Pathoma - RBC Disorders - Micro- and Macrocytic Anemia

Question 1

What is the underlying cause of microcytic anemia?

Answer 1

Decrease in hemoglobin

Question 2

What are the 4 types of microcytic anemia?

Answer 2

(1) Iron deficiency anemia
(2) Anemia of chronic disease (iron is unavailable for use)
(3) Sideroblastic anemia (decreased protoporphoryin)
(4) Thalassemia

Question 3

Where does absorption of iron occur?

Answer 3

Duodenum

Question 4

What are the proteins involved in iron absorption and transport?

Answer 4

Ferroportin (transports iron from gut lumen to blood)

Transferrin (transports iron within the blood)

Ferritin (stores intracellular iron)

Question 5

Describe iron lab measures:

• Serum iron
• Total-iron binding capacity (TIBC)
• % saturation
• Serum ferritin

Answer 5

Serum iron = iron in the blood

TIBC = transferrin molecules in the blood

% saturation = percentage of transferrin molecules bound to iron

Serum ferritin = iron stores

Question 6

How does a gastrectomy effect iron levels?

Answer 6

Gastric acids allow iron to maintain Fe2+ state, which is the form that can be absorbed (Fe2 go in TO the body)

Gastrectomy can cause iron deficiency because no acid means iron will be in Fe3+ form

Question 7

Lab values in iron deficiency anemia:

• Serum iron
• Total-iron binding capacity (TIBC)
• % saturation
• Serum ferritin
• RDW
• Free erythrocyte protoporphyrin

Answer 7

Serum iron - decreased

Total-iron binding capacity (TIBC) - increased (liver pumps out more transferrin in search of iron)

% saturation - decreased

Serum ferritin - decreased

RDW - increased (due to normocytic anemia early in disease and microcytic later in disease)

Free erythrocyte protoporphyrin - increased

Question 8

What is Plummer-Vinson syndrome

Answer 8

Iron deficiency anemia with esophageal web and atrophic glossitis

Presents as anemia with dysphagia and beefy-red tongue

Think: a plumber with bad breath (esophageal web), and plumber is pale (anemia) and fat with a big red tongue (glossitis)

Question 9

Describe the role of Hepcidin in anemia of chronic disease

Answer 9

Liver will produce acute phase reactants such as Hepcidin, which will sequester iron in storage sites

Question 10

Lab values in anemia of chronic disease:

• Serum iron
• Total-iron binding capacity (TIBC)
• % saturation
• Serum ferritin
• Free erythrocyte protoporphyrin

Answer 10

Serum iron - decreased

Total-iron binding capacity (TIBC) - increased

% saturation - decreased

Serum ferritin - increased

Free erythrocyte protoporphyrin - increased

Question 11

What is the cause of sideroblastic anemia

Answer 11

Defective protoporphyrin synthesis

Question 12

Describe the steps of protoporphyrin synthesis + it’s attachment to iron

Answer 12

All occurs in the mitochondria:

Succinyl CoA converted to aminolevulinic acid (ALA) via Aminolevulinic acid synthetase (ALAS)

ALA converted to prophobilinogen via ALAD

Prophobilinogen converted to proptoporphyrin

Protoporphyrin attached to iron via ferrochelatase

Question 13

What are ringed sideroblasts and how do they form?

Answer 13

Protoporphyrin deficiency wi;; cause iron to build up inside mitochondria, where they would usually be bound to protoporphyrin

Iron-laden mitochondria form a ring around the nucleus

Seen with Prussian blue stain

Question 14

Lab values in sideroblastic aneia:

• Serum iron
• Total-iron binding capacity (TIBC)
• % saturation
• Serum ferritin

Answer 14

Serum iron - increased

TIBC - decreased

% sat - increased

Serum ferritin - increased

Question 15

How does Thalassemia cause anemia?

Answer 15

Decreased SYNTHESIS of globin chains

Question 16

What type of gene defect causes alpha-thalassemia

Answer 16

Gene deletion

Question 17

What population is associated with Cis- and Trans- alpha thalassemia 2 gene deletion

Answer 17

Cis = Asians
Trans = Africans

Question 18

What causes damage in 3 gene deletion a-thalassemia?

Answer 18

HbH (beta tetramers) will damage RBCs

Question 19

What causes damage in 4 gene deletion a-thalassemia?

Answer 19

Hb Barts (gamma tetramers) will damage RBCs

Lethal in utero (hydrops fetalis)

Question 20

What type of gene defect causes beta-thalassemia

Answer 20

Gene mutation

Question 21

What are the possible results of mutation in beta-thalassemia

Answer 21

B0 = absent globin chain
B+ = diminished production of globin chain

Question 22

What will RBCs look like in beta-thalassemia minor (B/B+)

Answer 22

Microcytic, hypochromic RBCs with target cells (decreased hemoglobin in cytoplasm allows for membrane blebbing)

Question 23

What types/levels of hemoglobins will you see in beta-thalassemia minor?

Answer 23

Slightly decreased HbA (a2b2)

Increased HbA2 (a2d2)

Increased HbF (a2y2)

Question 24

What is the damage in b-thalassemia major (B0/B0)

Answer 24

Unpaired alpha chains will precipitate and damage RBCs, resulting in ineffective erythropoiesis and extravascular hemolysis

Question 25

Describe the cause and effect of erythroid hyperplasia in b-thalassemia major

Answer 25

Because there is such severe anemia, the body will try to even harder to make more RBCs and erythropoeisis will begin to take place in locations other than the norm (central axial skeleton), such as:

• skull (‘crewcut’ appearance on x-ray)
• facial bones (‘chipmunk faces’)
• extramedullary areas (hepatosplenomegaly)

Question 26

What types of cells will you see in b-thalassemia major

Answer 26

Microcytic, hypochromic RBCs with target cells

Nucleated RBCs (more easily escape from the locations of abnormal hematopoiesis)

Question 27

What type of hemoglobin will you see in b-thalassemia major

Answer 27

Little or no HbA

Elevated HbA2 and HbF

Question 28

What is the underlying cause behind macrocytic anemia and what are the causes

Answer 28

One less division of RBCs

Usually caused by Folate or B12 deficiency (necessary for DNA precursors)

Can also be cause by alcoholism, liver disease, and drugs

Question 29

What is megaloblastic anemia and what are the defining features

Answer 29

A macrocytic anemia caused by Folate or B12 deficiency that also causes megaloblastic change in other rapidly dividing cells

This is because Folate and B12 are needed to DNA synthesis in all cells, not just RBCs

Defining features:

• Megaloblastic anemia
• Hypersegmented neutrophils
• Megaloblastic change in rapidly-dividing (e.g. intestinal) epithelial cells

Question 30

Folate:

• Source
• Site of absorption
• Stores

Answer 30

Folate found in green vegetables

Absorbed in the jejunum

Liver stores lasting 3-4 months

Question 31

Clinical and lab findings in folate deficiency

Answer 31

• Macrocytic RBCs with hypersegmented neutrophils
• Glossitis (inflammation of tongue because cells are not turning over as quickly)
• Decreased serum folate
• Increased serum homocysteine
• Normal methylmalonic acid (vs. B12 deficiency which will have elevated)

Question 32

Describe the steps of Vitamin B12 (cobalamin) absorption

Answer 32

Dietary B12 complexed to meat products

Salivary amylase breaks B12-meat complex and saliva also produces R-binder to attach to B12 for travel through the stomach

Pancreatic proteases in the duodenum detach B12 from R-binder

B12 complexed with IF (made in parietal cells) can be absorbed in the ILEUM

Question 33

What is the body store of B12

Answer 33

Large hepatic stores (3-4 years)

Question 34

What is pernicious anemia

Answer 34

Autoimmune destruction of parietal cells leads to decreased IF production, so B12 cannot be absorbed, leading to megaloblastic anemia

Question 35

Describe 3 causes (other than pernicious anemia) that can lead to B12 deficiency

Answer 35

(1) Pancreatic insufficiency (no proteases to cleave B12 from R-factor)
(2) Damage to the terminal ileum, site of B12 absorption (e.g. Crohn’s Diphyllobathrium latum)
(3) Dietary deficiency (rare) - vegans

Question 36

Clinical and lab findings in Vitamin B12 deficiency

Answer 36

• Macrocytic RBCs with hypersegmented neutrophils (megaloblastic anemia)
• Glossitis (inflammation of tongue because cells are not turning over as quickly)
• Decreased serum folate
• Increased serum homocysteine
• Increased methylmalonic acid (vs. Folate deficiency which will have normal)
• Subacute combined degeneration of the spinal cord due to methylmalonic building causing destruction of myelin
• Leads to poor proprioception and vibratory sense (posterior column) and spastic paresis (lateral corticospinal tract)