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Iron deficiency anemia




Hematological system

Heme synthesis disorders
Coagulation disorders
Platelet disorders
Mixed platelet and coagulation disorders
Thrombosis syndromes (hypercoagulability)
Leukemoid reaction
Dysplastic and proliferative disorders
Plasma cell dyscrasias
Hematological system pathology review

Iron deficiency anemia


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High Yield Notes
6 pages

Iron deficiency anemia

18 flashcards

USMLE® Step 1 style questions USMLE

9 questions

USMLE® Step 2 style questions USMLE

12 questions

A 75-year-old man comes to his primary care provider because of weakness and fatigue for the past 6 months. He says that he has been feeling under the weather and not himself. He is usually very active but recently has been getting progressively short of breath while jogging. He denies any change to his sleeping habits and reports that he has felt fairly happy during this period. His temperature is 36.67°C (98°F); pulse is 110/min; respirations are 18/min, and blood pressure is 120/80 mm Hg. Physical examination is significant for conjunctival pallor, brittle nails, and a smooth tongue. Lab results show his serum ferritin level as 5 ng/mL. Which of the following is the most appropriate next step in management?


Content Reviewers:

Viviana Popa, MD

Anemia is a condition where there’s a decrease in the number of healthy red blood cells, or RBCs, in the body.

So, iron deficiency anemia means anemia caused by a deficiency in iron.

Iron deficiency anemia is also the most common type of anemia worldwide.

If we take a close look at our red blood cells, we’ll notice that they’re loaded with millions of copies of the same exact protein called hemoglobin, which binds to oxygen and turns our blood cells into little oxygen transporters, and basically allow us to move oxygen to all the tissues in our body.

If we take an even closer look at those hemoglobin proteins, we’ll find that they’re made of four heme molecules, which have, right in the middle, iron.

This iron molecule is what binds to oxygen, so each hemoglobin molecule can bind four molecules of oxygen.

In addition, iron is also an important part of proteins like myoglobin, which delivers and stores oxygen in muscles; and mitochondrial enzymes like cytochrome oxidase, which help generate ATP.

Normally, when a red blood cell dies, some iron is recycled from it.

But, we also lose about 1 milligram of iron every day - some through the sweat, some in shedded skin cells, and some in shedded cells in the gastrointestinal tract, which get out of the body through feces.

But most of us take in 10-20 mg of dietary iron every day, and absorb about 10% of it, or about 1 or 2 milligrams - so it all evens out at the end of the day!

Now, our diet contains two forms of iron.

The first is heme iron, or iron bound to hemoglobin or myoglobin, which comes from animal products like meat.

Heme iron is in the ferrous, or Fe2+, state.

The other form is non-heme iron, which is free iron molecules in the ferric, or Fe3+, state.

Non-heme iron comes from plant based foods like spinach and beans.

Now, when food is broken down in the stomach, iron is released.

Heme iron is absorbed directly into the duodenal cells, where it is broken down to release Fe2+ molecules.

Non-heme iron, however, needs to be reduced to heme iron first.

So the stomach’s hydrochloric acid activates a group of enzymes in the duodenal cells, collectively called ferri-reductase, which live up to their name by reducing non-heme iron to Fe2+ molecules.

Fe2+ molecules then bind to a protein in the duodenal cells called ferritin, which temporarily stores the iron.

And when iron is needed in the body, some Fe2+ molecules are released from ferritin and transported into the blood, where the enzyme hephaestin converts them back to the Fe3+ state.

Fe3+ molecules then bind to an iron transport protein called transferrin that carries iron to various target tissues and releases them there.

Fe3+ enters these various tissue cells, where there’s some more ferritin that can store them for future use.

Iron deficiency anemia can develop as a result of four main causes: decreased intake, decreased absorption, increased demand, and increased loss.

Decreased intake is the most common cause of iron deficiency anemia worldwide, and it occurs in infants, because breast milk is surprisingly low in iron; and vegetarians, whose iron intake is mostly nonheme iron, which is harder to absorb.

Decreased absorption can also occur when there’s a decrease in stomach acid production, like after a gastrectomy, where a part of the stomach is surgically removed.

Finally, decreased absorption may occur with inflammatory bowel disease or celiac disease, both of which cause inflammation and destruction of duodenal cells.

Next up, increased demand can occur in children and adolescents due to rapid growth and increase in blood volume, which requires them to make more hemoglobin.

Alternatively, it may occur during pregnancy, due to increased iron requirements for fetal development.

Finally, increased iron loss generally occurs in people with chronic slow bleeding, because iron is lost along red blood cells.

This includes females with frequent or heavy menstruation or people with bleeding gastric ulcers, and, most importantly, elderly males with colon cancer, because the tumor can bleed and cause anemia.

In fact, the first symptom of colon cancer is often iron deficiency anemia.

  1. "Robbins and Cotran Pathologic Basis of Disease, Professional Edition E-Book" Elsevier Health Sciences (2014)
  2. "Iron-Deficiency Anemia"  ()
  3. "Blood and Bone Marrow Pathology" Churchill Livingstone (2010)
  4. "Iron Deficiency Anemia" Medical Clinics of North America (2017)
  5. "Haematology" Churchill Livingstone (2012)
  6. "Iron-Deficiency Anemia" New England Journal of Medicine (2015)
  7. "Iron deficiency anemia"  (2007)