Introduction to Haematology

Question 1

What is the definition of haematology?

Answer 1

Biology and pathology of the cells that normally circulate in the blood 🩸

Question 2

What is the definition of haemopoiesis?

Answer 2

The physiological developmental process that gives rise to the cellular components of the blood

a single multipotent haemopoietic stem cell can divide and differentiate to form different cell lineages that will populate the blood

Question 3

What is the difference between symmetrical and asymmetrical division when the haemopoietic stem cell undergoes differentiation and/or self-renewal?

Answer 3

Symmetrical division:

• may yield two identical stem cells
• or two daughter cells that have undergone a degree of differentiation and concomitant loss of self-renewal capacity

Aysmmetrical division:

• both a stem cell and a daughter cell are generated

Question 4

What are the 2 different types of symmetrical division?

Answer 4

Symmetric self-renewal:

• increase stem cell pool
• no generation of differentiated progeny

Lack of self-renewal:

• depletion of stem cell pool
• generation of differentiated progeny ONLY

Question 5

What is meant by aysmmetric self-renewal and lack of self-renewal?

Answer 5

Asymmetric self-renewal:

• maintains the stem cell pool
• generation of differentiated progeny

Lack of self-renewal:

• maintain the stem cell pool
• no differentiated progeny

Question 6

What are the characteristics of the haemopoietic stem cell?

Answer 6

1. Self-renewal
2. High proliferative potential
3. Differentiation potential for all lineages
4. Long term activity throughout the lifespan of the individual

Question 7

What is an example that gives experimental proof of the properties of the haemopoietic stem cell?

Answer 7

• Stem cells transplanted from one mouse to another over several generations
• bone marrow transplantation in humans

Question 8

What are the 2 different haemopoietic lineages with examples?

Answer 8

Myeloid:

• granulocytes (white blood cells)
• erythrocytes (red blood cells)
• platelets

Lymphoid:

• B-lymphocytes
• T-lymphocytes

Question 9

How do stem cells help to maintain the cellular content of the blood?

Answer 9

Stem cells give rise to sufficient numbers of committed haemopoietic progenitors to maintain the cellular content of the blood throughout the lifespan of the individual

Question 10

What are the stages shown in haemopoiesis?

Answer 10

Question 11

What is the lifespan of an erythrocyte and neutrophil like?

Answer 11

Mature blood cells all have a finite life

an erythrocyte has a lifespan of about 120 days

a neutrophil only lasts for 6-10 hours in the bloodstream

Question 12

What is the difference between pluripotent and committed stem cells?

Answer 12

Pluripotent stem cells:

• ​develop into cells and tissues of the three primary germ layers
• can develop into any type of cell in the body

Committed stem cell:

• cells that have been committed to a particular pathway of differentiation

Question 13

Label the components of the trophoblast at 9 days

Answer 13

Extra-embryonic coelom is the chorionic cavity

this is a fluid-filled area formed from trophoblast and extra-embryonic mesoderm that forms the placenta

Question 14

What is the morula?

Answer 14

An early-stage embryo consisting of 16 cells (called blastomeres) in a solid ball contained within the zona pellucida

it goes on to form the blastula

trophoblasts are cells forming the outer layer of the blastocyst

Question 15

When does haematopoiesis start?

Where does this occur?

Answer 15

Haemopoiesis starts at day 27 in the aorto-gonado-mesonephros

this expands rapidly at day 35, and then disappears at day 40

Question 16

What happens when the aorto-gonado-mesonephros disappears at day 40?

Answer 16

The disappearance correlates with the migration of the haemopoietic stem cells to the foetal liver

this becomes the subsequent site of haemopoiesis

Question 17

What are the 4 main functions of blood cells?

Answer 17

• Oxygen transport
• coagulation (haemostasis)
• immune response to infection
• immune response to abnormal cells (senescent, malignant, etc.)

Question 18

What are the properties of erythrocytes?

How many are present in the body?

Answer 18

Biconcave discs that are 7.5 um in diameter

lifespan of 120 days in the blood

contain haemoglobin

there are 333,200 x 10⁶ red cells in the blood

Question 19

What is it called when there are reduced and raised red cells?

Answer 19

Anaemia occurs when there are reduced red cells

polycythaemia occurs when there are raised red cells

Question 20

What is relative polycythaemia?

Answer 20

The number of red blood cells has not changed but the plasma volume has been reduced

Question 21

What are the functions of white blood cells (leukocytes)?

What are the 3 different types?

Answer 21

They have functions in immunity and host defence

granulocytes:

• have cytoplasmic granules
• neutrophils, eosinophils, basophils

monocytes

lymphocytes

Question 22

How many neutrophils are present in the blood usually?

Answer 22

They are phagocytes and the most common white cell in adult blood

10 x 10⁹ per litre

they live for only a few hours in the blood

Question 23

What is it called when there are increased and decreased numbers of neutrophils in the blood?

Why might this occur?

Answer 23

Neutrophilia:

• increased numbers of neutrophils
• occurs in bacterial infection and inflammation

Neutropenia:

• decreased numbers of neutrophils
• occurs as a side effect of some drugs

Question 24

When might there be increased numbers of eosinophils?

Answer 24

Eosinophilia is an increase in the number of eosinophils

this occurs in allergies and parasitic infection

Question 25

What is the role of basophils?

When may there be an increase in basophils and what is this called?

Answer 25

Basophils are rare cells that are part of the primitive immune system

basophilia is an increase in the number of basophils

this occurs in chronic myeloid leukaemia

Question 26

What are the roles of monocytes?

Where do they migrate to?

Answer 26

They are phagocytic and act as antigen-presenting cells

they migrate to tissues and are then identified as macrophages and histiocytes

e.g. Kupffer cells in the liver, Langerhans cells in the skin

Question 27

When may there be an increase in monocytes?

Answer 27

Monocytosis

this is an increase in the number of monocytes

occurs in tuberculosis

Question 28

What is it called when there is an increase or decrease in lymphocytes?

Why might this occur?

Answer 28

Lymphocytosis:

• increase in number of lymphocytes
• occurs in chronic lymphocytic leukaemia
• atypical lymphocytes of glandular fever (infectious mononucleosis)

lymphopenia:

• decrease in the number of lymphocytes
• e.g. post bone marrow transplant

Question 29

What are the role of natural killer lymphocytes?

Answer 29

They are large granular lymphocytes that are part of the innate immune system

they recognise “non-self” - cells / viruses

Question 30

What are the roles of T-lymphocytes?

Answer 30

Part of the adaptive immune system

• involved in cell-mediated immunity
• target-specific cytotoxicity
• interact with B cells and macrophages
• regulate immune responses

Question 31

What are the roles of B-lymphocytes?

Answer 31

part of the adaptive immune system

• rearrange immunoglobulin genes to enable antigen-specific antibody production
• involved in humoral immunity

Question 32

What is plasmacytosis?

When may it occur?

Answer 32

An increase in the number of plasma cells (produced from B-lymphocytes)

occurs in infection and myeloma

Question 33

What are platelets formed from?

How many are present in the blood?

Answer 33

Platelets are derived from bone marrow megakaryocytes

there are 200 x 10⁹ per litre

Question 34

What are the roles of platelets?

Answer 34

Together with soluble plasma clotting factors and endothelial cells, they form part of the blood clotting system

they aggregate to plug holes in damaged blood vessels

Question 35

What are the four main subdivisions of haematology clinical practice?

Answer 35

• Coagulation
• malignant
• non-malignant
• transfusion

Question 36

What diagnostic tests are used in haematology?

Answer 36

• Full blood count
• blood film (or “smear”)
• coagulation screen

Question 37

What is involved in a full blood count?

Answer 37

• Haemoglobin concentration
• red cell parameters:

MCV - mean cell volume

MCH - mean cell Hb

• white cell count (WCC)
• platelet count

Question 38

What is a blood film?

Answer 38

A thin layer of blood smeared on a glass microscope slide and then stained in such a way as to allow the various blood cells to be examined microscopically

Question 39

What is a coagulation screen?

Answer 39

Tests that measure the time taken for a clot to form when plasma is mixed with specific reagents

various parts of the coagulation cascade can be assayed

Question 40

What types of things are looked at when a coagulation screen is performed?

Answer 40

• Prothrombin time
• activated partial thromboplastin time
• thrombin time

Question 41

What is involved in a bone marrow aspirate & trephine?

Answer 41

Under local anaesthetic, liquid marrow is aspirated from the posterior iliac crest of the pelvis

a trephine core biopsy is then taken with a hollow needle

Question 42

What is a trephine?

Answer 42

A hole saw used in surgery to remove a circle of tissue or bone

Question 43

What is involved in obtaining a blood specimen?

Answer 43

An accurate FBC and correct interpretation of a blood film

• need an appropriate sample from the patient
• collect into EDTA anticoagulated blood

this should be mixed well and [K₂EDTA] = 1.5 - 2.2 mg / ml

blood should be filled to the line on the tube

• Samples should get to the lab promptly since EDTA artefact can affect the results

Question 44

What is EDTA and what does it do?

Answer 44

It is a chemical that binds and holds onto minerals and metals

e.g. Iron, lead, mercury, copper, magnesium, etc.

when they are bound, they cannot have any effects on the body and are removed from the body

Question 45

Why may test results vary?

Answer 45

Technical failure:

• e.g. clotted sample or variation in reagents

normal variation:

• intra-individual variation e.g. diurnal variation of cortisol levels
• inter-individual variation e.g. platelet count

abnormal results

Question 46

How is a reference range established?

Answer 46

* Define the reference population

• reference population should be relevant to the test population
• consider if separate ranges are required for adults v children, men v women etc.
• determine the expected range of inter individual variation

Question 47

What is meant by a reference range?

Answer 47

The set of values for a given test that incorporates 95% of the normal population

this is determined by collecting data from vast numbers of laboratory tests

95% of results should fall within the reference range

Question 48

What is shown in this image?

Answer 48

The distribution of test results for healthy and diseased subjects

TN - true negative

TP - true positive

FN - false negative

FP - false positive

Question 49

What is meant by sensitivity?

How is it calculated?

Answer 49

The proportion of abnormal results correctly classified by the test

expresses the ability to detect a true abnormality

sensitivity = TP / (TP + FN )

Question 50

What is the definition of specificity?

How is it calculated?

Answer 50

The proportion of normal results correctly classified by the test

expresses the ability to exclude an abnormal result in a healthy person

specificity = TN / (TN + FP )

Question 51

When interpreting full blood count, what is it important to keep in mind?

Answer 51

Be alert to technical problems:

• e.g. thrombocytopenia is sometimes real and sometimes artefact

abnormal results:

• will be flagged by the laboratory but may trigger additional tests e.g. blood film

serious urgent abnormalities:

• laboratory staff will alert the on-call doctors e.g. new leukaemia

Question 52

Why is it important to know clinical details of patients when interpreting a full blood count?

Answer 52

FBC may fall outside the “normal range” but the results may be appropriate for the given clinical situation

e.g. Abnormal lymphocyte count

post-splenectomy mild lymphocytosis or 3 months post bone marrow transplant lymphopenia

Question 53

What are MCV and MCH in microcytic anaemia?

What are examples of microcytic anaemias?

Answer 53

MCV < 80 fl & MCH < 27 pg

• iron deficiency
• thalassaemia
• anaemia of chronic disease (some)
• lead poisoning
• sideroblastic anaemia (some cases)

Question 54

What is meant by microcytic anaemia?

Answer 54

The presence of small, often hypochromic, red blood cells

Question 55

What are the MCV and MCH in normocytic normochromic anaemia?

What are examples of anaemias in this category?

Answer 55

MCV 80-95 fl & MCH >/= 27 pg

• many haemolytic anaemias
• anaemia of chronic disease (some cases)
• after acute blood loss
• renal disease
• mixed deficiencies
• bone marrow failure (e.g. post-chemotherapy, infiltration by carcinoma)

Question 56

What is meant by normocytic normochromic anaemia?

Answer 56

Anaemia in which the average size and haemoglobin content of the red blood cells are within normal limits

under the microscope, the cells resemble normal erythrocytes

Question 57

What is MCV in macrocytic anaemia?

What are the 2 different types?

Answer 57

MCV > 95 fl

megaloblastic:

• vitamin B12 or folate deficiency

non-megaloblastic:

• ​alcohol
• liver disease
• myelodysplasia
• aplastic anaemia

Question 58

What is meant by macrocytic anaemia?

Answer 58

A type of anaemia that causes unusually large red blood cells

the red blood cells have low levels of haemoglobin

Question 59

What type of anaemias is shown here?

Answer 59

Iron deficiency anaemia

small, pale red cells (low MCV and MCH)

variable shape and size with long thin “pencil” cells

Question 60

What feature is visible in anaemia caused by vitamin B12 deficiency?

Answer 60

Hypersegmented neutrophils and oval macrocytes