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Frying J Pokorny, Prague Institute of Chemical Technology 12.1 Introduction Frying, especially deep fat frying, has become the most popular food prepara tion technology during the last five decades. The reason is that the preparation is easy even for less experienced cooks, the procedure is rapid, and the finished product is highly palatable. In the frying procedure, fat is the medium of heat transfer. Two main frying methods exist, namely shallow frying and deep frying. In case of shallow frying, the layer of frying oil is about 1-10mm thick in a pan and the fried food is only partially immersed; it has to be turned during the process to obtain an evenly cooked product. The frying takes about 5-10 min, and frying oil is used for greasing the food as it is cooking. The oil is not reused In case of deep frying, the layer of frying oil is 20-200mm thick or greater and the fried material is immersed in oil or floats on the surface. The frying again takes about 5-10min, depending on the dimensions of the food being fried and on the temperature. After frying, the food is removed and the frying oil is used again for the next frying. The duration of use depends mainly on the fryin medium, the technical equipment and on the food The increasing consumption of fried foods contributes to a high intake of fats and oils Because consumers wish to reduce their consumption of fats and oils pans are offered on the market that do not require any fat. When these are used the heat transfer medium is not oil and therefore the process should not be regarded as frying but as roasting. During frying, fat or oil is preheated to tem- peratures of 150-180C In contact with oil, fried food is heated rapidly in the surface layers to the temperature of the frying oil. The temperature reaches only 80-100C in inner layers
12 Frying J. Pokorny, Prague Institute of Chemical Technology ´ 12.1 Introduction Frying, especially deep fat frying, has become the most popular food preparation technology during the last five decades. The reason is that the preparation is easy even for less experienced cooks, the procedure is rapid, and the finished product is highly palatable. In the frying procedure, fat is the medium of heat transfer. Two main frying methods exist, namely shallow frying and deep frying. In case of shallow frying, the layer of frying oil is about 1–10 mm thick in a pan and the fried food is only partially immersed; it has to be turned during the process to obtain an evenly cooked product. The frying takes about 5–10 min, and frying oil is used for greasing the food as it is cooking. The oil is not reused. In case of deep frying, the layer of frying oil is 20–200 mm thick or greater and the fried material is immersed in oil or floats on the surface. The frying again takes about 5–10 min, depending on the dimensions of the food being fried and on the temperature. After frying, the food is removed and the frying oil is used again for the next frying. The duration of use depends mainly on the frying medium, the technical equipment and on the food. The increasing consumption of fried foods contributes to a high intake of fats and oils. Because consumers wish to reduce their consumption of fats and oils pans are offered on the market that do not require any fat. When these are used the heat transfer medium is not oil and therefore the process should not be regarded as frying but as roasting. During frying, fat or oil is preheated to temperatures of 150–180 °C. In contact with oil, fried food is heated rapidly in the surface layers to the temperature of the frying oil. The temperature reaches only 80–100 °C in inner layers
294 The nutrition handbook for food essons 12.2 Changes in frying oil 12.2.1 Types of reaction The oil is subject to three types of reaction during deep frying hydrolytic reactions oxidation reactions pyrolysis of oxidation products Triacylglycerols in frying oil are hydrolysed by steam produced from water in the fried product when it is in contact with the hot frying oil. As the two react ing partners are not miscible, the reaction is relatively slow, resulting in the for- mation of diacylglycerols and free fatty acids. Diacylglycerols are more polar and therefore their contact with water vapour is better; monoacylglycerols and free fatty acids are formed by further hydrolysis. Monoacylglycerols are rapidly hydrolysed into fatty acid and glycerol. Under deep frying conditions, glycerol is dehydrated into acrolein, which is very volatile and its vapours irritate the eyes The rate of oxidation reactions depends on the concentration of oxygen Oxygen present in the original frying oil is rapidly consumed, usually before the temperature of oil reaches the frying temperature. Additional oxygen can enter frying oil only through diffusion from air(Fujisaki et al, 2000). When contact with air is moderate the oxidation of the frying oil is slow. It is consumed for the destruction of natural antioxidants, and only when they are destroyed, tria- cylglycerols are oxidised, too. Hydroperoxides are formed as primary reaction products, but they are very unstable at high temperature so that their content rarely exceeds 1%0 Some components present in fried food affect the oxidation rate of frying oil (Pokorny, 1998). The oxidation rate could be reduced by addition of antioxidants even when they are less efficient than under storage conditions. Most synthetic antioxidants, such as BHT and BHA, are too volatile under frying so that they have only moderate activity. Gallates are more efficient in frying oils. Currently it is considered preferable to use natural antioxidants. Tocopherols are present in most frying oils, and their addition is efficient (Gordon and Kourimska, 1995) Ascorbyl palmitate, citric acid and its esters are useful as synergists. Rosemary and sage resins were also found to be active in frying oils( Che Man and Tan, 1999). Oxidation reactions can be inhibited by polysiloxanes, which form a very thin layer on the surface of the frying oil, preventing the access of oxygen(Ohta et al, 1988). Because they are not resorbed in the intestines they are considered safe for human consumption The third group of reactions are secondary reactions of hydroperoxides. They are decomposed in three ways during frying Decomposition into nonvolatile products with the same number of carbon atoms, such as epoxides, ketones or hydroxylic compounds. When the con-
12.2 Changes in frying oil 12.2.1 Types of reaction The oil is subject to three types of reaction during deep frying: • hydrolytic reactions; • oxidation reactions; • pyrolysis of oxidation products. Triacylglycerols in frying oil are hydrolysed by steam produced from water in the fried product when it is in contact with the hot frying oil. As the two reacting partners are not miscible, the reaction is relatively slow, resulting in the formation of diacylglycerols and free fatty acids. Diacylglycerols are more polar and therefore their contact with water vapour is better; monoacylglycerols and free fatty acids are formed by further hydrolysis. Monoacylglycerols are rapidly hydrolysed into fatty acid and glycerol. Under deep frying conditions, glycerol is dehydrated into acrolein, which is very volatile and its vapours irritate the eyes and mucosa. The rate of oxidation reactions depends on the concentration of oxygen. Oxygen present in the original frying oil is rapidly consumed, usually before the temperature of oil reaches the frying temperature. Additional oxygen can enter frying oil only through diffusion from air (Fujisaki et al, 2000). When contact with air is moderate the oxidation of the frying oil is slow. It is consumed for the destruction of natural antioxidants, and only when they are destroyed, triacylglycerols are oxidised, too. Hydroperoxides are formed as primary reaction products, but they are very unstable at high temperature so that their content rarely exceeds 1%. Some components present in fried food affect the oxidation rate of frying oil (Pokorny´, 1998). The oxidation rate could be reduced by addition of antioxidants even when they are less efficient than under storage conditions. Most synthetic antioxidants, such as BHT and BHA, are too volatile under frying so that they have only moderate activity. Gallates are more efficient in frying oils. Currently it is considered preferable to use natural antioxidants. Tocopherols are present in most frying oils, and their addition is efficient (Gordon and Kourimska, 1995). Ascorbyl palmitate, citric acid and its esters are useful as synergists. Rosemary and sage resins were also found to be active in frying oils (Che Man and Tan, 1999). Oxidation reactions can be inhibited by polysiloxanes, which form a very thin layer on the surface of the frying oil, preventing the access of oxygen (Ohta et al, 1988). Because they are not resorbed in the intestines they are considered safe for human consumption. The third group of reactions are secondary reactions of hydroperoxides. They are decomposed in three ways during frying: • Decomposition into nonvolatile products with the same number of carbon atoms, such as epoxides, ketones or hydroxylic compounds. When the con- 294 The nutrition handbook for food processors
Frying 295 entration of these products(known as polar products)exceeds 25-27%o, the frying oil has to be replaced by fresh oil. At still higher levels of polar prod ucts, foaming takes place, which increases the contact area of oil with air, and thus the rate of oxidation Decomposition into volatile low-molecular weight compounds, such as alde hydes, alcohols, ketones or hydrocarbons. Some products possess a typical fried flavour, e.g. 2, 4-decadienals or unsaturated lactones. They are formed from linoleic acid bound in frying oil. Decomposition into high molecular weight compounds, usually dimers or trimers with fatty acid chains bonded by C-C, C-o-C or C-0-o-C bonds. The content of polymers is a good indicator of the degree of frying oil degra- dation. When their content reaches 10%o, used oil should be replaced by fresh oil Several methods are used for monitoring oil degradation during frying(Wu and Nawar, 1986). Used oil can be analysed with use of HPLC (for polar cor pounds)or HPSEC (for polymers): this is best done in combination with column chromatography(Sanchez- Muniz et al, 1993). Among other methods, the spec- trophotometry, determination of permittivity(dielectric constant), specific gravity or different colour tests can be used(Xu, 2000) o Frying oil can be used for a longer time if it is purified from insoluble parti s and polar substances by using a suitable adsorbent, such as magnesium sil icate(Perkins and Lamboni, 1998). Commercial products for this pupose are available(Gertz et al, 2000). Their combination with antioxidants is recom- mended (Kochhar, 2000). Membrane processes have been proposed for purifica tion of frying oil(Miyagi et al, 2001). 12.2.2 Choice of frying oil Frying oil should contain some bound linoleic acid to generate a fried flavour (Warner et al, 1997). Some oils, such as soybean, sunflower or rapeseed oils are rich in linoleic acid, but are rather unstable under frying conditions and should be replaced very often by fresh oil, which is expensive( Gertz et al, 2000). Low polyunsaturated oils, such as olive oil, are highly priced Hydrogenated veget able oils are more stable but are objectionable because of the content of trans unsaturated fatty acids. Pork lard is an excellent frying medium from the standpoint of sensory value, but there are objections because of its high content of saturated fatty acids and of cholesterol. The best choice are high-oleic low polyenoic modified vegetable oils, such as fractionated palm oil, 1. e. the palm olein fraction( Che Man and Hussin, 1998), modified soybean, sunfower, rape seed, peanut, and even linseed oil. If they contain 3-10% linoleic acid, they still produce an attractive fried flavour and are sufficiently stable on frying. A problem is their availability on the market
centration of these products (known as polar products) exceeds 25–27%, the frying oil has to be replaced by fresh oil. At still higher levels of polar products, foaming takes place, which increases the contact area of oil with air, and thus the rate of oxidation. • Decomposition into volatile low-molecular weight compounds, such as aldehydes, alcohols, ketones or hydrocarbons. Some products possess a typical fried flavour, e.g. 2,4-decadienals or unsaturated lactones. They are formed from linoleic acid bound in frying oil. • Decomposition into high molecular weight compounds, usually dimers or trimers with fatty acid chains bonded by C–C, C–O–C or C–O–O–C bonds. The content of polymers is a good indicator of the degree of frying oil degradation. When their content reaches 10%, used oil should be replaced by fresh oil. Several methods are used for monitoring oil degradation during frying (Wu and Nawar, 1986). Used oil can be analysed with use of HPLC (for polar compounds) or HPSEC (for polymers); this is best done in combination with column chromatography (Sánchez-Muniz et al, 1993). Among other methods, the spectrophotometry, determination of permittivity (dielectric constant), specific gravity or different colour tests can be used (Xu, 2000). Frying oil can be used for a longer time if it is purified from insoluble particles and polar substances by using a suitable adsorbent, such as magnesium silicate (Perkins and Lamboni, 1998). Commercial products for this pupose are available (Gertz et al, 2000). Their combination with antioxidants is recommended (Kochhar, 2000). Membrane processes have been proposed for purification of frying oil (Miyagi et al, 2001). 12.2.2 Choice of frying oil Frying oil should contain some bound linoleic acid to generate a fried flavour (Warner et al, 1997). Some oils, such as soybean, sunflower or rapeseed oils are rich in linoleic acid, but are rather unstable under frying conditions and should be replaced very often by fresh oil, which is expensive (Gertz et al, 2000). Low polyunsaturated oils, such as olive oil, are highly priced. Hydrogenated vegetable oils are more stable but are objectionable because of the content of transunsaturated fatty acids. Pork lard is an excellent frying medium from the standpoint of sensory value, but there are objections because of its high content of saturated fatty acids and of cholesterol. The best choice are high-oleic lowpolyenoic modified vegetable oils, such as fractionated palm oil, i.e. the palm olein fraction (Che Man and Hussin, 1998), modified soybean, sunflower, rapeseed, peanut, and even linseed oil. If they contain 3–10% linoleic acid, they still produce an attractive fried flavour and are sufficiently stable on frying. A problem is their availability on the market. Frying 295
96 The nutrition handbook for food processors 12.3 Impact of deep frying on nutrients The following main changes occur in the frying process(Fillion and Henry, 1998) Mass transfer between frying oil and fried food Thermal decomposition of nutrients and antinutritional substances in fried Interaction between fried food components and oxidation products of fried oil (Dobarganes et al, 2000) 12.3.1 Impact of frying on main nutrients The main change in the food composition during frying is the loss of water and its replacement with frying oil. Most foods(other than nuts) contain water as their major component. In contact with hot frying oil, water is rapidly converted into steam, at least in the surface layer of fried material. The temperature of inner layers does not exceed the boiling point of water so that water losses are only moderate paces left in fried food after water evaporation are filled with frying oil (Pinthus et al, 1995). This process increases the available energy content of the product and because the energy intake in the diet is too high in many countries, it is desirable to reduce the absorption of frying oil. This may be achieved by drying pieces of food on the surface before immersion into oil(Baumann and Escher, 1995). Another way is to produce a crust on the surface of fried pieces, which prevents water losses and oil uptake, and preserves juiciness in fried mate- rial(Ateba and Mittal, 1994). It is possible to cover the surface with batter or various other preparations, such as cellulose derivatives(Priya et al, 1996). The oil absorption can be reduced by half using these procedures. The oil removed by absorption into fried food should be replenished by fresh oil from time to time in order to keep the volume of frying oil constant hanges in nutritional value depend not only on the amount of absorbed frying oil, but also on its composition. If fresh edible oil is used, the contents of essen- tial fatty acids and tocopherols in fried food rise. If food is fried in oil used for a longer time, the content of essential fatty acids and tocopherols becomes low so that the increase in nutritional value, due to absorbed oil, is not significant. On the contrary, such antinutritional products as polar lipids and polymers are absorbed with used frying oil. fried food is stored, even under refrigeration, the thin layer of frying oil on the surface is autoxidized, especially in case of oil rich in pe acids(Warner et al, 1994). Fried food should be stored either in vacuum or an inert gas or protected by antioxidants. If fat-rich food is fried such as bacon, sausages or fat fishes, some fat origi nally present in food is released into frying oil. Eicosapentaenoic and docosa- hexaenoic acids were detected in oils used for frying fish like sardines ( Sanchez-Muniz et al, 1992). Cholesterol may also be extracted into frying oil
12.3 Impact of deep frying on nutrients The following main changes occur in the frying process (Fillion and Henry, 1998): • Mass transfer between frying oil and fried food; • Thermal decomposition of nutrients and antinutritional substances in fried food; • Interaction between fried food components and oxidation products of fried oil (Dobarganes et al, 2000). 12.3.1 Impact of frying on main nutrients The main change in the food composition during frying is the loss of water and its replacement with frying oil. Most foods (other than nuts) contain water as their major component. In contact with hot frying oil, water is rapidly converted into steam, at least in the surface layer of fried material. The temperature of inner layers does not exceed the boiling point of water so that water losses are only moderate. Spaces left in fried food after water evaporation are filled with frying oil (Pinthus et al, 1995). This process increases the available energy content of the product and because the energy intake in the diet is too high in many countries, it is desirable to reduce the absorption of frying oil. This may be achieved by drying pieces of food on the surface before immersion into oil (Baumann and Escher, 1995). Another way is to produce a crust on the surface of fried pieces, which prevents water losses and oil uptake, and preserves juiciness in fried material (Ateba and Mittal, 1994). It is possible to cover the surface with batter or various other preparations, such as cellulose derivatives (Priya et al, 1996). The oil absorption can be reduced by half using these procedures. The oil removed by absorption into fried food should be replenished by fresh oil from time to time in order to keep the volume of frying oil constant. Changes in nutritional value depend not only on the amount of absorbed frying oil, but also on its composition. If fresh edible oil is used, the contents of essential fatty acids and tocopherols in fried food rise. If food is fried in oil used for a longer time, the content of essential fatty acids and tocopherols becomes low, so that the increase in nutritional value, due to absorbed oil, is not significant. On the contrary, such antinutritional products as polar lipids and polymers are absorbed with used frying oil. If fried food is stored, even under refrigeration, the thin layer of frying oil on the surface is autoxidized, especially in case of oil rich in polyunsaturated fatty acids (Warner et al, 1994). Fried food should be stored either in vacuum or an inert gas or protected by antioxidants. If fat-rich food is fried, such as bacon, sausages or fat fishes, some fat originally present in food is released into frying oil. Eicosapentaenoic and docosahexaenoic acids were detected in oils used for frying fish like sardines (Sánchez-Muniz et al, 1992). Cholesterol may also be extracted into frying oil. 296 The nutrition handbook for food processors
Frying 297 If plant foods are subsequently fried in the same oil, cholesterol or fish fatty acid may be absorbed Lipids present in food are decomposed only to a small extent, including high unsaturated fish oils. It is due to short frying time and limited access of oxygen Based on dry matter content, the concentration of most nutrients is reduced dur- ing frying, as the original nutrients are diluted with absorbed frying oil. Starch and non-starch carbohydrates are partially destroyed during frying, and starch lipid complexes are formed(Thed and Phillips, 1995). The fraction of resistant (undigestible) starch changes during the operation(Parchure and Kulkarni, 1997) Sucrose is hydrolysed into glucose and fructose, which are destroyed by heating. mostly by Maillard or caramelisation reactions. Proteins are rapidly denaturated in surface layers of food particles, more slowly in inner layers than on the surface. Enzymes get nearly completely deactivated. The availability of proteins in humans is usually reduced by fryin (Fukuda et al, 1989), especially on the surface(Pokorny et al, 1992). Some essen- tial amino acids are destroyed, such as lysine or tryptophan(Ribarova et al, 1994) If protein comes into contact with the hot walls of the frying pan above the oil level, it is dehydrated and pyrolysed into polycyclic aromatic compounds (Overvik et al, 1989) 12.3.2 Impact of frying on micronutrients Vitamins are relatively labile substances. Tocopherols are decomposed by oxi dation reactions so that frying oil used for repeated frying contains only traces of tocopherols. Ascorbic acid is also destroyed by mechanisms similar to those of reducing sugars. The Vitamin B complex is also substantially damaged by frying(Kimura et al, 1991; Olds et al, 1993). Carotenes and carotenoid pigments e easily oxidised and polymerised(Speek et al, 1988), which is visible from colour changes. Mineral components are also affected. Iron and other heavy metals are mostly bound in complexes, which are partially decomposed during frying, and metal ions may contaminate frying oil by decreasing its resistance to oxidation. Ferric ions are less digestible than iron in haem complexes. Sodium and potassium chlo- rides present in food are very slightly dissociated, and sodium and potassium ions react with free fatty acids forming soaps(Blumenthal and Stockler, 1986). Soaps are surface active agents, increasing foaming and thus accelerating oxidation Volatile mineral components, such as selenium or mercury derivatives, are par tially lost at high frying temperatures. Many foods contain antinutritional or even toxic substances, which are often partially decomposed or evaporated during frying 12.3.3 Changes in sensory characteristics Frying imparts a distinctive flavour to fried products; some flavours are common to all fried foods and some are additional and, specific for particular products, e.g. french fries(Wagner and Grosch, 1998)
If plant foods are subsequently fried in the same oil, cholesterol or fish fatty acids may be absorbed. Lipids present in food are decomposed only to a small extent, including high unsaturated fish oils. It is due to short frying time and limited access of oxygen. Based on dry matter content, the concentration of most nutrients is reduced during frying, as the original nutrients are diluted with absorbed frying oil. Starch and non-starch carbohydrates are partially destroyed during frying, and starchlipid complexes are formed (Thed and Phillips, 1995). The fraction of resistant (undigestible) starch changes during the operation (Parchure and Kulkarni, 1997). Sucrose is hydrolysed into glucose and fructose, which are destroyed by heating, mostly by Maillard or caramelisation reactions. Proteins are rapidly denaturated in surface layers of food particles, more slowly in inner layers than on the surface. Enzymes get nearly completely deactivated. The availability of proteins in humans is usually reduced by frying (Fukuda et al, 1989), especially on the surface (Pokorny´ et al, 1992). Some essential amino acids are destroyed, such as lysine or tryptophan (Ribarova et al, 1994). If protein comes into contact with the hot walls of the frying pan above the oil level, it is dehydrated and pyrolysed into polycyclic aromatic compounds (Övervik et al, 1989). 12.3.2 Impact of frying on micronutrients Vitamins are relatively labile substances. Tocopherols are decomposed by oxidation reactions so that frying oil used for repeated frying contains only traces of tocopherols. Ascorbic acid is also destroyed by mechanisms similar to those of reducing sugars. The Vitamin B complex is also substantially damaged by frying (Kimura et al, 1991; Olds et al, 1993). Carotenes and carotenoid pigments are easily oxidised and polymerised (Speek et al, 1988), which is visible from colour changes. Mineral components are also affected. Iron and other heavy metals are mostly bound in complexes, which are partially decomposed during frying, and metal ions may contaminate frying oil by decreasing its resistance to oxidation. Ferric ions are less digestible than iron in haem complexes. Sodium and potassium chlorides present in food are very slightly dissociated, and sodium and potassium ions react with free fatty acids forming soaps (Blumenthal and Stockler, 1986). Soaps are surface active agents, increasing foaming and thus accelerating oxidation. Volatile mineral components, such as selenium or mercury derivatives, are partially lost at high frying temperatures. Many foods contain antinutritional or even toxic substances, which are often partially decomposed or evaporated during frying. 12.3.3 Changes in sensory characteristics Frying imparts a distinctive flavour to fried products; some flavours are common to all fried foods and some are additional and, specific for particular products, e.g. french fries (Wagner and Grosch, 1998). Frying 297
