Download Normocytic Anemia

Normocytic Anemia
David Lee, MD, FRCPC
Normocytic anemia
• a heterogenous group of anemias
• normocytosis implies normal DNA
metabolism and hemoglobin synthesis
• no common pathophysiology
Approach to anemia
anemia
check MCV
MCV < 80
microcytic
anemia
MCV 80 - 100
normocytic
anemia
MCV > 100
macrocytic
anemia
Approach to normocytic anemia
normocytic anemia
Is there increased red cell production?
check reticulocyte count
increased
Is there
evidence of
hemolysis?
yes
hemolytic
anemia
normal or decreased
Is there evidence of:
- renal failure
- endocrine failure
- chronic inflammation
anemia of renal failure
anemia of endocrine failure
anemia of chronic disease
no
recent
bleed
If not, then consider
a primary marrow problem (MDS, MM, infiltration…)
bone marrow investigation
Approach to normocytic anemia
normocytic anemia
Is there increased red cell production?
check reticulocyte count
increased
Is there
evidence of
hemolysis?
yes
hemolytic
anemia
normal or decreased
Is there evidence of:
- renal failure
- endocrine failure
- chronic inflammation
anemia of renal failure
anemia of endocrine failure
anemia of chronic disease
no
recent
bleed
If not, then consider
a primary marrow problem (MDS, MM, infiltration…)
bone marrow investigation
Anemia of chronic disease
• Anemia due to cytokines IL-1, TNF-a,
TGF-b associated with chronic
inflammation
– rheumatoid arthritis
– systemic lupus erythematosis
– inflammatory bowel disease
– chronic infections: osteomyelitis, TB
Anemia of chronic disease
• Mechanisms
– defective iron utilization
• iron is present, but cannot be utilized by
erythroid precursors
– impaired response to erythropoietin
– ?blunted increase in erythropoietin in
response to anemia
Anemia of chronic disease
• usually normocytic, but 25% are
microcytic
• usually mild to moderate anemia
• anemia of chronic disease is a diagnosis
of exclusion
• bone marrow often needed to rule out
other causes of anemia
Iron studies in IDA and ACD
Test
IDA
ACD
serum iron low
low
TIBC
high
transf. sat.
low
normal or
low
low
serum
ferritin
marrow
iron
low
absent
normal or
increased
normal or
increased
Anemia of chronic disease
• Treatment
– treat the underlying cause
– erythropoietin can be effective, but is
expensive
Anemia of chronic renal failure
• Mechanism:
– mainly due to reduced production of
erythropoietin by diseased kidneys
– also iron or folate deficiency, chronic
inflammation, shortened red cell survival
• Treatment
– erythropoietin thrice weekly
– dialysis
Anemia of endocrine failure
• Uncommon cause of anemia, but
correctable
– hypothyroidism
– hypogonadism
– pan-hypopituitarism
Approach to normocytic anemia
normocytic anemia
Is there increased red cell production?
check reticulocyte count
increased
Is there
evidence of
hemolysis?
yes
hemolytic
anemia
normal or decreased
Is there evidence of:
- renal failure
- endocrine failure
- chronic inflammation
anemia of renal failure
anemia of endocrine failure
anemia of chronic disease
no
recent
bleed
Pure red cell aplasia
If not, then consider
a primary marrow problem (MDS, MM, infiltration…)
bone marrow investigation
Pure red cell aplasia
• Very rare cause of normocytic anemia
• immune-mediated destruction of red
cell precursors in the marrow
• reticulocyte count is low
• treatment: immune suppression
Approach to normocytic anemia
normocytic anemia
Is there increased red cell production?
check reticulocyte count
increased
Is there
evidence of
hemolysis?
yes
hemolytic
anemia
normal or decreased
Is there evidence of:
- renal failure
- endocrine failure
- chronic inflammation
anemia of renal failure
anemia of endocrine failure
anemia of chronic disease
no
recent
bleed
If not, then consider
a primary marrow problem (MDS, MM, infiltration…)
bone marrow investigation
Hemolytic anemia
• Anemia due to increased rate of RBC
destruction
• anemia occurs when rate of destruction
exceeds production
Normal red cell turnover
• normal RBC survival of ~ 120 days
• macrophages of the reticuloendothelial (RE)
system removes RBC’s
– unclear what marks a red cell for removal
– spleen is major site of RBC clearance
• RE system is extravascular
– 90% of normal RBC destruction occurs without
release of hemoglobin into circulation.
The fate of intravascular hemoglobin
free Hb
(a2b2 tetramers)
Hb
dimers
haptoglobin
liver
kidneys
haptoglobinhemoglobin
complex
metHb
globin
ferriheme (Fe3+)
binds to
hemopexin &
albumin
Extravascular vs Intravascular hemolysis
Test
Extravascular
Hemolysis
Intravascular
Hemolysis
LD


bilirubin


N to absent
absent
hemoglobinuria
absent
present
free Hb in plasma
absent
present
urine hemosiderin
absent
present
haptoglobin
Causes of intravascular hemolysis
– Mechanical
• prosthetic heart valve, tight AS
• march & bongo drummer’s hemoglobinuria
– Microangiopathic
• DIC, TTP, HUS
– Immunological
• acute hemolytic transfusion reaction, PNH
– Infection
• malaria
• Clostridium welchii sepsis
– Enzymopathy
• severe G6PD deficiency
Is there hemolysis?
• Look for 3 lines of evidence:
– 1. Damaged red cells on the blood film
– spherocytes (immune hemolysis, HS)
– red cell fragments (microangiopathic anemias)
– 2. Marrow response to hemolysis
– polychromasia on blood film
– reticulocytosis
– erythroid hyperplasia in marrow
– 3. Biochemical evidence of RBC destruction
– increased unconjugated bilirubin
– increased lactate dehydrogenase
– decreased/absent haptoglobin
Approach to normocytic anemia
normocytic anemia
Is there increased red cell production?
check reticulocyte count
increased
Is there
evidence of
hemolysis?
yes
hemolytic
anemia
normal or decreased
Is there evidence of:
- renal failure
- endocrine failure
- chronic inflammation
anemia of renal failure
anemia of endocrine failure
anemia of chronic disease
no
recent
bleed
If not, then consider
a primary marrow problem (MDS, MM, infiltration…)
bone marrow investigation
An approach to hemolytic anemia
Hemolytic anemia
Immune
• Autoimmune
• Alloimmune
Non-immune
Congenital
Acquired
Defects of:
• RBC membrane/
skeleton
• Infections
sepsis
malaria
(eg. Hereditary spherocytosis)
• Drug-induced
(other causes of
immune hemolysis
are rare)
• Mechanical
• RBC enzymes
(eg. G6PD deficiency)
• Hemoglobin
prosthetic heart valve
microangiopathic HA
An approach to hemolytic anemia
Hemolytic anemia
Immune
• Autoimmune
• Alloimmune
Non-immune
Congenital
Acquired
Defects of:
• RBC membrane/
skeleton
• Infections
sepsis
malaria
(eg. Hereditary spherocytosis)
• Drug-induced
(other causes of
immune hemolysis
are rare)
• Mechanical
• RBC enzymes
(eg. G6PD deficiency)
• Hemoglobin
prosthetic heart valve
microangiopathic HA
Immune hemolysis
• most frequent cause of hemolysis
• due to IgG or complement on red cells
– tags the red cell for phagocytosis
– spherocytes if incomplete phagocytosis
– lysis of RBC occurs if complement cascade
goes to completion
Autoimmune hemolysis
• Most common type of immune hemolysis
• primary (idiopathic)
• secondary
– autoimmune hemolysis secondary to:
• autoimmune condition (such as SLE)
• infection
• lymphoma or CLL
Diagnosis of immune hemolytic anemia
– 1. Direct Antiglobulin Test (DAT or direct Coomb’s test)
– detects IgG or complement on patient’s red cells
– the vast majority of patients with active immune hemolysis will
have a positive DAT.
– 2. Indirect Antiglobulin Test (IAT, indirect Coomb’s test)
– detects antibody in patient’s serum against red cell antigens
– A positive IAT does not necessarily mean hemolysis is occurring It may simply mean allo-immunization due to previous exposure
to “foreign” red cell antigens (past pregnancy or transfusion).
– 3. Peripheral Blood Film: spherocytes
Treatment of autoimmune
hemolysis
• treat the underlying cause, if there is
one
• stop suspect drugs if possible
• prednisone
• transfuse RBC’s, if needed
An approach to hemolytic anemia
Hemolytic anemia
Immune
• Autoimmune
• Alloimmune
Non-immune
Congenital
Acquired
Defects of:
• RBC membrane/
skeleton
• Infections
sepsis
malaria
(eg. Hereditary spherocytosis)
• Drug-induced
(other causes of
immune hemolysis
are rare)
• Mechanical
• RBC enzymes
(eg. G6PD deficiency)
• Hemoglobin
prosthetic heart valve
microangiopathic HA
Hereditary spherocytosis
• most common inherited red cell
membrane disorder
• 1/5000 in northern European populations
• autosomal dominant
• caused by mutations in the genes that
encode RBC membrane cytoskeleton
proteins.
Normal
membrane
cytoskeleton
Hereditary spherocytosis
loss of membrane = loss of SA = loss of deformability = increased splenic clearance
Hereditary spherocytosis
• Spherocytes are cleared by the spleen
more rapidly
– lack of deformability means they cannot
squeeze through the sieve-like slits of the
spleen.
Hereditary spherocytosis
• Clinical features:
– clinical severity varies
– most have mild to moderate anemia
– splenomegaly, cholelithiasis, jaundice may occur
• Laboratory features
– hemolytic anemia with spherocytes
– osmotic fragility test
– negative DAT
Hereditary spherocytosis
• Treatment
– most patients do not need treatment
– splenectomy
– counsel patient and family about
inheritance
An approach to hemolytic anemia
Hemolytic anemia
Immune
• Autoimmune
• Alloimmune
Non-immune
Congenital
Acquired
Defects of:
• RBC membrane/
skeleton
• Infections
sepsis
malaria
(eg. Hereditary spherocytosis)
• Drug-induced
(other causes of
immune hemolysis
are rare)
• Mechanical
• RBC enzymes
(eg. G6PD deficiency)
• Hemoglobin
prosthetic heart valve
microangiopathic HA
G6PD deficiency
• Most common inherited red cell
enzymopathy
– up to 10% of those with African and
Mediterranean descent
• X-linked
• hemolysis is due to increased oxidative
damage to red cells
G6PD deficiency
• clinical severity highly variable
– Most experience little or no anemia unless
exposed to precipitating event or drug
– precipitants:
• infections
• sulfa, primaquine, dapsone
• fava beans
G6PD deficiency
• Laboratory diagnosis
– bite cells
– Heinz bodies
– measure G6PD level
• Treatment
– supportive
– avoid precipitants
– counsel patient/family
Anemia cases
1. A 45 year old woman presents to your office with a 2 week history of increasing fatigue and jaundice. No
hepatomegaly or splenomegaly on examination.
Hb
MCV
RDW
WBC
Platelets
85
97.5
19.8
13.4
457
(120-150)
(80-96)
(11.5-14.5)
(4 - 10)
(150-450)
DAT
IAT
positive
positive
LD
T bili
direct bili
serum haptoglobin
Reticulocytes
Peripheral blood smear:
301
(94-172)
53
(0-17)
2
absent
357
(18-94)
some spherocytes
g/L
fL
x 10 9/L
x 10 9/L
U/L
mol/L
x 10 9/L
2. You are the ER doc in a remote town, 2 hours from a tertiary care hospital. At 2300h, a 57 year old man is
brought to the ER by his wife because of acute confusion and disorientation. She thought he had the “flu” for
the past 4 days because he has had a fever, headache, and was feeling unusually tired. He has been on no
medications and he had previously been well.
Hb
MCV
WBC
plt
retics
blood smear
creatinine
PT
PTT
70 g/L
98 fL
14.8 x 10 9/L
76 x 109/L
267 x 10 9/L
RBC fragments
polychromasia
thrombocytopenia
neutrophilia with left shift
97 mol/L
normal
normal
3. A 30 year old woman with a 1 year history of rheumatoid arthritis, involving hands, wrists,
On NSAIDS.
ESR
Hb
MCV
RDW
WBC
Plt
Retics
57 mm/hr
108 g/L
80 fL
18.5
8.2 x 109/L
317 x 10 9/L
89 x 109/L
4. A previously healthy 67 year old man with recurrent pneumonia.
Hb
103
MCV
98
WBC
3.9
Plt
153
Retics
56
Peripheral blood smear:
rouleaux
What next?
urea creatinine normal
LD
216
Coombs
neg
bili
normal
serum protein electrophoresis: IgG kappa monoclonal protein with depression of IgA, IgM and polyclonal
IgG.
Bone marrow investigation: excessive number of plasma cells
Skeletal survey: numerous lytic lesions in the axial skeleton and cranium.
This is case 3 from the iron lecture
Case 3. A 72 year old woman with a history of rheumatoid arthritis is found to
have a hemoglobin of 97 g/L (120-160) and an MCV of 79 fL (80-100). The
white blood cell and platelet counts are normal. Review of the peripheral blood
smear does not show much abnormality. She takes ibuprofen twice a day for
her joint symptoms.
1.
What is the differential diagnosis for her microcytic anemia?
2.
What other items on history and physical would be helpful?
3.
What other investigations are indicated?