LIPIDS (TG).ppt
- 1. Definition Classification Function Structure and properties of Triglyceride 10-10-2011
- 2. Lipids may be defined as organic substances which are relatively insoluble in water, but freely soluble in nonpolar organic solvents like benzene, chloroform, ether, acetone etc.
- 3. According to Bloor, lipids are compounds having the following characteristics: Insoluble in water Solubility in one or more organic solvents, such as ether, chloroform, benzene, acetone etc Some relationship to the fatty acids as esters either actual or potential Possibility of utilization by living organisms
- 4. Simple lipids Compound lipids Derived lipids Miscellaneous Waxes Fat & Oils (Triacyglycerols) Phospholipids Glycolipids Lipoproteins Other complex lipids Fatty acids Alcohols Mono & Diacylglycerols Carotenoids Squalene Hydrocarbons
- 5. Storage form of energy (Triacylglycerol) Structural components of biomembranes (phospholipids & cholesterol) Metabolic regulators (steroid hormones & prostaglandins) Act as surfactants, detergents & emulsifying agents
- 6. Act as electric insulators in neurons Provide insulation against changes in external temperature Give shape & contour to the body Protect internal organs by providing a cushioning effect (pads of fat) Help in absorption of fat soluble vitamins (A,D,E & K) Improve taste & palatability of food
- 7. Esters of fatty acids with glycerol or other higher alcohols. Simple lipids are: waxes & triacylglycerols Waxes: Esters of fatty acids with higher monohydroxy aliphatic alcohols. Cetyl alcohol (C16H33OH) is most commonly found in waxes
- 10. CH2 CH O CH2 O O C C C O O O CH2(CH2)13CH3 CH2(CH2)13CH3 CH2(CH2)13CH3 Glycerol backbone Ester bonds Fatty acids ( palmitic acid) Triacylglycerol
- 11. Oils • Liquids at 20oC • contain a higher proportion of unsaturated fatty acids or short chain triglycerides. • Generally plant origin. Fats • solids at room temperature • contain mainly saturated long chain fatty acids • mainly of animal origin
- 12. Physical properties 1. Neutral fats colourless, odourless & tasteless substances. The colour & taste of some of the naturally occurring fats is due to extraneous substances. 2. Solubility: Insoluble in water but soluble in organic solvents 3. Specific gravity: less than 1.0
- 13. 4. Emulsification: Emulsions of fat may be made by shaking vigorously in water & by emulsifying agents such as gums, soaps & proteins which produce more stable emulsions. 5. Consistency: when the constituent fatty acids have a higher chain length & are predominantly saturated, hard fat is formed eg. Pig fat Fat containing medium chain triglycerides or unsaturated fatty acids are soft fats e.g. butter, coconut oil.
- 14. 1. Hydrolysis 2. Saponification 3. Rancidity 4. Additive reactions:
- 15. Hydrolysis with a strong base Triglycerides split into glycerol and the salts of fatty acids The salts of fatty acids are “soaps” KOH gives softer soaps Saponification
- 16. 3 + Na+ - O C (CH2)14CH3 O CH CH2 OH OH CH2 OH CH CH2 CH2 O O O C (CH2)16CH3 O C O (CH2)16CH3 (CH2)16CH3 C O + 3 NaOH salts of fatty acids (soaps) Saponification
- 17. Refers to the appearance of an unpleasant smell & taste for fats & oils. It occurs when fat & oils are exposed to air, moisture, light, bacteria etc. 1. Hydrolytic rancidity : due to partial hydrolysis of the TG molecules due to traces of hydrolytic enzymes present in naturally occurring fats & oils.
- 18. 2. Oxidative rancidity: is the partial oxidation of unsaturated fatty acids. This results in formation of unpleasant products such as dicarboxylic acids, aldehydes, ketone etc.
- 19. The unsaturated fatty acids present in neutral fat exhibits all the additive reactions i.e. hydrogenation, halogenation etc. Oils which is liquid at ordinary temperature, on hydrogenation become solidified.
- 20. CH CH2 CH2 O O O C O (CH2)5CH CH(CH2)7CH3 C O (CH2)5CH CH(CH2)7CH3 C O + (CH2)5CH CH(CH2)7CH3 H2 3 Ni
- 21. CH CH2 CH2 O O O C (CH2)14CH3 O C (CH2)14CH3 O C (CH2)14CH3 O Hydrogenation converts double bonds in oils to single bonds. The solid products are used to make margarine and other hydrogenated items.
- 22. Saponification number Acid number Iodine number Polenske number Reichert-Meissl number Acetyl number
- 23. Definition: Defined as the number of mg of KOH required to hydrolyse (saponify) one gram of fat or oil. Measure of the average molecular size of the fatty acids present. The value is higher for fats containing short chain fatty acids. Example: - Human fat : 195-200 - butter : 230-240 - coconut oil : 250-260 - Oleo-margarine : 195 or less
- 24. Defined as the number of mg of KOH required to neutralize the fatty acids in a gm of fat or oil. Significance: The acid number indicates the degree of rancidity of the given fat.
- 25. Defined as the number of grams of iodine absorbed by 100gm of fat or oil. Measure the degree of unsaturation of a fat The more the iodine number, the greater of unsaturation Useful in determination of quality of an oil or its freedom from adultration Example: Fat or oil Iodine number Coconut oil 7-10 butter 25-28 Olive oil 80-85 Linseed oil 175-202
- 26. Defined as the number of ml of 0.1 normal KOH required to neutrilize the insoluble fatty acids (those not volatile with steam distillation) from 5gm of fat.
- 27. Defined as the number of ml of 0.1N alkali required to neutrilize the soluble volatile fatty acids distilled from 5g of fat. Useful in testing the purity of butter since it contains a good concetration of volatile fatty acids (butyric, caproic & caprylic acid) Butter : 25-30 (RM)
- 28. Defined as the number of mg of KOH required to neutrilise the acetic acid obtained by saponification of 1gm of fat after it has acetylated. Measure of the number of –OH group present Example: Oils Acetyl number Castor oil 146-150 Cotton seed oil 21-25 Olive oil 10.5
- 30. Structure of fat