Krafts' Anemia: Round 2

Question 1

Warm Autoimmune Hemolytic Anemia

Answer 1

Secondary:
Leukemia/lymphoma
Other malignancies
Autoimmune disorders
Infections
Drugs

Pathogenesis:
IgG coats red cells
Macrophages either:
wolf red cells down whole (cells disappear)
nibble at red cells (cells become spherocytes)

Clinical:
Any age, sex
Variable severity
Splenomegaly
Morphology
Spherocytosis

Diagnosis:
DAT (direct antibody test)

Treatment:
Steroids
Splenectomy if necessary

Question 2

Cold Autoimmune Hemolytic Anemia

Answer 2

Things You Must Know:
IgM, complement
Intravascular hemolysis
Agglutination

Pathogenesis of CAHA:
IgM, complement coat red cells
IgM falls off in warm body parts
IgM bridges red cells (agglutination)
Complement lyses red cells

Clinical:
Chronic hemolysis aggravated by cold
Pallor, cyanosis in cold body parts

Morphology:
Red cell agglutinates
Rare spherocytes

Diagnosis:
DAT positive for complement

Treatment:
Keep patient warm
Treat underlying cause

Question 3

Hemoglobinopathies

Answer 3

Things You Must Know:
Qualitative hemoglobin abnormality
Sickle cell is the most important
Sickle cells  hemolysis, vaso-occlusion

Structurally abnormal hemoglobin
Often one amino acid away from normal!
Best lab test: hemoglobin electrophoresis
Most important one: sickle cell anemia

Question 4

biochem of sickle cell

Answer 4

Point mutation in beta chain gene  
leads to...
abnormal beta chains  
(substitution of valine for glutamate)
leads to...
HgbS
  Aggregates and polymerizes on deoxygenation
  Red cell becomes sickle shaped
  Sickles clog up vessels…
  …plus, they are fragile

Question 5

Clinical Findings in Sickle Cell Anemia

Answer 5

Blacks (8% are heterozygous)
Severity of disease is variable
Chronic hemolysis
Vaso-occlusive disease
increased infections (autosplenectomy)

Question 6

Morphology of Sickle Cell Anemia

Answer 6

Sickle cells
“Post-splenectomy blood picture”:
nucleated red blood cells
targets
Howell-Jolly bodies
Pappenheimer bodies
increased platelet count

Question 7

Treatment of Sickle Cell Anemia

Answer 7

Prevent triggers:
infection
fever
dehydration
hypoxemia

Vaccinate against encapsulated bugs:
S. pneumoniae
H. influenzae

Blood transfusions
Bone marrow transplantation

Question 8

Thalassemia

Answer 8

Things You Must Know:
Quantitative defect in hemoglobin
Can’t make enough α or β chains
Variable disease severity
Hypochromic, microcytic anemia with increased RBC and target cells

Question 9

Genes in Thalassemia

Answer 9

Normal globin genes:
4 alpha-chain genes
2 beta-chain genes

Globin genes in thalassemia:
alpha-thal: deletion of alpha-chain gene(s)
beta-thal: defective beta-chain gene(s)

Globin chains in thalassemia
alpha-thal: decreased amount alpha chains
beta-thal: decreased amount beta chains

Problem: defective transcription, translation, 
or processing of mRNA of -chain gene
Severity of defect:
beta gene: normal gene
beta+ gene: produces some  chains
beta0 gene: produces no  chains

Question 10

What causes the anemia in thalassemia?

Answer 10

alpha-thalassemia
Not enough alpha chains
Excess unpaired beta, gamma, or delta chains
Newborns: gama4 tetramers (Hb Barts)
Adults: B4 tetramers (HbH)

B-thalassemia
Not enough B chains
Excess unpaired a chains

Question 11

Morphology of Thalassemia

Answer 11

Hypochromic, microcytic anemia
Depending on severity:
minimal anisocytosis and poikilocytosis
marked anisocytosis and poikilocytosis
Target cells
Basophilic stippling

Question 12

Clinical Findings in a-Thalassemia

Answer 12

Asians, blacks
Carrier state and thal trait: asymptomatic
HbH disease: moderate to severe disease
Hydrops fetalis: fatal in utero

Question 13

Clinical Findings in B-Thalassemia

Answer 13

Mediterraneans, Blacks, Asians
Thal minor: usually asymptomatic
Thal major: variable severity, usually presents in infancy

Question 14

Glucose-6-Phosphate Dehydrogenase Deficiency

Answer 14

Things You Must Know
decrease G6PD  →  increase peroxides →  cell lysis
Oxidant exposure
Bite cells (removal of Heinz bodies)
Self-limiting

The highest incidence of G6PD is in areas where malaria is endemic

Question 15

Why Do G6PD-Deficient Red Cells Die?

Answer 15

They can’t reduce nasties
Nasties attack hemoglobin bonds
Heme breaks away from globin
Globin denatures, sticks to red cell membrane (“Heinz body”)
Spleen bites out Heinz bodies

Question 16

Clinical Findings in G6PD Deficiency

Answer 16

Some patients asymptomatic
Others have episodic hemolysis
Triggers: broad beans (favism), drugs (antibiotics, aspirin)
Spontaneous resolution

Question 17

Morphology of G6PD Deficiency

Answer 17

Without exposure, no anemia
After exposure, get acute hemolysis:
Bite cells, fragments
Heinz bodies

Question 18

Microangiopathic Hemolytic Anemia

Answer 18

Things You Must Know:
Physical trauma to red cells
Schistocytes (small and pointy cells)
Find out why!

Question 19

Causes of MAHA

Answer 19

Artificial heart valve
Anything causing DIC, TTP, or HUS (Disseminated intravascular coagulation, thrombotic thrombocytopenic purpura, or hemolytic-uremic syndrome)

cell gets snagged on fibrin, breaks into a helmet cell (larger) and a microcyte or fragmented cell (triangulocyte, which confirms diagnoses).

Question 20

Anemia of Blood Loss

Answer 20

Things you must know:
Cause: traumatic, acute blood loss
At first, hemoglobin is normal!
After 2-3 days, see reticulocytes
Chronic blood loss is different             (it causes iron deficiency anemia).

Question 21

Anemia of Chronic Disease

Answer 21

Things You Must Know:
Infections, inflammation, malignancy
Iron metabolism disturbed
Normochromic, normocytic anemia
Anemia usually mild

malignant, inflammatory, and infectious conditions can all cause this

Pathogenesis of ACD:
Disturbed iron metabolism 
absorption is okay
…but release is screwed up
can’t get iron into hemoglobin
hepcidin over-produced
Shortened RBC survival
Impaired marrow response to anemia

Question 22

Labs in ACD vs. IDA

Answer 22

ACD
decreased serum iron
decreased/nl  TIBC (= transferrin)
increased ferritin
increased marrow storage iron

IDA
decreased serum iron
increased TIBC (= transferrin)
decreased ferritin 
decreased marrow storage iron

Question 23

Anemia of Renal Disease

Answer 23

Things You Must Know:
End-stage renal failure
Cause: lack of erythropoietin
May see echinocytes

Clinical Features:
End-stage renal failure
Anemia severity roughly correlates
with degree of renal failure

Management:
If mild, need not treat.
If severe, replace erythropoietin.

Question 24

Anemia of Liver Disease

Answer 24

Things You Must Know:
Anemia is frequent in liver disease
Multiple causes
“Uncomplicated” cases are rare
May see acanthocytes, targets

Causes of Anemia of Liver Disease:
“Uncomplicated” anemia of liver disease:
decreased RBC survival and impaired marrow response

Other factors can complicate the picture:
Folate deficiency
Iron deficiency from frequent hemorrhages

“Uncomplicated” cases:
Mild anemia
Usually normocytic; sometimes macrocytic
Poikilocytosis (targets, acanthocytes)

“Complicated” cases:
Megaloblastosis (from folate deficiency)
Microcytosis (from iron deficiency)

Clinical Findings in Anemia of Liver Disease:
3/4 of patients with liver disease are anemic!
Most cases are “complicated”
Alcohol abusers may get hemolytic episodes (which resolve with withdrawal of alcohol)

Question 25

Aplastic Anemia

Answer 25

Things You Must Know:
Pancytopenia
Empty marrow
Most are idiopathic

Causes of Aplastic Anemia:
Idiopathic
Drugs
Viruses
Pregnancy
Fanconi anemia

Clinical Findings in Aplastic Anemia:
Pallor, dizziness, fatigue (anemia)
Recurrent infection (leukopenia)
Bleeding, bruising (thrombocytopenia)

Morphology of Aplastic Anemia:
Blood: empty
Bone marrow: empty

Treatment of Aplastic Anemia:
Avoid further exposure
Give blood products
Drugs: G-CSF, prednisone, ATG
Bone marrow transplant as last resort
3-year survival: 70%