . Right? Think of your
13:46 write your bladder starts off. Itsy , teeny tiny, like a deflated
13:50 . And all day long you're making about a mil per minute,
13:55 And then what happens? It fills , fills up, fills up and
13:58 smooth muscles are getting stretched and stretched stretched and if we stretched too far
14:04 would think that I wouldn't be able get the force to be able to
14:08 that fluid out when it's time to the bathroom. But no smooth muscles
14:13 accommodate that because of that arrangement. now, I point out the hyper
14:20 because skeletal muscle is not remember what said when you work out and get
14:24 , you're not building new muscle, making the muscle itself bigger. All
14:33 . Now, when we talked about muscle, we said here's our muscle
14:38 . And what we did is we put a neuron associated with each of
14:42 individual muscle cells. And what we is a neuro muscular junction. So
14:47 muscle cell in your body, skeletal cell is associated with a neuron.
14:53 ? Smooth muscle on the other isn't like that. What happens is
14:58 , and we're gonna see the example this is not true. All
15:02 Typically what you have is you have of the autonomic nervous system.
15:06 again, we're going back to that or flight thing that we haven't really
15:11 yet. And instead of having a muscular junction, instead these sorts of
15:17 have little kind of bulges or bulbs the Teledyne Andrea. And what they
15:22 is they kind of act like a system. So instead of talking directly
15:26 the cell and saying, I want to contract right now, it sends
15:30 kind of this generic message. It all right, all your cells around
15:34 . I think it's time for you contract. And what they do is
15:38 some cells will receive that signal directly some might receive that signal indirectly.
15:46 . So, that relationship is going be one where it's not direct always
15:53 it's it's kind of an indirect way they're not talking like this, this
15:59 right here is not talking to that specifically. Okay. Now even though
16:05 innovated, smooth muscles are capable of their own action potentials. Alright.
16:12 can modify and change the rate at they're going to contract. You know
16:18 the rate at which they contract as as the strength. So they have
16:22 own kind of pacemaker activity which can their responsiveness or can basically decrease or
16:30 an action potential or contraction from So there's some inherent activities within the
16:37 that can affect this. Now typically muscle is going to be arranged in
16:42 of two ways. When we describe , we're really describing the more um
16:50 I've got to make sure I get right. Yeah. The single
16:52 I always get those two things Alright. They work together as a
16:58 . Alright. So here you can there's our there's our Teledyne dri a
17:02 can see all the very costly as can see all the cells that are
17:05 of surrounding it and all the cells connected to each other via gap
17:11 Question. Go ahead. Sorry. , very Casati. So that bull
17:20 structure is called a very Casati. about a varicose vein gross, right
17:27 outward. Yes. So there's no inside it there would be synaptic
17:34 So, it serves as kind of apps. But because it's not directly
17:38 with the cell, we don't call the synapse. That's a very good
17:42 . Thank you. So, here can see the varicose. Let's see
17:48 it's not interacting directly with the cell the cartoon and what it's doing.
17:52 acting like a sprinkler system. I'm releasing neuro transmitter out into this nearby
17:58 . Some of the cells are going respond and when they begin to contract
18:01 produce that action potential because there uh with the other cells via gap junctions
18:09 uh that movement of ion will move cell to cell to cell. That
18:13 be an electrical junction. All And so then that sheet starts at
18:19 the action potential began. That's gonna the first one that contracts. But
18:22 nearby elect cells that are connected electrically further and further away contract and contract
18:27 contract. So, ultimately the whole will contract as a result of their
18:33 . That's why it's called the single . It acts as a single unit
18:37 contract. And we mentioned, some these cells are self excitable. You
18:42 not need to have a signal from nervous system and do so the cells
18:48 have their own pacemaker activity and can their own action potential, thereby causing
18:55 whole sheet to contract. All The other type is the multi
19:03 And here it's not like this right , it's more like the skeletal muscles
19:08 that they have neuromuscular junctions. So each cell is innovated, it
19:15 its own synapse. So that means cell right here is going to be
19:20 independent of the other cells. Just you saw in skeletal muscle. Now
19:25 have motor units. Right? So can have many cells innovated by one
19:30 . But what you're seeing here now that neuro muscular junction, one
19:34 one cell. Lots of cells. cell or one neuron. Okay,
19:43 where you're going to see? These in some really, really discrete
19:47 So, for example, the easy to think about is the hair
19:51 Have you ever had goose bumps on side of your body and not on
19:53 other? Yeah, it's like hair up over here. And it's
19:57 what's going on? It's because those are individually innovated by or those smooth
20:05 that caused the pili to stand up individually innovated when you talk about your
20:11 , for example, right? I cover up one eye and shine light
20:17 this eye and this live. I will dilate or sorry, will
20:22 but this will remain dilated, Because it's they're responding to the light
20:27 they receive. So they're working independent each other. All right.
20:39 that's smooth muscle. And the truth , I mean, there's like
20:42 like 10 slides there or something like . But you're only gonna get like
20:45 question or two. So, the here is kind of look at how
20:49 they different from skeletal muscle? What distinguishes them or makes them unique from
20:56 skeletal muscles? Yeah, you have . That's good. So one of
21:06 will only be made up. That correct. So, the question
21:11 is the sensation, And I look it, is it just gonna be
21:15 single cell or is it gonna be unit? And it's typically it's gonna
21:19 that single unit type of structure. I mean, you can look at
21:24 one. It might be multi Again, multi units are very,
21:26 rare there in some very specific locations the body. Yeah. Yes.
21:39 Mhm. So what you do is the where your structure start changing.
21:49 , for example, um I was , oh, let me pull up
21:54 picture of the esophagus. I don't a picture an esophagus. So it's
21:56 gonna be helpful. Alright. So you're dealing with like the esophagus,
22:00 where that innovation occurs and where that muscle begins, that's where you're going
22:07 start seeing it. But where you new innovation. So let's say the
22:10 . Well, it does, it . I'm sorry. I'm thinking
22:15 I'm thinking of the trachea. Excuse . Alright, So in the
22:19 the you're gonna get a swallowing That's gonna be skeletal muscle. But
22:23 the smooth muscle begins and starts pushing down. So the esophagus is going
22:27 be independent of the smooth muscle that find around the stomach. And there
22:31 different parts of the stomach that have different purposes. And so in those
22:35 areas, in those different regions, gonna have unique since issue that are
22:40 innovated. And so that's what you'd is where you see that independent innovation
22:45 where a new sensation begins. right, so skeletal muscles don't form
22:53 issue. All right there, those typically are referred to as an individual
23:01 . So you'd point to and say is that muscle. So for
23:05 we have two esophageal sphincters. the esophageal sphincters are going to be
23:11 muscle. Right? So this one gonna when you swallow basically open
23:15 And what you're really doing is you're from that skeletal muscle that allows you
23:19 force the food from the back of uh Fairbanks really down into the esophagus
23:26 then once it gets to the it's all smooth muscle doing the
23:30 And what you're gonna do is basically relax that muscle. So that's number
23:33 , then you get to the next which is now a muscle that's going
23:37 constrict and push food down through the . Once you start to swallow that
23:42 is gonna just do its thing and going to keep pushing whatever it is
23:45 until it gets to your stomach. another structure that's the boundary between the
23:51 and the esophagus and that's gonna And that's that next sphincter. So
23:58 of those would be independent structures that working independently of each other.
24:03 the census of the esophagus that you're of, for example. So,
24:08 skeletal muscle would be from the Ferencz to that sphincter. And then now
24:12 getting the smooth muscle. All So, so, what I'm pointing
24:16 here is that the the skeletal muscle never the same thing as a smooth
24:21 . It is an independent structure All right. Yeah, that's all
24:28 . Not a dumb question, sensation a fancy word for saying sheet
24:34 Alright. So typically when you're talking smooth muscles, they form sheets of
24:39 . Yes. Harvest. Okay. So, when you're talking about muscle
24:55 , right, muscle cells work as motor unit. Right? So,
25:00 have a single cell or let's say cells? I'm just gonna use five
25:04 and one neuron. All right. within that muscle belly, I will
25:09 hundreds of muscle cells. So, unit is just that group of five
25:15 . What those five cells do is will work as a unit to create
25:18 certain amount of tension. If the isn't enough to to move the
25:24 The load being the thing you're trying to act on. Then. What
25:27 do is you'll recruited another motor unit you'll keep it recruiting enough motor units
25:31 in order to create the tension necessary move the load. Alright. What
25:36 census she um is is basically all cells that are available in that
25:41 Alright. So when we're looking at hollow tube and you're looking at all
25:47 cells say in the um in the census. Um When you stimulate
25:55 that's going to cause all those to simultaneously. It doesn't select for
25:59 here's just a couple. Right. , I just need to create this
26:02 tension. It's going to act on and the whole thing is going to
26:06 as a unit. So, sensation basically working as a group.
26:12 I will accept in that multi Which is the unique thing that's like
26:16 the eyes and stuff. All I'm ready to move on to back
26:23 skeleton mostly. I think this stuff more interesting for those of you who
26:28 interested in how your muscles develop and I guess is the best way this
26:34 going to be kind of interesting to . I think All right.
26:40 cardiac muscles are a census. Ium they're a unique cell type and the
26:48 that they arranged is very different than muscle and very different from skeletal
26:53 That's why we don't talk about We wait till you get to the
26:57 system. So A. And Two. First lecture cardiovascular. All
27:04 . Truth is not very different from muscles. Really how it's arranged.
27:11 . Alright. So, remember what said. We're talking about skeletal
27:14 So now from now on, it's back to skeletal muscles. When I
27:17 muscle and skeletal muscle. All Because if I say skeletal muscle every
27:22 it's gonna slow me down. All , muscles are going to be attached
27:26 bones. There's terms that we We call the origin and the
27:30 The assertion is the mobile attachment. basically where the muscle is going to
27:36 attached distantly. Alright. The origin is the proximal attachment is where you're
27:43 to be attached. So, that's stationary object. Alright. So,
27:47 from the origin. You're pulling the towards the origin is the idea
27:54 All right. Now, typically, we say that this is attached to
27:59 , the origin is attached to whereas the insertion is attached to
28:03 So here, we're talking epic Museum to perry Osti. Um Here the
28:09 is actually inserted to the bone. right. And what we're doing is
28:13 saying that's what we're pulling on and pulling that bone towards wherever that origin
28:19 located. When we look at a , we ask what is it trying
28:26 accomplish? All right. An agonist a muscle or it can be a
28:31 group. But typically we're talking about muscle that is directly involved in creating
28:37 . Alright. So, when I a contraction like this, my bicep
28:42 acting as the agonist, I'm pulling arm upward but there's a muscle muscle
28:48 opposes that movement that's called the Alright. And what it's trying to
28:54 is trying to stabilize the joint during movement of the agonist. And so
28:59 would be the triceps in this particular . My tricep is serving as an
29:05 an antagonist to my agonist. Now I was lifting up something heavy like
29:09 chair again obviously I'm going to need stabilize my body to oppose the weight
29:16 I'm moving the chair right naturally. I'm trying to pick up this chair
29:21 can see I'm doing, I can , this is helping to stabilize while
29:26 do the lifting, but I have in my back that are stabilizing my
29:31 so I can make the movement. refer to those as synergistic, they're
29:36 involved in the movement itself, but stabilize you to allow for the movement
29:41 occur. So no muscle is kind working by itself. There's always other
29:46 going on around it. Now, I answer the question we finished with
29:51 thought, when we are telling the to contract simultaneously, we're trying to
29:59 the antagonist to relax because of both are contracting with equal force at the
30:04 time. You're basically not going to any sort of movement right if this
30:09 contracting and that's contracting, then I'm going to allow this muscle to move
30:13 or this arm to move upward so that inhibition of the antagonist while the
30:22 is contracting is called reciprocal inhibition. , So when you're contracting here,
30:29 telling this muscle to start relaxing Alright. Now, to your
30:34 Go ahead. Well, so it's of a general term. So you
30:43 just think about where am I pulling ? So the origin is is typically
30:46 to be the proximal is typically where pulling to Not always pointing here,
30:51 I mean, we could, you , point to other but other
30:54 but because we're not naming specific I can't show you a picture.
30:59 the idea here origin is where I'm to insertion is what I'm pulling
31:05 Okay. It it depends on the , depends on the muscle that you're
31:09 at. Yes, no question. , or right, No, stretch
31:36 are a function of your skin. growing fast enough while your muscles are
31:39 faster. Think about women who are ladies, I'm sorry, you got
31:45 lines in your future. I heard butter is the best. I don't
31:49 . All right, but their bellies faster than than their skin, skin
31:54 actually grow. So they end up stretched lines on their bellies as they
31:59 . Guys who like to lift especially in their early teens, you
32:03 , like All right, I want pump myself up. What do I
32:05 ? I go out there and I pumping and working faster than my body
32:08 grow. So you end up with lines. So, what you're seeing
32:12 is when we talked about growth and , right? We talked about how
32:16 skin and you get fibrosis, in , what you're doing is you're seeing
32:20 nature of that epithelium trying to grow enough, but it doesn't So you
32:25 up with this material that doesn't look that great. Again, I heard
32:32 butter. Yes, this has to . Is it fully relaxing? It
32:42 on what the movement is, so can be serving kind of in a
32:45 a fashion where it's like, remember I'm trying to stabilize the
32:48 right? So, as I'm creating contraction, this muscle is doing an
32:53 movement that that allows for this movement occur because I'm inhibiting it, but
32:58 just turning everything off. Otherwise be . I was going to bring in
33:04 heavy book to kind of demonstrate this in just a moment, but I
33:07 lazy and did not do that. let me let me show you what
33:10 looks like. Alright, we have deal with the type of contractions that
33:15 heard you've probably heard of isotonic isotonic contractions is where you're going to
33:21 muscle tension, right? And while muscle tension is being produced, its
33:26 constant. Alright. And then when remains constant, the muscle length itself
33:31 changing. All right now lots of . Visual makes it easier here.
33:39 got something that weighs something Not very . Right. I'm moving at is
33:46 muscle changing its length? Yes. . So, the amount of tension
33:52 doesn't get any heavier while I lift . Right? It's it's basically a
33:56 weight. And so as I move , I've changed my lane similarly,
34:01 I put it down, the weight change. But does my muscle change
34:05 ? Yes. So here, I'm lane. So, concentric isotonic contractions
34:12 the muscle is shortening an east centric contraction. When the muscle is
34:19 And again, you can just just up something, pick up something
34:22 pick up something light, You can it. Right, picking this
34:26 My muscle gets smaller. That's a contraction. That's an e centric
34:32 Alright, Because I'm What I'm doing I'm trying to prevent this thing from
34:36 the floor so there is a slow while this is beginning to relax.
34:42 right. Now, what's happening in antagonist muscle? What's this? All
34:47 , when I go this direction, happening? Is that a concentric or
34:50 contraction? Alright. Would be And then coming down here would be
34:56 smaller Concentric. All right, you have a question. Okay.
35:05 . Yeah, I just mentioned I'll back. Isometric contraction is when the
35:10 length doesn't change. But you change tension. All right Here, we
35:16 a wall. I'm gonna try to the wall. I'm just gonna apply
35:21 little bit of force. All right my muscle doesn't change size, does
35:26 ? When I push up against Just a little bit. Alright,
35:30 if I apply more force and more and more force. More force?
35:35 load hasn't changed. Right? But amount of tension I'm producing changes.
35:41 I still can't produce enough tension to the muscle to cause the muscle to
35:45 its shape. Right? So even I'm developing more and more tension,
35:51 muscle itself doesn't change the shape. used to be a really popular way
35:56 work out in the 70s. They have ladies sit in chairs and
36:01 , okay get your arms put them is on tv public access tv.
36:05 . And he said all right, your arms together and press them.
36:10 an isometric contraction. Right? And pushing I can create more attention.
36:15 can produce less tension. Right? I'm working out that muscle because I'm
36:20 producing tension in the muscles. You try that. See okay, you
36:27 it's just not so popular anymore. the popular way to work out
36:32 dumbbells? How about yoga pants and free weights Pilates you name it.
36:37 you could throw a rock and you hit something new. Right?
36:45 Mhm. All right. So this kind of shows what we just described
36:50 . I'm sorry. Yes, go first. Mhm. That's right.
37:10 the idea here is when you're dealing isotonic, right? So the word
37:14 is so same tonic is you're dealing the tension is what it's actually referring
37:20 here. Right? So the tonic or the tension stays the same,
37:25 muscle length is changing. So think carrying something heavy, write your muscles
37:30 and your sustaining that contraction contraction that be isometric. Right? But now
37:35 have to put that item down, ? And it's heavy. You don't
37:39 to just drop it because you'll break it is in our little scenario.
37:43 what are you gonna do? You're slowly put it down and you're gonna
37:46 release the tension right? As you're , your muscle length is going,
37:51 amount of work your muscles doing is the same because the weight doesn't
37:55 But you're you're allowing your muscles to while you hold that thing up.
38:00 right. So in another classroom there's things and I can pick that up
38:04 demonstrate it better because me putting this , Right? I mean let's just
38:09 it this way. Right, I'm this out. Right? So I'm
38:12 with an isometric contraction. My muscles changing But when I put this
38:18 right? I'm controlling how fast it . Right? But my muscles are
38:23 longer as I put it down as lifted up, My muscles are getting
38:27 . So there's isotonic movement there, ? But if I hold it straight
38:32 , that's isometric. Where's my synergies ? Where are they? My
38:39 yep. Where's the other place? ? That's right abdomen When you're like
38:50 ? Yeah, just depends on what right. So so when you get
39:01 machines right, machines are there are specifically to work at a single muscle
39:07 , right? You can even see you go to certain gems. I
39:10 a picture and they say you're working your lats, your working out
39:14 Alright? But then there's some for example a dead lift. You
39:19 if you do a dead lift it out multiple muscle works your core,
39:23 your legs, works your back, ? So there's all sorts of different
39:28 and so different exercise will do different and depending on who you read and
39:33 know who you want to pay attention . You know certain exercises are better
39:37 others in terms of maintaining or keeping body in shape. You know,
39:42 example if you've ever done kettle I mean that does everything in your
39:47 . So kettle swings are a good to do. But if you're trying
39:50 build up muscle mass in your chest your arms, it's not gonna do
39:53 for you because you're basically shifting where work is going as you do the
39:59 right? All this is trying to you here is um what these
40:06 Alright, so this would be concentric here, where it's like see here's
40:09 kg stimulated. It lifts up the here, the weight is too heavy
40:13 you can stimulate it and the muscle . It produces tension, but it's
40:18 enough to lift the weight. That be a nice symmetric. So mussels
40:24 these characteristics, their contract, I'll they can forcibly shorten when they stimulate
40:29 . They're excitable. That means they to an electrical stimulus. I think
40:33 the lab, I don't know if doing the mp lab. I know
40:35 doing the physiology lab. You get muscles and you you can add electrodes
40:39 them, you get them to contract stuff, right? Extensible. That
40:44 you can stretch and bond beyond their length, their elastic. That means
40:50 you stretch them, they go back the original shape. Can you imagine
40:54 after you work your muscles and they're , meaning that they adapt based on
41:00 . Which was what we were kind describing yesterday, which means you use
41:04 , your body is going to respond produce the amount of muscles you need
41:08 order to do the job you're All right. Mhm. This thing
41:20 this they say like you break right? So the idea is you
41:24 micro tears and so part of this repairing the micro tears. Right?
41:29 kind of like the stress that we've about in bone, right? Every
41:33 you take a step, you create stress in the bone and the osteo
41:37 are there to detect where those stresses occurring and they direct where the bone
41:41 to be remodeled. So it's the sort of thing. It's the micro
41:44 mean, we're talking when I say terry, it's not like you're literally
41:47 your muscle. I can tell you what happens when you tear your
41:50 Because when I was in high school did that. It's not fun.
41:53 hard to repair. It takes forever your muscles to repair themselves. Not
41:58 lot of fun. Alright. But you're happening is like when you're stressing
42:03 muscles out over and over, then going to happen is is your body
42:07 , wait a second, I'm constantly to repair this. Let me make
42:11 side of skeleton, let me make thick and thin filaments. Now.
42:15 can create greater forces. I can the tearing that's taking place.
42:26 I don't know. I'm sorry. having a real hard see the truth
42:31 when we're talking 50 yards or however , 2030 yards from each other.
42:34 really hard to hear you liberum No. So the liberal remember is
42:41 connective tissue that kind of holds the in place. At least when I
42:45 of a Librium, that's what I'm of. So when you tear
42:48 that's that's actually pretty bad. You have to rest that joint,
42:53 And once you once you rest that it allows it to repair itself very
42:58 . It's hard to arrest a Right? Is that what you're referring
43:03 ? Yeah. Yeah. So if tear that, are you gonna be
43:06 to use that shoulder, know what gonna do? They're gonna bind you
43:10 and say let's let's let's allow that repair itself. And very often you
43:14 to go in and do surgery. kind of like doing a meniscal
43:16 Meniscal tear is the same thing like liberum. It's basically connective tissue holding
43:21 two bones together or in in socket a better way to probably put
43:27 All right. There's something called a shortening cycle. You'll see this in
43:31 very specific types of movements like running jumping and what you're doing is you
43:36 taking advantage of how energy is stored particular types of movement. It goes
43:42 these three phases. So the eccentric , what you're doing is you're actively
43:46 out that agonist muscle. All And so that muscle doesn't want to
43:51 stretched. And then what happens is go to the amortization phase. And
43:54 energy is now stored in that eccentric . So now it can serve as
43:59 spring when it contracts. And that's shortening. And so think about when
44:05 running, right? I mean we run on our on our on our
44:09 . But what we do is we downhill. What are we doing?
44:12 stretching that muscle, we bring our flat which now stores energy in that
44:18 muscle and then it contracts and springs forward. Alright, so this would
44:23 that strength. Uh shortening cycle. increases the amount of force that you're
44:29 to do. It stimulates something called stretch reflex. We haven't talked about
44:34 yet. Stretch reflex comes a little later. All right, there's also
44:41 force velocity relationship and this can sound confusing, but all you gotta do
44:46 think about what you're trying to accomplish the movement. And again, think
44:50 lifting something and putting something down when have a concentric contraction, the force
44:56 going to be inversely related to That means stronger force means slower
45:03 Alright, so here I've got this little thing. How much tension do
45:11 need to produce to lift this? if there's not a lot of
45:15 what's going to happen? I can the muscle pretty quickly. Right,
45:21 you just gotta think in terms of got something big, how much tension
45:33 am I gonna move it as fast I can move that? No,
45:35 can visualize it. I can't move as fast. Right, because I
45:40 to produce more force. So speed force. Have an inverse relationship
45:45 Alright, when you're dealing with the contractions. So the heavier the
45:50 the slower I go. All that makes sense. But that's concentric
45:54 centric force is directly related to The light or something is right,
46:01 slower I want to go. And , the way I think about it
46:05 if I put something down, I want to break it. All
46:10 So, I got something heavy, , gravity is pulling it and so
46:16 amount of tension I'm producing is heavy so I'm slowing down. The rate
46:21 which I'm putting something down. I'm sorry. That's backwards. The
46:26 force there is the faster muscle So, I'm trying to prevent it
46:29 falling. That's the way that you to think about it. Right?
46:32 wants to go fast. I don't it to go fast. So I
46:35 my time putting it down. If was something bigger, I don't
46:41 Like I said, there's usually something in here that I can play
46:45 I bet this chair where he's more do you bet? Oh yeah,
46:55 all cool walker too. All okay. Hopefully that will help.
47:07 right. So, if I want put this down, it wants to
47:11 fast. So the rate at which contract slows down its movement. So
47:17 want to go fast. Right? prevent this thing from falling. So
47:23 rate at which I'm contracting is This thing doesn't weigh a lot if
47:29 go fast. What's going to happen I'm gonna hurt myself or whatever,
47:34 ? So less tension. Less Yeah. Like what? Right
47:49 no. So what you're doing is remember in the antagonist muscle you're opposing
47:53 movement, right? So what you're is if I'm producing lots of
47:58 right? More force, the slower muscle contraction, Right? So I'm
48:03 this. So what's this one? ? More force? And this muscle
48:08 contracting faster, right? But their each other. And so you're creating
48:13 eccentric movement as that concentric is going ? I know it's you they oppose
48:21 other. That's that's the easiest thing do. Think in terms of
48:27 the thing's heavy. I don't want lift it again so far you with
48:34 with this. Alright, so all gotta do is remember concentric force inversely
48:40 . Then try to picture what you're . If it's big, I'm moving
48:46 right here. S centric just think your bicep. Just make your life
48:50 . Right? In a bicep? centric if it's big my speed is
48:57 , it's trying to prevent me from it right, gravity is pulling on
49:04 . I've been saying no, no, no, no,
49:06 I'm taking I'm contracting faster to prevent from falling faster. All right,
49:16 I'm leaving you with that confused look your face, it's just something you
49:20 to memorize in terms of muscle muscle fibers are going to be aligned
49:26 the tendon. All right, So can have what is called a
49:30 A muscle or a non pen eight . A pen eight muscle. Just
49:34 of refers to how it feathers. right. And so here with the
49:38 eight muscles, the muscle fibers are to be oblique to the Tendon.
49:44 that means in english. If you your tendon, oblique means at an
49:53 that's not perpendicular or parallel to the . All right. And so what
50:00 means is when I contract that I'm pulling in that direction.
50:07 And so the tendon which is pulling this direction gets pulled much, much
50:13 slowly in the direction that it wants go. But what are you doing
50:18 you're producing a lot more force to that movement. Right? So You're
50:28 to see PIN eight muscles where you're to have more muscle mass to get
50:34 force to create the movement. When dealing with non pin eight muscles,
50:40 have your tendon and the muscle fibers moving with that tendon. All right
50:47 parallel, so they produce fast so slow, more force.
50:54 Not as much force. Okay, these are just examples of what they
51:03 look like. So you can see , pin eight pin eight pin eight
51:09 parallel, parallel parallel. You can that why that's parallel. Right?
51:17 your tendon. Which way the fibers same direction here? You can see
51:22 tension between the parallels here, tendon . There's the belly parallel tendons over
51:31 tendons in the middle, tendons kind doing all sorts of weird stuff and
51:36 circular is weird. I promised you one time that we were going to
51:43 the muscle names, but only All right. Remember. I said
51:48 name things for what they do for they look like. So when you're
51:51 to memorize, have you guys, they making memorized muscles in the
51:55 Yeah. Alright. So let's make lives easy. All right. Typically
52:01 gonna have clues given to us. gonna tell us about location,
52:04 structure, size, shape. They even have origin insertions telling you where
52:08 coming and going to or what sort action they're doing. So, here's
52:12 example of an orientation rectus. What you think that means up and down
52:20 . That uh size, bravas, brief, brief, longest. That's
52:30 type of latin I learned long. big minor fastest. Okay.
52:41 huge, vast shape. Deltoid rhombus again square. Like name for the
52:52 that they perform an abductor lifts, drops. The presser drops again.
53:01 sensor causes extension. Right, Yeah, elevator lifts. It's like
53:11 el elevator. That's where the name from. And then opponents. I
53:16 know does something like that. That's opposition. Huh? So all
53:23 a sudden. Now the vocabulary of is a lot easier. Right
53:29 There's gonna be some kooky stuff in . But when you see words like
53:33 it's going to help you understand its alright? Or where it's located or
53:39 it's trying to accomplish. Ultimately, we're looking at, when we're looking
53:46 the skeletal muscular system is we're looking a system of levers. Alright.
53:52 so what a lever is is simply tool. It's one of the simple
53:56 , you remember learning your simple tools back when it's like earth science or
54:00 they call that class before biology high . So a lever basically is a
54:06 stiff object that moves something along a point. So what we have here
54:09 what is called the fulcrum. We have a moment arm, a
54:13 arm has a resistance force being applied it. That's the thing you're trying
54:17 move. And the applied force is force that you're going to add on
54:22 applied to the lever to move the force Okay. In our bodies.
54:30 this does it creates a mechanical I think it was Archimedes that said
54:33 me a lever long enough and I move the earth right? I don't
54:37 if those Archimedes, I could probably any name of any ancient scientists would
54:41 nod our heads. Yeah, that sounds good. All right.
54:45 the idea is it gives me this advantage. So your bones and your
54:49 are the levers, the joint serve your full crumb and then the muscles
54:53 the applied force. And then so resistance forces. Just the thing that
54:58 trying to move, There are three types of levers that are described.
55:03 have the first class, second class third class lever. So if you're
55:07 this for the first time, you look at tools that we're familiar
55:11 First class levers. The type of we're most familiar with is here's your
55:14 in the middle, your resistance forces one side, applied forces on the
55:17 side. Alright, there's not a of first class levers in the
55:21 If I want to nod my that would be an example of a
55:26 class lever. Fulcrum is my spinal or my vertebrae, right? The
55:32 on the back of my head, this direction is the applied force on
55:37 resistance force on this side. not very common. Second class levers
55:44 of like a wheelbarrow. I'm gonna my fulcrum at the end of my
55:48 of my moment arm, I'm gonna the weight that I'm trying to lift
55:52 the middle and I'm gonna put my force at the end. So Wilbur
55:56 a really good example. My full way over there, I lift up
56:00 here, I can move a lot weight. Did a lot of that
56:03 weekend, several yards of dirt, a lot of fun. Again,
56:09 don't have a lot of these. you can think of this example right
56:13 , right? The way that I'm to lift in this situation is my
56:20 , here's my fulcrum. My The muscle doing the lifting right?
56:26 the muscles in the back of my . Just lifting it up. I'm
56:31 all my weight. Okay, again, not very common. That's
56:35 second class lever. This is the common. Again, fulcrum at the
56:40 . But what I'm doing is I'm the resistance force, the weight at
56:44 far end away from the fulcrum and doing my applied force in between
56:49 All right. So, the example we're gonna use is using our biceps
56:54 , here's our resistance weight, And I'm doing a curl. So
57:00 my fulcrum, my elbow and there my applied force. My bicep is
57:08 between the fulcrum and the resistance. I contract the biceps, I move
57:14 resistance force. The 3rd Class Lever the most common. All right.
57:20 , what I'd be familiar with is the positioning of where the resistance and
57:23 applied forces of the fulcrum and know your third class is the most common
57:28 , but all of them are in body, wow, we're really slow
57:41 , But I guess we can take five minute break. Will that wake
57:45 up? Yeah, this stuff is fun stuff. This is where we're
57:51 find out about our bodies. Mhm . All right. So, like
58:09 said, I think this is kind the fun part about muscles and it's
58:12 at the type one versus type two . Alright. So when you hear
58:17 there are different muscle types that shouldn't surprising to you were just like turkeys
58:22 chickens. We have like meat and have dark meat. The differences are
58:25 meat and our dark meat is actually . So that when you look at
58:29 muscle, all that stuff is mixed . And so the light and dark
58:33 is basically described as the type one Type two muscle types. And what
58:38 can see here they have some There's differences in twitch differences in power
58:42 differences in fatigue resistance. So in of twitch time, type ones are
58:47 twitch. Type twos are fast And what that means is it takes
58:50 long time to develop force and it a long time to return back to
58:54 state of relaxation. Whereas with a witch you get a quick contraction and
58:58 quick relaxation. All right. In of power because they're very slow.
59:07 developed very little force overtime. They just kind of build up a
59:12 and then they kind of relax. with the fast it's like it's very
59:16 quick, you create a lot of very quickly and it dissipates very
59:21 But because this is slow, they're , very efficient. They're very efficient
59:26 using the energy that they have. so they resist very slowly. All
59:30 or not resist they resist fatigue very . So because of that they're because
59:35 slow they're gonna use that aerobic energy . So they're basically use oxygen to
59:41 lots of A. T. Which is why they're fatigue resistant.
59:44 when you're talking about the type they typically have very little aerobic
59:49 They typically are are dependent upon an activity or their tip reliant on that
59:56 gin system. So what they do they basically produce their force very
60:01 Then they get exhausted and tired and stop working. All right now,
60:07 I said, we all have these we have names for this type of
60:11 . The type one is referred to oxidative. Type two is referred to
60:14 glycol. It because their dependency on sort of pathway. So this is
60:19 one that yields more 80 P through phosphor relation, which means you go
60:22 glycol, Asus oxygen or uh piru or pyre of eight. Yes,
60:32 power of eight step one. I'm blanking right now Krebs cycle oxygen phosphor
60:36 and ultimately the electron transport chain. that's why you get more 80
60:40 That's why you're less fatigue resistant Or fatigue resistant whereas the glock politic you're
60:46 dependent on that first step. So make very little 80 p. And
60:49 you fatigued very very quickly. And you can kind of associate oxidative and
60:55 allergic. And the types of activities have. So most people are about
60:58 50 but people are really good at . Typically have a lot of like
61:02 fibers. Typically marathon runners would be . So it's a kind of an
61:06 way to kind of kind of think these things in terms of what sort
61:11 activities do I am I really really at. So for example, I'm
61:17 glycol ipic person. You can tell you see these pictures that we're gonna
61:21 here in just a second. I'm a type one. Type person.
61:24 more type two. Alright. Doesn't I can still sprint. It just
61:29 or lift weights. I'm not really strong like I used to be but
61:32 I in my UTE when I was Ute, you know. Yeah,
61:36 was a big guy and I played and I was fast. Now I'm
61:40 and a key. Um So type and type one or two A.
61:46 . Type of red muscle and the it's red muscle. So here is
61:49 white meat dark meat mixture that I trying to describe. So here what
61:54 have is we have Maya Globe and why it's red. All right.
61:58 the type one we said is Not very powerful. Right? But
62:02 fatigue resistant. And the reason is I've already got oxygen in there and
62:06 can basically supply that auction to this energy production cycle to produce the amount
62:15 force is not particularly large muscle They're actually pretty small. And that's
62:19 we're looking at. These are individual within a larger muscle. Type two
62:24 they're less numerous, they're kind of inside. But when we think of
62:27 other Type two's, these are ones lack my myoglobin, so they don't
62:31 store up oxygen there. The white , right? You can kind of
62:36 them very, very large in They're very powerful. The reason they're
62:40 because they have all those mile fibers them. Um And most prevalent in
62:48 bodies. Typically speaking, we don't to see this because we've already talked
62:53 that, but I think this is really good example that demonstrates this.
62:58 , so when we exercise muscle naturally through hypertrophy. Alright, that means
63:06 cell itself gets bigger. And the it gets bigger is because you're increasing
63:10 number of fibers inside each of those . Those mild fibers. The thick
63:15 thin filaments. Alright, you're not new muscle cells. You're making more
63:21 . Now, type two fibers have greater potential for hypertrophy. So here
63:27 have a sprinter here we have a runner, you can see what the
63:32 have. He looks like he is weightlifter, right? He produced burst
63:38 very quickly that propels him forward But he's not gonna be able to
63:42 that speed for a very long period time, right? We're talking 100
63:46 , maybe 200 m. And after , it's just like, kill
63:49 right? This person is again in same exact great shape, but he's
63:55 Type One person. Alright. His are well developed for that, that
64:01 endurance race. He's in good He's not in bad shape, even
64:05 it looks like he's starved to Right? It's just that's the way
64:09 muscle fibers work. Type two are to Aerobic performance because they have fewer
64:16 and the muscles are gonna thus fatigue easily. Here, the capillaries are
64:21 the muscles they provide the oxygen. have a way to store up the
64:24 . So you're able to keep that activity over and over again. This
64:30 a fantastic picture because there are those us who look at our bodies and
64:35 , I want to look like and pick that really, really, really
64:39 looking person. You want to look , all right, you want to
64:42 out and work out and work out ultimately get that body. You
64:46 it's like, no, if you're Type two, You're going to produce
64:51 type two body. If you're a one you're never going to produce a
64:56 two, you will only produce what a type one. You don't really
65:01 between the two. There's very little between those two states. So I
65:08 probably never ever be despite my just just percent. I'm young
65:12 I would never be a marathon Right? My muscles do not have
65:18 capacity. I can probably Jog five and then kill over dead. But
65:26 never, like I said, I to sprint the 100. I sprinted
65:30 the 200 when I was in high , right? I was I was
65:35 fullback. I was never that person was gonna go downfield and catch the
65:41 . You know, I had to the short burst up because I have
65:44 hulk body. My neck is probably largest neck you'll ever find when I
65:50 in high school 17.5 inch neck when work out now my neck and I'm
65:57 little fat too 19 and 3/4 I working out about three years ago,
66:03 again after a long hiatus because working sucks, you know, and my
66:08 just got bigger and like, I'm gonna get a small neck. It's
66:12 , I'm just the hulk. I out. That's what I do.
66:22 , rumors speak up. Right. . Huh. Stupid. No.
66:38 for nothing. Okay. That's all . It won't take long. I
66:43 where I'm at. Alright, go and ask your question. Mm.
66:53 . Okay. Well, it's So you're basically, it's determined primarily
67:14 your genetics. If your parents are and muscular, I mean, you
67:18 , they don't, they don't have bulk muscle, you're not gonna get
67:21 bulk muscle. Now, can you a sprinter into a long distance runner
67:27 little bit, Right? I you can turn 100 m runner
67:30 say, a a 400 m but you're not going to turn them
67:35 a marathoner, right? They don't the right muscle type to do.
67:39 you can train people to do things you can build up that specific muscle
67:44 , but they're not gonna be that . If you're talking about competition,
67:48 , you can't turn a sprinter into competitive marathon or because they're just not
67:53 to have the muscle type to make possible. Their muscle, their muscles
67:57 going to be the type to, you can work those type ones,
68:01 they're not gonna multiply, they're just in that right ratio that you started
68:05 life with. So, again, have this thing right here,
68:08 This is kind of just giving you example of different types of ratios,
68:13 ? If you're a sprinter, you're gonna turn into that because you cannot
68:18 the muscles and it doesn't matter, know, if you're 12 years old
68:21 hitting puberty, you're not gonna oh, well, I don't have
68:23 muscle now, I'm gonna have this or whatever vice versa you are what
68:27 are, and there's nothing wrong with , that's that's the key thing,
68:30 ? You look at yourself, I , and just say, okay,
68:34 is the muscle type. So I to accept the fact that I will
68:36 have a thick neck and when I weights and stuff I'm gonna just get
68:40 and not you know, you know I'm never gonna look like that,
68:46 never look like that either. Right, I could probably look like
68:51 , but maybe 30 years ago. . Mhm. Right. Mhm.
69:04 , Okay, but but he will be a like for example, he
69:09 never be a world class sprinter, ? What he is is he's at
69:14 person, he sits in the he can do all sorts of
69:16 What I'm trying to say here is think in terms of like being the
69:19 of the best, right, you turn a sprinter world, you can't
69:25 bolt, you cannot turn Hussein bolt , I don't know, a world
69:29 marathon. Okay, well Mr Olympio the same type of muscle type,
69:35 , I'm thinking of it, But that's the same type of muscle
69:39 that Hussein bolt would be because remember that fast burst. Right, let
69:45 show you another picture right. Here go, you can see he's working
69:50 hard. All right, that guy's going to run long distances every time
69:56 works out he makes those type two stronger Now this is the other
70:03 I cannot convince my wife I'll answer question, I'll talk about this.
70:07 ahead. So just to make sure Don't happen as a result of your
70:16 know, with you start with what got. Right? So Exactly.
70:22 born with what you have. You you can focus in on what you
70:27 and improve what you have, but can't change what you have into something
70:30 don't have. All right. And what this is about. Because I
70:34 to convince my wife over and my wife's a physical therapist. She
70:37 know better. She should listen and this, but she hates working.
70:42 hates lifting weights because lifting weights It's boring for those who like to
70:47 weights. I'm sorry, I'm It's boring. It's boring. You
70:53 to 10 or eight boring, It's I'm sorry, it's boring.
70:59 do it. I mean right after today, after my office hours,
71:03 going to go and work out. still boring, right? Yeah,
71:18 Yes. What I want to get here is what I want to point
71:22 here is that different exercises have different . Alright, so, my wife
71:28 to run because she likes that and thinks it's going to help her lose
71:33 and be cut, right? And said cut in a you know,
71:37 kind of a generic way. I , she's not turning into the hottest
71:42 on the planet, you know, just we're old people. This is
71:46 happens. I'm sorry, The older get, the harder it is to
71:50 that that beautiful figure that you have the height of your youth. It's
71:56 I'm saying it on the microphone, will stand by it. All
72:00 There's nothing wrong with it. All . But the point is, is
72:04 when you're doing resistance and sprint what you're gonna do is you're actually
72:09 muscle and burning energy in a very different way. Right?
72:13 what you're gonna do here is you're accommodate when you're doing resistance training or
72:18 training is you're accommodating hypertrophy. it's gonna make your muscles bigger,
72:22 ? It's gonna enhance the function of muscles and it's gonna get that greater
72:27 of strength. You get stronger. , That's what it means. All
72:32 . And this is a result of enhancement in calcium release. But you're
72:35 see a decrease in blood and muscle Alright, so, that will help
72:41 fatigue, but it doesn't inhibit Right? So, I can sprint
72:45 and faster and I can become but eventually I'm still gonna become
72:51 Right? I was like, I can sprint a little bit
72:54 I can sprint faster when you're dealing aerobic endurance training, you're doing something
73:00 different, right? You're basically increasing aerobic capacity of those cells.
73:07 Which means same performance at absolute less effort, in other words,
73:15 now if I tried to run a , literally kill over dead. All
73:19 . You'd have to be there with ambulance ready to to pick me
73:24 Alright. I tried I tried to with my son 15 years old.
73:27 were doing we were doing some running runs around the block, just
73:30 you know, la la la And just sitting there going, you're killing
73:34 , right? My wife's the same she has all that. Right?
73:39 What it does is it only increases size of the Type one. It
73:44 actually help remove the fats and all other things that you see. In
73:49 words, a hypertrophy. All that tone doesn't occur here because the type
73:55 don't get bigger. They don't get hypertrophic. They do grow, but
73:59 don't grow. I mean, look the picture. This actually looks like
74:03 college roommate. But I mean, at that. I mean, he's
74:07 out of shape. He's really good , right in terms of muscle
74:11 But, you know, it's You know, dad bod. Not
74:18 bad. All right now. what you're doing here is you're favoring
74:24 that growth of those type ones which going to give you the same sort
74:28 effects. Now. What does that when you exercise? Do both?
74:35 , build up endurance work on those ones, build up strength type twos
74:41 sit on the sofa and don't do , which I'm not gonna be mad
74:44 you for doing, like Mhm If just want Yes, it's like you
74:58 more of that flexibility. Right? . I mean, I can't plank
75:03 that. Can you plank like Yeah. Yeah, I've got bad
75:10 . I mean, you name All right, real quick. Because
75:13 got a lot to still cover. . Well, so, in terms
75:24 actual mass. Yes. Right. so they're going to be bigger.
75:27 of that is gonna be water, it's also solid in the cells.
75:31 , we're talking about side of skeletal and so on and so forth.
75:33 , hypertrophic muscle, right? A has grown bigger and bigger and bigger
75:37 naturally gonna be heavier than what you with the you know, the ones
75:43 aren't. So Type two becomes bigger the type one. Yes.
75:47 And again, go back, look the sprinter versus the marathon runner in
75:51 pictures and you're going, Yeah, , this guy here is 100 and
75:53 . Wind would blow him over this . You know, you can probably
75:57 a truck last little bit. Sedentary leads to skeletal muscle mass loss.
76:04 should be obvious to all of Right. I mean, we had
76:07 years of muscle mass loss, Yeah, Yeah. But this is
76:13 really good example of this. You tell this person was in a
76:16 You can see the leg that she using. Here's the leg that she
76:20 using and you can see that's what would be. Don't use the muscle
76:25 is not going to waste the time energy keeping it in shape. It's
76:28 to use the energy in much more ways like storing fat, right?
76:36 . This is important, right? you atrophy it is reversible, but
76:41 that fiber dies, it doesn't replace . Alright. So damaged muscle cells
76:49 not be replaced, they will be . Atrophy is not damage. Atrophy
76:54 just I'm not sending energy. I'm using it. I'm not gonna waste
76:57 energy. Yeah. Mhm. I don't know if it's it's probably
77:07 in terms of a psychological I muscle is muscle. It's just going
77:11 do like I said, the resistance you give it is going to respond
77:16 the resistance. Right? So, now, I can't I don't I
77:21 try to lift a lot. I'm trying to maintain a state of healthiness
77:26 I work out, right? I've as much muscle mass as I that
77:30 think is necessary for me. I I try to challenge myself a
77:33 bit, but I don't really push like, what is my max?
77:37 don't know. I have no I haven't listed lifted a max weight
77:40 I was in high school, But I sit there and I push
77:44 , Right? And so my muscles gonna grow. But if I sustain
77:47 my muscles aren't gonna grow, they're going to maintain that cardiovascular activity and
77:52 not really cardio but it's you working. Yeah. Yeah. Why
78:01 you try it for a month? what happens? No, I'm
78:05 But the idea is that remembers just your bones. Let's think of
78:10 We love grandma right? But we a little upset that grandma's not moving
78:15 all that much. She needs to out more, pick, pick the
78:18 in their yard, do stuff like . All right. Or be like
78:21 grandma 96 years old and goes out shovel snow on her sidewalk.
78:27 Crazy lady. Anyway, but think grandma's muscle mass, grandma doesn't do
78:33 lot of movement, right? She brittle bones. One because she's uh
78:38 has a little bit of osteoporosis because female, greater chance of that.
78:43 primarily because as we age, we more sedentary. All right. Part
78:48 the reason my body looks the way does because it's really, really comfortable
78:51 sit a lot. Right? But for example, I ate a little
78:58 less and I worked a little bit . Did a little bit less
79:01 My bones are going to have to with the stress I put on them
79:06 my muscles have to deal with the that I'm putting on them as
79:10 So they become bigger and stronger. when you're sedentary, you're not actually
79:16 the muscles so they're not going to the energy to grow them or maintain
79:21 . They will only maintain them to extent that they need to maintain them
79:24 do the activities that you're doing. your activity is literally walking to the
79:30 back to the sofa, you don't to maintain a lot of muscle to
79:33 that, Right? And that's what did for two years. We all
79:37 in our homes, right? Watched or Tiktok. Right? And every
79:46 and then we make our way to kitchen because you know, refrigerator be
79:50 lot easier if we just put those fridges by our beds, just open
79:54 up. All right. Now, you got out of the house and
79:58 out and stuff like that, that's for you. That's awesome. So
80:02 I wanna do is I want to as much time as I can
80:05 What do I have? Like I like 20 minutes to talk or introduce
80:09 to the ideas behind the nervous And really what we're gonna do is
80:13 gonna try to talk about the protective of the central nervous system. So
80:18 be clear, there are two central or two principal parts to the nervous
80:22 . The central nervousness is the brain the spinal cord when we're talking about
80:26 nervous system, this is the control , this is integration, we're taking
80:30 information and we're processing it and we're the information to go do something.
80:34 right. The peripheral nervous system is else. All right. So,
80:38 you think central brain and spinal cord then everything else is going to fall
80:42 the peripheral, on the periphery. nerves, peripheral ganglia, which we're
80:48 to learn about a little bit periphery. And this is where we're
80:51 to process that information. I may process but do the actions that the
80:57 nervous is telling us to do. also where we receive information. So
81:01 I step on attack, I'm receiving information through the peripheral nervous system.
81:06 setting that information up into the spinal and then I send information back out
81:11 the periphery, back down their nerves tell me to lift my leg.
81:15 ? I might also send the information my brain and make me Oh
81:18 I got to say ouch alright. processing brain and spinal cord, it's
81:24 just brain, It is spinal There are some principles when we're dealing
81:31 this. The central or the nervous that are that kind of govern how
81:37 organized. Alright, so lower levels relay messages up to the upper
81:43 All right, well, that kind makes sense. Right? So the
81:48 centers are really is the brain but are lower centers in the spinal cord
81:52 the lowest centers are gonna be external that. All right. There's going
81:57 be strong structural and functional patterns of , meaning that it's not just a
82:04 of mishmash or criss crossed wires. right. Basically. Information in the
82:10 the lines and the nerves and or neurons that are sending information to and
82:14 our highly highly organized and information goes very specific places within the higher
82:20 Right? So, for example, processing is going to take place in
82:24 occipital lobe. All right. That's that information always goes. It's not
82:29 well, let's end up to the lobe and see what happens today.
82:32 . It always goes to where it's to go. And there's this topographical
82:38 as well. So, if you to map where the information goes,
82:42 can actually see that. It kind matches the organization of your body.
82:46 , for example, I'm just gonna this. My You can see my
82:49 are on the bottom. My head's the high is the highest point and
82:53 the organization of my brain, my would be central and as I move
82:58 , it's gonna follow the organization of body so that my toes are down
83:02 on this side of my brain, ? So, it kind of matches
83:06 information goes. The last thing is your central nervous system is plastic,
83:11 that you will constantly make changes to structures of the brain, depending upon
83:17 information is being processed. Right? will be internal and external influences.
83:22 other words, your experiences both internally your body as well as externally outside
83:27 going to influence the organization of your . All right. Which is a
83:33 concept to understand when we but when we get there, we'll get
83:38 . All right. Um you've probably of gray and white matter at least
83:43 terms. And what those actually referred is like if you take a slice
83:46 the central nervous system, you'll see that are darker and lighter and really
83:51 they do is they represent different parts the neuron and where they're kind of
83:57 . All right. So when you're at gray matter and really gray matter
84:00 not gray, it's light beige and white matter is not white. It's
84:04 beige. Okay. And so what have here is we got the gray
84:08 , gray matter is primarily we'll set cell bodies are located, right?
84:13 you can think of it as clusters cell bodies that are pressed up
84:17 They're not their axons are going to leaving from where the gray matter is
84:22 . All right. And you'll have beds and you'll see dendrites there as
84:27 . But the idea here is this where information is being processed. All
84:32 . If you have a localized region right there, see these things,
84:38 are great matter as well. And the brain we refer to them as
84:42 . We've we've used that term Alright. when we talk about white
84:48 . So that's all the white You see up here and you can
84:50 there's doesn't matter where you look. matter and gray matter are existing between
84:55 brain and the spinal cord. White represents where you have my eliminated
85:00 In other words, where information is transmitted over distances. And the reason
85:05 white is because the myelin is primarily lipid and so lots of lipid,
85:11 lot of fat kind of looks white that's why it gives it this widest
85:15 . And so what you're doing is connecting different parts of the nervous system
85:20 other parts of the nervous system. you're sending information between one gray area
85:24 gray matter to another area of gray very typically now we want to protect
85:30 of this. And so we've got couple of different mechanisms of protection.
85:34 first level of protection is going to the bone. We've talked about the
85:37 , so we're going to ignore So your cranium is the first way
85:41 protect the brain and vertebrae is how protect the spinal cord. But underlying
85:46 bone is hard. And the truth , is nervous tissue is like warm
85:52 . Alright, It's not a hard . Okay if you get a chance
85:56 dissect the brain in the labs. don't know if you guys are going
85:59 be able to do that. It's fixed structure in other words, they've
86:02 it in a chemical that makes it and hard. And so it's kind
86:06 like a cheese heart, you as a substance, right? But
86:10 want you to imagine warm butter butter left out on the counter. If
86:13 look at it wrong, it starts , right? That's kind of what
86:17 is. And so to protect that from the bone is there's layers of
86:25 tissue membranes is the word I was for called meninges that lie between the
86:32 and that nervous tissue. Now, within these meninges there's this material called
86:38 cerebral spinal fluid. It's fluid, extra cellular fluid that's derived from blood
86:44 also serves as a protective barrier, of as a cushion. And then
86:48 we have the blood brain barrier which a molecular barrier between the blood and
86:54 surrounding tissues. Alright, So what do is we can regulate what goes
86:59 and what comes out of the nervous at the molecular level. So the
87:04 , as I said, there's three or I said, there's membranes and
87:10 you want to do this is Typically what we do is we go
87:13 the outside in because that makes the sense. But if you spell it
87:18 from the inside out, it spells a pad. And so that's one
87:21 that you can remember, it pad easier to remember than dap, you
87:26 , but however you do it I think I'm gonna go inside outward
87:32 I can stick to that. So inner layer is called the pia.
87:35 middle layer is called arachnoid and the layer is called the dura matter.
87:39 right. So we're gonna start with P. M. Matter PM
87:42 Here is your nervous tissue. You see the grooves in the sulk
87:47 Of the brain in this in this case. And the P.
87:50 Matter is the layer that is most affiliated or associated with that nervous
87:56 So what that means is it follows contours of the nervous tissue and because
88:03 serves as that barrier, this is the blood vessels are gonna penetrate into
88:07 nervous tissue to supply the nutrients needed that brain to be functional or the
88:12 cord to be functional for that Alright, so it's very very
88:17 very very delicate. And it's closely . When you cut out a brain
88:22 have to it's like you have to off that layer. All right.
88:29 next layer up which is represented by Right? Here is the arachnoid
88:35 Alright, when you hear the word , what do you think of
88:40 Right? And Rechnitz And spiders? , so that's how you I think
88:46 it is like okay, the reason called the arachnoid matters because there's a
88:51 between the arachnoid matter and the P matter. It's called the sub arachnoid
88:55 and it has all these little tiny is tropically that look like spiderwebs.
89:00 way I think about it, like is where the brain spiders live,
89:04 ? You know, the brain spider is when you sit there and you're
89:06 , you walk into a room into room and you're like, why did
89:09 come in here? Because the brain spiders, you know, affected your
89:13 somehow. Alright. But however, wanna remember it? So, you
89:17 the arachnoid matter. You have the . M. Matter. The sub
89:21 space in the sub arachnoid space. where you're gonna see cerebral spinal
89:26 The tropically hold that wedding holds the matter in position against that P.
89:34 Matter. Uh So that space can formed and then sitting in that sub
89:38 space are also going to be the vessels. The larger blood vessels before
89:43 get smaller and start penetrating into the . M. Matter and ultimately into
89:49 nervous tissue. All right, P. M. Matter. Subarachnoid
89:53 . CSF cerebral spinal fluid. Arachnoid . And then above that, right
89:59 against Iraq annoyed matter is the thickest called the Durham matter. Truth is
90:04 matters not one layer, it's two and they're closely adhered to each other
90:08 in some very specific areas. The two layers have specific names the
90:14 that's the inner layer next to the matter is called the meninges.
90:19 So why is it called the Because it's next to another man inks
90:23 is the singular form of meninges, is very confusing but it is what
90:28 is. All right. So the inks the arachnoid matter right next to
90:35 is the dura matter. That is main ninja layer. And then above
90:39 is the parry osteo later perry next still bone next to the bone
90:47 See how easy this is. as I said, they're hugely closely
90:53 , so you can even see in cartoon They're not only showing one
90:57 right? But we don't have a of it, but there's gonna be
91:01 areas where those two layers separate out where they separate out. You're gonna
91:07 this empty space that gets filled up blood and we refer to those spaces
91:12 between those two layers of the dura dural sinuses, right? And a
91:19 sinus is what is going to serve a vein in the brain. It's
91:26 an area where blood leaving the brain before it joins up with other blood
91:32 and then exits out of the nervous . We'll deal with this latter point
91:41 cfs CSF mix mixes in just a . Alright, so we have three
91:48 brain there. Then we have the X against its sub arachnoid space.
91:53 matter and then we have the dura inside the brain? I'm gonna back
92:03 a little bit. I'm gonna back to their early development. So in
92:07 development the nervous tissue starts out as a tube filled with fluid.
92:14 so think of a long tube. start off in the long tube and
92:18 your long tube you had another little tube that basically had fluid inside that
92:23 . And then as you grew your and your spinal cord developed from this
92:27 called the neural tube and your brain and it still has that space inside
92:33 . And what's left over after it over itself multiple times are these empty
92:38 inside called ventricles? All right now ventricles is where cerebral spinal fluid CSF
92:48 made and it's made from the The cells that line the the ventricles
92:54 called epidermal cells. They're a type glial cells. And the zep India
92:58 cells are responsible for drawing materials out the blood because they're close opposition
93:05 They say I want you and I you and I want you. And
93:07 it's doing is pulling that stuff in it's making the cerebral spinal fluid inside
93:12 ventricles. Now there are four ventricles the names are fairly straightforward.
93:17 We have two lateral ventricles. One on the left and one that's on
93:20 right. All right. So you see that's what the lateral ventricles kind
93:24 look like from the front from the , it's hard to see the
93:27 But you can see it kind of like a pair of horns that follow
93:31 shape of the brain and they come and they converge and where they're converging
93:36 called the inter ventricular foramen. The between the ventricles, right? And
93:42 they're doing is they're joining up with 3rd ventricle. See how complicated the
93:46 are, The first to converge to the 3rd ventricle. Now that third
93:52 which is located in the middle of brain around the diane cephalon, is
93:56 pretty thin. You can see from side, it looks big but here
93:59 is, it's kind of thin. then you see there's a little passageway
94:03 exits out to the fourth ventricle. little passageway is called the cerebral
94:10 Sounds very fancy, you know, a tube. And so the fluid
94:15 the lateral ventricles flows into the third , that fluid then continues on and
94:19 into the fourth ventricle and from the ventricle we're gonna have a couple of
94:24 . Alright. And here the openings to that sub arachnoid space, we
94:29 two that are on the sides. , so 12, that would be
94:32 the side of those would be lateral on the side openings. And then
94:38 have a median aperture. The median would be like right here and what
94:43 doing is it's opening up into that space and that sub arachnoid space then
94:49 the brain, that tube continues on and it forms what is called the
94:55 canal. And when we look at spinal cord, you're going to see
94:58 central canal there. So it's just with these ventricles. Here's a better
95:03 so that you can see all this . Alright? So here the light
95:08 represents the sub arachnoid space. You see how it goes all the way
95:12 the dark blue there that represents that sinus. Remember where the two pieces
95:17 the dura separate? All right, the lateral ventricles. There's the third
95:24 , there's the fourth ventricle. All red stuff. There represents the areas
95:30 we're making cerebral spinal fluid. All . That area where the red stuff
95:36 is called core oid plexus. So they're found in each of the
95:40 So both laterals, 3rd and 4th have this stuff and so they're constantly
95:46 the cerebral spinal fluid so it's filled and that pressure builds up and pushes
95:50 down to the third where you're gonna more. And so more pressure.
95:54 that pushes it down and then more and it pushes it out through the
95:58 and out through the median aperture and through the central canal. And that
96:02 fills up the subarachnoid space and it's because of all that pressure up and
96:07 and then there are these small penetrations granule ations Orville i that penetrate from
96:13 subarachnoid space through the dura And you this little bubble and so that fluid
96:18 filters out into the blood. So always recycling cerebral spinal fluid right?
96:25 making it and then you're recycling and it back to the blood. Now
96:30 fluid has multiple functions. It creates for the brain. It actually has
96:36 same density as the brain. So you were to take a brain and
96:39 it in a big swimming pool of spinal fluid, the brain wouldn't float
96:43 it wouldn't sink. It would just wherever you put. It kind of
96:47 right? It provides protection. It's primarily made up of water.
96:53 is non compressible. It's basically already dense as it can possibly be.
96:57 so trying to compress it becomes very So when you apply pressure at the
97:03 , that fluid or that force will to make the brain move. But
97:08 it's completely surrounded by this fluid, brain tends not to move really
97:13 So it kind of serves as a protection cushion. That's not really a
97:17 but a cushion like protection and it environmental stability basically. It's near or
97:23 to the extra cellular fluid of the . So you can exchange material between
97:28 two areas and so you if you make mucking with the extra cellular fluid
97:34 the brain. There's an outlet for material to leave to ensure that the
97:39 . C. F. Or sorry the CSF um or the ec.
97:44 . Of the brain becomes normalized and kind of what all that tells you
97:49 there. So, there are lots words. I had less words.
98:01 . Okay. Mhm. Like Yeah. No. And.
98:15 So I'm going to be very careful because this will probably be our
98:20 well, do circulation get through that we'll stop before we get a blood
98:24 barrier. Which means I've made up ground I think. But I don't
98:28 . All right. With regard to makeup, basically, remember the way
98:32 I'm making cerebral spinal fluid is I'm and drawing materials from the blood,
98:37 is plasma plus the cells. And is plasma? It's water plus
98:43 Alright. Now, generally speaking, we're talking about E C.
98:47 And I cf or sorry, when talking about the E. C.
98:50 . Where we had the interstitial fluid the stuff that was in the
98:53 So, there's some unique differences. ? So again, plasma proteins is
98:57 of them plus the presence of Well, the CSF is very similar
99:01 that except now, what I'm doing I'm making modifications. I don't just
99:05 interstitial fluid. I want a special . Alright. And that's what it
99:11 . And again, do not memorize chart because that's unimportant to our purposes
99:16 you were going to be a neuroscientist worked on the CSF, you would
99:20 those to your body. But the here is just look how different they
99:24 . I mean, look how similar how different. Right. I
99:26 plasma proteins, lots of plasma no proteins. You know, it's
99:29 sort of stuff. They're very, similar in content. And the reason
99:34 is because of how we make right. We're basically gonna use those
99:38 cells. The epidermal cells pull things . All right. They're gonna pump
99:42 sodium, which causes water to And then it basically pulls in other
99:46 that it deems necessary to make And there's just some examples of some
99:51 that it uses. Right? And once once you've created that cerebral spinal
99:57 , it has this unique makeup. a lot like plasma, but not
100:02 . Right. And then that's the that's going to be filtered out and
100:06 and around this theirselves. Now, be clear, CSF is not extra
100:11 fluid of the brain, Right? what's on what's on the floor of
100:15 CSF starts with a P ends with matter matter what's on the ceiling.
100:24 matter. Right? So, it between those two. There's barriers between
100:29 , right? It's in its own compartment down over here is the brain
100:33 . It's covered by that P. matter. So, there is no
100:36 interaction between the CSF and the brain itself. It's a separate compartment.
100:43 surrounding the brain tissue down in that's where the extra cellular fluid of
100:47 brain is. You still have blood that are penetrating through, right?
100:52 gonna talk about the blood brain barrier just a moment. But the idea
100:54 is that that fluid down here can exchange with the fluid up here because
101:00 just a barrier. It's a membrane sits between them. All you gotta
101:03 is pass things in between them. right. So, functionally it's a
101:10 barrier, but also functionally it's an protective barrier as well. Now,
101:17 have, like I said, two . I know you got to get
101:19 of here. All right, but want to just get this done and
101:21 we'll move to the next thing. , with regard to the to the
101:25 the circulation, we saw how it . It starts up here through the
101:28 , goes out through the apertures and goes around through the subarachnoid space to
101:33 granule ations. Your body is making 125 - 150 mils per day.
101:38 I steal your Fanta bottle for a . So, I will not touch
101:41 edges just over here. This is L. 120 500 500 500
101:48 Alright. Alright, 125 is a of this. That is how much
101:55 spinal fluid you're making right right up , or that's how much is in
102:01 . You're making this much the whole per day. So you're replacing your
102:06 spinal fluid four times daily in terms circulation. Alright, But again,
102:13 the pathway through it, and the that you're moving it is because you
102:16 silly on top of the epidermal they're going go fluid go and you're
102:21 pressure and that's driving it forward. If you actually prick through the p
102:27 matter, right? Like if you an epidural, one of the things
102:30 look for is let me see if fluid comes out because there's enough pressure
102:35 there to draw, or force fluid through that epidural uh needle, and
102:40 they're like, oh yeah, we the right spot, then they go
102:42 and they cap it. Yeah, actually kind of cool. I
102:47 I saw the look on your like, you know, but that's
102:50 , that's just a big picture, you can see a little bit
102:54 Alright, so when we come this is where we're going to
102:56 we're gonna start at the blood brain , and then we'll hopefully catch up
103:01 ourselves by the next class,
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