Surgery Vol 1 2021 Cairo University @AUDatabot (1).pdf

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Chapter 4: Acute Haemorrhage and Blood Transfusion

CHAPTER4

ACUTE HAEMORRHAGE AND BLOOD TRANSFUSION
CHAPTER CONTENTS

Classification of haemorrhage
Acute haemorrhage causes loss of both circulating
blood volume and oxygen carrying capacity. The
common causes include penetrating and blunt
trauma, gastrointestinal bleeding, and obstetrical
bleeding. Haemorrhage may be classified according
to

Site
•

External. Bleeding is visible as it occurs
through skin wounds or from a body orifice
as in epistaxis.

•

Internal
o In body cavities, e.g., haemoperitoneum
and haemothorax.
o Interstitial, e.g., fracture haematoma.

Type of disrupted vessel
•

Arterial. Blood is bright red and comes in
pulsatile jets.

•

Venous. Blood is dark red and comes in a
steady flow.

•

Capillary. Bleeding occurs as diffuse ooze of
bright red blood.

Timing in relation to trauma:

• Classification of haemorrhage
• Pathophysiological response to
haemorrhage
• Clinical picture of haemorrhage
• Treatment of haemorrhage
• Blood transfusion
o Collection & storage of blood
o Blood products
o Possible complications
o Alternatives to homologous
blood transfusion

Haemorrhage is classified according to:
• Site: External or internal.
• Type of disrupted vessel: Arterial, venous or
capillary.
• Timing: Primary, reactionary or secondary.
• Aetiology: Traumatic, pathological or
spontaneous.
Common causes of severe haemorrhage:
• Trauma:
Splenic or liver injury,
haemothorax, pelvis fracture
• Major surgery
• Bleeding oesophageal varices
• Bleeding duodenal ulcer
• Ruptured aortic aneurysm
• Pre and postpartum haemorrhage Ruptured
ectopic pregnancy.
Body response aims to:
• Stop bleeding
• Maintain effective blood volume.
This response is based on neural and
endocrinal mechanisms.

•

Primary haemorrhage occurs at the time of
trauma.

•

Reactionary haemorrhage occurs within 24
hours after trauma. As the blood pressure rises due to correction of hypovolaemia, an
insecure ligature slips or a clot is dislodged.

• Secondary haemorrhage occurs one to two weeks after trauma due to infection eroding
a vessel wall, e.g. after haemorrhoidectomy. It can be fatal if a large artery is involved,
e.g., the carotid after sloughing of the skin flaps of a radical neck dissection.

Aetiology
•

Traumatic, which might be accidental or iatrogenic.

• Pathological
o Atherosclerotic, e.g., ruptured aortic aneurysm.
o Inflammatory, e.g., bleeding peptic ulcer.

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Hemorrhage
Definition:

Escape of RBCs outside the vessles, or organs

Classification:
Site
1. External: wounds or epistaxis or haematemesis.
2. Internal:
a. In body cavities, e.g., haemoperitoneum and haemothorax.
b. Interstitial, e.g., fracture haematoma.
Type of vessel
1. Arterial. Blood is bright red and comes in pulsatile jets.
2. Venous. Blood is dark red and comes in a steady flow.
3. capillary. Bleeding occurs as diffuse ooze of bright red blood.
Timing:
1. Primary haemorrhage occurs at the time of trauma.
2. Reactionary haemorrhage
- Occurs within 24 hours after trauma .
- Due to an insecure ligature slips or a clot is dislodged.
3. Secondary haemorrhage
- 1- 2 weeks after trauma, due to infection eroding a vessel wall
- It can be fatal if a large artery is involved.
Aetiology
1. Traumatic
 Accidental.
 Surgical.
 lnterventional procedures, e.g. percutaneous transhepatic cholangiography (PTC).
2. Pathological
 Atherosclerotic (ruptured aortic aneurysm) .
 Inflammatory (bleeding peptic ulcer).
 Neoplastic (haematuria In renal cancer}.
3. Bleeding diathesis can increase the amount of traumatic and pathological bleeding,
or cause bleeding with little or no trauma (spontaneous haemorrhage).

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Physiological response to hemorrhage:

Locally:
Stopping the bleeding
- Vasoconstriction and retraction of the intima of the injured vessel.
- Platelet plug.
- Blood clotting.
They are more effective when the vessel is completely transected than when
there is a side tear, and in traumatic than in pathological cases.

Systemically:
A. Neural factors.
↓ stimulation of arterial baroreceptors (aortic arch and carotid sinus) and atrial
stretch receptors → Inhibition of the normal inhibitory discharge in the vagus
and glossopharyngeal nerves on the vasomotor centre  stimulation of the
sympathetic system.
 The effects include:
1. Constriction of veins:
- Normally contain two-thirds of the blood volume
- Displaces blood from the periphery into the heart.
2. Constriction of arterioles
- Involves mainly the arterioles of the skin, skeletal muscle, and
splanchnic area  Raises the peripheral resistance.
3. Increased rate and strength of cardiac contraction.
Maintaining effective circulatory volume and perfusion of critical tissues (brain and
heart). at the expense of less critical tissues (skin, skeletal muscle and splanchnic
area).
B. Endocrine factors
1 Catecholamine:
↑heart rate and myocardial contraction and cause constriction of them arterioles of
the skin, kidney and viscera.
2 The metabolic hormones
 ↑ACTH, cortisol, growth hormone and glucagon.
 Insulin release is inhibited by adrenaline and noradrenaline.
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3 The renin-angiotensin aldosterone system.
- Renin secreted in response to renal hypoperfusion.
- Renin splits angiotensinogen to angiotensin I
- Which is converted to angiotensin II by a converting enzyme in the lung.
- Angiotensin II is a powerful vasoconstrictor and sodium and water retention by the
kidney as well as release of aldosterone.
4 ADH (vasopressin).
C. Transcapillary refill.
 ↓blood volume and constriction of arterioles  drops the capillary hydrostatic pressure and
promotes movement of fluid from the interstitium into the capillaries.
 The resulting haemodilution increases the blood volume and lowers its viscosity, thus
improving effective circulatory volume.
N.B
- This Mechanism can compensate for losses up to 15% of blood volume only.
- Blood volume is estimated as 70 ml/kg in adults, 80ml/kg in children.
- i.e in adult : 15% from 5 Liters = 750 cc
- in neonate: 10 % from 280 cc = 28 cc

Clinical Picture
Symptoms
1 Weakness and fainting especially when standing.
2 The patient feels cold and thirsty.

Signs
1 Mental status: vary from anxious to drowsy..
2 Pulse and blood Pressure.
- Mild loss (< 500 ml): Pulse and B.P may remain normal.
- More loss: Tachycardia but the blood pressure remains stable.
- Further loss: Hypotension develops.
3 Respiratory rate· Tachypnea and air hunger.
4 Temperature.
 Hypothermia
5 Skin: Pale, cold (vasoconstriction) and clammy with slow capillary refill.
6 Oliguria results due to diminished renal perfusion.

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Estimating blood loss
 Blood volume is estimated as 70 mi/Kg in adults and 80 mi/Kg in children.
1.

Clinical data

Blood loss
Mental status
Skin
Capillary refill
Blood pressure
-systolic
-diastolic
-pulse pressure
Respiratory rate
Urine (ml/h)
2.

Class II
15-30%
(750-1500 ml)
Aggressive
to-drowsy.
Pale and cold
>2 sec.

Class III
Class IV
30-40%
>40%
(1500-2000ml) (>2000ml)
Anxious
Drowsy
restless.
to unconscious
Pale and colder. Pale and very cold
>2 sec.
>2 sec. undetectable.

Normal
Normal
Normal
14-20
>30

Normal(supine)
Raised
Low
20-30
20-30

Low
Low
low
30-35
10-20

Low
Low
low
>35
0-10

Type of injury.




3.

Class I
Up to 15%
(750ml)
Normal
to anxious)
Normal
Normal

Haematoma around a fracture of the tibia may contain 500-1500 ml of blood.
Fractured shaft of femur, soo-2000 ml;
Fractured pelvis, 2000-3000 mi.

Blood loss at operation


Sum of the suction reservoir and the amount mopped up by the swabs.

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Management of Hemorrhage
Stop hemorrhage.





(Packing, Pressure, Position)

The wound is covered by a dressing
And pressure is applied manually, or by a sphygmomanometer cuff.
o Tourniquets are contraindicated.
Elevation of the limb above the heart (decreases arterial bleeding).
Other examples:
o Anti-shock garment (PASG),
o Balloon tamponade from oesophageal varices.

Restore blood volume.
Class II





The deficit is estimated at 15-30% {750-1500 ml/70 kg).
The replacement solution is lactated Ringer's.
The amount is 3 times the estimated deficit (3:1).
Administration.
o Two liters are given as a bolus.
o If there is definite improvement: the remaining litre is given more slowly followed by
the maintenance requirements and continued observations
o Haematocrit <30 requires blood transfusion.
o If there is moderate improvement. the possibilities are:
 inadequate replacement.
 Cardiac tamponade and tension pneumothorax.
 Blood transfusion is started if bleeding is still active.

Class III and IV





Management as class II till blood transfusion.
Plasma expander can be used until blood is available.
The volume of transfused blood equal the estimated deficit (1:1).
Failure to improve and a rising OJP indicate:
o Tension pneumothorax, Cardiac tamponade, Cardiac failure.
o Major thoracic, abdominal, or pelvic injury.

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Optimize oxygen delivery.




40% oxygen is given for class II haemorrhage
100% for classes Ill and IY.
Mechanical ventilation can be used to improve oxygen delivery.

General care of the patient.



Bed rest and analgesia (morphia, 3-5 mg IV).
Morphine: contraindicated in head injury and in respiratory insufficiency.

Monitoring:






Foley's catheter.
Vital signs.
C.B.C: haematocrits
ECG for early detection of shock-induced arrhythmias.
Invasive Monitoring:
- Central venous pressure
- A pulmonary artery catheter

Failure to respond to fluid resuscitation:
CVP low= continuous bleeding.
CVP high= tension pneumothorax -cardiac tamponade- cardiac contusion

N.B Of Reactionary Hemorrhage:
a. Resuscitation by fluids or blood transfusion.
b. Secure legation or angiographic embolisation of the bleeding site.

N.B Of secondary hemorrhage :
a. Surgical legation of the bleeding vessel proximal to the eroded site.
b. Or packing of the bleeding site if tissues are friable from infection which makes
legation difficult + broad spectrum antibiotics.

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Metabolic response to injury
Definition:
 Metabolic disturbances follow all forms of trauma (operations, burns and fractures,…)
 Proportionate to the severity of the trauma and to the nutritional state of the patient.
 At first (6:8 days): Catabolic.
 Followed (10-60 days) by an anabolic phase with repair of tissue, repletion of stores of fat
and proteins and weight gain. It is controlled by growth hormone, androgens and
ketosteroids.

Catabolic Phase:
1. ↓Water excretion:
- Increased of ADH from the posterior pituitary.
- In the first 24:48 hours urine excretion is reduced to 500 ml per day.
2. ↓Sodium excretion:
- Drops from 100 mEq to 10 mEq per day.
- Due to Increased secretion of aldosterone.
- The duration is 5:6 days.
- Independent on whether Na+ is given or not.
3. ↑Potassium:
- Increased urinary excretion (maximal the day of operation to 48hours).
- It increases from 70:100 mEq to 100:140 mEq.
- It is due to mobilization and excretion of intracellular K+.
4. ↑Protein:
- Increase the nitrogen excretion from a normal of 10:12 gm daily to 30 gm/day.
- Skeletal muscle breakdown  Aminoacids used for gluconeogenesis and proteins.
- Through the adrenocortical hormones. (abscent in Addison's disease)
5. ↑Glucose:
- Glycogen breakdown  blood glucose level rises
- Due to Adrenaline and Glucagon.
- Also stimulation of gluconeogenesis from amino-acids due to increased cortisol.
- known as diabetis of injury.
6) Fat:
- Under control of interleukins and TNF.
- Lipases release glycerol and fatty acids.
- Glycerol is used for gluconeogenesis and fatty acids are oxidised for energy.

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Anabolic phase
-

Starts from the second week and may last for several weeks.
There is a positive nitrogen balance (3:5 gm nitrogen per day).
The patient will gain weight and strength.
The responsible factors are the growth hormone and gonadal hormones.
later the patient restores body fat previously lost.

Objective of Metabolic Response
1. Mobilization of nitrogen and K+  raw materials for the healing of wounds
2. Conservation of Na+ and water  maintain plasma volume after
haemorrhage.
3. A well-nourished person shows catabolism vigorously  heals well.
While the malnourished dose not  wound dehiscence or non-union of
fractures.

Practical Applications:
1. First 24:48 hours after operation water is administered excessively, water
intoxication results.
An overload of 1.5 litres  neausea and disorientation.
An overload of 2.5 litres  metal lethargy.
If more  convulsions and coma.
2. Excessive administration of saline in the early post-operative period  Na+ retention
and secondarily water retention.
3. Administration of K+ in the first 24hours after operation  high level of K in the
blood.
-----------------------------------------

A system for post-operative fluid administration:
1. In the first 24hours give 2 litres of glucose5%.
2. On the following day give 2litres of glucose 5% and 500ml of saline.
3. From the 4th day add 20mEq of K+ is added to each litre to give a total of 50
mEq/day.

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Blood Transfusion & Blood products
Indication for Blood Transfusion:

(restore blood volume).

 In acute haemorrhage.
 During major operation.
 Postoperatively after major surgery.
 Preoperative blood transfusion is needed if Hb is less than ↓ 8 gm/dl.
 To arrest haemorrhage in haemorrhagic states.

Blood Sparing Strategies
1. Pre-operative autologous blood donation:
 In elective surgery where blood will be lost and where Hb is at least 11-12 gm/dl.
 If the blood is not used it will be wasted
 If the patient needs more blood the advantage is lost.

2. Erythropoietin:
 Used in the anaemia associated with renal failure and in major surgery.
 It is given subcutaneously 600 u/kg 3 times weekly and on the day of surgery.
 It is usually given with oral or I.V. iron therapy.

3. Acute Normovolemic Haemodilution:
 Following induction, 1000 ml of blood are removed and replaced with crystalloids.
 The blood is given to the patient when it is needed during or after the surgery.
 The patients Hb must be initially high.

4. Intraoperative Blood Salvage:
 In clean operations using the cell saver equipment.
 Aspirates, anticoagulants and filters the extravasated blood.
 Then red cells are washed and given as packed red cells.
It is usually used in liver transplantation.

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Blood and blood products
I) Stored whole blood:
 Collected into a sterile plastic bag.
 The bag contains 75 ml of anticoagulant solution CPDA (Citrate Phosphate Dextrose
Acid).
 Stored at 4°C and can be used within 21 days.ood and blood products
 Disadvantage of stored blood
1. Citrate anticoagulant
2. Has an acid pH (6.6-6.8)
3. High level of K+ (from stored red cells)
4. High ammonia (from red cells adenosine)
5. Reduced red cell (2,3-DPG)  impaired release of oxygen from oxy-Hb.
6. White blood cells and platelets are destroyed after 24 hours in the stored blood.
7. Also the levels of clotting factors V and VIII fall quickly.

II-Blood fractions
1. Packed Red Cells:
 Used in chronic anemia, elderly, cardiac and children and will avoid overload.
 The plasma is replaced by 100 ml of a crystalloid solution containing NaCl,
adenine, glucose and mannitol (SAG-M blood).
2. Platelet Rich Plasma:
 It is prepared by centrifugation of freshly donated blood.
 It is used in thrombocytopenia and during surgery.
3. Platelet Concentrate:
 Prepared by centrifugation of platelet rich plasma.
 They also carry HLA antigens.  reaction (with repeated transfusion).
 Indications: Thrombocytopenia, DIC, Massive transfusion, aplastic anaemia.

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4. Plasma Products:
a.Human albumin 4.5%:
It is prepared by repeated fractionation of plasma followed by heat treatment.
Free from the danger of transmission of hepatitis.
Stored for several months in liquid form at 4°C.
It is used in burns and in hypoproteinaemia.
There is salt-poor human albumin 20% used in cirrhotic patients with ascites.
b.Fresh-Frozen Plasma FFP:
Plasma removed from fresh blood and rapidly frozen and stored at -40°C.
It is a good source of all the coagulation factors, albumin and
immunoglobulins.
It is used during surgery on liver failure, in Christmas disease and
haemophilia.
It is not used as plasma expander.
c. Cryoprecipitate:
 FFP at -4°C, a glutinous precipitate remains.
 It is stored at -40°C.
Very rich source of factor VIII, Von Willebrand factor and fibrinogen.
 Used in treatment of haemophilia, Von Willibrand's disease and is given I.V.
d. Factor VIII and factor IX concentrates:
 They are now available in freeze-dried form.
e. Fibrinogen:
 Used in severe depletion of fibrinogen e.g. DIC
 Carries a high risk of hepatitis.
f. Immunoglubins Ig G:

Provide passive immunity to non-immunised patients exposed to serious
infection (viral or bacterial) e.g. human tetanus immunoglogin.

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Changes occur during storage of blood

Red cell viability
Platelet viability
Coagulation factor V & XIII
Potassium content (mmol/L)

0 days
95%
95%
95%
3.5

7 days
90%
0%
30%
10

14 days
85%
0%
30%
25

21 days
75%
0%
30%
30

Indications for transfusion

Product
Whole blood

Indication
Class III % haemorrhage

Precaution Storage life
ABO &Rh. 21 days

Packed RBC

Severe anaemia

ABO &Rh. 21 days

FFP

Bleeding due to non-specified coagulation
factor deficiency. coumarin overdose.

ABO

1 year at -40 °C

Platelet

Primary or secondary thrombocytopenia

ABO

24-72 hours

ABO

1 year at -40 °C

Cryoprecipitates Bleeding with fibrinogen depletion
VIII & fibrinogen.
Factor VIII
Factor IX

Haemophilia A.
Haemophilia B. coumarin overdose.

2 years

Albumin

Acute volume expansion. Hypoalbuminaeia.

4 years

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Complication of Blood Transfusion
I - Transfusion- related complication:
1.

Haemolytic reactions.

Aetiology:
 Antibodies in the recipient's blood against antigens of the donor's cells.
 Mostly due to human error.
Clinically
 Present after the transfusion of less than 50 ml.
 Fatal more than 200 cc
 Fever, chills, constricting pain in the chest, dyspnoea and pain In the flanks.
 tachycardia and hypotension
 Anaesthetized patients: haemolytic reactions are sudden tachycardia, hypotension
and bleeding tendency.
 Major hemolytic reaction will lead to
 haemoglobinuria, jaundice and acute renal failure, DIC.
Management
 Stop transfusion
 Send for repeat typing and matching.
 Infusion of Lactated Ringer and IV corticosteroids.
 Osmotic diuretic as mannitol may be needed.
 IV infusion of sodium bicarbonate may be indicated.
2.

Pyrogenic reactions.





Commonest complication.
Present by: chills, fever, headache, nausea and vomiting.
Due to minor bacterial contamination.
Transfusion is stopped and the patient is given IV aspirin or paracetamol.

3.

Allergic reactions.







Range from mild itching and urticaria to a severe laryngeal oedema.
Due to antibodies against a protein in the donors plasma
Common with repeated transfusions in the past.
Treatment is by antihistaminic and corticosteroids.
If the reaction is severe, blood transfusion should be stopoed.

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4.

Post- transfusion purpura:
 In patients who have been previously sensitized to a foreign platelet antigen.

5.

Immunological sensitization:
- Antibodies developed from repeated transfusion.

II - Circulatory Overload
6.

Congestive cardiac failure.
 Occur in elderly persons especially if a large volume administered too rapidly.
 It is recommended packed red cells to correct anaemia in elderly persons.

III - Transmission of diseases
7.

Transmission of infection
Viral hepatitis (B or C):

The most feared complication.
AIDS / HIV infection can be transmitted by blood or by its products.
Syphilis: This is now rare.
Malaria: The disease is transmitted only by red cells, not by blood components.
Septicemia

IV – Others:
8.

Hyperkalaemia:
 storage of blood  progressive increase of potassium from erythrocytes.
 Several units  hyperkalaemia  cardiac arrhythmias or even arrest.

9.

Citrate intoxication:
- Citrate will bind to the calcium leading to hypocalcaemia
- which augments the effects of hyperkalaemia on the myocardium.
- If more than 2 units of blood are administered, it is important to administer 10 ml
of 10% calcium gluconate for each two units of blood.

10. Hemosidrosis:

-

Repeated red cell transfusion over many years will cause iron overload of the
macrophage system (usually after 100 units) e.g. in thalasaemia.
Treatment is by iron chelation therapy with desferrioxamine.

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11. Air

-

embolism.
Introduction of air through ill-fitting tubing especially if blood is introduced under
pressure.
Air enters the Rt. ventricle causing an air-lock and Rt. sided heart failure.
Treatment:
1. Trendelberg position (air will pass into the veins of the lower limbs)
2. Place the patient on the left side (air will float to the apex of the ventricle)
3. Oxygen therapy.
4. In severe cases aspiration of the right ventricle.

12. Massive

blood transfusion:

 Definition:
- Transfusion of 2500 ml of blood at one time
- or 5000 rot or more over 24hours (all body volume).
 Effect:
1 hypothermia.
- Warm the blood before transfusion
- as hypothermia can cause acidosis or cardiac arrest.
2 Hyperkalaemia. (discuss).
3 Citrate intoxication (discuss)
4 Hypocalcaemia.
5 Coagulation failure.: stored blood poor in:
 Platelets,
 Factor VIII and factor V.
 Coagulation factor.
 it is recommended to transfuse one unit of fresh frozen plasma and platelets for
every unit of stored blood
6 Diminished 02 carrying capacity of red blood corpuscles.
13. DIC:

(Discuss)

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Parenteral Fluid Therapy
Crystalloid solutions
5% Dextrose:
- It contains 278 mmol/l of glucose ( caloric content negligable).
- Glucose 5% supplies mainly water.
- Pass to IC and EC compartment. Only 7.5% stays in the intravascular
compartment.
Normal saline (0.9%):
- It contains 154 mmol/l Na+, 154 mmol/l Cl-.
- 500ml of saline can provide daily requirement of Na+.
- GIT losses have to replace by saline volume for volume.
Dextrose saline (0.18% saline,4%dextrose):
- It contains 30 mmol/l Na+, 30mmol/l Cl- and 222mmol/l dextrose.
Ringer`s solution:
- It contains 147mmol/l Na+, 4 mmol/l K+ and 2.2 mmol/l Ca++.
Hartmann`s solution=Ringer lactate solution:
- It contains 131mmol/l Na+, 5 mmol/l K+,29 mmol/l HCO3-, 111mmol/l Cl-,
2mmol/l Ca++.
- Ringer lactate solution is the best solution to be used in hypovolaemic shock.

Colloid Solutions
Albumin 4.5%:
- Molecular range from 45000 to 70000.
- It stays in the intravascular space.
- It corrects hypovolaemia but is expensive.
Gelatin (e.g. Haemaccel):
- It is produced from hydrolysis of bovine collagen.
- Half life in circulation 8:10 hours.
- Contains K and Ca++. So if mixed with citrated blood in a giving set
coagulation of blood

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-

Chapter 4: Acute Haemorrhage and Blood Transfusion

o Neoplastic, e.g., haematuria in renal cancer.
• Bleeding diathesis can increase the amount of traumatic and pathological bleeding, or
cause bleeding with little or no trauma (spontaneous haemorrhage).

Pathophysiological response to haemorrhage
The pathophysiological response to haemorrhage has two aims

1. Stopping the bleeding
•

Vasoconstriction and retraction of the intima of the injured vessel.

• Platelet plug.
• Blood clotting.

, -- Capillary ·
Pressure

Capillary refill
+-+ heart rate

Arteriolar

constriction Constriction
-venous

+-+ contractillty +-+ TPR

I++ Aldosterone

Venous
Arteriolar
constriction

++ Na reabsorption

++ Blood volume

capacitance

++ Arterial Prossuro
towards normal

++ Arterial Pressure
towards normal

Fig. 4.1. Main compensatory mechanisms for haemorrhage.

2.

Maintaining effective circulatory volume

and perfusion of critical
tissues (brain and heart), at the expense of less critical tissues (skin, skeletal muscle
and splanchnic area). This is achieved by neural and endocrine factors (Fig. 4.1 ).
A. Neural factors. A sympathoadrenal discharge develops due to decrease in
stimulation of arterial baroreceptors (aortic arch and carotid sinus) and atrial
stretch receptors leading to reduction of the normal inhibitory discharge in the
vagus and glossopharyngeal nerves on the vasomotor centre with consequent
stimulation of the sympathetic system. The effects include

• Constriction of veins, which normally contain two-thirds of the blood volume,
displaces blood from the capacitance side of the circulation into the heart.
• Constriction of arterioles raises the peripheral resistance but this is not uniform.
It involves mainly the arterioles of the skin, skeletal muscle, and splanchnic
area. Perfusion of the heart and brain is maintained because heir metabolic
needs override the alpha-adrenergic vasoconstrictor discharge.
•

Increased rate and strength of cardiac contraction.

Chapter 4: Acute Haemorrhage and Blood Transfusion

1111111111

B. Endocrine factors
• Catecholamine discharge occurs from the adrenal medulla and from the nerve
endings throughout the autonomic nervous system. They increase the heart rate
and myocardial contraction and cause constriction of the arterioles of the skin,
kidney and viscera.
ones hormone and glucagon are
As cortisol,
stress growth
• The metabolic hormones ACTH,

increased. Insulin release is inhibited by adrenaline and noradrenaline.
• The renin-angiotensin aldosterone system. The juxtaglomerular cells of the
afferent renal arterioles secrete renin in response to renal hypoperfusion. Renin
splits angiotensinogen to angiotensin I, which is converted to angiotensin II by a
converting enzyme in the lung. Angiotensin II is a powerful vasoconstrictor and
stimulates sodium and water retention by a direct action on the kidney as well as
indirectly through release of aldosterone from the zona glomerulosa of the
Intravasal adrenal cortex. Angiotensin-mediated vasoconstriction takes some 20 minutes
to occur, whereas baroreceptor-vasoconstriction occurs within seconds.

Tintin

now

ADH (vasopressin). Blood loss greater than 10% stimulates ADH release. ADH
increases the permeatJility of the renal collecting tubules allowing water
absorption into the hypertonic renal medu~ary interstitium. With severe
haemorrhage high levels of ADH also cause vasoconstriction.
C. Transcapiilary refill. Reduction of blood volume and constriction of arterioles
causes a fall in capillary hydrostatic pressure and promotes movement of fluid from
the interstitium into the capillaries, resulting in increased blood volume.
•

If ovulatory

compensationphase a spasmof
changes
celldistressphase
Capillaryrefill
Clinical picture of haemorrhage
decompensation irreversible
failure

The manifestations depend upon the amount of blood loss. Its rate and on cardiovascular
reserve. Thus, loss of only 500 ml of blood may cause hypotension in a patient with
coronary artery disease, whereas in a healthy young adult, losses greater than 1500 ml
may not lower systolic pressure initially. The following are the clinical manifestations of
hypovolaemia.

Symptoms
• Weakness and fainting especially when standing.
• The patient feels cold and thirsty.

Signs
•

The patient looks tired. With decreasing cerebral perfusion, the mental status may vary
from anxious to drowsy but the patient usually remains al.ert.

•

Pulse and blood pressure. With mild blood loss (less than 500 ml), pulse and blood
pressure may remain normal thanks to the efficient compensatory mechanisms. With
more blood loss, tachycardia develops but the blood pressure remains stable. With
further blood loss, however, the compensatory mechanisms can no longer maintain the
blood pressure and progressive hypotension develops (Table 4.1 ).

•

Pulse pressure (PP) decreases leading to a thready pulse.

•

Respiratory rate. Tachypn~a and air hunger.

•

Hypothermia, which predisposes to coagulopathy and should be avoided.

IIIIIIII

Chapter 4: Acute Haemorrhage and Blood Transfusion

• Skin becomes pale, cold and sweaty with slow capillary refill and collapsed veins.
•

Oliguria results due to diminished renal perfusion.

Table 4.1. Clinical parameters in different classes of haemorrhage.
- - -- -- - - - -C
-la_s_s_l
Blood loss (in 70 Kg
person)

15- 30% (7501500 ml)

(1500-2000 ml)

Normal to anxious

Anxious to
restless

Aggressive to
drowsy

Drowsy to unconscious

Skin

Normal

Pale and cold

Pale and colder

Pale and very cold

Capillary refill

Normal

>2 sec.

>2 sec

>2 sec undetectable

Pulse/minute

<100

100-120

100-140

>140

- Systolic

Normal

Normal (supine)

Low

Low

- Diastolic

Normal

Raised

Low

Low

- Pulse pressure

Normal

Low

Low

Low

14 -20

20-30

30- 35

>35

>30

20-30

10-20

0-10

Mental status

Up to 15%
(750 ml)

30-40%

>40% (2000 ml)

Blood pressure

Respiratory rate
Urine (ml/h)

Estimating blood loss

Blood volume is estimated as 70 ml/Kg in adults and 80 ml/Kg in children. In any patient
with haemorrhage, it is of importance to have a rough estimate of the amount of blood loss
determined from the following.
• Clinical data. Four classes of haemorrhage are recognized based on clinical changes
in haemodynamic parameters and indices of tissue perfusion (Table 4.1 ). This table
provides only general guidance.
• Type of injury. The haematoma around a closed fracture of the tibia may contain 5001500 ml of blood, that around a fractured shaft of femur, 500-2000 ml; that in a
fractured pelvis, 2000-3000 ml.
•

Blood loss at operation is the sum of the amount in the suction reservoir and the
amount mopped up by the swabs, the latter is calculated as the difference in swab
weight after and before operation multiplied by a correction factor of 1.5-2 depending
on the magnitude of the operation.

Investigations
•

Complete blood picture, including haematocrit. The initial haematocrit value is often
normal (RBCs and plasma are lost in the same ratio). Some 4-6 hours later, serial
haematocrits will show a reduction. Haemodilution is caused by movement of interstitial
fluid into the circulation and because of crystalloid replacement of lost blood.

• Coagulation profile.
• Cross matching.

Treatment of haemorrhage
1. Stop haemorrhage. First-aid treatment is by packing, pressure, and position. A skin
wound is covered by a dressing, and pressure is applied manually, by a

1.5 b4 5 Crystalloid

Chapter 4: Acute Haemorrhage and Blood Transfusion -

sphygmomanometer cuff or by a bandage. Tourniquets are contraindicated because of
complications unless the limb is going to be amputated. Elevation of the limb above the
heart level stops venous and decreases arterial bleeding. Other examples of first aid
treatment include the pneumatic anti-shock garment (PASG), which can tamponade
lower limb, pelvic and abdominal haemorrhage. The garment increases peripheral
resistance and so raises the blood pressure. Another example is balloon tamponade of
haemorrhage from oesophageal varices. The definitive management depends upon the
cause of bleeding.
2. Restore blood volume. A large bore cannula is inserted in a large peripheral vein,
preferably in the upper limb, or by a cut down on the long saphenous vein, if
necessary. Volume replacement depends on the class of the haemorrhage.
Class II
• The deficit is estimated at 15-30% (750-1500 ml/70 kg).
• The replacement solution is lactated Ringer's.
• The amount is 3 times the estimated deficit (-3 L). The 3: 1 rule serves to replenish
the interstitial fluid volume when the crystalloid diffuses out of the capillaries.
• Administration. Two litres are given as a bolus and the response is monitored. If
there is definite improvement: the remaining litre is given more slowly followed by
the maintenance requirements and continued observations (a haematocrit <30
requires blood transfusion). If there is moderate improvement, the possibilities are
inadequate replacement, continuing haemorrhage or myocardial insufficiency.
Cardiac tamponade and tension pneumothorax must be excluded. Blood
transfusion is started if bleeding is still active.
Cardiac
Class Ill and IV

means Aorns Aneurysm

failure

• The management is as for class II but these patients need blood transfusion. The
initial volume of transfused blood is that of the estimated deficit (1500-2000 ml).
•

Failure to improve and a rising CVP indicate tension pneumothorax, cardiac
tamponade, or cardiac failure. If these are excluded and the patient does not
improve, major thoracic, abdominal, or pelvic injury is usually present and calls for
immediate operation to control the bleeding. Clean blood in the thorax or abdomen
can be aspirated, anticoagulated and then transfused back into the patient (autotransfusion), if a cell-saver is available.

• Transfusion should continue until the haematocrit has reached 30%, the urine
output 50 ml/hour, and the CVP has risen to the upper half of the normal range.
3. Optimize oxygen delivery. Forty percent oxygen is given for class II haemorrhage
and 100% for classes Ill and IV. Intubation and mechanical ventilation and the use of
inotropes (dopamine and dobutamine), vasodilators and vasopressors may be
40
necessary if raising oxygen carrying capacity by blood transfusion does not improve
lass
oxygen delivery.
01 31
4. Monitoring is important to prevent the clinical sequelae and complications of
hypovolaemic shock, i.e., cardiac arrest, adult respiratory distress syndrome (ARDS),
acute renal failure, GIT dysfunction with stress bleeding, and disseminated
intravascular coagulation (DIC).

2

What to monitor?
• The parameters in Table 4.1 suffice if the patient is fit and responds quickly to bolus
infusion of 2 litres of Ringers lactate solution. A Foley catheter is necessary to

morphine is fine

body core temperature 25 normally Any increase
111111!1 Chapter 4: Acute Haemorrhage and Blood Transfusion Perfusion

means

055m

monitor urine output. Serial rectal temperatures, haematocrits and cardiac
monitoring (ECG for early detection of shock-induced arrhythmias) are important.
•

preload

Invasive monitoring is needed if the patient is old or has compromised cardiac
reserve , class Ill or IV haemorrhage, or does not respond well to initial crystalloid
administration. Central venous pressure (CVP), blood gases, and blood lactate
(index of anaerobic metabolism), are necessary. A pulmonary artery catheter is
required in complex situations to monitor the function of the left side of the heart.

RIFailure to respond to treatment is due to either

• Continuous bleeding.
• Pump failure (tension pneumothorax, cardiac tamponade, or cardiac contusion).
Pump failure is distinguished by a high CVP reading.
• Irreversible shock

catheter
Swansans
Blood transfusion
Blood is a precious commodity. Its only source is the human being, who willingly parts with
some of his life fluid to save the life of a fellow human. Handling of blood should, therefore,
be conducted with the deserved dignity, and it should also be administered in its proper
indication.
Advances in technology allowed the evolution of synthetic blood substitutes that have the
ability to carry oxygen. Though still not the perfect substitute, with further refinement these
substances are expected, in the future, to solve the problem of limited sources and
complications of blood transfusion.

Collection and storage of blood
For standard transfusion blood is collected into a citrate anticoagulant solution which also
contains dextrose to preserve the viability of RBC's during storage.
One blood bag (unit) contains 70-100 ml of the anticoagulant and 400-450 ml of blood.
Blood must be kept at 2-6°C during storage.

Common blood products
•

Packed red cells (red cell concentrate). The transfusion of packed red cells is very
useful in anaemic patients, in the elderly and in cardiac patients as it improves the
oxygenation ability without overloading the circulation.

•

Fresh frozen plasma. Plasma removed from fresh blood is rapidly frozen and stored
at -40°C. It is a good source of all the coagulation factors. It is useful to correct
coagulation disorders in haemophilia, Christmas disease and in liver failure.

•

Platelet concentrates. The amount obtained from one unit of blood will increase the
circulating number of platelets by 10,000 to 15,000/ul. As the half life of platelets is
short, they should be freshly prepared. They are very useful in patients with
thrombocytopenia.

• Cryoprecipitate. This is prepared from fresh frozen plasma and is very rich in factor
VIII and fibrinogen. It is stored at -40°C.

Chapter 4: Acute Haemorrhage and Blood Transfusion -

Possible complications of blood transfusion
•

Immunological complications
a. Incompatible red cells

b. Incompatible white cells

Acute haemolytic reaction

c. Incompatible platelets

Pyrogenic reaction
Purpura

d. Reaction to a protein in the plasma -

Allergic reaction

(a) Acute haemolytic reaction. Most often these reactions are due to the presence of
antibodies in the recipient's blood against one or more of the antigens of the donor's
red cells. Clinically haemolytic reactions present after the transfusion of less than 50
ml by fever, chills, constricting pain in the chest, dyspnoea and pain in the flanks.
Examination reveals tachycardia and hypotension. In anaesthetized patients, the
only manifestations of haemolytic reactions are sudden tachycardia, hypotension
and bleeding tendency. A major haemolytic reaction will lead to haemoglobinuria,
jaundice and acute renal failure due to acute tubular necrosis. Consumption
coagulopathy will lead to generalized bleeding tendency.
Management

o Stop the transfusion immediately.
o Send the donor's blood and a sample of the patient's blood for repeat typing and
matching.
o Correct shock by infusion of crystalloid solution (Lactated Ringer) and IV
corticosteroids.
o Insert a Foley catheter and check that there is an adequate urine output. An
osmotic diuretic as mannitol may be needed. Keep an alkaline urine to protect
against acute renal failure. IV infusion of sodium bicarbonate may be indicated.
o Should the patient develop acute renal failure, he must receive the appropriate
treatment.
(b) Pyrogenic reactions. These are the commonest unpleasant consequences of
blood transfusion. The patient develops chills, fever, headache, nausea and
vomiting. These reactions are due to the presence of recipient antibodies against
some components of the donor's white blood cells. Transfusion is stopped and the
patient is given IV aspirin or paracetamol.
(c) Post-transfusion purpura may develop in patients who have been previously
sensitized to a foreign platelet antigen.
(d) Allergic reactions may develop due to immunoglobulin antibody in the recipient
complexing with a protein present the donor's plasma. These range from mild
itching and urticaria to a severe reaction with laryngeal edema and collapse. These
reactions are common in those patients who received many transfusions in the
past. Treatment is by antihistaminics and corticosteroids. If the reaction is severe,
blood transfusion should be stopped.
•

Congestive cardiac failure. This is liable to occur in elderly persons especially if a
large volume of blood is administered too rapidly. It is recommended to transfuse
packed red cells rather than whole blood to correct anaemia in elderly persons.

..rl)I
•

Chapter 4: Acute Haemorrhage and Blood Transfusion

Transmission of infection

o Viral hepatitis (B or C). This is now the most feared complication. The virus can be
transmitted by whole blood or blood products. It is obligatory to test donors for
hepatitis viruses.
o AIDS/HIV infection can be transmitted by blood or by its products.
o Syphilis. This is now rare. Spirochetes cannot survive at the blood bank

temperature for more than 4 days.
o Malaria. The disease is transmitted only by red cells, not by blood components.
o Septicemia. Bacteria can survive, but they cannot multiply significantly in
refrigerated blood. However, if the blood is allowed to warm, bacteria can grow and
Gram-negative endotoxins can cause septic shock.

•

Hyperkalaemia. With prolonged storage of blood, there is progressive loss of
potassium from erythrocytes into the plasma. Transfusion of several units of aged
blood may produce cardiac arrhythmias or even arrest due to hyperkalaemia.

•

Citrate intoxication: Excess citrate will bind to the recipient's calcium leading to
hypocalcaemia which augments the effects of hyperkalaemia on the myocardium. If
more than 2 units of blood are administered, it is important to administer 10 ml of 10%
calcium gluconate for each two units of blood.

•

Air embolism.

•

Transfusion related acute lung injury (TRALI). This is the result of incompatibility
between donor's antibodies and recipient granulocytes. It gives a clinical picture similar
to ARDS.

• Complications of massive blood transfusion. This implies transfusion of 2500 ml of
blood at one time or 5000 ml or more over 24 hours.
o Hypothermia. A special warming unit should be used to warm blood before
transfusion as hypothermia can cause acidosis and cardiac arrest.

o Hyperkalaemia.
o Hypocalcaemia.
o Coagulation failure. This is due to the dilution of clotting factors and platelets when

large volumes of stored blood are being used to replace blood losses, because
stored blood is poor in platelets, factor VIII and factor V. In these situations, it is
recommended to transfuse one unit of fresh frozen plasma and platelets for every
unit of stored blood.
o Diminished 02 carrying capacity of red blood corpuscles.

Alternatives to homologous blood transfusion
1. Autologous blood transfusion: A patient who is going to have a major elective operation
can donate some units of his own blood over several days. The blood is kept in the
refrigerator to be given back to him during surgery.
2. Preservation of the blood lost during surgery and its reinfusion to the patient. This
needs a special apparatus (cell saver).

Chapter 4: Acute Haemorrhage and Blood Transfusion Table 4.2. Indications for transfusion of blood and its products
Product

Indication

Precautions

Storage life

Whole blood

Class Ill & IV haemorrhage

ABC & Rh

21 days

Red cell concentrates

Severe anaemia

ABC & Rh

21 days

Fresh frozen plasma

Bleeding due to non-specified coagulation
factor deficiency

ABO

1 year at - 40°C

Coumarin overdose
Platelet concentrates

Primary or secondary thrombocytopenia

ABO

24 - 72 hours

Cryoprecipitates of
factor VIII &fibrinogen

Bleeding with fibrinogen depletion

ABO

1 year at - 40°C

Factor VIII

Haemophilia A

Factor IX

Haemophilia B. Coumarin overdose

Albumin 5% or 20%

Acute volume expansion. Hypoalbuminaemia

2 years
4 years

Chapter 5: Haemostasis -

CHAPTER 5

HAEMOSTASIS
Introduction:
Haemostasis is the physiological arrest of bleeding.
It involves vasoconstriction, platelet plug formation and
fibrin deposition to form a stable clot sealing the disruption
in the vessel wall. A fourth mechanism, fibrinolysis breaks
down the clot, restoring vascular patency after bleeding
has stopped. Natural haemostasis sometimes fails leading
to excessive bleeding or thrombosis.

Natural haemostasis
Primary haemostasis
Arrest of haemorrhage within the first few minutes is
achieved by:

CHAPTER CONTENTS
• Introduction
• Natural haemostasis
o Primary haemostasis
o Secondary haemostasis
o Fibrinolysis
• Heemostatic disorders
o Congenital disorders
o Acquired disorders
• Preoperative evaluation of
haemostasis
• Excessive operative and
postoperative bleeding
• Surgical haemostasis

1. Vasoconstriction of the disrupted vessels. This is achieved by:
• Contractile proteins in the endothelium (even capillaries constrict).
• Neurogenic reflexes.
• Direct smooth muscle stimulation (spasm).
• Vasoconstrictors , e.g. thromboxane.
Vasoconstriction is more efficient in arteries than veins because arteries contain
more muscular fibres. Vasoconstriction is less effective in the following conditions:
o When a vessel is partially injured.
o In stiff atherosclerotic vessels.
o In large veins (poor muscle coat).
2. Platelet plug. Platelets serve the following haemostatic functions:
• Adhere to exposed subendothelial collagen.
• Release the contents of their granules, e.g. ADP, and serotonin.
• Aggregate to form a plug that seals the bleeding vessel. Thromboxane from
platelet membrane phospholipid, ADP, serotonin, thrombin etc, are
responsible for aggregation.
• Platelet phospholipid has a vital role in blood coagulation.
3. Tamponade of the bleeding by surrounding tissue tension. Interstitial haemorrhage
tends to be less profuse than external or internal haemorrhage.
Secondary haemostasis:
Maintenance of haemostasis after the first few minutes requires that the platelet
plug be reinforced by fibrin deposition, i.e. coagulation otherwise, the soft platelet plug may
be washed away be the blood flow. Coagulation is activated by two mechanisms.

-

Chapter 5: Haemostasis

1. Extrinsic; initiated by activation of factor VII upon admixture of plasma and tissue
factor.
2. Intrinsic, initiated by activation of factor XII upon contact with a non-endothelial
surface, more directly by activation of factor IX through activated factor VII.
Intrinsic pathway

Extrinsic pathway

'"""doilier collage,

vu

tissue factor

I

Vila

OCI1 - - - - Xlla

!

XI - -- -

Vlll

l

X

PL

Xa

~1
PL

Prothrombin

Thrombin (Ila)

Fibrinogen

Fibrin monomer
XIII
stable fibrilpolymer

I

hos holi id .

The common pathway is activated when activation of
the intrinsic and extrinsic pathways leads to activation of
factor x, and eventually to the formation of the fibrin clot (Fig.

5.1 ).

Sequential activation occurs locally; any activated
coagulation factor spilling into the general circulation is
neutralized by inhibitors such as antithrombin Ill and proteins C
and S. Deficiency of these proteins may cause spontaneous
thrombosis, e.g. mesenteric vascular occlusion .
Fibrinolysis

plasminogen

...0

i

>

;:;

u

Ill
QI

::,

fibrinogen

rn
rn

i=

plasmin-

FOP
Once haemostasis is achieved, the clot obstructing the
FiQ. 5.2. Fibrinolysis
vessel is no longer needed. Circulating plasminogen and tissue
plasminogen activator bind to the fibrin clot leading to local formation of plasmin which
digests the clot and restores vascular patency (Fig. 5.2). Circulating inhibitors neutralize
plasminogen activators and plasmin which form or overflow into the circulation. The
products of fibrin digestion by plasmin are called fibrin degradation products (FOP). D-

Chapter 5: Haemostasis -

dimers result from plasmin cleavage of cross linked fibrin and constitute a marker of
fibrinolysis.
Hypercoaguable states

Haemostasis disorders:~
Bleeding diathesis
Hypercoaguable States:

An acquired tendency to thrombosis occurs in pregnancy, estrogen use (HRT or
contraception), and malignancy. This tendency is increased if there is an associated
inherited thrombohilia, e.g. deficiency of a natural anticoagulant (antithrombin Ill, protein C
or protein S).
Haematology consultation is required for a personnel or family history of
spontaneous/recurrent thrombosis whether arterial and/or venous as well as obstetric
history of recurrent miscarriages. Surgical patients should have standard DVT prophylaxis.
Estrogen should be stopped 1 month before elective surgery.
Bleeding diathesis: Congenital or acquired
Congenital disorders

E

1.

Haemophilia A and B: These are due to deficiency of factors VIII and IX
respectively. Inheritance (in both) is sex-linked (from females to males).
Manifestations vary from frequent episodes of spontaneous bleeding starting in
childhood, (<1% of factor activity). to bleeding only after trauma or surgery (factor
level 5-20% of normal). Patients are liable to recurrent haemarthrosis.

Management involves:
Infusion of factor concentrate within 1 hour before surgery and for 10 days
thereafter.
Avoiding aspirin and the nonsteroidal anti-inflammatory drugs (NSAIDs)
because of their anti-platelets effect, and avoiding IM injections (large
haematomas can develop).
As the patient will need repeated transfusion.he needs vaccination against
hepatitis 8.
2. von Willebrand disease (vWD): von Willebrand disease, together with haemophilia
A and 8, constitute more than 95% of inherited coagulopathies. Inheritance is
autosomal dominant with variable expression. vWD is due to deficiency of vW factor
which enhances platelet adhesion and acts as a carrier to factor VIII, preventing its
premature destruction. Manifestations are due to platelet and coagulation problems.
Treatment is to supply vWF and cryoprecipitate.

Acquired disorders
These are more prevalent than congenital ones.

E

1. Hepatic disorders:

Both acute and chronic liver diseases may be accompanied by haemostatic
abnormalities. Aetiology is multifactorial.

-

Chapter 5: Haemostasis

• Coagulation factors:

o Decreased concentration of all clotting factors except factor VIII and vWF
(from endothelium).
o Dysfibrinogenaemia. Defective polymerization of the fibrin clot.
o Antithrombin level is decreased, this contributes to intravascular coagulation
in cirrhotics.
Prothrombin time (PT) is the first to be prolonged (decreased synthesis of factor
VII) which has a short half life. In more severe diseases, partial thromboplastin
time (PTT) is also prolonged (decrease synthesis of other factors, e.g. V, IX and
X).
• Platelets:

o Thrombocytopenia due to splenic sequestration or destruction due to
hypersplenism.

Gtibody

o Abnormal function due to preponderance of small, less active platelets.

The bleeding time is, however, normal in most cirrhotics.
• Fibrinolysis:

9
Stop plasminogg

o Reduced synthesis of inhibitors of fibrinolysis, e.g., alpha 2 anti-prothrombin.
o Impaired clearance of plasminogen activators. Fibrin degradation products
(FOP) level may increase.

Like
DIC • Treatment:
o Vitamin K administration.

bit

plated

o In the setting of bleeding or an invasive procedure give:

are fire

• Fresh frozen plasma (FFP) if PT or aPTTT >1.5 times normal.
• Cryoprecipitate to correct severe hypofibrinogenemia (<100 mg/di).
o Desmopressin (0.3 ug/kg) can raise the levels of factor VIII and vWF, and
shorten the bleeding time before an invasive procedure.

2. Vitamin K deficiency:

The sources of this fat soluble vitamin are the diet and bacterial synthesis in the
colon. Bile is necessary for its absorption. Causes of deficiency include:
• Inadequate diet (or TPN).
• In debilitated patients given prolonged broad spectrum antibiotics (reduce colonic
bacteria).
• Cholestatic jaundice.
• Malabsorption.
• Oral anticoagulants.
Vitamin K is a co-factor in the synthesis of factor II, VII, IX, and X. Deficiency leads
to easy bruising and increased traumatic bleeding. Both the PT and PTT are prolonged.
Treatment is with vitamin K1 by slow IV infusion (5-10 mg), or daily IM injections for 3
days (10-20 mg/day). In an emergency, factor concentrates, (II, VII, IX and X), or fresh
frozen plasma may be needed as well as blood.

Chapter S: Haemostasis -

3. Disseminated intravascular coagulation (DIC):
Two processes occur.
• Widespread activation of coagulation within the circulation leading to consumption of
coagulation factors, including fibrinogen, and to depletion of platelets. This is due to
entery of procoagulant substances into the circulation.
• Stimulation of fibrinolysis by increased levels of fibrin degradation products (FOP),
worsen the coagulopathy by inhibiting fibrin polymerization.

Causes include:
• Septicaemia.
• Severe shock, trauma, and burns.
• ABO incompatible transfusion.

• Malignancies, e.g., metastatic carcinoma of the lung, pancreas, stomach, prostate,
and leukaemia.
• Obstetric accidents (eclampsia, abruptio placenta, amniotic fluid embolism, and
retained dead fetus).

Diagnosis is suspected by:
• Diffuse bleeding from wounds, incisions, drain and venopuncture sites.
• Widespread bruising, purpura and mucosa! bleedtng.
• Occasionally, the thrombi are not lysed quibkly and ischaemic manifestations
occur, e.g., gangrene of skin and digits.
• Uncoagulable blood in severe cases.

Laboratory features include:
• Thrombocytopenia.
Prolongation of PT, PTT and low fibrinogen level (N=2-4 g/L).
• Raised level of FOP and O-dimers.

Treatment:
• Treatment of the underlying cause to stop the cycles of
coagulation/fibrinolysis, e.g. draining an abscess and antibiotics for
infection.
• Replacement of consumed coagulation factors and platelets with fresh
frozen plasma (3-4 units initially) and cryoprecipitate when available (it is
rich in factor VIII and fibrinogen), and platelet transfusion (10-12 packs
may be needed initially).
• Blood transfusion to restore circulating blood volume and oxygen carrying
capacity since hypoxia exacerbates DIC.
• Heparin is only used is 'there is a large vessel thrombosis.

4. Anticoagulants:
Anticoagulants are used to prevent or treat arterial or venous thromboembolism.
Bleeding may occur if the dose is not properly adjusted.

IIIIIIIIII

Chapter 5: Haemostasis

A problem arises when a patient on warfarin requires surgery. Preoperatively the_
INR must be allowed to drop below 1.5 before the surgery to avoid excessive bleeding.
This is achieved by stopping the daily warfarin dose for 4-5 days before elective surgery or
using FFP in an emergency (or recombinant factor VIia to avoid risk of blood component
therapy.
An INR <1.5 must be confirmed before surgery.
Preoperative low molecular weight heparin is required if stopping warfarin is
associated with a high risk of recurrent thrombosis. LMWH, e.g. enoxaparin, 1 mg/Kg SC
every 12 hours is started 36 hours after the last dose of warfarin and stopped 24 hours
before operation.
Postoperatively LMWH is restarted 24 hours post-procedure. Warfarin is restarted
on postoperative day 1 at the preoperative dose. Stop heparin and continue with warfarin
when the INR reaches target level, e.g. 2-3.
5. Massive blood transfusion (Chapter 4)
6. Platelets disorders:
Thrombocytopenia:

Decreased production by the bone marrow (leukemia, cancer infiltration,
viral infection and chemotherapy.
Increased destruction (ITP, drug-induced e.g. heparin, thiazides and
sulpha).
Increased sequestration in hypersplenism.
Disorders of platelets' functions:

Drugs as aspirin, clopidogrel and NSAIDs inhibit cycloxygenase and
prostaglandin synthesis, thus they interfere with platelet adhesiveness.
Dipyridamole (Persantin) reduces platelet adhesiveness.
• Uraemia and hypothermia can cause platelet dysfunction.
N.B.: Aspirin and NSAID should be stopped 7 days before surgery.

Preoperative evaluation of haemostasis:
All patients scheduled for elective surgery should be evaluated for a possible
haemostatic defect by history, examination and, when appropriate, laboratory tests.
History:

This is the most important part of the haemostatic evaluation. Points to be covered
include:
1. Family history of bleeding. If positive in maternal grandfathers, maternal uncles, or
a brother.it suggests haemophilias (A or B); in a parent or sibling of either sex, it
suggests vWD (autosomal dominant inheritance with variable expression).
2. History of bleeding tendency, e.g., spontaneous bleeding, prolonged bleeding after
a haemostatic challenge (circumcision, dental extraction, surgery or trauma),
bleeding from multiple sites, or easy bruisability.

Chapter 5: Haemostasis

IDIII

3. Age at onset of bleeding. A long history and onset in childhood suggest a
hereditary disorder. Recent onset in an adult suggests an acquired disorder.
4. Inquire about liver disease, chronic renal failure, massive blood transfusion
and drug intake.
5. Characters of the bleeding:

• Defects of primary haemostasis (platelet/vessel abnormalities). Bleeding is
·superficial i.e. skin and mucous membranes, such as petichiae, purpura, easy
bruisability, epistaxis, and menorrhagia. Excessive oozing occurs immediately
following surgery or trauma and is usually controlled by local pressure. Visceral
bleeding, e.g., CNS is not common.
• Defects of secondary haemostasis (coagulation/fibrinolysis). Bleeding is deep,
e.g. haemoarthrosis, haematomas in muscles, retroperitoneal or visceral, in
addition to easy bruisability. Onset following surgery or trauma is delayed and

local pressure is usually ineffective. Mucous membrane bleeding is not common.
• Excessive fibrinolysis or thrombolytic agents cause generalized bleeding, e.g.
from the wound, drain site, or IV sites.
Examination:

The following points are checked in the preoperative patient if a bleeding tendency
is suspected.
1. Cutaneous signs of liver disease, e.g. jaundice, and spider naevi.
2. Skin and mucous membranes are examined for bleeding, petichiae, or bruising.
3. Musculoskeletal system. Muscle haematomas, and haemoarthrosis (coagulopathy).
4. Abdomen. Hepatomegaly, and splenomegaly. The latter may be the cause of platelet
sequestration and thrombocytopenia.

Tests of Haemostasis
Indications:

1. Patients with a personal history or a family history of abnormal bleeding.
2. Patients with diseases or who receive medications that can interfere with
haemostasis.
Tests of primary haemostasis:

1. Platelet count. Normal=150.000-400.000/ul.
• Spontaneous bleeding occurs with counts 10.000-20.000luL.
• Prolonged bleeding with minor trauma occurs with counts 20.000-50.000/ul.
• Prolonged bleeding with major surgery/trauma occurs with counts 50.000100.000/ul.
• No haemostatic abnormality occurs in counts more than 100.000/ul.
2. Bone marrow aspiration and biopsy.
• Megakaryocytes are normal or increased in thrombocytopenia due to peripheral
destruction or sequestration.

Chapter 5: Haemostasis

Megakaryocytes are rare in bone marrow damage, e.g., chemotherapy, or
replacement, e.g. leukaemias.
3. Bleeding time (BT) is prolonged with platelet and vascular defects.
4. Tests of platelet function (adhesion, release, aggregation) may be necessary when
the BT is prolonged but platelet counts are normal.
Tests of secondary haemostasis:

1. Prothrombin time (PT) measures the time of cloning through the extrinsic and
common pathways which involve factor VII and factors X, V, II and fibrinogen
respectively.
2. PartiaJ thromboplastin time (PTT) measures the time of clotting through the intrinsic
pathway (factors XII, XI, IX, and VIII) and the common pathway.
3. Thrombin time (Tl) measures the time of clotting after thrombin is added to plasma. It
is sensitive to abnormalities of fibrin formation, e.g. due to FOP in DIC.
Other tests:

1. Fibrinogen level is decreased in DIC.
2. Fibrin degradation product (FOP) and D-dimer screens for fibrinolysis.
3. Individual coagulation factor assays.
4. Clot stability test evaluates factor XIII, deficiency of which is not detected by the PT
or PTT.

Excessive operative and postoperative bleeding
Causes:

1. Inadequate surgical haemostasis is the commonest cause. If the bleeding persists, it
becomes complicated by DIC and the coagulopathy of massive blood transfusion.
2. Haemorrhagic diathesis not detected preoperatively. The PT, PTT and TT are not
very sensitive and may be normal even when the deficient factor concentration is
down to 20% of normal level. A PT of 2-3 seconds above normal level is