Haematology

Question 1

where are red blood cells made in the adults

Answer 1

bone marrow (vertebrae, ribs, sternum, skull, sacrum, pelvis and ends of the femurs)

Question 1

where are red blood cells made in a 0-2 month old foetus

Answer 1

yolk sac

Question 2

where are red blood cells made in a 2-7 month old foetus

Answer 2

liver, spleen

Question 3

where are red blood cells made in a 5-9 old foetus

Answer 3

bone marrow

Question 4

where are red blood cells made in infants

Answer 4

bone marrow (all bones)

Question 5

what do pluripotent stem cells differentiate into

Answer 5

myeloid stem cells and lymphoid stem cells

Question 6

where are haemopoietic stem cells found

Answer 6

• in the bone marrow
• in the peripheral blood after treatment with G-CSF
• umbilical cord blood

Question 7

what are the three fate decisions made by a HSC

Answer 7

• self renewal (creating an identical copy)
• apoptosis
• differentiation (maturation and specialisation)

Question 8

what are the three types of control for stem cell fate in terms of division

Answer 8

1. symmetrical division = contraction of stem cell numbers (reducing them)
2. asymmetrical division = maintenance of stem cell numbers
3. symmetrical division = expansion of stem cell numbers

Question 9

stroma

Answer 9

the bone marrow microenvironment that supports the developing haemopoietic cell

• this is a rich environment for growth and development of stem cells
• stroll cells supported by an extracellular matrix

Question 10

what are some of the supporting cells of the stroma and their supporting proteins

Answer 10

cells:
- macrophages
- fibroblasts
- endothelial cells
- fat cells
- reticulum cells

proteins:
- fibronectin
- haemonectin
- collagen
- proteoglycans
- laminin

Question 11

what is a trephine

Answer 11

the instrument used to perform a bone marrow biopsy

Question 12

what are the principles of leukaemogenesis

Answer 12

Question 13

when are haematological malignancies and pre-malignant conditions termed “clonal”

Answer 13

fi they arise from a single ancestral cell

Question 14

what are myeloproliferative disorders

Answer 14

these are clonal disorders of haemopoiesis leading to increased numbers of one or more mature blood progeny

Question 15

Myelodysplasic syndromes (MDS)

Answer 15

these are characterised by dysplasia and ineffective haemopoiesis in more than one of the myeloid series (RED cells PLATELETS and WHITE cells)

often secondary to previous chemotherapy or radiotherapy

Question 16

autologous transplant

Answer 16

known as an autograft and uses the patients own blood stem cells

Question 17

what is an allograft

Answer 17

an allogeneric transplant which the stem cells come from a donor

Question 18

synergic transplant

Answer 18

a transplant between identical twins

Question 19

allogenic transplant

Answer 19

HLA identical so between brother and sister or two sisters and two brothers

Question 20

haplotype identical

Answer 20

a half matched family member which is usually a parent or a half matched sibling

Question 21

volunteer unrelated (VUD)

Answer 21

also known as matched unrelated (MUD)

Question 22

what are the indications for an autologous stem cell transplant

Answer 22

• relapsed Hodgkins disease
• non-hodgkins lymphoma
• myeloma

Question 23

what are the advantages of umbilical blood transplants

Answer 23

more rapidly available that VUD
less rigorous matching to patient type as the patient immune system is more naive

Question 24

disadvantages of umbilical cord transplant

Answer 24

small amount - adults will often require a double cord transplant

slower engraftment
if relapse they cannot go back for DLI

Question 25

indications ofr an allogenic transplant

Answer 25

acute and chronic leukemias
relapsed lymphoma
aplastic anaemia
hereditary disorders

Question 26

what are the issues with stem cell transplants

Answer 26

limited donor availability
mortality of around 10-50% depending on risk factors
immunosuppression
infertility in both sexes
risk of cataract formation
hypothyroidism with dry eyes and mouth
risk of 2nd malignancy
risk of osteoporosis/avascular necrosis
replapse

Question 27

what are the four things needed for normal red cell production

Answer 27

drive - kidneys
recipe - genes
ingredients - iron, b12, folic acid and other minerals
functioning bone marrow - no increased loss or destruction of red cells

Question 28

what is the main role of RBC

Answer 28

CO2 removal and O2 delivery from lungs to tissues

Question 29

what is the role of transferrin (Tf)

Answer 29

it is a glycoprotein synthesised in hepatocytes which delivers iron to all tissues including erythroblasts, hepatocytes and muscle

Question 30

what is the enzyme responsible for converting iron into haem

Answer 30

ALA-s2

EXCESS iron is stored as ferritin

Question 31

how do macrophages get iron

Answer 31

they swallow dying blood cells and break down the gglbin into amino acids and release them into the amino acid pool, the haem is broken down into bilirubin which is unconjugated so it makes its way to the liver to become conjugated

haem is also broken down into iron and this can be stored inside the macrophage as ferritin (the soluble form of iron)

Question 32

hepcidin

Answer 32

this is the low iron hormone and it acts to reduce the levels of iron in the plasma (this is what is lost in HC)

• it acts by binding derroportin and degrades it - reducing iron absorption (enterocyte) and decreasing iron release from the RES
• Hepcidin is synthesised in the liver

Question 33

Hypochromic microcytic RBC conditions

Answer 33

IDA = not enough haem
Thalassaemia = not enough globin

Question 34

what are the causes of IDA

Answer 34

• dietary (premature neonates and adolescent females)
• malabsorption
• blood loss

Question 35

when is IV iron indicated

Answer 35

• intolerant of oral iron
• complicance
• renal aneamia and Epo replacement

Question 36

causes of anaemia of chronic disease

Answer 36

infection
inflammation
neoplasia

RES iron blockage where the iron is trapped in macrophages and results in a raised level of hepcidin

reduced repo response

depressed marrow activity or cytokine marrow depression

Question 37

what is the definition of haemolytic anaemia

Answer 37

• anaemia related to reduced RBC lifespan
• no blood loss
• no haematinic deficiency

Question 38

what happens due to the lifespan of RBC reducing

Answer 38

can begin to raise reticulocytes as it drops and increases bilirubin due to increased breakdown

then when this hits below 20 days then Hb drop
reticulocytes increase
bilirubin increases
splenic activity increases

Question 39

haemolytic example of an RBC enzyme related anaemia

Answer 39

pyruvate kinase deficiency anaemia
1. chronic/extravascular anaemia
2. ATP depletion
3. autosomal recessive

glucose 6 phosphate dehydrogenase deficiency
- acute episodic intravascular haemolytic
- x-linked recessive
- acute haemolytic from oxidative stress
1. favism
2. drugs such as antimalarials, sulphonamides and others

Question 40

what are the three types of acquired haemolytic anaemia

Answer 40

autoimmune = warm (IgG) and cold type (IgM)
isoimmune = haemolytic disease of newborn (HDN)
non-immune = fragmentation haemolytic

Question 41

polycythaemia

Answer 41

too much red cell production

Question 42

B12/flate functions

Answer 42

• essential for DNA synthesis and nuclear maturation
• required for all dividing cells
• results in megaloblastic anaemia intially but will effect other organs

Question 43

how is b12 absorbed

Answer 43

b12 is ingested
gastric parietal cells produce intrinsic factor
b12 released by enzymes/acid in stomach and duodenum
intrinsic factor binds to b12
IF-B12 complex binds to cubulin which is a specific receptor in the ileum and B12 is absorbed into the blood and is then bound to transcobalamin

Question 44

what are the main tissues effects by b12 or folate deficiency

Answer 44

bone marrow
epithelial surfaces such as the mouth, stomach, small intestine, urinary and female genital tracts

Question 45

clinical b12 deficiency neurological manifestations

Answer 45

bilateral neuropathy or demyelination fo the posterior or pyramidal tracts of spinal cord

biochemical basis unclear - likely related to problem with homocysteine to methionine

Question 46

increased cell turnover causes of folate deficiency

Answer 46

haemolytic
severe skin disorders
pregnancy

Question 47

alpha gene permutations

Answer 47

Question 48

thalassaemia clinical significance of alpha

Answer 48

1 missing = mild microcytosis
2 missing = microcytosis with increased red cell count and sometimes very mild often asymptotic anaemia
3 missing = significant anaemia and bizarre shaped small red cells - HbH disease
4 missing = incompatible with life as you need alpha chains for metal haemoglobin

Question 49

HbH

Answer 49

• lack go alpha chains means there is an excess of beta chains
• these end up joining together
• blood transfusion required during periods of stress

Question 50

what is the clinical result of sickle cell disease

Answer 50

• reduced red cell survival (anaemia) = haemolytic which can also cause chronic endothelial dysfunction
• vaso-occlusion
  tissue hypoxia/infarction
• pain and tissue damage

Question 51

moya moya

Answer 51

when new collateral vessels are made in the circle of willis - 10% of children with sickle cell also have a stroke