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Before
explaining what Haemostasis is,
we need to put the question into
context. Pathology has many disciplines
- Haematology, Biochemistry, Virology,
Bacteriology, Molecular Biology,
etc...
- Our
field of activity (haemostasis)
is included in the area covered
by Haematology
- the science of blood and its diseases.
In order to better understand our
activity, a simple understanding
of blood is required.
BLOOD
Blood,
the red viscous liquid in arteries
and veins, is rapidly circulated
by a pump: the Heart.
Blood has a complex composition.
It irrigates every tissue and performs
a multiplicity of functions.
The
flow through a series of very small
vessels (the capillary net between
the arterial and the venous circulation)
allows the transport of gases (oxygen
and carbon dioxide), nutritive materials
(carbohydrates, fats and proteins)
and all the elements that are necessary
for our defences against micro-organisms:
bacteria, parasites and viruses.
This defence mechanism uses a multitude
of different components found in
blood - antibodies and different
types of white cells (e.g. neutrophils,
monocytes, lymphocytes and eosinophils).
Every
beat of the heart sends about half
its volume of blood towards the
lungs. There, the carbon dioxide
is removed and ejected in the expired
air, while at the same time oxygen
is absorbed and bound in the red
cells. The other half volume of
blood is sent via the aorta (arterial
circulation) to the various tissues.
It returns to the heart via the
vena cava (venous circulation).
Blood
composition
About
half the volume of blood is composed
of cells (red cells, white cells
and platelets) while the other half
is liquid, the plasma. Red cells
or red corpuscles are scientifically
known as erythrocytes. White cells
or white corpuscles are scientifically
known as leukocytes (many different
types exist: neutrophils, monocytes,
lymphocytes and eosinophils).
The
Red Cells (Erythrocytes) contain
the haemoglobin. Their fundamental
role is to carry the oxygen from
the lungs to the tissues.
The
White Cells (Leukocytes) consist
of a number of different cell types.
The main types are the neutrophils,
monocytes and lymphocytes. The neutrophils
and monocytes (including macrophages)
play an essential role in the body's
non-specific defence against infections
(act as 'scavengers'), while the
lymphocytes play a role in the cellular
supports of immunity (the more specific
defence mechanism).
The
Platelets. Small circulating
cells that work together with the
coagulation factors (proteins in
the plasma) and plays an essential
role in prevention of blood loss.
The Plasma, a yellow liquid,
composed mainly of lightly salted
water (0.9%) contains variable quantities
of other components including nutritional
materials and waste products.
Its
physiochemical properties are remarkably
constant, especially its pH (the
degree of acidity, which is maintained
at pH7.42) and the concentration
of various inorganic elements (especially
sodium, potassium, chlorine, phosphates,...)
*
The nutritional materials in the
plasma are composed of sugars (mainly
glucose), fats (cholesterol, triglycerides,
fatty acids), amino acids (building
bricks of proteins), mineral salts
and vitamins.
*
Waste products mainly consist of
urea and bilirubin. Urea is the
final product of the degradation
of nitrogenous substances, whereas
bilirubin comes from the haemoglobin
as a result of the destruction of
red cells by the macrophages (a
type of monocyte).
*
There are numerous different proteins
in the plasma. These include:
-
all the coagulation factors including
fibrinogen - which coagulates (clots)
to form the fibrin clot (for information
a plasma whose fibrin has been removed
is called serum)
-
albumin, which is quantitatively
the most abundant protein in plasma
in healthy individuals. It plays
an essential role in transporting
hormones and vitamins.
-
Various other proteins including
hormones and some growth factors.
These are the chemical messengers
carried by blood that regulate the
production of the various cells
of the different body components
(e.g. erythopoietin which stimulates
the synthesis of the red cells by
the bone marrow).
The
larger proteins are involved in
a process called oncotic pressure,
which helps to keep the blood volume
constant.
Blood
Analysis
Many
diseases cause changes in blood
composition that can be measured
in a blood sample.
There are 3 common types of blood
analyses:
-
Haematological
-
Biochemical
-
Microbiological
The
first part of any analysis involves
collecting a blood sample. After
putting a pressure cuff on the arm
above the planned puncture point,
blood is collected from a vein in
the bend of the arm via a needle.
In certain cases, when only a few
drops of blood are needed, it can
be collected after pricking a fingertip.
The results of the tests obtained
are compared to standard norms that
may vary according the age and sex
of the patient, but also to the
method used by the laboratory performing
the analysis.
Now
let's get to the heart of the matter:
what is Haemostasis?
HAEMOSTASIS
Haemostasis
is the body's normal physiological
response for the prevention and
stopping of bleeding/haemorrhage.
It results in the blocking of any
vascular breach. Generally speaking,
it helps ensure blood fluidity and
blood vessel integrity. Abnormalities
in haemostasis can result in bleeding
(haemorrhage) or blood clots (thrombosis).
Haemostasis
consists of:
• Primary Haemostasis with:
•
Local vascular contraction (to reduce
blood flow to the injury site)
•
platelet plug formation
•
Clotting of the plasma (secondary
haemostasis), involving interaction
between numerous factors and inhibitors.
• Fibrinolysis - process for
removing the clot once blood vessel
integrity has been restored.
When
there is a breach in a blood vessel,
the first priority (primary haemostasis)
is to "plug" this breach. The main
players in the blood are the platelets
and Fibrinogen: these react together
and block the breach by the formation
of a platelet plug.
Brêche
= Breach
Epanchement sanguin = Bleed/haemorrhage
Aggrégation plaquettaire
= platelet aggregation
Adhésion plaquettaire = platelet
adhesion
Activation de la coagulation = activation
of coagulation
Fibrine = fibrin
Figure
1: Formation of the clot. (Source:
Introduction à l'étude de
l'hémostase et de la thrombose
- B. Boneu, J-P. Cazenave - 1997)
Bleeding at the site of the vascular
injury is stopped by the formation
of an extravascular clot. An injury
causes a transitory vasoconstriction
of the small blood vessels reducing
blood flow. Platelets stick to the
sub-endothelial tissue at the site
of injury and finally they aggregate
together. Initiation of coagulation
leads to the formation of fibrin,
which helps stabilise this clot
and stops bleeding.
Following
this first step, the formation of
a clot (coagulation) stops any further
bleeding (secondary haemostasis).
This process consists of a series
of chemical reactions involving
various plasma components. To date
10 major coagulation factors are
known to be involved in this process.
These complex interactions lead
to the transformation of a soluble
protein, the fibrinogen, into an
insoluble protein, the fibrin, which
forms the frame of the clot Wound
healing finally closes the bridge
and fibrinolysis dissolves the clot.
Abnormalities
in Coagulation
Coagulation
problems are diagnosed by laboratory
examination of the blood coagulation
process, either by using a global
test (clotting time), analytical
test (looking specifically at the
different components of coagulation)
or by a 'blood count' (the amount
of haemoglobin and the number of
white cells, red cells and platelets
per cubic millimetre of blood).
Some
of these tests can also be used
to measure the effect of any anticoagulant
treatment that is given to treat
or reduce the risk of thrombosis.
Diagnostica Stago's activity is
to develop and design the equipment
and the different test methods that
are used in the laboratory to measure
and allow better understanding of
coagulation/haemostasis.
CONCLUSION
Haemostasis
can be compared to a balance
A careful equilibrium
between coagulation factors (activators)
and anti-coagulation factors (inhibitors)
maintains blood fluidity. Any upset
in this equilibrium will upset this
balance resulting in either:
-
Thrombosis: the formation of a clot
or
-
Haemorrhage: bleeding
VISUALISATION
OF THROMBOSIS
Venous
thrombosis is a common disease and
it is estimated that 159 people
in every 100,000 are affected each
year. Clots in veins are the most
frequent, but the major risk is
when these break and block blood
flow in the lungs (pulmonary embolism).
Because of the danger associated
with this type of disease, a number
of experimental models have been
created to study the effect of antithrombotic
drugs. The following model system
has been used to visualise the formation
of a thrombus by the haematology
department at the faculty of Pharmacy
in Bordeaux, France.
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Click on
the picture to display the
formation of the clot |
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In
this experimental model of thrombosis
a laser creates a vascular lesion
in small veins or arterioles (diameter
between 15 to 25µm). Blood flow
can be observed using reverse phase
microscopy and recorded.
In this model you can see that immediately
after the lesion is created a small
clot (thrombus) is formed. This
is rapidly washed away in the blood
flow and this cycle repeats many
times. Eventually a large clot forms
reducing the blood flow. In certain
cases the thrombus can occlude (block)
the vessel, stopping blood flow
and can result in tissue damage.
- If you wish to see the film of
clot formation please click on the
figure.
-
To obtain the bibliography on this
experimental model please go to
http://www.u-bordeaux2.fr/hemato/p05.html.
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