Myelodysplastic Syndromes and Bone Marrow Failure

Question 1

What are myelodysplastic syndromes (MDS)?

Answer 1

Biologically heterogeneous group of acquired haemopoietic stem cell disorders (~ 4 per 100,000 persons).

Question 2

What is MDS characterised by?

Answer 2

Development of a clone of marrow stem cells with abnormal maturation resulting in functionally defective blood cells + a numerical reduction.

Question 3

What does the development of a clone of marrow cells with abnormal maturation in MDS result in?

Answer 3

Cytopenia(s)

Qualitative (functional) abnormalities of erythroid, myeloid + megakaryocytic maturation

Increased risk of transformation to leukaemia (AML)

Question 4

What is the epidemiology of MDS?

Answer 4

Typically disorder of elderly.

Sx + signs are those of general marrow failure.

Develops over weeks + months.

Question 5

List 5 blood and bone marrow morphological features of MDS?

Answer 5

• Pelger-Huet anomaly (bilobed neutrophils)
• Dysgranulopoieses of neutrophils
• Dyserythropoiesis of red cells
• Dysplastic megakaryocytes e.g. micromegakaryocytes
• Increased proportion of blast cells in marrow (normal < 5%)

Question 6

What is this?

Answer 6

Normal neutrophils

Multilobed with granules in cytoplasm

Question 7

What is this?

Answer 7

Pelger-Heut anomaly

Only 2 lobules, connected by thin bridge of cytoplasm

Question 8

What is this?

Answer 8

Refractory anaemia dysgranulopoiesis

Abnormal lack of granules in neutrophils

Question 9

What is this?

Answer 9

Myelokathexis

Condensed nuclei with thin intrasegmented filaments + vacuoles

Question 10

What is this?

Answer 10

Refractory anaemia-dyserythropoiesis

Question 11

What is this?

Answer 11

Refractory anaemia-dyserythropoiesis

Question 12

What is this?

Answer 12

Ringed sideroblasts

Question 13

What is this?

Answer 13

Myeloblasts with Auer rods

Question 14

What are Auer rods a sign of?

Answer 14

AML

Question 15

Which prognostic variables are included in the Revised International Prognostic Scoring System (IPSS-R) in MDS (2012)?

Answer 15

BM blasts (%)

Karyotype

Hb (g/L)

Platelets (x10^9/L)

Neutrophils (x10^9/L)

Question 16

How is the IPSS-R score interpreted?

Answer 16

The higher the score, the lower the survival + time to progress to AML.

Question 17

Which driver mutations in MDS carry prognostic significance?

Answer 17

TP53, EZH2, ETV6, RUNX1, ASXL1

Others: SF3B1, TET2, DNMT3A

Question 18

In which group of MDS patients are the majority of common mutations found in?

Answer 18

More frequently in high risk MDS than low risk

Question 19

What is the sequelae of disease in MDS?

Answer 19

Deterioration of blood counts: Worsening consequences of marrow failure.

Development of AML:

• Develops in 5-50% < 1y (depends on subtype)
• Some cases of MDS are much slower to evolve
• AML from MDS has an extremely poor prognosis + is usually not curable

Question 20

Why is AML from MDS much harder to treat than those with AML without prior MDS?

Answer 20

Those without prior MDS more likely to have normal stem cells in BM

Question 21

What is the rule of thumb for outcomes of MDS progression?

Answer 21

⅓ die from infection (low neutrophils, can’t fight)

⅓ die from bleeding (low platelets)

⅓ die from acute leukaemia

Question 22

What is the treatment of MDS?

Answer 22

Allogeneic stem cell transplantation (SCT)

Or

Intensive chemotherapy

(Only minority of patients can benefit from these, as most are too old/ frail)

Question 23

What supportive care can be given to those with MDS?

Answer 23

Blood product support: transfusions

Abx for infections

Growth factors to enhance residual BM activity

Question 24

What growth factors can be given to those with MDS? What cell lineage is each given to enhance?

Answer 24

EPO: Hb

G-CSF: Neutrophils

Thrombopoetin (TPO) receptor agonists: Platelets

Question 25

What biological modifiers are used in the treatment of MDS?

Answer 25

Immunosuppressive therapy

Hypomethylating agents: Azacytidine + Decitabine

Lenalidomide

Question 26

Which forms of chemotherapy may be used in MDS?

Answer 26

1. Oral Hydroxyurea
2. Subcutaneous low dose Cytarabine
3. Intensive chemo (for high risk): designed to treat AML

Question 27

Which one of the following about MDS is true?:
A. Myelodysplasia has a bi-modal age distribution

B. The primary modality of treatment of MDS is by intensive chemotherapy

C. ⅓ of MDS patients can be expected to die from leukaemic transformation

D. There is no good correlation between the severity of cytopenias and the overall life expectancy

E. White cell function is frequently well preserved in MDS

Answer 27

C. ⅓ of MDS patients can be expected to die from leukaemictransformation

Question 28

What can the common myeloid progenitor give rise to?

Answer 28

1. RBCs
2. Mast cells
3. Megakaryocytes which give rise to platelets
4. Myeloblasts which give rise to basophils, neutrophils, eosinophils + monocytes

Question 29

What can the common lymphoid progenitor give rise to?

Answer 29

1. Natural killer cells
2. B Lymphocytes
3. T Lymphocytes

Question 30

How does stage of maturation in the bone marrow determine the lineages affected?

Answer 30

Pluripotent haematopoeitic cell: impairs production of ALL peripheral blood cells (Rare)

Committed progenitor cells: Bi- or unicytopenias

Question 31

What are 3 congenital causes of primary bone marrow failure?

Answer 31

Fanconi’s anaemia (multipotent stem cell)

Diamond-Blackfan anaemia (red cell progenitors)

Kostmann’s syndrome (neutrophil progenitors)

These are more commonly seen in kids

Question 32

What is an acquired causes of primary bone marrow failure?

Answer 32

Idiopathic aplastic anaemia (multipotent stem cell)

Most common primary BM failure syndrome (over congenital)

Question 33

Which form of bone marrow failure is more common?

Answer 33

Secondary is more common than primary

Primary are relatively rare

Question 34

What are secondary causes of bone marrow failure?

Answer 34

Marrow infiltration

Haematological (leukaemia, lymphoma, myelofibrosis)

Non-haematological (Solid tumours)

Radiation

Drugs

Chemicals (benzene)

Autoimmune

Infection (Parvovirus, Viral hepatitis)

Question 35

Which drugs can cause bone marrow failure?

Answer 35

PREDICTABLE (dose-dependent, common): Cytotoxic drugs.

IDIOSYNCRATIC (NOT dose-dependent, rare): Phenylbutazone, Gold salts.

Abx: Chloramphenicol, Sulphonamide.

DIURETICS: Thiazides.

ANTITHYROID DRUGS: Carbimazole.

Question 36

What is the epidemiology of aplastic anaemia?

Answer 36

2-5 cases/million/yr (world-wide)

All age groups can be affected

Peak incidence: 15-24y + > 60y

Question 37

Give 2 characteristic test findings in aplastic anaemia

Answer 37

Blood: Cytopenia

BM: Hypocellular

Question 38

How is aplastic anaemia classified?

Answer 38

Severe aplastic anaemia (SAA)

Non-severe aplastic anaemia (NSAA)

Using Camitta criteria based on % reticulocytes, neutrophils + platelets in peripheral blood

+ cellularity of BM

Question 39

Describe the aetiological classification of aplastic anaemia

Answer 39

Idiopathic: 70-80% (majority)

Inherited: Dyskeratosis congenita, Fanconi anaemia, Scwachman-Diamond syndrome

“Secondary”: Radiation, cytotoxics, SLE

Idiosyncratic: Chloramphenicol, NSAIDs, hepatitis viruses

Paroxysmal Nocturnal Haemaglobinuria

Question 40

What is the pathophysiology of idiopathic aplastic anaemia?

Answer 40

Failure of BM to produce blood cells

“Stem cell” problem (CD34, LTC-IC) [Long-Term Culture-Initiating Cells].

Immune attack: Humoral or cellular (T cell) attack against multipotent haematopoietic stem cell.

Question 41

What is the triad of bone marrow failure findings in aplastic anaemia?

Answer 41

Anaemia: Fatigue, breathlessness.

Leucopenia: Infections

Platelets: Easy bruising/ bleeding

Question 42

What is this?

Answer 42

Normal bone marrow

White = fat

Question 43

What is this?

Answer 43

Aplastic bone marrow

Few cells, majority fat

Question 44

List 6 differentials to aplastic anaemia for findings of pancytopenia and hypo cellular marrow

Answer 44

Hypoplastic MDS/ AML

Hypocellular ALL

Hairy cell leukaemia

Mycobacterial (usually atypical) infection

Anorexia Nervosa

Idiopathic Thrombocytopenic Purpura

Question 45

Give 6 approaches to management of aplastic anaemia

Answer 45

1. Seek + remove a cause
2. Supportive
3. Immunosuppressive therapy
4. Drugs to promote marrow recovery
5. Stem cell transplantation
6. Other tx in refractory cases

Question 46

What supportive treatment can be given to those with aplastic anaemia?

Answer 46

Blood/ platelet transfusions (Leucodepleted, CMV -ve, irradiated)

Abx

Iron Chelation Therapy

Question 47

What is the specific treatment for idiopathic aplastic anaemia based on?

Answer 47

Severity of illness

Age of patient

Potential sibling donor

Question 48

What are the specific treatments for aplastic anaemia?

Answer 48

Immunosuppressive therapy – older patient:

• Anti-Lymphocyte Globulin (ALG)
• Ciclosporin
• Eltrombopag

Androgens: oxymethalone

Stem cell transplantation:

• Young with donor (80% cure)
• VUD/MUD for > 40 yrs (50% survival)

Question 49

What are complications associated with aplastic anaemia?

Answer 49

1. Relapse of AA (35% >15y)
2. Clonal haematological disorders
3. Solid tumours ~3% risk

Question 50

Which clonal haematological disorders may arise as a complication following immunotherapy for aplastic anaemia?

Answer 50

Myelodysplasia

Leukaemia ~20% risk over 10y

PNH (paroxysmal nocturnal haemoglobinuria): May be a transient phenomenon.

Question 51

Regarding Aplastic Anaemia – which one answer is true?

A. Immunosuppressive therapy is only used to treat a minority of patients with aplastic anaemia.

B. If treated with immunosuppression, then relapse of Aplastic Anaemia occurs in less than 15% of cases.

C. The cure rate of AA treated by sibling-related allogeneic stem cell transplantation in a patient under 40 years old is > 70%.

D. Severe aplastic anaemia is differentiated from non-severe aplastic anaemia on the basis of the acquired cytogenetic abnormalities in the bone marrow.

E. Leucodepletion of cellular blood products is only exceptionally undertaken for patients with aplastic anaemia.

Answer 51

C. Cure rate of AA treated by sibling-related allogeneic stem cell transplantation in a patient <40y is > 70%.

Question 52

What is Fanconi Anaemia?

Answer 52

Most common form of inherited aplastic anaemia.

Autosomal recessive or X-linked inheritance.

Multiple mutated genes are responsible. When these genes become mutated, results in:

• Abnormalities in DNA repair
• Chromosomal fragility (breakage in the presence of in-vitro mitomycin or diepoxybutane)

Question 53

What are 6 congenital abnormalities associated with Fanconi Anaemia?

Answer 53

• Short Stature
• Hypopigmented spots + café-au-lait spots
• Abnormality of thumbs
• Microcephaly or hydrocephaly
• Hyogonadism
• Developmental delay

No abnormalities 30%

Question 54

List 5 complications that arise in fanconis anaemia with their prevalence

Answer 54

Aplastic anaemia: 90%

Myelodysplasia: 32%

Leukaemia: 10%

Cancer (epithelial): 5%

Liver disease: 4%

Question 55

What is Dyskeratosis Congenita (DC)?

Answer 55

An inherited disorder characterised by:

• Marrow failure
• Cancer predisposition
• Somatic abnormalities

Question 56

What is the classical triad of dyskeratosis congenita?

Answer 56

Skin pigmentation

Nail dystrophy

Leukoplakia (white patches on tongue)

Question 57

List 4 somatic abnormalities/ complications in dyskeratosis congenita

Answer 57

Abnormal skin pigmentation: 89%

Nail dystrophy: 88%

BM failure: 85.5%

Leukoplakia: 78%

Question 58

What is the general approach to management of bone marrow failure e.g. in congenital syndromes?

Answer 58

1. Supportive: Blood/platelet transfusions, Abx +/- Iron Chelation Therapy
2. Drugs to promote marrow recovery: TPO receptor agonists
   (e.g. eltrombopag),
   ?Oxymetholone,
   ?Growth factors
3. Stem cell transplantation
4. Future ? haemopoietic gene therapy

Question 59

What are telomeres?

Answer 59

Found at the end of chr

Act to prevent chr fusion/ rearrangements during chr replication

Protect the genes at the end of the chr from degradation

Question 60

What is the association between telomeres and dyskeratosis congenita?

Answer 60

Telomere length is reduced in marrow failure diseases (especially short in patients with DC)

Question 61

What is maintenance of telomere length required for?

Answer 61

Indefinite proliferation of human cells

Question 62

What is the genetic basis of dyskeratosis congenita?

Answer 62

X-linked recessive trait: most common inherited pattern (mutated DKC1 gene: defective telomerase function).

Autosomal dominant trait: (Mutated TERC gene: encodes the RNA component of telomerase).

Autosomal recessive trait: gene for this form of DC not yet identified.

Question 63

Which one of the following is true?

A. Telomeric shortening is a feature of both idiopathic aplastic anaemia and dyskeratosis congenita.

B. Development of malignancy is an uncommon complication of Fanconi Anaemia.

C. A single genetic defect has been identified as the underlying cause for Fanconi Anaemia.

D. Fanconi Anaemia is usually inherited in an autosomal dominant fashion.

E. Telomeric function is considered to be unimportant in the pathophysiology of Dyskeratosis Congenita.

Answer 63

A. Telomeric shortening is a feature of both idiopathic aplastic anaemia and dyskeratosis congenita.

Question 64

Why is immunosuppression used in aplastic anaemia?

Answer 64

Most cases of AA have immunological// immune mediated attack on stem cells

Immunesuppression dampens AI attack on stem cells

Allow stem cells to recover