TEJIDO SANGUÍNEO | ¡Fácil explicación! (Histología)
Hello, how are you? I'm
Dr. Romy, and this is Sala QSP, your
medical channel. In today's video, I'm going to talk about
blood tissue, so without further
ado, let's begin. To
talk about blood tissue, it's important to
remember that in connective tissue, we had
three types:
embryonic,
mature, and
specialized. Blood tissue is precisely
a type of specialized connective tissue.
With that introduction,
we can begin our topic: What is
blood? Blood is
composed of cells and
extracellular material. These cells are fluids
and some solutes that form a
viscous element called
blood tissue.
In an adult, it represents approximately 6 liters. This
means that an older adult
will have approximately 6 liters of blood,
which represents 7 to 8% of their
total body weight. For example, if I
weigh 50 kg, those 50 kg represent 100%
of my total body weight, and I want to know
how many kilograms of my 50 kg are equivalent to
my blood, using a rule of three
will give me a result. 3.5 kg, so
out of the 50 kg I weigh, 3.5 kg
corresponds to my blood. You can also
do this calculation with a
slightly simpler formula using your
body weight multiplied by
0.07, which will give us the same
result. What are the functions
of blood tissue? It will help us
transport oxygen and
nutrients, it will transport waste products and
carbon dioxide from the cells, it will
help in the distribution of hormones and
regulatory substances, it will maintain
homeostasis, and it will transport cells and
humoral agents of our
immune system. How is blood composed? It will
be composed of 45%
cells and 55% plasma. The
cells that make up
blood will be a red series, which
we know as red blood cells, which will
be formed by erythrocytes, a
white series, which will be our
white blood cells, and finally, we will
have platelets. As for the
plasma, it will be made up of
91-92% water, 7-8%
proteins, and 1% electrolytes. 1 to 2%
per solute. So the component that
makes up the largest amount of plasma will
be water. We will also have certain
proteins, for example,
albumin, globulins, and
fibrinogen. Let's talk about hematocrit.
Hematocrit is a test that
will help us measure the number of
erythrocytes in our
blood. We will put a
blood sample in a microhematocrit tube and
take it to a centrifuge. This
centrifuge will spin
this tube thousands of times per minute,
which will help separate the
liquid and solid parts. The
liquid part, which we will see at the
top, will be the
plasma, and the solid part, which will be
at the bottom, will correspond
to the number of erythrocytes.
So, hematocrit allows us
to measure the number of erythrocytes
a person has. Normal values
worldwide are 35
to 45% for women and 39 to
50% for men. However, these values will vary.
Modifications In those patients
who live in high-altitude regions
This is because at high altitudes there is
a lack of oxygen and the body, to
compensate for this lack of oxygen, begins to
increase its population of erythrocytes, which is why
at high altitudes women
normally have a hematocrit of
42 to 50% and men of 47 to 60%.
Here we have a table from the
histology book by Paula Ros showing the
cells that make up blood,
the formed elements of blood.
The normal number of erythrocytes
in men is 4.7 to 5.7 million
cells, and for women, 3.9 to 5
million cells. As for the
white blood cell series, which are leukocytes, the
normal number for both men and women is
3,500 to 10,500 cells per
liter. Regarding platelets, the
normal amount is 150,000
to
450,000 cells per liter. Remember that
the number of erythrocytes will change
in patients who live at
high altitudes because the
lack of oxygen causes their
erythrocyte population to increase. Therefore, at high
altitudes, the normal
erythrocyte count for men
is 5.4 to 5.6 million cells per
liter, and for women, 4.7 to 4.9
million cells per liter. Let's talk
a little bit about the proteins that
make up plasma. Remember that
these represent approximately 7%,
and the main ones are albumin,
globulins, and fibrinogen.
Albumin is the main
protein component of plasma; it is
synthesized in the liver. These proteins
exert oncotic pressure and
also act as
transport proteins, helping to
transport certain drugs.
Albumins are proteins that, wherever they are found, whether
in tissues
or blood vessels, will
draw water along with them. That's why it's
important for these albumins to be
present in the blood
vessels because they
prevent the fluid
flowing within our
blood vessels from leaking into our
tissues. In a pathological case, when there is
a loss of albumin from our
blood vessels and we have a greater
amount in our tissues,
this albumin will also leak into our
tissues. This results in
edema, which is the accumulation of
fluid in the interstitial space. The
level of
our tissues is affected
because when the amount of albumin
in the tissues increases, it draws water away
from our blood vessels, causing
the affected tissue to become waterlogged.
Normal albumin levels range
from 3.4 to 5.4 g/L. Another
important protein in
blood tissue is globulins. We
have two types: immunoglobulins, which are
antibodies, and non-immune globulins,
which are transport proteins.
We also have fibrinogen, which is
synthesized in the liver and
participates in coagulation.
Thanks to thrombin, fibrinogen is
transformed into fibrin, and fibrin acts
like glue, binding
cells—
erythrocytes and platelets—to form
a clot and subsequently a scab.
Let's talk about the difference between serum and
plasma. It's important to emphasize that when
we take a blood sample
without the use of an anticoagulant,
for example, through
venipuncture, serum is serum, while plasma is plasma. This will
be the blood sample that we
will take using an
anticoagulant; an example of this is
citrate and heparin. The plasma
will also contain fibrinogen. Now let's talk about
the main cells that make up
our blood tissue, which are
the erythrocytes.
Erythrocytes are anucleate cells; they do
not have a nucleus, nor do they
have organelles. Their main function is to
transport oxygen and eliminate
carbon dioxide. They
live for approximately 120 days and have a
surface area of 140 microns squared, a
diameter of 7.8 microns, a thickness
of 2.6 microns at the periphery, and 0.8 microns at the
center.
This cell has
the shape of a biconcave disc
with a depression in the
center. Now, speaking of the
plasma membrane of this cell, it is
important to remember certain
proteins. The plasma membrane of this
cell, like any other
plasma membrane, is a bilayer. The phospholipid layer
contains
transmembrane proteins that span
the entire plasma membrane. We also
have peripheral proteins. The
important transmembrane proteins to
remember are glycophorin
C and Band 3 proteins. Other
peripheral proteins to consider
include
alpha and beta spectrin, the
Band 4.1 protein complex, and the ankyrin protein complex.
While erythrocytes
lack organelles and a nucleus, they do
have an important element inside:
hemoglobin. This
protein helps
transport oxygen and
carbon dioxide. Without hemoglobin,
the erythrocyte cannot perform this
function. Remember that a protein is a
chain of 10 to 12 amino acids.
When approximately 5 to
10 amino acids are joined, it forms a polypeptide. The
union of five amino acids simply
forms a peptide. So, why
is it important to remember these
concepts? Because this protein,
called hemoglobin, is made up of
four polypeptide chains.
These polypeptides that will
form this protein will be the
globins, and we will have four types of
globins: alpha globin, beta globin,
delta globin, and gamma globin.
So, hemoglobin will be
formed by four globin chains.
What will these four globin chains be
that will form the
hemoglobin protein? It will be formed by
two alpha chains and two beta chains.
In addition to these
four polypeptide chains,
four other proteins will be added to them,
which will be known as the heme group.
The heme group will be the
porphyrin protein plus an iron molecule in
its center, and it is to this
iron molecule that the
oxygen or carbon dioxide molecules will bind. So,
we can see here that the
heme group will be formed by a protein
known as porphyrin, and in its
center, we will have an
iron molecule. That is the heme group that will
bind to the four globin chains of
each erythrocyte. It can transport
four molecules of oxygen or four
molecules of carbon dioxide. Why is this?
Because we only have four
iron ion molecules to which
oxygen and carbon dioxide can bind, and this is
how the hemoglobin in erythrocytes is formed,
allowing it to fulfill this vital function
for our tissues. During
gestation, different
types of hemoglobin are synthesized:
hemoglobin A, hemoglobin A
sub2, and hemoglobin F or
fetal hemoglobin. Hemoglobin A is the one
found in the greatest quantity in an
adult, constituting approximately 96%
of the hemoglobin present in our
body. Hemoglobin A sub2 is
found
in approximately 3%. On the other hand,
hemoglobin F or fetal hemoglobin
constitutes only 1% of the
hemoglobin present in our body.
However, during fetal life, there will be a
greater quantity of this type of
hemoglobin because it is the
main hemoglobin of the fetus. How will it be?
Hemoglobin A is composed of two
alpha chains and two beta chains. Hemoglobin A2
is composed of two
alpha chains and two delta chains, and
fetal hemoglobin is composed
of two alpha chains and two gamma chains.
Now let's talk about the [ __ ] blood
group system. We have four
blood groups: group A,
group B, and group AB.
Whether a person has
type A, type
B, or type AB blood depends on the
presence of certain proteins
found on the
plasma membrane of the erythrocyte. These
proteins are the antigens. As I
mentioned, there are certain
proteins on the plasma membrane of the
erythrocyte. It is to these peripheral proteins that
other proteins, known
as antigens, bind. This is what gives
an erythrocyte its characteristic of being
group A, group B, or group AB. Where do
these antigens bind? They
bind to glycophorins. All
human beings have enzymes that
synthesize the antigen, meaning
that all They will derive from blood
type O. Here we are seeing the structure
of the antigen O, which is the base antigen.
However, for a person to be
group A or group B, these people will
have certain enzymes that will change
the antigen or add a molecule,
giving it the characteristic of
becoming group A or group B. For
a person to have group A blood, their
base antigen O will undergo a
modification thanks to the enzyme alpha-
glucosyltransferase. People with
type A blood have this enzyme, alpha-
glucosyltransferase, which will
add a molecule of n-ethylgalactosamine to this base antigen. The
addition of n-
ethylgalactosamine to the antigen O
converts the antigen O into antigen A, and that is
how we get type A blood.
People with type B blood will
have the enzyme galactose transferase,
which will add a
molecule of galactose to the base antigen O. So, the
addition of galactose to the antigen O
converts the blood to type B. And
people with type AB blood will have
both enzymes: alpha-
glucosyltransferase and galactose.
Therefore, transferase will have
both types of proteins on the surface
of the erythrocyte's plasma membrane; they will
have type A antigens and
type B antigens. The relevance
of knowing the blood groups is
that they will produce certain
antibodies. People with
type A blood will create
anti-B antibodies. Why? Because they will only
recognize other erythrocytes that
also have the type A antigen. When
an erythrocyte with type
B antigens comes into contact with a
type A erythrocyte, the latter will secrete
anti-B antibodies because it does not recognize the proteins
on the plasma membrane of
this erythrocyte. On the other hand, those with
type B blood will create
anti-A antibodies for precisely the same reason:
since the antigens or proteins
on the plasma membrane of
type B erythrocytes have galactose, they will not
recognize other erythrocytes that do not
have this protein. People
with type AB blood will not have
antibodies because they have both
proteins on their surface. Having
both proteins allows them to recognize
type B or type A cells because they have the
same proteins. Not having antibodies
and being able to receive blood types A, B, and O
because they don't generate
antibodies against type O either, they are
known as universal recipients.
People with type A blood
can receive blood of any type. Type
O will generate anti-
A and anti-B antibodies because type A and
type B erythrocytes have proteins foreign to
type O, they will generate antibodies that
destroy these cells because they won't
recognize them. However, a
characteristic of type O is that they will
be universal donors. Why? Because
types A, B, and
AB do not generate antibodies against
type O, therefore type O can
donate to any group. Okay, why don't
any generate antibodies against type O?
Because they all have the
base of this protein. Let's talk about the
Rh blood group system. Besides
having a blood type, whether type O, A, B,
or AB, we also have an
Rh system. What does the Rh system mean?
Like antigens, these are simply
proteins on the
plasma membrane of the erythrocyte. These
proteins, known as
Rh antigens, will bind to
transmembrane proteins that... The
Rh30 polypeptide and the
Rh50 glycoprotein are Rh antigens. Rh derives from *Resus*, a monkey
in which
these antigens were first found. There are more than 47-49
types of Rh antigens; however, the
most important are the D antigen, the
C antigen, and the E antigen.
The
D antigen is the most abundant. These proteins,
found on the plasma membrane of
erythrocytes, determine whether a
person is Rh positive or Rh negative. A
person with the Rh antigen or protein
on their erythrocytes is Rh
positive, and a person without this
protein on their plasma membrane is
Rh negative. When an
Rh positive person comes into contact with an
Rh negative person, they generate antibodies that
destroy the Rh negative erythrocyte
because it is different and
foreign to the Rh negative erythrocyte.
This is what
happens when an Rh negative mother
has an Rh positive baby in her womb; the
mother's blood comes into contact with the baby's blood. The
mother's blood recognizes the
baby's red blood cells as
foreign simply because they have the
Rh protein. Since these red
blood cells are unfamiliar to the mother, she begins to produce
antibodies against her
own child's blood.
The baby's red blood cells begin to be destroyed. In a
desperate and compensatory response, the baby
begins to produce more red blood cells, causing
its organs to swell. This
results in kernicterus, a
pathology that affects the
central nervous system and is quite dangerous.
This clinical condition, where the mother
begins to destroy her
own child's blood, is known as
erythroblastosis fetalis. Now let's
talk about the cells that
make up
the white blood cells,
or leukocytes. There are two types
of leukocytes:
granulocytes and
agranulocytes. Granulocytes are
cells that possess
granules, while agranulocytes are cells
that do not possess granules, or may
contain very small granules in
small quantities. Among the granulocytes,
we have neutrophils,
basophils, and
echinoderms. Among the agranulocytes, we
have lymphocytes and monocytes.
Let's talk first about neutrophils.
Neutrophils are the
most abundant leukocytes
in the blood. They measure approximately
10 to 12 microns. Their nucleus has
multiple lobes
connected by thin cords, which are
also nuclear material. So,
neutrophils have many lobes connected
by thin cords, which are also
nuclear material. They constitute
approximately 60 to 70% of
total white blood cells and have a
lifespan of approximately one week.
How many lobes can a
neutrophil have? Two to four lobes.
Precisely because of the number of lobes
this cell has, it is also
called a polymorphonuclear leukocyte.
Neutrophils in women have
a tail on one of their
lobes, known as a...
The Barr body is
only found in cells that have the
X chromosome, specifically in
female cells. Here we can see in the
histological slide the neutrophil or polymorphonuclear leukocyte,
which will have a nucleus
with multiple lobes joined by
thin cords. And women will have
this little tail on one of their
lobes, known as the
Barr body. Neutrophils will
have three types of granules:
primary or azurophilic granules.
Azurophils are simply
lysosomes. Okay, the primary or
azurophilic granules are simply
lysosomes. We will have
secondary or specific granules, and
tertiary granules. These are mobile cells that
leave the circulation and
migrate to the connective tissue. They are one of
the main defense cells of
our body. Let's talk now about
eosinophils. Eosinophils are
the leukocytes that mainly
act against parasites. They measure
approximately the same as the...
Neutrophils will have two lobes in their
nucleus; they will be bilobed. They will
constitute 4% of total white blood cells
and will have a lifespan of
approximately 3 to 4 days. Like
neutrophils, they will have
azurophilic granules, which are lysosomes, and
specific granules. What will
these specific granules be?
We will have the major basic protein, the
cyanophil cationic protein,
the eosinophil peroxidase, and
finally, the
eosinophil-derived neurotoxin. These
first three granules will be responsible
for exerting a cytotoxic effect on
protists and certain parasites, and the
eosinophil-derived neurotoxin is what
will cause dysfunction of
the parasites' nervous system.
We can see this here in a slide
where we can see an eosinophil. Here
we have the cell, and
we can observe that its nucleus will
have two lobes. Ova, right? It looks like a U, a
horseshoe, it can also look like a little
kidney. So, in that way you
'll recognize the ecii, speaking of
basophils, which will also be
cells that will have granules. They will
measure approximately 10 microns, they will
have abundant and large granules, they will
represent 0.5 percent of the
total white blood cells, and they will live
approximately two to three days. They will also
have specific granules and
azurophilic granules. How are we going to
recognize a basophil on the histological slide?
We're going to observe a cell
like you're seeing here in this photograph
or in this one, where we're going to see the
cell with a central nucleus, but
before seeing the nucleus,
the number of granules will be more visible. As
you can see, it looks like multiple dots,
multiple specks that we're going to find
on this cell. Those are the granules of
the basophils. So, whenever
we see this cell with many granules,
as we're also seeing on this
histological slide, we're talking about a
Basophils. Now we're going to talk about
those cells that don't have
granules, the
agranulocytes. Let's talk first about
lymphocytes. Lymphocytes measure
approximately 6 to 15 microns, have
a spherical nucleus with a slight
indentation, constitute
approximately 30% of
total white blood cells, and have a lifespan
of approximately a few months to
several years. We have three types of
lymphocytes: T lymphocytes, B lymphocytes, and
natural killer cells. T lymphocytes
differentiate in the thymus and
participate in the destruction of
antigens that enter our
body. Let's talk first about
CD8 cytotoxic lymphocytes. These
lymphocytes are responsible for
cell-mediated immunity. They are
cells that destroy other
cells that have been modified by
viruses or cancer cells.
CD4 helper lymphocytes are those
responsible for
antibody-mediated immunity. These lymphocytes
will act with the major
histocompatibility complex. Regulatory T lymphocytes
will prevent
excessive activity of the immune system,
meaning they will control other
cell types. Gamma and
Delta lymphocytes will act against
infectious agents and also against
tumor cells. B lymphocytes are those
that will differentiate in the blood vessels and
bone marrow and will participate in
antibody production; they will express
immunoglobulin M and also
immunoglobulin D. Natural
killer lymphocytes are... These are going to be the
natural killers of our body. How are we going to
recognize a lymphocyte in a
histological slide? We'll see that we'll
have a cell where the
plasma membrane and cytoplasm will be
scarce, almost imperceptible. Why? Because
the nucleus will be so large that it will
cover almost the entire cell, as we
're seeing here in this image. It will
have a very large nucleus that may
have a small indentation. So, a
very large nucleus where we can barely
see the periphery of the cell is a
lymphocyte. Finally, we're going to talk about
monocytes, which are also a
type of granulocyte. They will
measure approximately 18 microns. They will
have a spherical nucleus with a
pronounced indentation. They will constitute
approximately 3 to 8% of the
total white blood cells. They will circulate
in the blood for approximately 3 days.
Monocytes transform into macrophages
when they leave the
bloodstream. When they are in the
bloodstream, they are known as monocytes.
When they leave the blood vessels and
migrate to the tissues, they are known as macrophages.
Macrophages, depending on the tissue they are in,
will
receive different names. Macrophages
found in bone tissue
are known as osteoclasts. When they are
in the tissue of the
respiratory system, they are known
as alveolar macrophages or
dust cells. Kuffer cells are
macrophages
found in the liver. How will we
recognize a monocyte on the histological slide? It
will be a cell where
we can barely see the
cytoplasm and the plasma membrane.
Obviously, here the nucleus is
displaced to one side, but like
the previous cells, it will have
a fairly large nucleus, but
its indentation will be noticeable. As
you can see here, it looks like a heart; it will have
a pronounced indentation, a
large nucleus, but with a
very pronounced indentation. When this monocyte migrates
to the tissues and transforms into a
macrophage, we will see the macrophage
in the same way, a
cell that will have a The central nucleus is
rounded, but it won't be
very large
or pronounced; it will be a medium-sized central nucleus
surrounded by
multiple vacuoles in the cell's cytoplasm. This is what
a macrophage looks like. Remember, a
monocyte when it's in the
bloodstream, a macrophage when it molts into
certain tissues. Finally, we'll
talk about platelets or thrombocytes,
which are cells that measure two to
three microns. They are anucleate and
derive from megakaryocytes. In
fact, thrombocytes are fragments
of a megakaryocyte. They have a lifespan of
approximately 10 days. What are
the functions of platelets?
Platelets
monitor blood vessels, looking for
leaks or ruptures; form
blood clots to plug
any
damaged blood vessels; and repair
damaged tissues beyond the
blood vessels. Thrombocytes have
four zones. These cells have
a peripheral zone located on the
periphery of... These cells have a
structural zone, an organelle zone, and a
membranous zone. Finally, we can
observe here the
normal values for both the red blood cell series and the
white blood cell series, each of the leukocytes, and the
number of platelets. This is a chart
from Rose Paulina's book. Lastly,
we have here a histological slide
where we can see different types of
leukocytes to review. Here
we can see a monocyte because we are
seeing a cell with a fairly
large nucleus displaced towards the periphery
with a prominent indentation, making
its nucleus resemble a heart. Here
we have a neutrophil because we
have a cell that will have
multiple lobes that will be joined
by thin cords, which
will also be nuclear material. We
also have a eosinophil where we
can observe here that it will have two
lobes; it will be bilobed, and
a
horseshoe shape will appear. Here we have a lymphocyte,
since we will also have a
fairly large central nucleus, but there will not
be a pronounced indentation in the
deepest part. In this slide, we can
observe the erythrocytes, which are
clearly visible and distinguishable.
This is how you will
recognize the different cells of the
blood tissue. We have reached the end
of the video. If you liked it, please leave
a like, a comment, and share it with
your friends. I tried to summarize this topic as much as
possible, so today I'm not going to
talk about Homo esthesia because I think it
deserves a separate video. Don't forget to
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