Leukocyte extravasation | leukocyte adhesion and rolling

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hello friends welcome to another video

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tutorial from shamans biology we've been

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talking about the immune system and

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immunology lecture series and this is

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the fifth video of the immunology

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lecture and in this video we want to

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talk about the leucocyte rolling

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addition and release of leukocyte from

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the vessel into the infected area of the

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tissue which is liquid side extraversion

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so we'll talk about these three things

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together now remember as this is series

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of videos it will be very beneficial for

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you if you watch the previous video so

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keep watching the videos as a series

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because in the last video we talked

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about the very first part of the defense

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mechanism of our body which is the

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integral part of innate immunity

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involved with the inflammatory response

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in the inflammation what happens

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whenever there is a damage due to the

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wound or something bacteria take entry

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for example here we see the bacteria is

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this blue colored things here so Mackel

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is dendritic cells which are present

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there in the tissue or let us say

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neutrophils which can also be present in

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the tissue

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they will engulf those bacteria metrof

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watch for example same as a phagocytosis

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now after this engulfment it will also

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start releasing certain factors okay

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the factor is called interleukins

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remember there are some molecular

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patterns that are found in the bacteria

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which is unique to them and this

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macrophages dendritic cells which are

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the prime cell so the first line of

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cells against those those pathogens they

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can find those pathogen associated

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molecular patterns and using those

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pathogen associated molecular patterns

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this macrophages or dendritic cell they

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can exactly sense the type of pathogen

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that are entering into our body they can

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sense it once the sense that pathogen

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they start engulfing that pathogen

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inside now this sense that pathogen with

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the help of the presence

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of different receptor molecules like

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toll-like receptor TLR nada Regan we

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talked about all these in details so

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with the help of these things they can

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recognize the presence of the pathogen

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and then once they engulf the pathogen

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they start releasing interleukins which

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are the part of chemokines

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molecules now the thing is once they are

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releasing these interleukins which is

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interleukin 1 interferon type 1

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interleukin 8 and different types of

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interleukins and also some other things

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like histamines bloody kindness liquor

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trains which are also secondary response

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chemicals but these are the primary

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response chemicals that are being

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released in the infected tissue at the

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start point of the infection

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once this interleukins are released and

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the cytokine is a release those things

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are now filled there the concentration

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of those in turn because let me change

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the color let's take the green color for

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the concentration so the concentration

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of those interleukins are getting higher

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and higher in the tissue side that thing

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is acting as a chemical movement a

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movement towards chemical that thing is

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known as chemotaxis for the leukocytes

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that are present in the blood vessel

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okay so leukocytes are present in the

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blood vessel it's rolling it's moving

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through the blood vessels because the

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blood is always circulating but once we

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have high concentration of this in

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cytokines like interleukin 1 interferons

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this cytokine concentration is telling

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this leukocytes to migrate towards

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themselves that is known as a chemical

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derived movement or chemotaxis so

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leukocytes will move from the red blood

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from these vessels into the infected

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adjacent tissue area by the q axis

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mechanism but there is a barrier that is

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the endothelial wall of the blood vessel

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you see the blood vessel wall though is

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thinner but still there are cells

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covering it it is a wall it's a physical

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wall which these leukocytes needs to

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evade to come the adjacent tissue it

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cannot damage the wall because if itself

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damage the wall that will be a bad thing

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to do

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so this is some way that cells will

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migrate from this vessel into the tissue

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that whole process we are going to talk

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about right now and why this is

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important because there are different

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types of leukocytes you know all those

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cells we know of T lymphocytes are there

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which are different but the leukocytes

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cell means your cinephile basophils

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lymphocyte monocyte okay so all this

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cells that we know of in this white

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blood cells they are functional cells

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and they are required for the helping

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and the generation of some more unified

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response against that pathogen that will

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be known as awkward immunity one such

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very important cell is neutrophil that

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will be required in this area okay so in

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this case they want those lymphocytes

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they want all those lymphocyte cells now

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before going into there they those

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leukocytes cells are moving through this

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blood stream and they are moving really

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fast because the red blood cell is

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moving and also they are moving with

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themselves very very fast movement so

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the first thing for taking them into

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this tissue is that to slow them down

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and finally stop them if you do not stop

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somebody is running running like that

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let us apparently this thing is running

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and flowing I want to take this to my

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side the first thing I should do is slow

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it then stop it then take it so there

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are three different stages will be there

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first is the attachment or tethering of

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the leucocyte into the endothelial wall

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okay this is the attachment or T during

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that is known as a cap cheering the

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first thing capturing or tethering

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second is the process called rolling

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what tethering means there should be

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some way this leukocytes cells will be

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in contact with the endothelial cell

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that is the attachment only

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okay the first thing capture then we do

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the rolling rolling means once we

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capture those two things once we capture

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the endothelial cell with the leukocytes

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then we can start it rolling rolling

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means is not moving and running it means

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is it's just circulating it's just

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rolling very very slowly then the third

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part is the firm capturing or firm

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attachment then going to be a proper

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attachment but it will be not that

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strong form very firm attachment over

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there and then once the firm attachment

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is done means after the end of the firm

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attachment we can tell the leuco side is

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now stopped then the fourth part

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squeezing that leukocyte between the mm

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endothelial cell this is the fourth

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thing so there are four stages for the

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whole process let me write those stages

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here first is the contact second is

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rolling the third one is firm attachment

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and the fourth one is the migration of

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the leucocyte into the infected tissue

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these are the four stages if you break

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them down for our convenience now for

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this first thing of which is called

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contact I told you no contact means the

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leukocytes should be in direct

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interaction with the endothelial cell

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surface how they achieve this there are

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specific proteins that leukocytes start

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expressing so as now normally this

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proteins are expressed in neutral

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leukocytes all the time but these

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endothelial cells start expressing only

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when they sense this high concentration

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of intelligence once this cells start

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the sense of the interleukin

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concentration going high the endothelial

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cells start expressing a protein on the

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surface of the cell which is known as

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selecting okay now what is that let me

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just draw simple thing this is let us

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say the red blood this is the blood

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vessel and these are let us say the

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endothelial cells okay

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and let us say this is the leucocyte

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that we are talking about so the

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leucocyte they are having a specific

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carbohydrate moiety outside that is

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known as signle lated EU is X this is a

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carbohydrate structure known as silent

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Lewis X molecules that will always

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present there okay in the surface of

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this leukocytes but the endothelial

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cells do not have anything there so

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normally when there is no infection

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there is no interleukins

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the leukocyte is moving very fast along

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with the blood stream but now once there

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is the presence of all those

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interleukins and all those cytokines

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interference and all those things the

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concentration is going high in the

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nearer tissue that influence this

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endothelial cells to produce

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selectins which is another cell surface

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molecule so all these cells start

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expressing another surface receptor

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non-selective example of selecting is e

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selecting P selecting okay with the help

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of this selecting and selecting which

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are present both side in the leukocytes

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as well as so the Sally later lewis x

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the function is selecting so it's just

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like kind of looking like a hook that is

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a hoop from the leuco side and the hoop

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coming from the endothelial cell so once

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they they create this hook so there can

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be contact between leukocyte and this

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surface receptor of selecting contact

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could be made so as the process of

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rolling rolling means slowing down a

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little bit because now let us say two

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types of selections that are present and

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they are looking like hooks one from the

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leuco side from from the endothelial

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cells so as they are moving the hooks

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are connecting again disconnecting

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connecting and disconnecting so what is

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going on they are not allowed to move

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very fast but they can kind of a roll on

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the surface of this selecting and the

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interaction with the selecting and the

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selected lewis x they can start kind of

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roll look like a walking once first they

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are flying they're running but now due

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to the expression of this selecting we

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make them to walk slowly let us known as

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a rolling or leukocyte rolling so select

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themes are not enough to completely slow

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down but completely stop but it slows

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down the movement a little bit after

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some time when this getting kind of

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rolling thing is going on

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then this endothelial molecules and this

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leukocytes both leukocytes also have

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some other surface molecules known as

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LFA one leukocyte rolling factor this is

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called LFA one they have this LFA one on

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their surface but this LFO one cannot

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interact with selecting it

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interact with another type of surface

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receptor molecule known as integral

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which is also being expressed by this

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sense by this you endothelial cells so

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now what we will see endothelial cells

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start expressing this intervenes so once

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they start expressing the integrins

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which is drawn in the green color this

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LFA one let's say this is the LFA one

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and this is one example of integrins I

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am one

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so LFA one can interact with the I am

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one which is present on the surface of

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endothelium so this binding of LFA one

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with the I cam one can actually stop the

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movement and rolling of leukocytes okay

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selecting interactions will slow down

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leukocyte LFA 1 and I came 1

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interactions we stopped the leukocytes

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completely once the leukocyte rolling is

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completely stopped now it is firmly

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attached to some part of this

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endothelial cell so it is now stopped

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which is called the firm attachment so

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for the firm attachment we need intake

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greens for slowing down we need a

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rolling we need silly things okay that

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is the idea now again though they have

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this LFA one from the beginning the

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leukocytes and if they have even I can

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but this interaction won't be that

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strong if there is no Intel UK this LFA

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one attachment with ikm one interaction

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is not that strong usually but if there

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is a presence of interleukin 8 in this

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endothelial cells surface because they

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they get this Intel

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in this area and this showcase that on

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the circus surface and then this

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leukocyte have those interleukin 8

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receptor so the binding of LFA 1 and I

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came on gets much stabilized

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once this leukocyte interacts with

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interleukin 8 with the help of

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interleukin 8 receptor so with the help

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of this three range job binding finally

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the interleukin can be stopped

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okay integrins can do its job but the

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integral functionality will be enhanced

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in the presence of interleukin 8 okay

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that thing will be done here

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once the LICO side is rolling is done

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and it's kind of a fixed in the area

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then we need to do what is known as the

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extra vision of this leukocyte so the

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leucocyte migration from this

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endothelial and actually through this

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endothelial layer of the cells vascular

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endothelial cell into the tissue which

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is just in the attached proximity with

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this blood vessel right and for this

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fourth thing or migration they also need

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the help of some integrins like I cam

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peak M these are some other integrals

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which help this process because you know

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once it is interact and attached this

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the junction between the two adjacent

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cells they start they start actually

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modifying their body the leukocytes

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start modifying its body with the help

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of acting rearrangement in acting fibers

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acting fibers start to rearrange the

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cell and start producing reports once

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you produce pseudopods that can take

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entry through this adjacent endothelial

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vascular endothelial cells and this

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leukocyte now can easily squeeze through

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those two endothelial cells it is not

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damaging it squeezing through the inner

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space between these two cells into space

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now as its squeezing through it it will

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take some time for this whole process to

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work but this squeezing is done because

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they are moving the towards the

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interleukin constant

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which is high in this tissue compared to

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the blood vessel through the process

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called chemotaxis okay so that is how

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the whole process of leukocyte rolling

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addition and movement occur and this is

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the second part of the innate immune

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response because you know the first part

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is the development of all those

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interleukins in the first place movement

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and migration of the cells to the place

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causing inflammation inflammation in the

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other hand drives this leukocytes to

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come from the lead blood vessel into the

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tissue infected tissue so that is the

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second part and once this leukocytes

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start coming there so they will see some

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more cells start to gather in the

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infected area so it will again further

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rise the concentration of the other

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interleukins interference even the

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production of tumor necrosis factor

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along with that they will start causing

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more and more of a inflammatory response

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because it will boost the inflammatory

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response in further stream so that in a

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sense is a process of leukocytes rolling

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and adhesion and my tration I hope you

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understand this video if you like this

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video please hit the like button share

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17:55

through this whole series of immunology

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video I hope it will help you thank you