Difference between revisions of "Fatty acid" - New World Encyclopedia
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| − | '''Fatty acids''' are a class of compounds containing a long hydrocarbon chain and a terminal carboxylate group (-COOH). They have the general structure CH<sub>3</sub>(CH<sub>2</sub>)<sub>n</sub>COOH. Fatty acids belong to a | + | '''Fatty acids''' are a class of compounds containing a long hydrocarbon chain and a terminal carboxylate group (-COOH). They have the general structure CH<sub>3</sub>(CH<sub>2</sub>)<sub>n</sub>COOH. Fatty acids belong to a category of biological molecules called [[lipid]]s, which are generally water-insoluble but highly soluble in organic solvents. |
| − | Fatty acids function as fuel molecules and serve as components of many other classes of lipids, | + | Fatty acids function as fuel molecules and serve as components of many other classes of lipids, including [[triglyceride]]s (commonly known as “[[fats]]”) and [[phospholipid]]s, which are important building blocks of [[biological membrane]]s. Fatty acid derivatives also function as [[hormone]]s and intracellular messengers. |
| − | Fatty acids can be either [[saturated]] or unsaturated | + | Fatty acids can be either [[saturated]] or [[unsaturated]], a distinction that has important consequences for their chemical properties as well as the properties of other lipids with fatty acid components: |
| − | |||
| − | |||
| − | + | *''Saturated fatty acids'' have no double bonds between the carbon atoms of the fatty acid chain (as the carbons are fully “saturated” with hydrogen atoms). | |
| + | * ''Unsaturated fatty acids'' have one or more double bonds between carbon atoms. | ||
| + | |||
| + | Dietary fats rich in saturated fatty acids, which are common in some dairy products (such as butter), meat, and poultry, correlate with heart disease, stroke, and even some [[cancer]]s. High levels of [[#Types of fats and their chemical properties|saturated fats]] increase the amount of ''low-density lipoprotein'' (LDL), a transport molecule that carries fat and [[cholesterol]] from the [[liver]], while lowering the amount of ''high-density lipoprotein'' (HDL), which clears cholesterol from the bloodstream. | ||
| + | |||
| + | In contrast, foods with high percentages of monounsaturated and [[#Types of fats and their chemical properties|omega-3]] and [[omega-6]]* fatty acids may work to prevent heart disease by lowering the LDL:HDL ratio. A diet with vegetable oils, fatty fish (such as salmon), and nuts is important in this respect. | ||
| + | |||
| + | ''Trans fatty acids,'' a type of unsaturated fatty acid, are popular with manufacturers of processed foods because they are less vulnerable to rancidity and more solid at room [[temperature]] than ''cis'' fatty acids, which are more commonly found in nature. In essence, changing the chemical structure of the unsaturated fatty acids in plant oils helps manufacturers to simulate some of the properties of saturated fatty acids. However, trans fats reduce the fluidity (and functionality) of [[Cell (biology)|cell]] [[membrane]]s. Trans fats have been associated with many health problems, but their biochemistry is poorly understood. | ||
==Chemical structure of fatty acids== | ==Chemical structure of fatty acids== | ||
[[Image:Myristic-acid-3D-vdW.png|thumb|right|200px|A three-dimensional representation of the saturated fatty acid ''myristic acid''.]] | [[Image:Myristic-acid-3D-vdW.png|thumb|right|200px|A three-dimensional representation of the saturated fatty acid ''myristic acid''.]] | ||
| − | + | Fatty acids are distinguished by two important characteristics: (1) chain length and (2) degree of unsaturation. | |
===Chain length=== | ===Chain length=== | ||
Fatty acid chains in naturally occurring triglycerides are typically unbranched and range from 14 to 24 [[carbon]] atoms, with 16- and 18-carbon lengths being the most common. Fatty acids found in [[plant]]s and [[animal]]s are usually composed of an even number of carbon atoms, because their [[biosynthesis]] in these organisms involves [[acetyl-CoA]], a [[coenzyme]] carrying a two-carbon-atom group. [[Bacteria]], however, possess the ability to synthesize odd- and branched-chain fatty acids. Consequently, ruminant animal fat, such as in cattle, contains significant proportions of branched-chain fatty acids, due to the action of bacteria in the [[rumen]]*. | Fatty acid chains in naturally occurring triglycerides are typically unbranched and range from 14 to 24 [[carbon]] atoms, with 16- and 18-carbon lengths being the most common. Fatty acids found in [[plant]]s and [[animal]]s are usually composed of an even number of carbon atoms, because their [[biosynthesis]] in these organisms involves [[acetyl-CoA]], a [[coenzyme]] carrying a two-carbon-atom group. [[Bacteria]], however, possess the ability to synthesize odd- and branched-chain fatty acids. Consequently, ruminant animal fat, such as in cattle, contains significant proportions of branched-chain fatty acids, due to the action of bacteria in the [[rumen]]*. | ||
| − | Fatty acids with long chains are more susceptible to intermolecular forces of attraction (in this case, [[van der Waals forces]]*), raising their [[melting point]]*. Long chains also yield more [[energy]] per molecule when metabolized. | + | Fatty acids with long chains are more susceptible to intermolecular forces of attraction (in this case, [[van der Waals forces]]*), raising their [[melting point]]*. Long chains also yield more [[energy]] per molecule when metabolized. |
===Degree of unsaturation=== | ===Degree of unsaturation=== | ||
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====Saturated fatty acids==== | ====Saturated fatty acids==== | ||
| − | When each carbon atom in the chain is bonded to two hydrogen atoms, the fatty acid is said to be saturated. | + | When each carbon atom in the chain is bonded to two hydrogen atoms, the fatty acid is said to be saturated. Saturated fatty acids do not contain any double bonds between carbon atoms, because the carbon molecules are "saturated” with hydrogen; that is, they are bonded to the maximum number of hydrogen atoms. Saturated fatty acids form straight chains and, as a result, can be packed together very tightly, allowing living organisms to store chemical energy very densely. |
====Unsaturated fatty acids==== | ====Unsaturated fatty acids==== | ||
'''Monounsaturated fatty acids''' contain one double bond near the middle of the chain, creating a "kink" in the chain. One of the carbon atoms, bonded to only one hydrogen atom, forms a double bond with a neighboring carbon atom. | '''Monounsaturated fatty acids''' contain one double bond near the middle of the chain, creating a "kink" in the chain. One of the carbon atoms, bonded to only one hydrogen atom, forms a double bond with a neighboring carbon atom. | ||
| − | '''Polyunsaturated fatty acids''' may contain between two and six double bonds, resulting in multiple "kinks." | + | '''Polyunsaturated fatty acids''' may contain between two and six double bonds, resulting in multiple "kinks." As the degree of unsaturation increases, the melting points of polyunsaturated fatty acids become lower. |
| − | As the degree of unsaturation increases, the melting points of polyunsaturated fatty acids become lower. | ||
The double bonds in unsaturated fatty acids may occur either in a ''cis'' or ''trans'' [[isomer]], depending on the [[geometry]] of the double bond. In the ''cis'' conformation, the hydrogens are on the same side of the double bond, whereas in the ''trans'' conformation, they are on the opposite side. A ''trans'' double bond between [[carbon]] atoms makes the molecule less 'kinked' in comparison to fatty acids with ''cis'' double bonds. '''Trans fatty acids''' are characteristically produced during industrial hydrogenation of plant oils. Research suggests that amounts of trans fats correlate with circulatory diseases such as [[atherosclerosis]] and [[coronary heart disease]] more than the same amount of non-trans fats, for reasons that are not well understood. | The double bonds in unsaturated fatty acids may occur either in a ''cis'' or ''trans'' [[isomer]], depending on the [[geometry]] of the double bond. In the ''cis'' conformation, the hydrogens are on the same side of the double bond, whereas in the ''trans'' conformation, they are on the opposite side. A ''trans'' double bond between [[carbon]] atoms makes the molecule less 'kinked' in comparison to fatty acids with ''cis'' double bonds. '''Trans fatty acids''' are characteristically produced during industrial hydrogenation of plant oils. Research suggests that amounts of trans fats correlate with circulatory diseases such as [[atherosclerosis]] and [[coronary heart disease]] more than the same amount of non-trans fats, for reasons that are not well understood. | ||
==Fatty acids are important components of membrane lipids== | ==Fatty acids are important components of membrane lipids== | ||
| − | + | The differences in geometry between the various types of unsaturated fatty acids, as well as between saturated and unsaturated fatty acids, play an important role in the construction of biological structures. For example, the presence of short and/or unsaturated fatty-acid chains in phospholipids and [[glycolipid]]s generally enhances the fluidity of biological membranes, which are barriers that differentiate the cell from its environment, or define compartments within the cell (called [[organelle]]s). At reduced temperatures, some organisms may vary the type and relative amounts of fatty acids to maintain the flexibility of their membranes. These changes in membrane lipid components contribute to the survival of plants, bacteria, and hibernating animals during winter. | |
| − | |||
| − | The differences in geometry between the various types of unsaturated fatty acids, as well as between saturated and unsaturated fatty acids, play an important role in the construction of biological structures | ||
==Triglyceride is the storage form of fatty acids== | ==Triglyceride is the storage form of fatty acids== | ||
| − | Fatty acids are also important components of another type of lipid, | + | Fatty acids are also important components of another type of lipid, triglyceride (commonly known as ''fat''), which consist of three fatty acid chains bonded to a glycerol backbone. A triglyceride is an [[ester]]* of glycerol; i.e., a molecule formed from a condensation (water-releasing) reaction between the three hydroxyl (-OH) groups of glycerol and the carboxyl groups of the three fatty acid molecules. |
| − | Triglycerides play an important role in [[metabolism]] as highly concentrated energy stores; when metabolized, they yield more than twice as much energy as [[carbohydrate]]s and [[protein]]s (approximately 9 [[calorie|kcal]]/g versus 4 kcal/g). | + | Triglycerides play an important role in [[metabolism]] as highly concentrated energy stores; when metabolized, they yield more than twice as much energy as [[carbohydrate]]s and [[protein]]s (approximately 9 [[calorie|kcal]]/g versus 4 kcal/g). Some [[plant]] [[species]], such as [[avocado]]s, [[olive]]s, and [[nut]]s, have substantial amounts of triglycerides in [[seed]]s or [[fruit]]s that serve as energy reserves for the next generation. |
==Fatty acids function as a fuel source== | ==Fatty acids function as a fuel source== | ||
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==Fatty acid derivatives serve as hormones and intracellular messengers== | ==Fatty acid derivatives serve as hormones and intracellular messengers== | ||
| − | The human body can produce all but two of the fatty acids it needs. Since these two fatty acids | + | The human body can produce all but two of the fatty acids it needs for healthy functioning. Since these two fatty acids cannot be synthesized and must be supplied in the diet, they are called [[essential fatty acid]]s. The essential fatty acids for humans—[[linoleic acid]] and [[alpha-linolenic acid]]—are widely distributed in plant and fish oils. In the human body, essential fatty acids are primarily used to produce hormone-like substances that regulate a wide range of functions, including blood pressure, blood clotting, blood lipid levels, the immune response, and the inflammation response to injury infection. |
==Related topics== | ==Related topics== | ||
===Fatty acids in the diet=== | ===Fatty acids in the diet=== | ||
| − | Naturally occurring fats contain varying proportions of saturated and unsaturated fatty acids, which in turn determine their relative energy content and melting point. The following table | + | Naturally occurring fats contain varying proportions of saturated and unsaturated fatty acids, which in turn determine their relative energy content and melting point. The following table provides the fatty acid and cholesterol composition of some common dietary fats.<ref> |
{{cite book | {{cite book | ||
| title=McCance & Widdowson's The Composition of Foods | | title=McCance & Widdowson's The Composition of Foods | ||
| Line 108: | Line 110: | ||
===Nomenclature=== | ===Nomenclature=== | ||
| − | In [[IUPAC nomenclature]], the name of a fatty acid is derived from its parent hydrocarbon by substituting the suffix -''oic'' for the final -''e''. (In | + | In [[IUPAC nomenclature]], the name of a fatty acid is derived from its parent hydrocarbon by substituting the suffix -''oic'' for the final -''e''. (In common nomenclature, the suffix is usually -''ic''.) For example, octodecanoic acid (stearic acid) is so called because its parent hydrocarbon is octadecane. An 18-carbon fatty acid with one double bond is called octadec''enoic'' acid; one with two double bonds is octadeca''dienoic'' acid. |
| − | The notation [[Stearic acid|C18:0]] | + | The notation [[Stearic acid|C18:0]] signifies that the fatty acid chain consists of 18 carbon atoms and does not contain any double bonds, whereas the notation [[Oleic acid|C18:1]] describes an 18-carbon chain with one double bond. |
| − | There are two methods for describing the position of a double bond in the hydrocarbon chain: | + | There are two methods for describing the ''position'' of a double bond in the hydrocarbon chain: |
| − | * ''cis''/''trans''-Delta-''x'' or ''cis''/''trans''-Δ<sup>''x''</sup>: The double bond is located on the ''x''th carbon-carbon bond, counting from the carboxyl end. The ''cis'' or ''trans'' notation indicates whether the molecule is arranged in a cis or trans conformation. In the case of a molecule having more than one double bond, the notation is, for example, ''cis'',''cis''-Δ<sup>9</sup>,Δ<sup>12</sup>. | + | * ''cis''/''trans''-Delta-''x'' or ''cis''/''trans''-Δ<sup>''x''</sup>: The superscript indicates that the double bond is located on the ''x''th carbon-carbon bond, counting from the carboxyl end. The ''cis'' or ''trans'' notation indicates whether the molecule is arranged in a cis or trans conformation. In the case of a molecule having more than one double bond, the notation is, for example, ''cis'',''cis''-Δ<sup>9</sup>,Δ<sup>12</sup>. |
| − | * Omega-''x'' or ω-''x'' : Alternatively, the position of a double bond can be counted | + | * Omega-''x'' or ω-''x'' : Alternatively, the position of a double bond can be counted starting from the distal end, with the ω carbon (methyl carbon) as position one. Sometimes, the symbol ω is substituted by a lowercase letter ''n'', making the notation ''n''-6 or ''n''-3. |
==References== | ==References== | ||
Revision as of 21:59, 5 February 2007
| Types of Fats in Food |
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| See Also |
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Fatty acid Portal |
Fatty acids are a class of compounds containing a long hydrocarbon chain and a terminal carboxylate group (-COOH). They have the general structure CH3(CH2)nCOOH. Fatty acids belong to a category of biological molecules called lipids, which are generally water-insoluble but highly soluble in organic solvents.
Fatty acids function as fuel molecules and serve as components of many other classes of lipids, including triglycerides (commonly known as “fats”) and phospholipids, which are important building blocks of biological membranes. Fatty acid derivatives also function as hormones and intracellular messengers.
Fatty acids can be either saturated or unsaturated, a distinction that has important consequences for their chemical properties as well as the properties of other lipids with fatty acid components:
- Saturated fatty acids have no double bonds between the carbon atoms of the fatty acid chain (as the carbons are fully “saturated” with hydrogen atoms).
- Unsaturated fatty acids have one or more double bonds between carbon atoms.
Dietary fats rich in saturated fatty acids, which are common in some dairy products (such as butter), meat, and poultry, correlate with heart disease, stroke, and even some cancers. High levels of saturated fats increase the amount of low-density lipoprotein (LDL), a transport molecule that carries fat and cholesterol from the liver, while lowering the amount of high-density lipoprotein (HDL), which clears cholesterol from the bloodstream.
In contrast, foods with high percentages of monounsaturated and omega-3 and omega-6 fatty acids may work to prevent heart disease by lowering the LDL:HDL ratio. A diet with vegetable oils, fatty fish (such as salmon), and nuts is important in this respect.
Trans fatty acids, a type of unsaturated fatty acid, are popular with manufacturers of processed foods because they are less vulnerable to rancidity and more solid at room temperature than cis fatty acids, which are more commonly found in nature. In essence, changing the chemical structure of the unsaturated fatty acids in plant oils helps manufacturers to simulate some of the properties of saturated fatty acids. However, trans fats reduce the fluidity (and functionality) of cell membranes. Trans fats have been associated with many health problems, but their biochemistry is poorly understood.
Chemical structure of fatty acids
Fatty acids are distinguished by two important characteristics: (1) chain length and (2) degree of unsaturation.
Chain length
Fatty acid chains in naturally occurring triglycerides are typically unbranched and range from 14 to 24 carbon atoms, with 16- and 18-carbon lengths being the most common. Fatty acids found in plants and animals are usually composed of an even number of carbon atoms, because their biosynthesis in these organisms involves acetyl-CoA, a coenzyme carrying a two-carbon-atom group. Bacteria, however, possess the ability to synthesize odd- and branched-chain fatty acids. Consequently, ruminant animal fat, such as in cattle, contains significant proportions of branched-chain fatty acids, due to the action of bacteria in the rumen.
Fatty acids with long chains are more susceptible to intermolecular forces of attraction (in this case, van der Waals forces), raising their melting point. Long chains also yield more energy per molecule when metabolized.
Degree of unsaturation
Fatty acids may also differ in the number of hydrogen atoms that branch off of the chain of carbon atoms.
Saturated fatty acids
When each carbon atom in the chain is bonded to two hydrogen atoms, the fatty acid is said to be saturated. Saturated fatty acids do not contain any double bonds between carbon atoms, because the carbon molecules are "saturated” with hydrogen; that is, they are bonded to the maximum number of hydrogen atoms. Saturated fatty acids form straight chains and, as a result, can be packed together very tightly, allowing living organisms to store chemical energy very densely.
Unsaturated fatty acids
Monounsaturated fatty acids contain one double bond near the middle of the chain, creating a "kink" in the chain. One of the carbon atoms, bonded to only one hydrogen atom, forms a double bond with a neighboring carbon atom.
Polyunsaturated fatty acids may contain between two and six double bonds, resulting in multiple "kinks." As the degree of unsaturation increases, the melting points of polyunsaturated fatty acids become lower.
The double bonds in unsaturated fatty acids may occur either in a cis or trans isomer, depending on the geometry of the double bond. In the cis conformation, the hydrogens are on the same side of the double bond, whereas in the trans conformation, they are on the opposite side. A trans double bond between carbon atoms makes the molecule less 'kinked' in comparison to fatty acids with cis double bonds. Trans fatty acids are characteristically produced during industrial hydrogenation of plant oils. Research suggests that amounts of trans fats correlate with circulatory diseases such as atherosclerosis and coronary heart disease more than the same amount of non-trans fats, for reasons that are not well understood.
Fatty acids are important components of membrane lipids
The differences in geometry between the various types of unsaturated fatty acids, as well as between saturated and unsaturated fatty acids, play an important role in the construction of biological structures. For example, the presence of short and/or unsaturated fatty-acid chains in phospholipids and glycolipids generally enhances the fluidity of biological membranes, which are barriers that differentiate the cell from its environment, or define compartments within the cell (called organelles). At reduced temperatures, some organisms may vary the type and relative amounts of fatty acids to maintain the flexibility of their membranes. These changes in membrane lipid components contribute to the survival of plants, bacteria, and hibernating animals during winter.
Triglyceride is the storage form of fatty acids
Fatty acids are also important components of another type of lipid, triglyceride (commonly known as fat), which consist of three fatty acid chains bonded to a glycerol backbone. A triglyceride is an ester of glycerol; i.e., a molecule formed from a condensation (water-releasing) reaction between the three hydroxyl (-OH) groups of glycerol and the carboxyl groups of the three fatty acid molecules.
Triglycerides play an important role in metabolism as highly concentrated energy stores; when metabolized, they yield more than twice as much energy as carbohydrates and proteins (approximately 9 kcal/g versus 4 kcal/g). Some plant species, such as avocados, olives, and nuts, have substantial amounts of triglycerides in seeds or fruits that serve as energy reserves for the next generation.
Fatty acids function as a fuel source
When they are not attached to other molecules, fatty acids are known as free fatty acids. Free fatty acids are an important source of fuel for many tissues since they can yield relatively large quantities of ATP, the chemical energy currency of the cell. Although many cell types can use either glucose or fatty acids for fuel, heart and skeletal muscle prefer fatty acids. On the other hand, the brain cannot use fatty acids as a source of fuel. During starvation or periods of low carbohydrate intake, the brain relies instead on glucose or on ketone bodies produced by the liver from fatty acid metabolism.
Fatty acid derivatives serve as hormones and intracellular messengers
The human body can produce all but two of the fatty acids it needs for healthy functioning. Since these two fatty acids cannot be synthesized and must be supplied in the diet, they are called essential fatty acids. The essential fatty acids for humans—linoleic acid and alpha-linolenic acid—are widely distributed in plant and fish oils. In the human body, essential fatty acids are primarily used to produce hormone-like substances that regulate a wide range of functions, including blood pressure, blood clotting, blood lipid levels, the immune response, and the inflammation response to injury infection.
Related topics
Fatty acids in the diet
Naturally occurring fats contain varying proportions of saturated and unsaturated fatty acids, which in turn determine their relative energy content and melting point. The following table provides the fatty acid and cholesterol composition of some common dietary fats.[1] [2]
| Saturated | Monounsaturated | Polyunsaturated | Cholesterol | Vitamin E | |
|---|---|---|---|---|---|
| g/100g | g/100g | g/100g | mg/100g | mg/100g | |
| Animal fats | |||||
| Lard | 40.8 | 43.8 | 9.6 | 93 | 0.00 |
| Butter | 54.0 | 19.8 | 2.6 | 230 | 2.00 |
| Vegetable fats | |||||
| Coconut oil | 85.2 | 6.6 | 1.7 | 0 | .66 |
| Palm oil | 45.3 | 41.6 | 8.3 | 0 | 33.12 |
| Cottonseed oil | 25.5 | 21.3 | 48.1 | 0 | 42.77 |
| Wheat germ oil | 18.8 | 15.9 | 60.7 | 0 | 136.65 |
| Soya oil | 14.5 | 23.2 | 56.5 | 0 | 16.29 |
| Olive oil | 14.0 | 69.7 | 11.2 | 0 | 5.10 |
| Corn oil | 12.7 | 24.7 | 57.8 | 0 | 17.24 |
| Sunflower oil | 11.9 | 20.2 | 63.0 | 0 | 49.0 |
| Safflower oil | 10.2 | 12.6 | 72.1 | 0 | 40.68 |
| Rapeseed oil | 5.3 | 64.3 | 24.8 | 0 | 22.21 |
Nomenclature
In IUPAC nomenclature, the name of a fatty acid is derived from its parent hydrocarbon by substituting the suffix -oic for the final -e. (In common nomenclature, the suffix is usually -ic.) For example, octodecanoic acid (stearic acid) is so called because its parent hydrocarbon is octadecane. An 18-carbon fatty acid with one double bond is called octadecenoic acid; one with two double bonds is octadecadienoic acid.
The notation C18:0 signifies that the fatty acid chain consists of 18 carbon atoms and does not contain any double bonds, whereas the notation C18:1 describes an 18-carbon chain with one double bond.
There are two methods for describing the position of a double bond in the hydrocarbon chain:
- cis/trans-Delta-x or cis/trans-Δx: The superscript indicates that the double bond is located on the xth carbon-carbon bond, counting from the carboxyl end. The cis or trans notation indicates whether the molecule is arranged in a cis or trans conformation. In the case of a molecule having more than one double bond, the notation is, for example, cis,cis-Δ9,Δ12.
- Omega-x or ω-x : Alternatively, the position of a double bond can be counted starting from the distal end, with the ω carbon (methyl carbon) as position one. Sometimes, the symbol ω is substituted by a lowercase letter n, making the notation n-6 or n-3.
ReferencesISBN links support NWE through referral fees
- Krogh, D. 2005. Biology: A Guide to the Natural World, 3rd edition. Upper Saddle River, NJ: Pearson.
- Purves, W., D. Sadava, G. Orians, & H. C. Heller. 2004. Life: The Science of Biology, 7th edition. Sunderland, MA: Sinauer.
- Stryer, L. 1995. Biochemistry, 4th edition. New York, NY: W.H. Freeman.
External links
- Chemical Structure of Fats and Fatty Acids
- Plant Oils and Fats, from the Cyberlipid Center Web site
- Fat content and fatty acid composition of seed oils. Retrieved 2006-10-07. From Udo Erasmus' book, Fats that Heal Fats that Kill
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- ↑ Food Standards Agency (1991). "Fats and Oils", McCance & Widdowson's The Composition of Foods. Royal Society of Chemistry.
- ↑ Ted Altar. More Than You Wanted To Know About Fats/Oils. Sundance Natural Foods Online. Retrieved 2006-08-31.
