Session 3: Haemopoeisis, Spleen and Bone Marrow

Question 1

Where does haemopoiesis take place?

Answer 1

The sole site of haemopoiesis is in the bone marrow.

Question 2

Where does haemopoiesis take place in infants and children?

Answer 2

In bone marrow throughout the body.

Question 3

Where does haemopoiesis take place in adults predominantly?

Answer 3

In the pelvis, sternum, skill, ribs and vertebrae.

Question 4

A blood cells derive from a single common precursor. Which?

Answer 4

The multipotential haematopoietic stem cell also called a haemocytoblast.

Question 5

Explain the lineage of thrombocytes (platelets).

Answer 5

HSC differentiates into a common myeloid progenitor. This progenitor in its turn is turned into a megakaryocyte which then forms platelets.

Question 6

Which growth factor is thrombopoiesis dependent on?

Answer 6

Thrombopoietin

Question 7

Which are the granulocytes?

Answer 7

Basophils, neutrophils and eosinophils.

Question 8

Explain the lineage of granulopoiesis.

Answer 8

HSC -> common myeloid progenitor -> Myeloblast.

Question 9

Which growth factor is granulopoiesis dependent on?

Answer 9

G-CSF.

Question 10

What are neutrophils mainly involved in?

Answer 10

Migration to areas of inflammation by chemotaxis to phagocytose invading microbes and destroy them by respiratory burst.

Question 11

What are eosinophils mainly involved in?

Answer 11

Phagocytosis of multicellular parasites such as helminths in response to the immune system.

Question 12

What is inappropriate activation of eosinophils associated with?

Answer 12

Asthma and allergy.

Question 13

What are basophils mainly involved in?

Answer 13

Plays a role in parasitic infections and allergy.

Question 14

What are monocytes?

Answer 14

Monocytes circulate in the blood for 1-3 days before moving into tissues where they differentiate into macrophages or dendritic cells. Monocytes in the blood can also perform phagocytosis after recognising antibodies or complement that coats pathogens. Also by binding directly via pattern-recognition receptors that recognise pathogens.

Question 15

Explain monocytopoiesis.

Answer 15

HSC -> CMP -> Myeloblast -> Monocyte

Question 16

Where can B and T lymphocytes be found?

Answer 16

They can be found in blood but most commonly they are found in the lymphatic system.

Question 17

Where does development of B lymphocytes occur?

Answer 17

In the fetal liver and bone marrow.

Question 18

Where does development of T lymphocytes occur?

Answer 18

In the fetal liver and later on moves on to the thymus early in gestation.

Question 19

How does maturation of B lymphocytes occur?

Answer 19

It requires exposure to antigen in the lymph nodes. They can now recognise non-self antigens and produce large quantities of antibodies.

Question 20

How do T lymphocytes differ to B lymphocytes?

Answer 20

T lymphocytes recognise a wide range of antigens that are presented to them by antigen-presenting cells. Meaning T lymphocytes needs the antigens presented to them. B lymphocytes do not.

Question 21

Explain the lymphocyte lineage.

Answer 21

HSC -> Common lymphoid progenitor -> small lymphocyte -> and then either to B lymphocytes or T lymphocytes. Growth factors include Its and TNFs.

Question 22

Explain erythropoiesis.

Answer 22

HSC -> CMP -> Erythrocyte by growth factor erythropoietin.

Question 23

Where does erythropoiesis take place?

Answer 23

In the bone marrow.

Question 24

What is the life span of a red blood cell?

Answer 24

Around 120 days.

Question 25

What is erythropoietin released by?

Answer 25

The kidneys.

Question 26

What is erythropoietin production increased by?

Answer 26

As a response to a decreased oxygen level in the blood (hypoxia).

Question 27

What is erythropoietin’s main function?

Answer 27

To inhibit apoptosis of progenitor cells of RBCs. Activation of erythropoietin cells on these progenitors allows them to develop, differentiate and proliferate. During this process RBCs extrude their nucleus and most of their organelles.

Question 28

What is an immature red blood cell called?

Answer 28

Reticulocyte.

Question 29

How long does it take for a reticulocyte to become a red blood cell?

Answer 29

Around 1-2 days.

Question 30

Why is a reticulocyte count good to do?

Answer 30

IT provides a good diagnostic estimate o the amount of erythropoiesis occurring in a patient’s blood marrow.

Question 31

Why are red blood cells susceptible to damage in G6PD deficiency?

Answer 31

Because they lack nuclei they are unable to replace damaged proteins by re-synthesis. This means that the increased oxidative damage that occurs due to G6PD deficiency and NADPH deficiency red blood cells are more prone to damage.

Question 32

Why are red blood cells susceptible to damage in pyruvate kinase deficiency?

Answer 32

Because the lack of mitochondria means that red blood cells rely on glycolysis for their energy production.

Question 33

Explain the structure of red blood cells.

Answer 33

Anucleated biconcave discs.

Question 34

Explain the structure of the cell membrane of an erythrocyte.

Answer 34

The lipid bilayer contains proteins such as spectrin, ankyrin, band 3 and protein 4.2. These proteins contribute to the cytoskeleton and structure of the RBCs.

Question 35

What happens if there would be a mutation of the genes expressing those membrane associated proteins?

Answer 35

It can result in hereditary spherocytosis or hereditary elliptocytosis.

Question 36

What is the structure of the adult haemoglobin?

Answer 36

Two alpha sub units and two beta subunits.

Question 37

What decreases the affinity of haemoglobin to oxygen?

Answer 37

An increase in BPG, CO2, temperature or a decrease in pH.

Question 38

What are some sources of haemopoietic stem cells?

Answer 38

Aspiration of bone marrow (not very common)
GCSF mobilised stem cells in the peripheral blood.
Umbilical cord stem cells acquired at time of a normal delivery.

Question 39

Where can the spleen be found?

Answer 39

The left upper quadrant of the abdomen.

Question 40

What does the spleen consist of?

Answer 40

Red pulp and white pulp.

Question 41

Explain how blood enters the spleen and where it goes.

Answer 41

It enters via the splenic artery.
White cells and plasma pass through the white pulp.
Red blood cells pass through the red pulp.

Question 42

What is the function and structure of the red pulp?

Answer 42

To remove old red cells and metabolise haemoglobin.

Sinuses lined by endothelial macrophages and cords.

Question 43

What is the function and structure of the white pulp?

Answer 43

Synthesis of antibodies and remove antibody-coated bacteria and blood cells.
Similar structure to lymphoid follicles.

Question 44

What are the general functions of the spleen?

Answer 44

Removal of red cells by macrophages.
Synthesis of antibodies and removal of antibody coated bacteria.
Immunological function where 25% of T-cells and 15% of B-cells are found in the spleen.
Blood pooling.
Extramedullary haemopoiesis.

Question 45

What is blood pooling?

Answer 45

Platelets and red blood cells can be rapidly mobilised during bleeding.

Question 46

What is extra medullary haemopoiesis?

Answer 46

Pluripotential stem cells proliferate during haematological stress or if the marrow fails.

Question 47

Why is it important to counsel people who have had their spleens removed?

Answer 47

Because of the increased risk of sepsis.

Question 48

What is splenomegaly?

Answer 48

An enlarged spleen.

Question 49

Give some causes of splenomegaly.

Answer 49

Increased workload such as:
Haemolytic anaemia where an increased number of defective red cells are removed.
Portal hypertension
Infiltration by leukaemias and lymphomas.
Accumulation of waste products of metabolism.
Overworking either red or white pulp.
Gaucher’s disease or sarcoidosis.
Infectious disease such as malaria, HIV and glandual fever by Epstein Barr Virus.

Question 50

What is hyposplenism?

Answer 50

A term used to describe reduced splenic function.

Question 51

What are patients with hyposplenism at an increased risk of?

Answer 51

Sepsis.

Question 52

What are some causes of hyposplenism?

Answer 52

Disease which destroy spleen tissue such as sickle-cell disease and coeliac disease as well as splenectomy.

Question 53

What are Howell-Jolly bodies?

Answer 53

Basophilic nuclear remnants (clusters of DNA) in circulating erythrocytes.

Question 54

How do Howell-Jolly bodies come about?

Answer 54

During erythropoiesis RBCs normally expels their nuclei but in some cases a small portion of DNA remains inside.

Question 55

A blood film from a patient can reveal Howell-Jolly bodies. Why would you take a blood film to see if there are Howell-Jolly bodies present?

Answer 55

Usually the RBCs with Howell-Jolly bodies are removed by the spleen in a healthy person. However the presence of Howell-Jolly bodies is a good indicator of hyposplenism and hence reduced splenic function.

Question 56

What is the reticuloendothelial system?

Answer 56

A network of cells located throughout the body that is part of the larger immune system.
The role is to remove dead or damaged cells and to identify and destroy foreign antigens in blood and tissues.

Question 57

What cells can be found in the reticuloendothelial system?

Answer 57

Phagocytic cells, include monocytes and different types of macrophages.

Question 58

What macrophage types can be found in the following:

1. Liver
2. Connective tissue
3. CNS
4. Peritoneal cavity
5. Spleen
6. Skin and mucosa

Answer 58

1. Kupffer cells
2. Tissue histiocytes
3. Microglia
4. Peritoneal macrophages
5. Red pulp macrophages
6. Langerhans cells

Question 59

Explain the breakdown of haemoglobin.

Answer 59

Recycled by the spleen and broken down into haem portion and globin portion.

Question 60

What is the fate of the globin portion?

Answer 60

It is broken down into its constitutive amino acids.

Question 61

What is the fate of the haem portion?

Answer 61

Metabolised to bilirubin which is the removed in the liver where it is conjugated and secreted in bile.

Question 62

What happens to bilirubin in the colon?

Answer 62

Bacteria deconjugate and metabolise bilirubin into colourless urobilinogen. This is the oxidised into urobilin and stercobilin.

Question 63

What are causes of massive splenomegaly?

Answer 63

Chronic myeloid leukaemia
Myelofibrosis
Malaria
Schistosomiasis

Question 64

What are causes of moderate splenomegaly?

Answer 64

Same as massive but also:
Lymphoma
Leukaemias
Myeloproliferative disordes
Liver cirrhosis
Portal hypertension
Infections such as glandular fever by Epstein Barr virus

Question 65

What are causes of mild splenomegaly?

Answer 65

Same as massive and moderate as well as:
Hepatitis
Endocarditis
Infiltrative disorder such as sarcoidosis

Question 66

Explain how the body responds to becoming anaemic.

Answer 66

A reduced pO2 is detected in the interstitial peritubular cells in the kidney.
This increases the production of erythropoietin by the kidneys.
Erythropoietin stimulates maturation and released of RBCs from the bone marrow.
The number of red cells increase and so does haemoglobin.
More oxygen can be delivered.

Question 67

Define cytopenia.

Answer 67

A reduction in the number of blood cells.

Question 68

Give examples of types of cytopenias.

Answer 68

Anaemia
Leucopenia
Neutropenia
Thrombocytopenia
Pancytopenia (reduction in all three lines)

Question 69

Define cytosis or cytophilia.

Answer 69

An increase in the number of blood cells.

Question 70

Give expamples of cytosis/cytophilia.

Answer 70

Erythrocytosis
Leucocytosis
Neutrophilia
Lymphocytosis
Thrombocytosis

Question 71

What are the most common causes of an increase in neutrophils?

Answer 71

Infections
Acute inflammation
Tissue damage.

Question 72

Give some causes of neutropenia.

Answer 72

B12/folate deficiency.
Hyposplenism
Aplastic anaemia
Radiation
Drugs
Viral infection
Congenital disorders