Iron deficiency

Iron deficiency
Synonyms

sideropenia, hypoferremia

DiseasesDB = 6947
Iron in heme
Classification and external resources
Specialty Hematology
ICD-10 E61.1
ICD-9-CM 269.3
MedlinePlus 000584
eMedicine med/1188

Iron deficiency is the most common nutritional deficiency in the world.[1][2][3] Iron is present in all cells in the human body and has several vital functions, such as: carrying oxygen to the tissues from the lungs as a key component of the hemoglobin protein; acting as a transport medium for electrons within the cells in the form of cytochromes; facilitating oxygen use and storage in the muscles as a component of myoglobin and as an integral part of enzyme reactions in various tissues. Too little iron can interfere with these vital functions and lead to morbidity and death.[4]

Total body iron averages approximately 3.8 g in men and 2.3 g in women. In blood plasma, iron is carried tightly bound to the protein transferrin. There are several mechanisms that control human iron metabolism and safeguard against iron deficiency. The main regulatory mechanism is situated in the gastrointestinal tract. When loss of iron is not sufficiently compensated by adequate intake of iron from the diet, a state of iron deficiency develops over time. When this state is uncorrected, it leads to iron deficiency anemia. Before anemia occurs, the medical condition of Iron Deficiency without anemia is called Latent Iron Deficiency (LID) or Iron-deficient erythropoiesis (IDE).

Untreated iron deficiency can lead to iron deficiency anemia— a common type of anemia.[5] Anemia is a condition characterized by inadequate red blood cells (erythrocytes) or hemoglobin. Iron deficiency anemia occurs when the body lacks sufficient amounts of iron, resulting in reduced production of the protein hemoglobin. Hemoglobin binds to oxygen, thus enabling red blood cells to supply oxygenated blood throughout the body. Children, pre-menopausal women (women of child-bearing age) and people with poor diet are most susceptible to the disease. Most cases of iron deficiency anemia are mild, but if not treated can cause problems like fast or irregular heartbeat, complications during pregnancy, and delayed growth in infants and children.[6]

Signs and symptoms

Deaths due to iron-deficiency anaemia per million persons in 2012
  0-0
  1-1
  2-3
  4-5
  6-8
  9-12
  13-19
  20-30
  31-74
  75-381
Disability-adjusted life year for iron-deficiency anemia per 100,000 inhabitants in 2004.[7]
  no data
  less than 50
  50-100
  100-150
  150-200
  200-250
  250-300
  300-350
  350-400
  400-450
  450-500
  500-1000
  more than 1000

Symptoms of iron deficiency can occur even before the condition has progressed to iron deficiency anemia.

Symptoms of iron deficiency are not unique to iron deficiency (i.e. not pathognomonic). Iron is needed for many enzymes to function normally, so a wide range of symptoms may eventually emerge, either as the secondary result of the anemia, or as other primary results of iron deficiency. Symptoms of iron deficiency include:

Continued iron deficiency may progress to anaemia and worsening fatigue. Thrombocytosis, or an elevated platelet count, can also result. A lack of sufficient iron levels in the blood is a reason that some people cannot donate blood.

Causes

Though genetic defects causing iron deficiency have been studied in rodents, there are no known genetic disorders of human iron metabolism that directly cause iron deficiency.

Athletics

Possible reasons that athletics may contribute to lower iron levels includes mechanical hemolysis (destruction of red blood cells from physical impact), loss of iron through sweat and urine, gastrointestinal blood loss, and haematuria (presence of blood in urine).[11][12] Although small amounts of iron are excreted in sweat and urine, these losses can generally be seen as insignificant even with increased sweat and urine production, especially considering that athletes' bodies appear to become conditioned to retain iron better.[11] Mechanical hemolysis is most likely to occur in high-impact sports, especially among long distance runners who experience "foot-strike hemolysis" from the repeated impact of their feet with the ground. Exercise-induced gastrointestinal bleeding is most likely to occur in endurance athletes. Haematuria in athletes is most likely to occur in those that undergo repetitive impacts on the body, particularly affecting the feet (such as running on a hard road, or Kendo) and hands (e.g. Conga or Candombe drumming). Additionally, athletes in sports that emphasize weight loss (e.g. ballet, gymnastics, marathon running, and wrestling) as well as sports that emphasize high-carbohydrate, low-fat diets, may be at an increased risk for iron deficiency.[11][12]

Diagnosis

As always, laboratory values have to be interpreted with the lab's reference values in mind and considering all aspects of the individual clinical situation.

Serum ferritin can be elevated in inflammatory conditions; so a normal serum ferritin may not always exclude iron deficiency, and the utility is improved by taking a concurrent C-reactive protein (CRP). The level of serum ferritin that is viewed as "high" depends on the condition. For example, in inflammatory bowel disease the threshold is 100, where as in chronic heart failure (CHF) the levels are 200.

Treatment

Before commencing treatment, there should be definitive diagnosis of the underlying cause for iron deficiency. This is particularly the case in older patients, who are most susceptible to colorectal cancer and the gastrointestinal bleeding it often causes. In adults, 60% of patients with iron deficiency anemia may have underlying gastrointestinal disorders leading to chronic blood loss.[14] It is likely that the cause of the iron deficiency will need treatment as well.

Upon diagnosis, the condition can be treated with iron supplements. The choice of supplement will depend upon both the severity of the condition, the required speed of improvement (e.g. if awaiting elective surgery) and the likelihood of treatment being effective (e.g. if has underlying IBD, is undergoing dialysis, or is having ESA therapy).

Examples of oral iron that are often used are ferrous sulfate, ferrous gluconate, or amino acid chelate tablets. Recent research suggests the replacement dose of iron, at least in the elderly with iron deficiency, may be as little as 15 mg per day of elemental iron.[15]

Food sources

Mild iron deficiency can be prevented or corrected by eating iron-rich foods and by cooking in an iron skillet. Because iron is a requirement for most plants and animals, a wide range of foods provide iron. Good sources of dietary iron have heme-iron, as this is most easily absorbed and is not inhibited by medication or other dietary components. Three examples are red meat, poultry, and insects.[16][17] Non-heme sources do contain iron, though it has reduced bioavailability. Examples are lentils, beans, leafy vegetables, pistachios, tofu, fortified bread, and fortified breakfast cereals.

Iron from different foods is absorbed and processed differently by the body; for instance, iron in meat (heme-iron source) is more easily absorbed than iron in grains and vegetables ("non-heme" iron sources).[18] Minerals and chemicals in one type of food may also inhibit absorption of iron from another type of food eaten at the same time.[19] For example, oxalates and phytic acid form insoluble complexes which bind iron in the gut before it can be absorbed.

Because iron from plant sources is less easily absorbed than the heme-bound iron of animal sources, vegetarians and vegans should have a somewhat higher total daily iron intake than those who eat meat, fish or poultry.[20] Legumes and dark-green leafy vegetables like broccoli, kale and oriental greens are especially good sources of iron for vegetarians and vegans. However, spinach and Swiss chard contain oxalates which bind iron, making it almost entirely unavailable for absorption. Iron from non-heme sources is more readily absorbed if consumed with foods that contain either heme-bound iron or vitamin C. This is due to a hypothesised "meat factor" which enhances iron absorption.[21]

Following are two tables showing the richest foods in heme and non-heme iron.[22] In both tables, food serving sizes may differ from the usual 100g quantity for relevancy reasons. Arbitrarily, the guideline is set at 18 mg, which is the USDA Recommended Dietary Allowance for women aged between 19 and 50.[23]

Abstract: richest foods in heme iron
Food Serving Size Iron % Guideline
clam 100g 28 mg 155%
pork liver 100g 18 mg 100%
lamb kidney 100g 12 mg 69%
cooked oyster 100g 12 mg 67%
cuttlefish 100g 11 mg 60%
lamb liver 100g 10 mg 57%
octopus 100g 9.5 mg 53%
mussel 100g 6.7 mg 37%
beef liver 100g 6.5 mg 36%
beef heart 100g 6.4 mg 35%
Abstract: richest foods in non-heme iron
Food Serving Size Iron % Guideline
raw yellow beans 100g 7 mg 35%
spirulina 15g 4.3 mg 24%
falafel 140g 4.8 mg 24%
soybean kernels 125ml=1/2cup 4.6 mg 23%
spinach 125g 4.4 mg 22%
lentil 125ml=1/2cup 3.5 mg 17.5%
treacle (CSR Australia) 20ml=1Tbsp 3.4 mg 17%
molasses (Bluelabel Australia) 20ml=1Tbsp 1.8 mg 9%
candied ginger root 15g~3p 1.7 mg 8.5%
toasted sesame seeds 10g 1.4 mg 7%
cocoa (dry powder) 5g~1Tbsp .8 mg 4%

Iron deficiency can have serious health consequences that diet may not be able to quickly correct; hence, an iron supplement is often necessary if the iron deficiency has become symptomatic.

Blood transfusion

Blood transfusion is sometimes used to treat iron deficiency with hemodynamic instability.[24] Sometimes transfusions are considered for people who have chronic iron deficiency or who will soon go to surgery, but even if such people have low hemoglobin, they should be given oral treatment or intravenous iron.[24]

Bioavailability and bacterial infection

Iron is needed for bacterial growth making its bioavailability an important factor in controlling infection.[25] Blood plasma as a result carries iron tightly bound to transferrin, which is taken up by cells by endocytosing transferrin, thus preventing its access to bacteria.[26] Between 15 and 20 percent of the protein content in human milk consists of lactoferrin[27] that binds iron. As a comparison, in cow's milk, this is only 2 percent. As a result, breast fed babies have fewer infections.[26] Lactoferrin is also concentrated in tears, saliva and at wounds to bind iron to limit bacterial growth. Egg white contains 12% conalbumin to withhold it from bacteria that get through the egg shell (for this reason, prior to antibiotics, egg white was used to treat infections).[28]

To reduce bacterial growth, plasma concentrations of iron are lowered in a variety of systemic inflammatory states due to increased production of hepcidin which is mainly released by the liver in response to increased production of pro-inflammatory cytokines such as Interleukin-6. This functional iron deficiency will resolve once the source of inflammation is rectified; however, if not resolved, it can progress to Anaemia of Chronic Inflammation. The underlying inflammation can be caused by fever,[29] Inflammatory Bowel Disease, infections, Chronic Heart Failure (CHF), carcinomas, or following surgery.

Reflecting this link between iron bioavailability and bacterial growth, the taking of oral iron supplements causes a relative overabundance of iron that can alter the types of bacteria that are present within the gut. There have been concerns regarding parenteral iron being administered whilst bacteremia is present, although this has not been borne out in clinical practice. A moderate iron deficiency, in contrast, can provide protection against acute infection, especially against organisms that reside within hepatocytes and macrophages, such as Malaria and Tuberculosis. This is mainly beneficial in regions with a high prevalence of these diseases and where standard treatment is unavailable.

See also

References

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  2. Hider, Robert C.; Kong, Xiaole (2013). "Chapter 8. Iron: Effect of Overload and Deficiency". In Astrid Sigel, Helmut Sigel and Roland K. O. Sigel. Interrelations between Essential Metal Ions and Human Diseases. Metal Ions in Life Sciences. 13. Springer. pp. 229–294. doi:10.1007/978-94-007-7500-8_8.
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Further reading

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