Blood PDF - Composition, Functions, and Medical Applications

Summary

This document provides information on blood composition, including the percentage of plasma and formed elements. It details the functions of blood, such as gas transport, as well as medical applications and conditions, including anemia and sickle-cell disease. The document is aimed at students studying biology or medical related topics.

Full Transcript

BLOOD
Dr. Emad I H Shaqoura, M.D, M.Sc.
Lecturer of Anatomy & Histology
Faculty of Medicine, Islamic University-Gaza
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BLOOD COMPOSITION
Blood is a specialized connective tissue in which the cells are
suspended in fluid extracellular material called plasma.
Normal blood volume in an adult is about 5 Lit.
Centrifugation of a non-clotted blood sample results in separation
of blood into three layers:
1. Erythrocytes: about 45% of the total blood volume in
healthy adults, & is called the hematocrit.
2. Plasma: about 55% of the total blood volume.
3. Buffy coat: less than 1% of the total blood volume &
composed of leukocytes & platelets. 2/28/2021
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BLOOD FUNCTIONS
Blood is a distributing vehicle, transporting O2, CO2,
nutrients, metabolites, hormones, and other substances to
cells throughout the body.
Blood also participates in heat distribution, the regulation of
body temperature, and the maintenance of acid-base and
osmotic balance.
Leukocytes are one of the body’s chief defenses against
infection.

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BLOOD COMPOSITION

Blood

Formed
Plasma 55%
Elements 45%

- Erythrocytes.
- WBCs.
- Platelets.
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COMPOSITION OF PLASMA

Plasma

Plasma Other
Water 92%
Proteins 7% Solutes 1%

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COMPOSITION OF PLASMA
The major plasma proteins include the following:
1. Albumin, the most abundant plasma protein, is made in the
liver and serves primarily to maintain the osmotic pressure
of the blood.
2. α-Globulins and ß-globulins, made by liver and other cells,
include transferrin and other transport factors; fibronectin;
prothrombin and other coagulation factors; lipoproteins
and other proteins entering blood from tissues.
3. γ-Globulins, which are immunoglobulins (antibodies)
secreted by plasma cells in many locations.
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COMPOSITION OF
PLASMA
4. Fibrinogen, the largest plasma protein, also made in the
liver, which, during clotting, polymerizes as insoluble, cross-
linked fibers of fibrin that block blood loss from small
vessels.

5. Complement proteins, a system of factors important in
inflammation and destruction of microorganisms.

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BLOOD CELLS
Blood cells can be studied histologically in smears.
Blood smears are routinely stained with special mixtures of
acidic (eosin) and basic (methylene blue) dyes.
These mixtures may also contain dyes called azures that are
more useful in staining cytoplasmic granules containing
charged proteins and proteoglycans.
Azurophilic granules produce metachromasia in stained
leukocytes.
Some of these special stains are Giemsa and Wright stain.

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ERYTHROCYTES
Erythrocytes (red blood cells or RBCs) are terminally
differentiated structures lacking nuclei and completely filled
with hemoglobin.
RBCs are the only blood cells whose function does not
require them to leave the vasculature.
Human erythrocytes suspended in an isotonic medium
are flexible biconcave discs.
They are approximately 7.5 μm in diameter, 2.6 μm thick at
the rim, but only 0.75 μm thick in the center.

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ERYTHROCYTES
Because of their uniform diameters and their presence in
most tissue sections, RBCs can often be used by histologists
as an internal standard to estimate the size of other cells or
structures.
The biconcave shape provides a large surface-to-volume
ratio and facilitates gas exchange.
Being flexible, erythrocytes can bend and adapt to the
irregular small diameters of capillaries frequently assuming a
cup-like shape.
In larger blood vessels RBCs often adhere to one another
loosely in stacks called rouleaux.
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ERYTHROCYTES
The plasmalemma consists of about 40% lipid, 10% carbohydrate, and
50% protein (mostly integral membrane proteins), including ion channels,
the anion transporter called band 3 protein, and glycophorin A.
The glycosylated extracellular domains attached to the latter proteins
include antigenic sites that form the basis for the ABO blood typing
system.
Several peripheral proteins are associated with the inner surface of the
membrane, including spectrin, dimers of which form a lattice bound to
underlying actin filaments, and ankyrin, which anchors the lattice to the
glycophorins and band 3 proteins.
This submembranous meshwork stabilizes the membrane, maintains the
cell shape, and provides the cell elasticity required for passage through
capillaries.
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ERYTHROCYTES
Erythrocyte cytoplasm lacks all organelles but is densely
filled with hemoglobin, that accounts for the cells’ uniform
acidophilia.
Erythrocyte differentiation includes loss of the nucleus and
organelles, shortly before the cells are released by bone
marrow into the circulation.
Lacking mitochondria, erythrocytes rely on anaerobic
glycolysis for their minimal energy needs.
Lacking nuclei, RBCs cannot replace defective proteins.

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ERYTHROCYTES
Human erythrocytes normally survive in the circulation for
about 120 days.
By this time defects in the membrane’s cytoskeletal lattice or
ion transport systems begin to produce swelling or other
shape abnormalities, as well as changes in the cells’ surface
oligosaccharide complexes.
Senescent or worn-out RBCs displaying such changes are
removed from the circulation, mainly by macrophages of the
spleen, liver, and bone marrow.
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MEDICAL APPLICATION
Anemia is a decreased concentration of erythrocytes below the normal
range leading to inability of tissues to receive adequate O2.
Symptoms of anemia include: lethargy, shortness of breath, fatigue, skin
pallor, and heart palpitations.
Anemia may result from: insufficient red cell production, e.g., due to iron
deficiency, or from blood loss with a stomach ulcer or excessive
menses.
Erythrocytosis, or polycythemia: is an increased concentration of
erythrocytes in blood may be a physiologic adaptation as at high altitudes,
where O2 tension is low.
Elevated hematocrit increases blood viscosity, putting strain on the
heart, and, if severe, can impair circulation through the capillaries.

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MEDICAL APPLICATION
Sickle cell disease is caused by a mutation of one nucleotide (a point
mutation) in the gene for the hemoglobin β chain.
When the altered hemoglobin (called HbS) is deoxygenated in capillaries,
it polymerizes and forms rigid aggregates that cause a characteristic
sickle shape.
The sickled erythrocyte is less flexible and more fragile and has a
shortened life span that can lead to anemia.
It increases the blood viscosity and can damage the wall of blood vessels,
promoting blood coagulation.
Sickle cells can block capillaries, restricting O2 delivery to tissues and
leading to varying degrees of ischemia or anoxia and organ damage.

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LEUKOCYTES
Leukocytes (WBCs) leave the blood and migrate to the tissues
where they become functional.
According to the type of cytoplasmic granules and their nuclear
morphology, leukocytes are divided into: granulocytes and
agranulocytes.
Both types are spherical in blood plasma, but they become
amoeboid and motile after leaving the blood vessels and invading
the tissues.
Their estimated sizes appear slightly larger than they are in the
circulation.
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LEUKOCYTES
Granulocytes possess two major types of cytoplasmic granules:
1. Lysosomes (often called azurophilic granules in blood cells).
2. Specific granules that bind neutral, basic, or acidic stains and have
specific functions.
Granulocytes have polymorphic nuclei with two or more distinct lobes
and include the neutrophils, eosinophils, and basophils.
All granulocytes are terminally differentiated with a life span of only a few
days.
Their Golgi complexes and rough ER are poorly developed.
They have few mitochondria and depend largely on glycolysis.
Granulocytes normally die by apoptosis in the connective tissue & the
resulting cellular debris is removed by macrophages.
2/28/2021
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LEUKOCYTES
Agranulocytes do not have specific granules, but they do contain
azurophilic granules (lysosomes), with affinity for the basic stain
azure A.
The nucleus is spherical or indented but not lobulated.
This group includes lymphocytes and monocytes.
All leukocytes are key players in the defense against invading
microorganisms, and in the repair of injured tissues, specifically
leaving the microvasculature in injured or infected tissues.
The number of leukocytes in the blood varies according to
age, sex, and physiologic conditions.
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NEUTROPHILS (PMNL)
Mature neutrophils constitute 50% - 70% of circulating WBCs;
circulating immature forms raise this value by 3% to 5%.
Neutrophils are 12-15 μm in diameter in blood smears, with
nuclei having 3-5 lobes linked by thin nuclear extensions.
In females, the inactive X chromosome may appear as a
drumstick-like appendage on one of the lobes of the nucleus.
Neutrophils are inactive and spherical while circulating but
become actively amoeboid during diapedesis and upon adhering to
solid substrates such as collagen in the ECM.
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NEUTROPHILS (PMNL)

Neutrophils are active phagocytes and are usually the first
leukocytes to arrive at sites of infection, where they actively
pursue bacterial cells using chemotaxis.

The cytoplasmic granules of neutrophils provide the cells’
functional activities and are of two main types:
1. Azurophilic primary granules.

2. Specific secondary granules.
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NEUTROPHILS (PMNL)
Azurophilic primary granules or lysosomes are large, dense
vesicles and have a major role in both killing and degrading
engulfed microorganisms.
 They contain proteases and antibacterial proteins, including the
following:
1. Myeloperoxidase (MPO), which generates hypochlorite and other
agents toxic to bacteria.
2. Lysozyme, which degrades components of bacterial cell walls.
3. Defensins, small cysteine-rich proteins that bind and disrupt the
cell membranes of many types of bacteria.
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MEDICAL APPLICATION

Several kinds of neutrophil defects, often genetic in origin, can affect
function of these cells, for example by:

decreasing adhesion to the wall of venules,

causing the absence of specific granules,

deficits in certain factors of the azurophilic granules.

Individuals with such disorders typically experience more frequent
and more persistent bacterial infections, although macrophages and
other leukocytes may substitute for certain neutrophil functions.
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NEUTROPHILS (PMNL)
Specific secondary granules are smaller and less dense, stain faintly
pink, and have diverse functions, including secretion of various
ECM-degrading enzymes such as collagenases, delivery of
additional bactericidal proteins to the phagolysosomes, and
insertion of new cell membrane components.
Activated neutrophils at infected or injured sites release
chemokines that attract other leukocytes and cytokines that
direct activities of these and local cells of the tissue.
Important lipid mediators of inflammation are also released from
neutrophils.
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NEUTROPHILS (PMNL)

Neutrophils contain glycogen, which is broken down into
glucose to yield energy via the glycolytic pathway.

The ability of neutrophils to survive in an anaerobic
environment is highly advantageous.

Neutrophils are short-lived cells with a half-life of 6-8 hours
in blood and a life span of 1-4 days in connective tissues
before dying by apoptosis.

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MEDICAL APPLICATION
Neutrophils look for bacteria to engulf by pseudopodia and
internalize them in vacuoles called phagosomes.
Immediately thereafter, specific granules fuse with and discharge
their contents into the phagosomes which are then acidified by
proton pumps.
Azurophilic granules then discharge their enzymes into this
acidified vesicle, killing and digesting the engulfed microorganisms.
During phagocytosis, free oxygen radicals are formed resulting in
powerful microbial killing system inside the neutrophils.

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MEDICAL APPLICATION

Lysozyme cleaves cell wall to kill certain bacteria.

Lactoferrin protein avidly binds iron, a crucial element in bacterial
nutrition whose lack of availability then causes bacteria to die.

A combination of these mechanisms will kill most microorganisms,
which are then digested by lysosomal enzymes.

Apoptotic neutrophils, bacteria, semi-digested material, and tissue
fluid form a viscous, usually yellow collection of fluid called pus.

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EOSINOPHILS
Eosinophils constitute only 1% to 4% of
leukocytes.
In blood smears, this cell is the same
size as a neutrophil or slightly larger.
They have a characteristic bilobed
nucleus.
The main identifying characteristic is
the abundance of large, acidophilic
specific granules typically staining pink
or red.
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EOSINOPHILS
Ultrastructurally the
eosinophilic specific granules
are oval in shape, with
flattened crystalloid cores
containing major basic
proteins (MBP), an arginine-
rich factor that accounts for
the granule’s acidophilia and
constitutes up to 50% of the
total granule protein.
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EOSINOPHILS

Functions of eosinophils:
1. MBPs, along with eosinophilic peroxidase, other enzymes and
toxins, act to kill parasitic worms or helminths.
2. Eosinophils also modulate inflammatory responses by releasing
chemokines, cytokines, and lipid mediators, with an important
role in the inflammatory response triggered by allergies.
3. They also remove antigen-antibody complexes from interstitial
fluid by phagocytosis.

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MEDICAL APPLICATION
An increase in the number of eosinophils in blood (eosinophilia) is
associated with allergic reactions and helminthic infections.
In patients with such conditions, eosinophils are found in the
connective tissues underlying epithelia of the bronchi, GIT, uterus,
and vagina, and surrounding any parasitic worms present.
In addition, these cells produce substances that modulate
inflammation by inactivating the leukotrienes and histamine
produced by other cells.
Corticosteroids produce a rapid decrease in the number of blood
eosinophils, probably by interfering with their release from the
bone marrow into the bloodstream.
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BASOPHILS
Basophils are also 12 -15 μm in diameter but make up less
than 1% of blood leukocytes and are therefore difficult to
find in normal blood smears.
The nucleus is divided into two irregular lobes, & usually
obscured by the overlying large specific granules.
The specific granules (0.5 μm in diameter) typically stain
purple with the basic dye of blood smear stains and are
fewer, larger, and more irregularly shaped than the granules
of other granulocytes.
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BASOPHILS
The strong basophilia of the granules is due to the presence of heparin
and other sulfated GAGs.
Basophilic specific granules also contain histamine and other mediators of
inflammation, including platelet activating factor, eosinophil chemotactic
factor, and phospholipase A that catalyzes an initial step in producing
lipid-derived proinflmmatory factors called leukotrienes.
Basophils migrate into connective tissues and supplement the functions
of mast cells.
Both of them have metachromatic granules containing heparin and
histamine, have surface receptors for IgE, and secrete their mediators in
response to certain antigens and allergens.
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LYMPHOCYTES
Lymphocytes are the most numerous type of agranulocyte in
normal blood smears or CBCs.
They have spherical nuclei.
Lymphocytes are typically the smallest leukocytes.
Although they are morphologically similar, lymphocytes can
be subdivided into functional groups by distinctive surface
molecules (called “cluster of differentiation” or CD markers)
that can be distinguished using antibodies with
immunocytochemistry.
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LYMPHOCYTES

Major classes include:
1. B lymphocytes.
2. Helper and cytotoxic T lymphocytes (CD4+ & CD8+,
respectively).
3. Natural killer (NK) cells.
These and other types of lymphocytes have diverse roles in
immune defenses against invading microorganisms and
certain parasites or abnormal cells.
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LYMPHOCYTES
Circulating lymphocytes have a wide range of sizes:
1. Small lymphocytes: newly released cells that have
diameters similar to those of RBCs.
2. Medium lymphocytes.
9-18 μm in diameter
3. Large lymphocytes:
represent activated lymphocytes or NK cells.

The small lymphocytes have spherical nuclei with highly
condensed chromatin and only a thin surrounding rim of
scant cytoplasm, making them easily distinguishable from
granulocytes. 2/28/2021
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LYMPHOCYTES

Larger lymphocytes have larger, slightly indented nuclei and
more cytoplasm that is slightly basophilic, with a few
azurophilic granules (lysosomes), mitochondria, free
polysomes, and other organelles.

Lymphocytes vary in life span according to their specific
functions; some live only a few days and others survive in the
circulating blood or other tissues for many years.
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MEDICAL APPLICATION

Lymphomas are a group of disorders involving neoplastic
proliferation of lymphocytes or the failure of these cells to
undergo apoptosis.

Although often slow-growing, all lymphomas are considered
malignant because they can very easily become widely spread
throughout the body.

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MONOCYTES
Monocytes are agranulocytes that are precursor cells of
mononuclear phagocyte system.
All monocyte-derived cells are antigen-presenting cells and have
important roles in immune defense of tissues.
Circulating monocytes have diameters of 12 to 15 μm, but
macrophages are somewhat larger.
The nucleus is large and usually distinctly indented or C-shaped.
The chromatin is less condensed than in lymphocytes and typically
stains lighter than that of large lymphocytes.

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MONOCYTES

The cytoplasm of the monocyte is basophilic and contains many
azurophilic granules, some of which are at the limit of the light
microscope’s resolution.

These granules are distributed through the cytoplasm, giving it a
bluish-gray color in stained smears.

Mitochondria and small areas of rough ER are present, along with
a Golgi apparatus involved in the formation of lysosomes.

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MEDICAL APPLICATION

Extravasation of immigrating monocytes occurs in the early phase
of inflammation following tissue injury.

Acute inflammation is usually short-lived as macrophages undergo
apoptosis or leave the site, but chronic inflammation usually
involves the continued recruitment of monocytes.

The resulting continuous presence of macrophages can lead to
excessive tissue damage that is typical of chronic inflammation.

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PLATELETS

Blood platelets (or thrombocytes) are very small non-nucleated,
membrane-bound cell fragments only 2 to 4 μm in diameter.

Platelets originate from giant polyploid bone marrow cells called
megakaryocytes.

Platelets promote blood clotting and help repair minor tears or
leaks in the walls of small blood vessels, preventing blood loss.

Circulating platelets have a life span of about 10 days.

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PLATELETS
In blood smears, platelets often appear in clumps.
Each individual platelet is generally discoid, with a very lightly
stained peripheral zone, the hyalomere, and a darker-staining
central zone containing granules, called the granulomere.
A sparse glycocalyx surrounding the platelet plasmalemma is
involved in adhesion and activation during blood coagulation.
Ultrastructural analysis reveals a peripheral marginal bundle
of microtubules and microfilaments, which helps to maintain
the platelet’s shape.
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PLATELETS
Also in the hyalomere are two systems of membrane channels:
1. Open canalicular system of vesicles: connected to invaginations
of the plasma membrane, which may facilitate platelets’ uptake
of factors from plasma.
2. Dense tubular system: a much less prominent set of irregular
tubular vesicles derived from the ER and stores Ca2 + ions.
Together, these two systems facilitate the extremely rapid
exocytosis of proteins from platelets (degranulation) upon
adhesion to collagen or other substrates outside the vascular
endothelium.

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PLATELETS
The central granulomere has specific granules, and sparse
mitochondria and glycogen particles.
1. Electron-dense delta granules (δG), 250-300 nm in diameter,
contain ADP, ATP, and serotonin taken up from plasma.
2. Alpha granules (αG) are larger (300-500 nm in diameter) and
contain platelet-derived growth factor (PDGF), platelet factor 4,
and several other platelet-specific proteins.
Most of the stained granules seen in platelets with the light
microscope are alpha granules.
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PLATELETS

The role of platelets in controlling hemorrhage and in wound
healing can be summarized as follows:

1. Primary aggregation: Disruptions in the endothelium, which are
very common, allow the platelet glycocalyx to adhere to collagen. Thus,
a platelet plug is formed as a fist step to stop bleeding.

2. Secondary aggregation: Platelets in the plug release a specific
adhesive glycoprotein and ADP, which induce further platelet
aggregation and increase the size of the platelet plug.

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PLATELETS

3. Blood coagulation: During platelet aggregation, fibrinogen from
plasma, von Willebrand factor and other proteins released from the
damaged endothelium, and platelet factor 4 from platelet granules
promote the sequential interaction (cascade) of plasma proteins, giving
rise to a fibrin polymer that forms a three dimensional network of
fibers trapping red blood cells and more platelets to form a blood clot,
or thrombus. Platelet factor 4 is a chemokine for monocytes,
neutrophils, and fibroblasts and proliferation of the fibroblasts is
stimulated by PDGF.
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PLATELETS

4. Clot retraction: The clot that initially bulges into the blood vessel
lumen contracts slightly because of the interaction of platelet actin
and myosin.

5. Clot removal: Protected by the clot, the endothelium and
surrounding tunic are restored by new tissue, and the clot is then
removed, mainly dissolved by the proteolytic enzyme plasmin,
formed continuously through the local action of plasminogen
activators from the endothelium on plasminogen from plasma.
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MEDICAL APPLICATION
Aspirin and other non-steroidal anti-inflammatory agents have an
inhibitory effect on platelet function and blood coagulation
because they block the local prostaglandin synthesis that is needed
for platelet aggregation, contraction, and exocytosis at sites of
injury.
Bleeding disorders result from abnormally slow blood clotting.
One such disease directly related to a defect in the platelets is a
rare autosomal recessive glycoprotein Ib deficiency, involving a
factor on the platelet surface needed to bind subendothelial
collagen and begin the cascade of events leading to clot formation.
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