Hem & Onc - Pathology (Normocytic anemia)

Question 1

What defines normocytic anemia?

Answer 1

Anemia with blood cells of MCV of 80-100 fL

Question 2

What are the divisions of normocytic, normochromic anemias?

Answer 2

Hemolytic and nonhemolytic

Question 3

What are the divisions of hemolytic, normocytic anemias? What is the basis for this classification?

Answer 3

(1) Intrinsic vs. Extrinsic (2) Intravascular vs. Extravascular; According to cause of hemolysis (i.e., whether intrinsic or extrinsic to the RBC) & by location (i.e., intravascular vs. extrascular)

Question 4

What are lab findings that characterize intravascular hemolysis?

Answer 4

(1) DECREASED HAPTOGLOBIN (2) Increased LDH (3) Blood smear - schistocytes & increased reticulocytes (4) Urobilinogen in urine (e.g., paroxysmal nocturnal hemoglobinuria, mechanical destruction [aortic stenosis, prosthetic valve], microangiopathic hemolytic anemias)

Question 5

What happens in extravascular hemolysis? What are physical and lab findings that characterize this?

Answer 5

Macrophages in spleen clear RBCs; (1) Increased LDH (2) Increased LDH plus (3) INCREASED UCB (i.e., unconjugated bilirubin), which causes JAUNDICE (e.g., hereditary spherocytosis)

Question 6

What are lab values that help you distinguish between intravascular and extravascular hemolysis?

Answer 6

Intravascular = decreased haptoglobin (& possibly Hb in urine); Extravascular = increased UCB (leading to jaundice)

Question 7

What are examples of nonhemolytic, normocytic anemia?

Answer 7

(1) Anemia of chronic disease (ACD) (2) Aplastic anemia (3) Chronic kidney disease

Question 8

By what process does anemia of chronic disease occur?

Answer 8

Inflammation –> Increased hepcidin (released by liver, binds ferroportin on intestinal mucosal cells and macrophages thus inhibiting iron transport) –> Decreased release of iron from macrophages

Question 9

What are the lab findings (i.e., iron studies) of ACD?

Answer 9

(1) Decreased iron (2) Decreased TIBC (3) Increased ferritin

Question 10

What is unique about ACD in terms of its classification?

Answer 10

Typically starts as a nonhemolytic, normocytic anemia but can become a microcytic, hypochromic anemia

Question 11

In general, what event(s) cause(s) aplastic anemia? More specifically, what are examples of things that cause this event to occur, and consequently lead to aplastic anemia?

Answer 11

Caused by failure or destruction of myeloid stem cells; (1) Radiation and drugs (benzene, chloramphenicol, alkylating agents, antimetabolites) (2) Viral agents (parvovirus B19, EBV, HIV, HCV) (3) Fanconii’s anemia (DNA repair defect) (4) Idiopathic (immune mediated, primary stem cell defect) - may follow acute hepatitis

Question 12

What blood cell findings characterize aplastic anemia? What about bone marrow findings?

Answer 12

Pancytopenia characterized by severe anemia, leukopenia, & thrombocytopenia; Normal cell morphology but hypocellular bone marrow with fatty infiltration (dry bone marrow tap)

Question 13

What are the symptoms of aplastic anemia?

Answer 13

(1) Fatigue (2) Malaise (3) Pallor (4) Purpura (5) Mucosal bleeding (6) Petechiae (7) Infection

Question 14

What are the treatment options for aplastic anemia?

Answer 14

(1) Withdrawal of offending agent (2) Immunosuppressive regimen (antithymocyte globulin, cyclosporin) (3) Allogeneic bone marrow transplantation (4) RBC and platelet transfusion (5) G-CSF (6) GM-CSF

Question 15

How does chronic kidney disease lead to nonhemolytic, normocytic anemia?

Answer 15

Decreased erythropoietin (EPO) –> Decreased hematopoiesis

Question 16

What are examples of intrinsic hemolytic normocytic anemia? Which of these are extravascular versus intravascular?

Answer 16

(1) Hereditary spherocytosis = E (2) GP6D deficiency = I or E (3) Pyruvate kinase deficiency = E (4) HbC defect = E (5) Paroxysmal nocturnal hemoglobinuria = I (6) Sickle cell anemia = E

Question 17

What is the defect in hereditary spherocytosis?

Answer 17

Defect in proteins interacting with RBC membrane skeleton & plasma membrane (e.g., ankyrin, band 3, protein 4.2, spectrin)

Question 18

Describe and explain the morphology of RBCs seen in hereditary spherocytosis.

Answer 18

Less membrane causes small and round RBCs with no central pallor (increased MCHC, increased red cell distribution width)

Question 19

How does hereditary spherocytosis often present?

Answer 19

(1) Splenomegaly (2) Aplastic crisis (parvovirus B19 infection)

Question 20

What lab findings characterize hereditary spherocytosis?

Answer 20

Positive osmotic fragility test; Normal to decreased MCV with abundance of cells; masks microcytia

Question 21

What is the treatment for hereditary spherocytosis, and why?

Answer 21

Splenectomy; Because premature removal of RBCs (spherocytes) by spleen due to augmented RBC morphology (Recall specifics: less membrane causes small and round RBCs with no central pallor [increased MCHC, increased red cell distribution width] –> premature removal of RBCs by spleen)

Question 22

What is the hereditary nature of G6PD deficiency?

Answer 22

X-linked

Question 23

What effect does a defect in G6PD have?

Answer 23

Defect in GP6D –> Decrease Glutathione –> Increase RBC susecptibility to oxidant stress

Question 24

What are 4 causes of oxidant stress? With what hematologic disorder is oxidant stress associated?

Answer 24

(1) Sulfa drugs (2) Infections (3) Fava Beans (4) Antimalarials; G6PD deficiency

Question 25

In G6PD deficiency, where are RBCs primarily destroyed?

Answer 25

Extravascular (but also minimal intravascular)

Question 26

What are signs/symptoms associated with G6PD deficiency? What do lab results classically show?

Answer 26

Back pain, hemoglobinuria a few days after oxidant stress; Blood smear shows RBCs with Heinz bodies and bite cells; Think: “STRESS makes me eat BITES of FAVA BEANS with HEINZ ketchup.”

Question 27

What is the hereditary nature of pyruvate kinase deficiency?

Answer 27

Autosomal recessive

Question 28

What effect does a defect in pyruvate kinase have?

Answer 28

Decreased ATP –> rigid RBCs

Question 29

In pyruvate deficiency, where are RBCs destroyed?

Answer 29

Extravascular hemolysis

Question 30

What condition can pyruvate kinase deficiency cause at early stages of life?

Answer 30

Hemolytic anemia of newborn

Question 31

What causes HbC defect?

Answer 31

Glutamic acid-to-lysine mutation at residue 6 in Beta-globin

Question 32

What is important to know about HbC and sickle cell patients?

Answer 32

Patients with HbSC (1 of each mutant gene) have milder disease than HbSS patients

Question 33

In HbC defect, where are RBCs destroyed?

Answer 33

Extravascular hemolysis

Question 34

What mechanism causes paroxysmal nocturnal hemoglobinuria?

Answer 34

Increased complement-mediated RBC lysis (impaired synthesis of GPI anchor or decay-accelerating factor that protect RBC membrane from complement)

Question 35

How does the mutation arise in paroxysmal nocturnal hemoglobinuria, and where?

Answer 35

Acquired mutation in hematopoietic stem cell

Question 36

What are the symptoms most associated with paroxysmal nocturnal hemoglobinuria?

Answer 36

PNH triad: Coombs (-) hemolytic anemia, pancytopenia, & venous thrombosis

Question 37

What do the labs for PNH show?

Answer 37

CD55/59 (-) RBCs (i.e., RBCs lack proteins protecting them from complement attack) on flow cytometry

Question 38

In PNH, where are RBCs destroyed, and how in general?

Answer 38

Intravascular hemolysis; Complement-mediated RBC lysis

Question 39

How do you treat paroxysmal nocturnal hemoglobinuria?

Answer 39

Eculizumab

Question 40

What exactly causes the HbS phenotype characteristic of sickle cell anemia?

Answer 40

HbS point mutation causes a single amino acid replacement in Beta chain (substitution of glutamic acid with valine) at position 6

Question 41

Explain the pathogenesis of sickle cell disease.

Answer 41

Low O2 or dehydration precipitates sickling (deoxygenated HbS polymerizes) –> Anemia & Vaso-occlusive diease

Question 42

What is seen in newborns with sickle cell anemia, and why?

Answer 42

Initially asymptomatic, because of high HbF and low HbS (i.e., HbF is protective early in life)

Question 43

What advantage do HbS heterozygotes (sickle cell trait) have? Give the ethnic population most associated with carrying this trait, and the percentage of this population that carries it.

Answer 43

Resistance to malaria; African Americans - 8%

Question 44

What lab result(s) characterize sickle cell disease?

Answer 44

Sickled cells (crescent-shaped RBCs) seen on blood smear

Question 45

What is seen on x-ray in sickle cell anemia patients, and why? What other condition shares this finding?

Answer 45

“Crew cut” on skull x-ray, due to marrow expansion from increased erythropoiesis (also the case in thalassemias)

Question 46

What are 6 complications seen in homozygotes with sickle cell disease?

Answer 46

(1) Aplastic crisis (due to parvovirus B19) (2) Autosplenetomy (Howell-Jolly bodies) –> Increased risk with encapsulated organisms; functional splenic dysfunction occurs in early childhood (3) Splenic sequestration crisis (4) Salmonella osteomyelitis (5) Painful crisis (vaso-occlusive): dactylitis (painful hand swelling), acute chest syndrome (most common cause of death in adults), avascular necrosis, stroke (6) Renal papillary necrosis (due to low O2 in papilla) and microhematuria (medullary infarcts)

Question 47

What is/are the treatment(s) for sickle cell anemia?

Answer 47

Hydroxyurea (increased HbF) & bone marrow transplantation

Question 48

In sickle cell anemia, where are RBCs destroyed?

Answer 48

Extravascular hemolysis

Question 49

What infections are complications of sickle cell disease?

Answer 49

(1) Encapsulated organisms (increased risk due to autosplenectomy complicated) (2) Salmonella osteomyelitis

Question 50

What kidney complications are associated with sickle cell disease, and why?

Answer 50

Renal papillary necrosis (due to low O2 in papilla) and microhematuria (medullary infarcts)

Question 51

What is the general mechanism behind painful crisis complication in sickle cell disease? What are examples of painful crisis seen in sickle cell disease patients?

Answer 51

Low O2 or dehydration precipitates sickling (deoxygenated HbS polymerizes) –> vaso-occlusive; (1) Dactylitis (painful hand swelling) (2) Acute chest syndrome (3) Avascular necrosis

Question 52

What complication may parvovirus B19 cause in patients with sickle cell disease?

Answer 52

Aplastic crisis

Question 53

In what complication of sickle cell disease are Howell-Jolly bodies seen?

Answer 53

Autosplenectomy (Note: Howell-Jolly bodies = basophilic nuclear remnants [clusters of DNA] in circulating erythrocytes, typically cleared by spleen)

Question 54

What are the spleen-related complications of sickle cell disease?

Answer 54

(1) Splenic sequestration crisis (2) Autosplenetomy (which is associated with Howell-Jolly bodies in RBCs on blood semar & increases risk of infection with encapsulated organisms), note: functional splenic dysfunction occurs in early childhood

Question 55

What are examples of extrinsic hemolytic, normocytic anemias?

Answer 55

(1) Autoimmune hemolytic anemia (2) Microangiopathic anemia (3) Macroangiopathic anemia (4) Infections

Question 56

In cases of autoimmune hemolytic anemia, which antibodies are warm versus cold agglutinin? What is a good way to remember this?

Answer 56

Warm agglutinin (IgG), Cold agglutinin (IgM); “WARM weather is GGGreat” & “COLD ice cream is yuMMM”

Question 57

In cases of autoimmune hemolytic anemia, where are warm versus cold agglutinin seen? Which agglutinin(s) cause(s) acute versus chronic anemia?

Answer 57

Warm agglutinin (IgG) - CHRONIC anemia seen in SLE, CLL, or with certain drugs (e.g., alpha-methyldopa) ; Cold agglutinin (IgM) - ACUTE anemia triggered by cold, seen in CLL, Mycoplasma pneumonia infections, or infectious mononucleosis

Question 58

What is important to know about the etiology of many warm and cold AIHA?

Answer 58

Many warm and cold AIHA are idiopathic in etiology

Question 59

What is the primary lab finding associated with AIHA?

Answer 59

Coombs test positive

Question 60

What is the difference between Direct and Indirect Coomb’s tests?

Answer 60

(1) DIRECT COOMB’S TEST - anti-Ig antibody added to patient’s blood, RBCs agglutinate if RBCs are coated with Ig (2) INDIRECT COOMB’S TEST - normal RBCs added to patient’s serum. If serum has anti-RBC surface Ig, RBCs agglutinate when anti-Ig antibodies (Combs reagent) added (i.e., need Coomb’s reagent to trigger reaction).

Question 61

What is the pathogenesis of microangiopathic anemia?

Answer 61

RBCs damaged when passing through obstructed or narrowed vessel lumina

Question 62

In what conditions is microangiopathic anemia seen?

Answer 62

DIC, TTP-HUS, SLE, & malignant hypertension

Question 63

What is the characteristic lab finding in microangiopathic anemia, and why?

Answer 63

Schistocytes (helmet cells) are seen on blood smear, due to mechanical destruction of RBCs

Question 64

What is the pathogenesis of macroangiopathic anemia?

Answer 64

Prosthetic heart valves and aortic stenosis may cause hemolytic anemia secondary to mechanical destruction

Question 65

What is/are the lab finding(s) in macroangiopathic anemia?

Answer 65

Schistocytes seen on peripheral blood smear

Question 66

What are examples of infections that cause extrinsic hemolytic normocytic anemia, and how do they cause it in general?

Answer 66

E.g., malaria, babesia; Increase destruction of RBCs

Question 67

What what kind of anemia is urobilinogen in urine associated? Give 3 examples of conditions causing this.

Answer 67

Normocytic, normochromic, intravascular hemolysis; Urobilinogen in urine (e.g., paroxysmal nocturnal hemoglobinuria, mechanical destruction [aortic stenosis, prosthetic valve], microangiopathic hemolytic anemias).

Question 68

What test (not osmotic fragility test) is useful in screening for Hereditary spherocytosis?

Answer 68

Eosin-5-maleimide binding test useful for screening.

Question 69

What disease has increased incidence in paroxysmal noctural hemoglobinuria patients?

Answer 69

Increased incidence of acute leukemias

Question 70

What are 4 symptoms/components of painful crisis in sickle cell patients? Which of these is the most common cause of death?

Answer 70

Painful crisis (vaso-occlusive): (1) dactylitis (painful hand swelling) (2) acute chest syndrome (most common cause of death in adults) (3) avascular necrosis (4) stroke

Question 71

How is sickle cell anemia diagnosed?

Answer 71

Diagnosis: Hemoglobin electrophoresis