Omegaâ'3 fatty acids, also called Ïâ'3 fatty acids or nâ'3 fatty acids, are polyunsaturated fatty acids (PUFAs). The fatty acids have two ends, the carboxylic acid (-COOH) end, which is considered the beginning of the chain, thus "alpha", and the methyl (-CH3) end, which is considered the "tail" of the chain, thus "omega". One way in which a fatty acid is named is determined by the location of the first double bond, counted from the tail, that is, the omega (Ï-) or the n- end. Thus, in omega-3 fatty acids the first double bond is between the third and fourth carbon atoms from the tail end. However, the standard (IUPAC) chemical nomenclature system starts from the carboxyl end.
The three types of omegaâ'3 fatty acids involved in human physiology are α-linolenic acid (ALA) (found in plant oils), eicosapentaenoic acid (EPA), and docosahexaenoic acid (DHA) (both commonly found in marine oils). Marine algae and phytoplankton are primary sources of omegaâ'3 fatty acids. Common sources of plant oils containing the omegaâ'3 ALA fatty acid include walnut, edible seeds, clary sage seed oil, algal oil, flaxseed oil, Sacha Inchi oil, Echium oil, and hemp oil, while sources of animal omegaâ'3 EPA and DHA fatty acids include fish, fish oils, eggs from chickens fed EPA and DHA, squid oils, and krill oil. Dietary supplementation with omegaâ'3 fatty acids does not appear to affect the risk of death, cancer or heart disease. Furthermore, fish oil supplement studies have failed to support claims of preventing heart attacks or strokes.
Omegaâ'3 fatty acids are important for normal metabolism. Mammals are unable to synthesize omegaâ'3 fatty acids, but can obtain the shorter-chain omegaâ'3 fatty acid ALA (18 carbons and 3 double bonds) through diet and use it to form the more important long-chain omegaâ'3 fatty acids, EPA (20 carbons and 5 double bonds) and then from EPA, the most crucial, DHA (22 carbons and 6 double bonds). The ability to make the longer-chain omegaâ'3 fatty acids from ALA may be impaired in aging. In foods exposed to air, unsaturated fatty acids are vulnerable to oxidation and rancidity.
Health effects
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Supplementation does not appear to be associated with a lower risk of all-cause mortality.
Cancer
The evidence linking the consumption of marine omegaâ'3 fats to a lower risk of cancer is poor. With the possible exception of breast cancer, there is insufficient evidence that supplementation with omegaâ'3 fatty acids has an effect on different cancers. The effect of consumption on prostate cancer is not conclusive. There is a decreased risk with higher blood levels of DPA, but an increased risk of more aggressive prostate cancer was shown with higher blood levels of combined EPA and DHA. In people with advanced cancer and cachexia, omegaâ'3 fatty acids supplements may be of benefit, improving appetite, weight, and quality of life.
Cardiovascular disease
Evidence in the population generally does not support a beneficial role for omegaâ'3 fatty acid supplementation in preventing cardiovascular disease (including myocardial infarction and sudden cardiac death) or stroke. However, omegaâ'3 fatty acid supplementation greater than one gram daily for at least a year may be protective against cardiac death, sudden death, and myocardial infarction in people who have a history of cardiovascular disease. No protective effect against the development of stroke or all-cause mortality was seen in this population. Eating a diet high in fish that contain long chain omegaâ'3 fatty acids does appear to decrease the risk of stroke. Fish oil supplementation has not been shown to benefit revascularization or abnormal heart rhythms and has no effect on heart failure hospital admission rates. Furthermore, fish oil supplement studies have failed to support claims of preventing heart attacks or strokes.
Evidence suggests that omegaâ'3 fatty acids modestly lower blood pressure (systolic and diastolic) in people with hypertension and in people with normal blood pressure. Some evidence suggests that people with certain circulatory problems, such as varicose veins, may benefit from the consumption of EPA and DHA, which may stimulate blood circulation and increase the breakdown of fibrin, a protein involved in blood clotting and scar formation. Omegaâ'3 fatty acids reduce blood triglyceride levels but do not significantly change the level of LDL cholesterol or HDL cholesterol in the blood. The American Heart Association position (2011) is that borderline elevated triglycerides, defined as 150â"199Â mg/dL, can be lowered by 0.5-1.0 grams of EPA and DHA per day; high triglycerides 200â"499Â mg/dL benefit from 1-2 g/day; and >500Â mg/dL be treated under a physician's supervision with 2-4 g/day using a prescription product.
ALA does not confer the cardiovascular health benefits of EPA and DHAs.
The effect of omegaâ'3 polyunsaturated fatty acids on stroke is unclear, with a possible benefit in women.
Inflammation
A 2013 systematic review found tentative evidence of benefit for lowering inflammation levels in healthy adults and in people with one or more biomarkers of metabolic syndrome. Consumption of omegaâ'3 fatty acids from marine sources lowers blood markers of inflammation such as C-reactive protein, interleukin 6, and TNF alpha.
For rheumatoid arthritis, one systematic review found consistent, but modest, evidence for the effect of marine nâ'3 PUFAs on symptoms such as "joint swelling and pain, duration of morning stiffness, global assessments of pain and disease activity" as well as the use of non-steroidal anti-inflammatory drugs. The American College of Rheumatology has stated that there may be modest benefit from the use of fish oils, but that it may take months for effects to be seen, and cautions for possible gastrointestinal side effects and the possibility of the supplements containing mercury or vitamin A at toxic levels. The National Center for Complementary and Integrative Health has concluded that "[n]o dietary supplement has shown clear benefits for rheumatoid arthritis", but that there is preliminary evidence that fish oil may be beneficial, but needs further study.
Developmental disabilities
Although not supported by current scientific evidence as a primary treatment for attention deficit hyperactivity disorder (ADHD), autism, and other developmental disabilities, omegaâ'3 fatty acid supplements are being given to children with these conditions.
One meta-analysis concluded that omegaâ'3 fatty acid supplementation demonstrated a modest effect for improving ADHD symptoms. A Cochrane review of PUFA (not necessarily omegaâ'3) supplementation found "there is little evidence that PUFA supplementation provides any benefit for the symptoms of ADHD in children and adolescents", while a different review found "insufficient evidence to draw any conclusion about the use of PUFAs for children with specific learning disorders". Another review concluded that the evidence is inconclusive for the use of omegaâ'3 fatty acids in behavior and non-neurodegenerative neuropsychiatric disorders such as ADHD and depression.
Fish oil has only a small benefit on the risk of premature birth. A 2015 meta-analysis of the effect of omegaâ'3 supplementation during pregnancy did not demonstrate a decrease in the rate of preterm birth or improve outcomes in women with singleton pregnancies with no prior preterm births. A systematic review and meta-analysis published the same year reached the opposite conclusion, specifically, that omegaâ'3 fatty acids were effective in "preventing early and any preterm delivery".
Mental health
There is some evidence that omegaâ'3 fatty acids are related to mental health, including that they may tentatively be useful as an add-on for the treatment of depression associated with bipolar disorder. Significant benefits due to EPA supplementation were only seen, however, when treating depressive symptoms and not manic symptoms suggesting a link between omegaâ'3 and depressive mood. There is also preliminary evidence that EPA supplementation is helpful in cases of depression. The link between omegaâ'3 and depression has been attributed to the fact that many of the products of the omegaâ'3 synthesis pathway play key roles in regulating inflammation such as prostaglandin E3 which have been linked to depression. This link to inflammation regulation has been supported in both in vitro and in vivo studies as well as in meta-analysis studies. The exact mechanism in which omegaâ'3 acts upon the inflammatory system is still controversial as it was commonly believed to have anti-inflammatory effects.
There is, however, significant difficulty in interpreting the literature due to participant recall and systematic differences in diets. There is also controversy as to the efficacy of omegaâ'3, with many meta-analysis papers finding heterogeneity among results which can be explained mostly by publication bias. A significant correlation between shorter treatment trials was associated with increased omegaâ'3 efficacy for treating depressed symptoms further implicating bias in publication.
A study in 2013, (Stafford, Jackson, Mayo-Wilson, Morrison, Kendall), stated the following in its conclusion: "Although evidence of benefits for any specific intervention is not conclusive, these findings suggest that it might be possible to delay or prevent transition to psychosis. Further research should be undertaken to establish conclusively the potential for benefit of psychological interventions in the treatment of people at high risk of psychosis."`
Cognitive aging
Epidemiological studies are inconclusive about an effect of omegaâ'3 fatty acids on the mechanisms of Alzheimer's disease. There is preliminary evidence of effect on mild cognitive problems, but none supporting an effect in healthy people or those with dementia.
Brain and visual functions
Brain function and vision rely on dietary intake of DHA to support a broad range of cell membrane properties, particularly in grey matter, which is rich in membranes. A major structural component of the mammalian brain, DHA is the most abundant omegaâ'3 fatty acid in the brain. It is under study as a candidate essential nutrient with roles in neurodevelopment, cognition, and neurodegenerative disorders.
Atopic diseases
Results of studies investigating the role of LCPUFA supplementation and LCPUFA status in the prevention and therapy of atopic diseases (allergic rhinoconjunctivitis, atopic dermatitis and allergic asthma) are controversial; therefore, at the present stage of our knowledge (as of 2013) we cannot state either that the nutritional intake of nâ'3 fatty acids has a clear preventive or therapeutic role, or that the intake of n-6 fatty acids has a promoting role in context of atopic diseases.
Risk of deficiency
People with PKU often have low intake of omegaâ'3 fatty acids, because nutrients rich in omegaâ'3 fatty acids are excluded from their diet due to high protein content.
Asthma
As of 2015 there was no evidence that taking omega 3 supplements can prevent asthma attacks in children.
Chemistry
An omegaâ'3 fatty acid is a fatty acid with multiple double bonds, where the first double bond is between the third and fourth carbon atoms from the end of the carbon atom chain. "Short chain" omegaâ'3 fatty acids have a chain of 18 carbon atoms or less, while "long chain" omegaâ'3 fatty acids have a chain of 20 or more.
Three omegaâ'3 fatty acids are important in human physiology, α-linolenic acid (18:3, n-3; ALA), eicosapentaenoic acid (20:5, n-3; EPA), and docosahexaenoic acid (22:6, n-3; DHA). These three polyunsaturates have either 3, 5, or 6 double bonds in a carbon chain of 18, 20, or 22 carbon atoms, respectively. As with most naturally-produced fatty acids, all double bonds are in the cis-configuration, in other words, the two hydrogen atoms are on the same side of the double bond; and the double bonds are interrupted by methylene bridges (-CH
2-), so that there are two single bonds between each pair of adjacent double bonds.
List of omegaâ'3 fatty acids
This table lists several different names for the most common omegaâ'3 fatty acids found in nature.
Forms
Omegaâ'3 fatty acids occur naturally in two forms, triglycerides and phospholipids. In the triglycerides, they, together with other fatty acids, are bonded to glycerol. Phospholipid omegaâ'3 is composed of two fatty acids attached to a phosphate and choline, versus the three fatty acids attached to glycerol in triglycerides.
The triglycerides can be converted to the free fatty acid or to methyl or ethyl esters, and the individual esters of omegaâ'3 fatty acids are available.
Biochemistry
Transporters
DHA in the form of lysophosphatidylcholine is transported into the brain by a membrane transport protein, MFSD2A, which is exclusively expressed in the endothelium of the bloodâ"brain barrier.
Mechanism of action
The 'essential' fatty acids were given their name when researchers found that they are essential to normal growth in young children and animals. The omegaâ'3 fatty acid DHA, also known as docosahexaenoic acid, is found in high abundance in the human brain. It is produced by a desaturation process, but humans lack the desaturase enzyme, which acts to insert double bonds at the Ï6 and Ï3 position. Therefore, the Ï6 and Ï3 polyunsaturated fatty acids cannot be synthesized and are appropriately called essential fatty acids.
In 1964 it was discovered that enzymes found in sheep tissues convert omegaâ'6 arachidonic acid into the inflammatory agent called prostaglandin E2 which both causes the sensation of pain and expedites healing and immune response in traumatized and infected tissues. By 1979 more of what are now known as eicosanoids were discovered: thromboxanes, prostacyclins, and the leukotrienes. The eicosanoids, which have important biological functions, typically have a short active lifetime in the body, starting with synthesis from fatty acids and ending with metabolism by enzymes. If the rate of synthesis exceeds the rate of metabolism, the excess eicosanoids may, however, have deleterious effects. Researchers found that certain omegaâ'3 fatty acids are also converted into eicosanoids, but at a much slower rate. Eicosanoids made from omegaâ'3 fatty acids are often referred to as anti-inflammatory, but in fact they are just less inflammatory than those made from omegaâ'6 fats. If both omegaâ'3 and omegaâ'6 fatty acids are present, they will "compete" to be transformed, so the ratio of long-chain omegaâ'3:omegaâ'6 fatty acids directly affects the type of eicosanoids that are produced.
Interconversion
Conversion efficiency of ALA to EPA and DHA
Humans can convert short-chain omegaâ'3 fatty acids to long-chain forms (EPA, DHA) with an efficiency below 5%. The omegaâ'3 conversion efficiency is greater in women than in men, but less studied. Higher ALA and DHA values found in plasma phospholipids of women may be due to the higher activity of desaturases, especially that of delta-6-desaturase.
These conversions occur competitively with omegaâ'6 fatty acids, which are essential closely related chemical analogues that are derived from linoleic acid. They both utilize the same desaturase and elongase proteins in order to synthesize inflammatory regulatory proteins. The products of both pathways are vital for growth making a balanced diet of omegaâ'3 and omegaâ'6 important to an individual's health. A balanced intake ratio of 1:1 was believed to be ideal in order for proteins to be able to synthesize both pathways sufficiently, but this has been controversial as of recent research.
The conversion of ALA to EPA and further to DHA in humans has been reported to be limited, but varies with individuals. Women have higher ALA-to-DHA conversion efficiency than men, which is presumed to be due to the lower rate of use of dietary ALA for beta-oxidation. One preliminary study showed that EPA can be increased by lowering the amount of dietary LA, and DHA can be increased by elevating intake of dietary ALA.
Omegaâ'6 to omegaâ'3 ratio
Human diet has changed rapidly in recent centuries resulting in a reported increased diet of omegaâ'6 in comparison to omegaâ'3. The rapid evolution of human diet away from a 1:1 omegaâ'3 and omegaâ'6 ratio, such as during the Neolithic Agricultural Revolution, has presumably been too fast for humans to have adapted to biological profiles adept at balancing omegaâ'3 and omegaâ'6 ratios of 1:1. This is commonly believed to be the reason why modern diets are correlated with many inflammatory disorders. While omegaâ'3 polyunsaturated fatty acids may be beneficial in preventing heart disease in humans, the level of omegaâ'6 polyunsaturated fatty acids (and, therefore, the ratio) does not matter.
Both omegaâ'6 and omegaâ'3 fatty acids are essential: humans must consume them in their diet. Omegaâ'6 and omegaâ'3 eighteen-carbon polyunsaturated fatty acids compete for the same metabolic enzymes, thus the omegaâ'6:omegaâ'3 ratio of ingested fatty acids has significant influence on the ratio and rate of production of eicosanoids, a group of hormones intimately involved in the body's inflammatory and homeostatic processes, which include the prostaglandins, leukotrienes, and thromboxanes, among others. Altering this ratio can change the body's metabolic and inflammatory state. In general, grass-fed animals accumulate more omegaâ'3 than do grain-fed animals, which accumulate relatively more omegaâ'6. Metabolites of omegaâ'6 are more inflammatory (esp. arachidonic acid) than those of omegaâ'3. This necessitates that omegaâ'6 and omegaâ'3 be consumed in a balanced proportion; healthy ratios of omegaâ'6:omegaâ'3, according to some authors, range from 1:1 to 1:4. Other authors believe that a ratio of 4:1 (4 times as much omegaâ'6 as omegaâ'3) is already healthy. Studies suggest the evolutionary human diet, rich in game animals, seafood, and other sources of omegaâ'3, may have provided such a ratio.
Typical Western diets provide ratios of between 10:1 and 30:1 (i.e., dramatically higher levels of omegaâ'6 than omegaâ'3). The ratios of omegaâ'6 to omegaâ'3 fatty acids in some common vegetable oils are: canola 2:1, hemp 2â"3:1, soybean 7:1, olive 3â"13:1, sunflower (no omegaâ'3), flax 1:3, cottonseed (almost no omegaâ'3), peanut (no omegaâ'3), grapeseed oil (almost no omegaâ'3) and corn oil 46:1.
History
Although omegaâ'3 fatty acids have been known as essential to normal growth and health since the 1930s, awareness of their health benefits has dramatically increased since the 1980s.
On September 8, 2004, the U.S. Food and Drug Administration gave "qualified health claim" status to EPA and DHA omegaâ'3 fatty acids, stating, "supportive but not conclusive research shows that consumption of EPA and DHA [omegaâ'3] fatty acids may reduce the risk of coronary heart disease". This updated and modified their health risk advice letter of 2001 (see below).
The Canadian Food Inspection Agency has recognized the importance of DHA omegaâ'3 and permits the following claim for DHA: "DHA, an omegaâ'3 fatty acid, supports the normal physical development of the brain, eyes and nerves primarily in children under two years of age."
Historically, whole food diets contained sufficient amounts of omegaâ'3, but because omegaâ'3 is readily oxidized, the trend to shelf-stable, processed foods has led to a deficiency in omegaâ'3 in manufactured foods.
Dietary sources
Dietary recommendations
In the United States, the Institute of Medicine publishes a system of Dietary Reference Intakes, which includes Recommended Dietary Allowances (RDAs) for individual nutrients, and Acceptable Macronutrient Distribution Ranges (AMDRs) for certain groups of nutrients, such as fats. When there is insufficient evidence to determine an RDA, the institute may publish an Adequate Intake (AI) instead, which has a similar meaning, but is less certain. The AI for α-linolenic acid is 1.6 grams/day for men and 1.1 grams/day for women, while the AMDR is 0.6% to 1.2% of total energy. Because the physiological potency of EPA and DHA is much greater than that of ALA, it is not possible to estimate one AMDR for all omegaâ'3 fatty acids. Approximately 10 percent of the AMDR can be consumed as EPA and/or DHA. The Institute of Medicine has not established a RDA or AI for EPA, DHA or the combination, so there is no Daily Value (DVs are derived from RDAs), no labeling of foods or supplements as providing a DV percentage of these fatty acids per serving, and no labeling a food or supplement as an excellent source, or "High in..." As for safety, there was insufficient evidence as of 2005 to set an upper tolerable limit for omegaâ'3 fatty acids, although the FDA has advised that adults can safely consume up to a total of 3 grams per day of combined DHA and EPA, with no more than 2 g from dietary supplements.
The American Heart Association (AHA) has made recommendations for EPA and DHA due to their cardiovascular benefits: individuals with no history of coronary heart disease or myocardial infarction should consume oily fish two times per week; and "Treatment is reasonable" for those having been diagnosed with coronary heart disease. For the latter the AHA does not recommend a specific amount of EPA + DHA, although it notes that most trials were at or close to 1000Â mg/day. The benefit appears to be on the order of a 9% decrease in relative risk. The European Food Safety Authority (EFSA) approved a claim "EPA and DHA contributes to the normal function of the heart" for products that contain at least 250Â mg EPA + DHA. The report did not address the issue of people with pre-existing heart disease. The World Health Organization recommends regular fish consumption (1-2 servings per week, equivalent to 200 to 500Â mg/day EPA + DHA) as protective against coronary heart disease and ischaemic stroke.
Contamination
Heavy metal poisoning by the body's accumulation of traces of heavy metals, in particular mercury, lead, nickel, arsenic, and cadmium, is a possible risk from consuming fish oil supplements. Also, other contaminants (PCBs, furans, dioxins, and PBDEs) might be found, especially in less-refined fish oil supplements. However, heavy metal toxicity from consuming fish oil supplements is highly unlikely, because heavy metals selectively bind with protein in the fish flesh rather than accumulate in the oil. An independent test in 2005 of 44 fish oils on the US market found all of the products passed safety standards for potential contaminants.
Throughout their history, the Council for Responsible Nutrition and the World Health Organization have published acceptability standards regarding contaminants in fish oil. The most stringent current standard is the International Fish Oils Standard. Fish oils that are molecularly distilled under vacuum typically make this highest-grade; levels of contaminants are stated in parts per billion per trillion.
Fish
The most widely available dietary source of EPA and DHA is oily fish, such as salmon, herring, mackerel, anchovies, menhaden, and sardines. Oils from these fish have a profile of around seven times as much omegaâ'3 as omegaâ'6. Other oily fish, such as tuna, also contain n-3 in somewhat lesser amounts. Consumers of oily fish should be aware of the potential presence of heavy metals and fat-soluble pollutants like PCBs and dioxins, which are known to accumulate up the food chain. After extensive review, researchers from Harvard's School of Public Health in the Journal of the American Medical Association (2006) reported that the benefits of fish intake generally far outweigh the potential risks. Although fish are a dietary source of omegaâ'3 fatty acids, fish do not synthesize them; they obtain them from the algae (microalgae in particular) or plankton in their diets.
Fish oil
Marine and freshwater fish oil vary in content of arachidonic acid, EPA and DHA. They also differ in their effects on organ lipids. Not all forms of fish oil may be equally digestible. Of four studies that compare bioavailability of the glyceryl ester form of fish oil vs. the ethyl ester form, two have concluded the natural glyceryl ester form is better, and the other two studies did not find a significant difference. No studies have shown the ethyl ester form to be superior, although it is cheaper to manufacture.
Krill
Krill oil is a source of omegaâ'3 fatty acids. The effect of krill oil, at a lower dose of EPA + DHA (62.8%), was demonstrated to be similar to that of fish oil on blood lipid levels and markers of inflammation in healthy humans. While not an endangered species, krill are a mainstay of the diets of many ocean-based species including whales, causing environmental and scientific concerns about their sustainability.
Plant sources
Table 1. ALA content as the percentage of the seed oil.
Table 2. ALA content as the percentage of the whole food.
Flaxseed (or linseed) (Linum usitatissimum) and its oil are perhaps the most widely available botanical source of the omegaâ'3 fatty acid ALA. Flaxseed oil consists of approximately 55% ALA, which makes it six times richer than most fish oils in omegaâ'3 fatty acids. A portion of this is converted by the body to EPA and DHA, though the actual converted percentage may differ between men and women.
In 2013 Rothamsted Research in the UK reported they had developed a genetically modified form of the plant Camelina that produced EPA and DHA. Oil from the seeds of this plant contained on average 11% EPA and 8% DHA in one development and 24% EPA in another.
Eggs
Eggs produced by hens fed a diet of greens and insects contain higher levels of omegaâ'3 fatty acids than those produced by chickens fed corn or soybeans. In addition to feeding chickens insects and greens, fish oils may be added to their diets to increase the omegaâ'3 fatty acid concentrations in eggs.
The addition of flax and canola seeds to the diets of chickens, both good sources of alpha-linolenic acid, increases the omegaâ'3 content of the eggs, predominantly DHA.
The addition of green algae or seaweed to the diets boosts the content of DHA and EPA, which are the forms of omegaâ'3 approved by the FDA for medical claims. A common consumer complaint is "Omegaâ'3 eggs can sometimes have a fishy taste if the hens are fed marine oils".
Meat
Omegaâ'3 fatty acids are formed in the chloroplasts of green leaves and algae. While seaweeds and algae are the source of omegaâ'3 fatty acids present in fish, grass is the source of omegaâ'3 fatty acids present in grass fed animals. When cattle are taken off omegaâ'3 fatty acid rich grass and shipped to a feedlot to be fattened on omegaâ'3 fatty acid deficient grain, they begin losing their store of this beneficial fat. Each day that an animal spends in the feedlot, the amount of omegaâ'3 fatty acids in its meat is diminished.
The omegaâ'6:omegaâ'3 ratio of grass-fed beef is about 2:1, making it a more useful source of omegaâ'3 than grain-fed beef, which usually has a ratio of 4:1.
In a 2009 joint study by the USDA and researchers at Clemson University in South Carolina, grass-fed beef was compared with grain-finished beef. The researchers found that grass-finished beef is higher in moisture content, 42.5% lower total lipid content, 54% lower in total fatty acids, 54% higher in beta-carotene, 288% higher in vitamin E (alpha-tocopherol), higher in the B-vitamins thiamin and riboflavin, higher in the minerals calcium, magnesium, and potassium, 193% higher in total omegaâ'3s, 117% higher in CLA (cis-9 trans-11, which is a potential cancer fighter), 90% higher in vaccenic acid (which can be transformed into CLA), lower in the saturated fats linked with heart disease, and has a healthier ratio of omegaâ'6 to omegaâ'3 fatty acids (1.65 vs 4.84). Protein and cholesterol content were equal.
In most countries, commercially available lamb is typically grass-fed, and thus higher in omegaâ'3 than other grain-fed or grain-finished meat sources. In the United States, lamb is often finished (i.e., fattened before slaughter) with grain, resulting in lower omegaâ'3.
The omegaâ'3 content of chicken meat may be enhanced by increasing the animals' dietary intake of grains high in omegaâ'3, such as flax, chia, and canola.
Kangaroo meat is also a source of omegaâ'3, with fillet and steak containing 74Â mg per 100Â g of raw meat.
Seal oil
Seal oil is a source of EPA, DPA, and DHA. According to Health Canada, it helps to support the development of the brain, eyes, and nerves in children up to 12 years of age. Like all seal products, it is not allowed to be imported into the European Union.
Other sources
A recent trend has been to fortify food with omegaâ'3 fatty acid supplements. Global food companies have launched omegaâ'3 fatty acid fortified bread, mayonnaise, pizza, yogurt, orange juice, children's pasta, milk, eggs, popcorn, confections, and infant formula.
The microalgae Crypthecodinium cohnii and Schizochytrium are rich sources of DHA but not EPA, and can be produced commercially in bioreactors. Oil from brown algae (kelp) is a source of EPA. The alga Nannochloropsis also has high levels of EPA.
In 2006 the Journal of Dairy Science published a study which found that butter made from the milk of grass-fed cows contains substantially more α-linolenic acid than butter made from the milk of cows that have limited access to pasture.
References
Further reading
External links
- University of Maryland Medical Center, Omegaâ'3 Fatty Acids