week 3 part 1

Question 1

Haemopoiesis

Answer 1

the production of blood cells and platelets, which occurs in the bone marrow.

Question 2

Erythropoiesis

Answer 2

Produces red blood cells (erythrocytes),

Question 3

Lymphopoiesis

Answer 3

Refers to the production of new lymphocytes, including B lymphocytes, T lymphocytes, and natural killer (NK) cells.

Question 4

Neutrophils lifespan

Answer 4

7-8 hrs

Question 5

Platelets lifespan

Answer 5

7-10 days

Question 6

What do “blasts” mean at the end of cells - e.g. erythrobasts?

Answer 6

Nucleated precursor cell

Question 7

Megakaryocytes

Answer 7

platelet precursor, polyploid

Question 8

Reticulocytes

Answer 8

Immediate red cell precursor

Question 9

Myelocytes

Answer 9

nucleated precursor between neutrophils and blasts

Question 10

Where do these precursor cells come from?

Answer 10

Progenitors, and ultimately all haemopoietic cells come from haemopoietic stem cells (HSC)

Question 11

What are the sites of haemopoiesis?

Answer 11

Embryonically, haemopoietic stem cells originate in the mesoderm

Circulating committed progenitors detectable as early as week 5

Yolk sac, the first site of erythroid activity, stops by week 10

Liver starts by week 6

Bone marrow by week 16

In adults, haemopoiesis is restricted to the marrow within axial skeleton, pelvis and proximal long bones

Question 12

Venous sinuses

Answer 12

Arterioles drain into ‘sinuses’ – wide venous vessels, which open into larger central sinuses

In contrast to capillaries, ‘sinuses’ are larger and have a discontinuous basement membrane

Question 13

Release of mature cells from marrow

Answer 13

Formed blood cells can pass through fenestrations in endothelial cells to enter circulation

Release of red cells is associated with sinusoidal dilatation and increased blood flow

Neutrophils actively migrate towards the sinusoid

Question 14

Myeloid:erythroid ratio

Answer 14

Myeloid:erythroid ratio: relationship of neutrophils and precursors to proportion of nucleated red cell precursors (ranges from 1.5:1 to 3.3:1) – can change (eg reversal in haemolysis as a compensatory response)

Question 15

How do we assess haemopoiesis?

non-lymphoid mature cells

Answer 15

1. Routinely undertaken- blood count, cell indices (by non-specialists), morphology (blood film-specialist)
2. Less common (specialist)-bone marrow
   examination

Question 16

Immunophenotyping

Answer 16

Identify patterns of protein (antigen) expression unique to a cell lineage

Use antibodies (in combination) specific to different antigens

Question 17

What regulates haemopoiesis?

Answer 17

Intrinsic properties of cells (e.g stem cells vs progenitor cells vs mature cells)

Signals from immediate surroundings and the periphery (microenvironmental factors)

Specific anatomical area (‘niche’) for optimal developmental signals

Question 18

What happens in Malignant Haemopoiesis?

Answer 18

Malignant haemopoiesis is usually characterised by increased numbers of abnormal & dysfunctional cells & loss of normal activity

Question 19

What causes haematological malignancies?

Answer 19

Genetic, epigenetic, environmental interaction

ACQUIRED somatic mutations in regulatory genes [driver mutations vs passenger mutations (‘noise’)]

Recurrent cytogenetic abnormalities (eg deletions, chromosomal translocations etc): NOT causal in most, but contributory

Question 20

What are clones?

Answer 20

Clone: population of cells derived from a single parent cell

This parent cell has a genetic marker (driver mutation or chromosomal change) that is shared by the daughter cells

Clones can diversify but contain a similar genetic ‘backbone’

Normal haemopoiesis is polyclonal; malignant haemopoiesis is usually monoclonal

Question 21

Driver’ mutations

Answer 21

Confer growth advantage on the cells and are selected during the evolution of the cancer
A term used to describe changes in the DNA sequence of genes that cause cells to become cancer cells and grow and spread in the body.

Question 22

Passenger mutations

Answer 22

Do not confer growth advantage, but happened to be present in an ancestor of the cancer cell when it acquired one of its drivers

Passenger mutations are defined as those which do not alter fitness but occurred in a cell that coincidentally or subsequently acquired a driver mutation, and are therefore found in every cell with that driver mutation.

Question 23

Types of haematological malignancies based on:

Answer 23

1. Lineage: Myeloid, Lymphoid
2. Developmental stage
3. Blood involvement: leukaemia
4. Lymph node involvement with lymphoid malignancy: lymphoma
5. Myeloma: plasma cell malignancy in marrow

Question 24

Features of clinical aggression

Answer 24

rapid progression of symptoms

Question 25

Features of histological aggression

Answer 25

Large cells with high nuclear-cytoplasmic ratio, prominent nucleoli, rapid proliferation

Question 26

Difference between histology and presentation of acute leukaemias/high-grade lymphomas and chronic leukaemias/low-grade lymphomas

Answer 26

acute leukaemias & high-grade lymphomas are histologically and usually clinically more aggressive than chronic leukaemias & low-grade lymphomas

Question 27

Leukaemia

Answer 27

Leukaemia is the name for cancer of a particular line of the stem cells in the bone marrow. This causes unregulated production of certain types of blood cells. Types of leukaemia can be classified depending on how rapidly they progress (chronic is slow and acute is fast) and the cell line that is affected (myeloid or lymphoid).

Question 28

Leukaemia types

Answer 28

• Acute lymphoblastic leukaemia (ALL) is the most common in children
• Acute myeloid leukaemia (AML) is the next most common
• Chronic myeloid leukaemia (CML) is rare

Question 29

Ages of onset of the leukaemias

Answer 29

ALL peaks aged 2 – 3 years

AML peaks aged under 2 years

Question 30

Leukemia pathophysiology

Answer 30

Leukaemia is a form of cancer of the cells in the bone marrow. A genetic mutation in one of the precursor cells in the bone marrow leads to excessive production of a single type of abnormal white blood cell.

The excessive production of a single type of cell can lead to suppression of the other cell lines, causing underproduction of other cell types. This results in a pancytopenia, which is a combination of low:
Red blood cells (anaemia),
White blood cells (leukopenia)
Platelets (thrombocytopenia)

Question 31

Blood features of leukaemia

Answer 31

The excessive production of a single type of cell can lead to suppression of the other cell lines, causing underproduction of other cell types. This results in a pancytopenia, which is a combination of low:
Red blood cells (anaemia),
White blood cells (leukopenia)
Platelets (thrombocytopenia)

Question 32

Risk factors for Leukemia

Answer 32

Down’s syndrome
Kleinfelter syndrome
Noonan syndrome
Fanconi’s anaemia

Question 33

Features of Leukemia

Answer 33

Persistent fatigue
Unexplained fever
Failure to thrive
Weight loss
Night sweats
Pallor (anaemia)
Petechiae and abnormal bruising (thrombocytopenia)
Unexplained bleeding (thrombocytopenia)
Abdominal pain
Generalised lymphadenopathy
Unexplained or persistent bone or joint pain
Hepatosplenomegaly

Question 34

Diagnosis of Leukemia

Answer 34

Full blood count, which can show anaemia, leukopenia, thrombocytopenia and high numbers of the abnormal WBCs
Blood film, which can show blast cells
Bone marrow biopsy
Lymph node biopsy

Further tests may be required for staging:
Chest xray
CT scan
Lumbar puncture
Genetic analysis and immunophenotyping of the abnormal cells

Question 35

Management of Leukemia

Answer 35

Treatment of leukaemia will be coordinated by a paediatric oncology multi-disciplinary team. Leukaemia is primarily treated with chemotherapy.

Other therapies:
Radiotherapy
Bone marrow transplant
Surgery

Question 36

Complications of Chemotherapy

Answer 36

Failure to treat the leukaemia
Stunted growth and development
Immunodeficiency and infections
Neurotoxicity
Infertility
Secondary malignancy
Cardiotoxicity

Question 37

Prognosis of Leukemia

Answer 37

The overall cure rate for ALL is around 80%, but prognosis depends on individual factors. The outcomes are less positive for AML.

Question 38

Infective causes of lymphadenopathy

Answer 38

infectious mononucleosis
HIV, including seroconversion illness
eczema with secondary infection
rubella
toxoplasmosis
CMV
tuberculosis
roseola infantum

Question 39

Neoplastic causes of lymphadenopathy

Answer 39

leukaemia

lymphoma

Question 40

Lymphadenopathy

Answer 40

Lymphadenopathy refers to the enlargement of one or more lymph nodes, the bean-shaped glands found in the neck, armpits, chest, groin, and abdomen

Question 41

Symptoms of Lymphadenopathy

Answer 41

A ‘lump’: lymphadenopathy

General Symptoms (‘B symptoms’)
Fever or
night sweats or
weight loss – (10% over a 6-month period)

Itch without rash, alcohol-induced pain

Symptoms relevant to known/suspected systemic illness (INDAM)

Question 42

What do tender lymph nodes suggest?

Answer 42

Caused by bacteria/virus rather than neoplasia

Question 43

What do non-tender lymphadenopathy siggest?

Answer 43

Lymphoma and metastatic cancers

Question 44

What does a rubbery/soft lymphadenopathy suggest?

Answer 44

Lymphoma

Question 45

Lymphomas

Answer 45

Lymphomas are a group of cancers that affect the lymphocytes inside the lymphatic system. These cancerous cells proliferate within the lymph nodes and cause the lymph nodes to become abnormally large (lymphadenopathy).

Question 46

The two types of lymphomas

Answer 46

There are two main categories of lymphoma: Hodgkin’s lymphoma and non-Hodgkin’s lymphoma. Hodgkin’s lymphoma is a specific disease and non-Hodgkins lymphoma encompasses all the other lymphomas.

Question 47

Hodgkin’s lymphoma

Answer 47

Hodgkin’s lymphoma is a malignant proliferation of lymphocytes characterised by the presence of the Reed-Sternberg cell. It has a bimodal age distributions being most common in the third and seventh decades

Question 48

Risk factors for Hodgkin’s lymphoma

Answer 48

HIV
Epstein-Barr Virus
Autoimmune conditions such as rheumatoid arthritis and sarcoidosis
Family history

Question 49

Features of Hodgkin’s lymphoma

Answer 49

Lymphadenopathy is the key presenting symptom. The enlarged lymph node or nodes might be in the neck, axilla (armpit) or inguinal (groin) region. They are characteristically non-tender and feel “rubbery”.
B symptoms are the systemic symptoms of lymphoma: Fever, Weight loss, Night sweats

Other symptoms can include:
Fatigue
Itching
Cough
Shortness of breath
Abdominal pain
Recurrent infections

Question 50

Diagnosis/investigations in Hodgkin’s lymphoma

Answer 50

Lactate dehydrogenase (LDH) is a blood test that is often raised in Hodgkin’s lymphoma but is not specific and can be raised in other cancers and many non-cancerous diseases.

Lymph node biopsy is the key diagnostic test.

The Reed-Sternberg cell is the key finding from lymph node biopsy in patients with Hodgkin’s lymphoma.

CT, MRI and PET scans can be used for diagnosing and staging lymphoma and other tumours.

Question 51

The Reed-Sternberg cell

Answer 51

The Reed-Sternberg cell is the key finding from lymph node biopsy in patients with Hodgkin’s lymphoma. They are abnormally large B cells that have multiple nuclei that have nucleoli inside them. This can give them the appearance of the face of an owl with large eyes. The Reed-Sternberg cell is a popular feature in medical exams.

Question 52

The Ann Arbor staging system

Answer 52

The Ann Arbor staging system is used for both Hodgkins and non-Hodgkins lymphoma. The system puts importance on whether the affected nodes are above or below the diaphragm.

Question 53

The Ann Arbor staging system (what are the stages?)

Answer 53

Stage 1: Confined to one region of lymph nodes.
Stage 2: In more than one region but on the same side of the diaphragm (either above or below).
Stage 3: Affects lymph nodes both above and below the diaphragm.
Stage 4: Widespread involvement including non-lymphatic organs such as the lungs or liver.

Question 54

Management of Hodgkin’s lymphoma

Answer 54

The key treatments are chemotherapy and radiotherapy. The aim of treatment is to cure the condition. This is usually successful however there is a risk of relapse, other haematological cancers and side effects of medications.

Chemotherapy creates a risk of leukaemia and infertility.

Radiotherapy creates a risk of cancer, damage to tissues and hypothyroidism.

Question 55

A common type of Non-Hodgkin’s lymphoma

Answer 55

Diffuse large B cell lymphoma

Question 56

Different types of Non-Hodgkin’s lymphoma

Answer 56

A few notable ones are:

1. Burkitt lymphoma is associated with Epstein-Barr virus, malaria and HIV.
2. MALT lymphoma affects the mucosa-associated lymphoid tissue, usually around the stomach. It is associated with H. pylori infection.
3. Diffuse large B cell lymphoma often presents as a rapidly growing painless mass in patients over 65 years.

Question 57

Risk factors for Non-Hodgkin’s lymphoma

Answer 57

HIV
Epstein-Barr Virus
H. pylori (MALT lymphoma)
Hepatitis B or C infection
Exposure to pesticides and a specific chemical called trichloroethylene used in several industrial processes
Family history

Question 58

Management of Non-Hodgkin’s lymphomas

Answer 58

Watchful waiting
Chemotherapy
Monoclonal antibodies such as rituximab
Radiotherapy
Stem cell transplantation

Question 59

Use of monoclonal antibodies in Non-Hodgkin’s lymphomas

Answer 59

Rituximab (CD20) in B cell NHL

Brentuximab (CD30) in T cell NHL

Question 60

Burkitt tumours

Answer 60

Fastest growing human tumour

Endemic type (EBV link) vs sporadic

HIV association

Disease sites

Chromosomal translocations involving c-myc

High cure rates in high income countries – beware of tumour lysis at the start

Question 61

Microscopy findings of Burkitt’s lymphoma

Answer 61

starry sky’ appearance: lymphocyte sheets interspersed with macrophages containing dead apoptotic tumour cells

Question 62

Nodular sclerosing Hodgkin’s lymphoma

Answer 62

Nodular sclerosing - Most common (around 70%), Good prognosis, More common in women. Associated with lacunar cells

Question 63

Mixed cellularity Hodgkin’s lymphoma

Answer 63

Around 20%
Good prognosis
Associated with a large number of Reed-Sternberg cells

Question 64

Lymphocyte predominant Hodgkin’s lymphoma:

Answer 64

Around 5%

Best prognosis

Question 65

Lymphocyte depleted Hodgkin’s lymphoma:

Answer 65

Rare

Worst prognosis

Question 66

Gastric MALT lymphoma

Answer 66

associated with H. pylori infection in 95% of cases
good prognosis
if low grade then 80% respond to H. pylori eradication
paraproteinaemia may be present

Question 67

Prognosis of non-Hodgkin’s lymphomas

Answer 67

Low-grade non-Hodgkin’s lymphoma has a better prognosis

High-grade non-Hodgkin’s lymphoma has a worse prognosis but a higher cure rate