Module 4. Lipids

1. Module 4. Lipids Food Chemistry 2 ND Food Technology

2. Table of Contents • Introduction • Classification • Fatty acids • Gliserides • Phospholipids • Unsaponifiables • Emulsions & emulsifiers • Physical properties of oils & fats • Cocoa butter & confectionary fats • Heated fats - frying

3. 1. Introduction • Difficult to give definitions – too many different types – usually water-insoluble organic compounds found in biological systems • Either hydrophobic (non-polar) or amphipathic (polar and non-polar regions) • Types of lipids for domestic & industrial purposes • Oils, margarine & butter, dripping, lard, shortening, tallow, waxes • General characteristics: • Oily & greasy feel (leaves greasy spot on filter paper) • Not easily mix with water (float on water) • Dispersed in detergent, hot water or alcohol

4. 2. Classification • Origin • Animal • Mammal depot fat (lard, tallow), milk fat (ruminant), marine (fish oil) • Marine – eicosapentanoic (EPA), docosahexaenoic (DHA) – in tuna, sardines – mostly unsaturated – biomedical advantages for human body • Veg • Seed oils (canola), fruit coats (olive oil), kernel oils (coconut oil) • Visible / invisible • Visible – lard, butter, margarine, shortening, cooking oils • Invisible – fat in eggs, meat, poultry, fruits, veg, grain • Based on melting point: • Fats – solid / semisolid @ room temp (usually animal origin - margarine) • Oils – liquid (melting point) below room temp (usually plant origin - sunflower oil)

5. 2. Classification • Based on structure: Basic lipid components Quantitative Phospholipids Hexoses Sphingosine Sterols Glyserol Fatty acids Fatty alcohols Phosphoric acid amino alcohols Fatty aldehydes Sterol esters Mono-, di-, tri glyserides Cerebrosides Sphingomyelin Phosphatidyl esters Plasmalogens Glyceryl ether Waxes Ether esters

6. 3. Fatty acids • Simplest lipids – fatty acids, formula: R-COOH (R is a hydrocarbon chain, COOH is a carboxyl functional group) • Fatty acids differ from each other by: • Length of hydrocarbon tail • Degree of unsaturation (no. of double bonds) • Sat. are waxy at room temp. • Unsat. Are liquid at room temp. • Less double bonds, longer carbon tail → higher melting temp • Positions of double bonds • Essentiality – essential fatty acids (e.g. oleic, linoleic, linolenic) – not produced by body, only from plant origin – usually unsaturated • Common names – for frequently used fatty acids • IUPAC naming: • Carboxyl carbon named C-1, remaining carbons named sequentially • Carbon adjacent to carboxyl named , rest also followed by greek letters ( refers to carbon farthest from carboxyl group) • No carbon-carbon double bond – saturated, at least 1 double bond - unsaturated

7. 3. Fatty acids • IUPAC naming: • 1 double bond – monounsaturated, 2/more double bonds – polyunsaturated • Positions of double bonds indicated by Δn (n indicates the lower-numbered carbon of each double bond • Shorthand notation: uses 2 numbers seperated by colon, e.g. arachidonate: Eicosatetraenoate No. of C-atoms in fatty acid 20:4 Δ5,8,11,14 Common name Double bond positions No. of C-C double bonds

8. 3. Fatty acids • NB – draw structures if IUPAC name is given, Tables 2.2, 2.3, p37-38 • 2 types of double bonds: • Cis – Hydrogens on same side of bond – causes bending of hydrocarbon chains • Bending prevents close packing of hydrocarbons → cis unsaturated fats lower melting point • Trans – Hydrogens on opposite sides of bond - mostly saturated fats – higher melting point – more stable • Draw structures indicating difference between cis & trans!

9. 4. Gliserides • A 3-carbon alcohol – usually combines with fatty acids (esterification) • Glyseride also neutral lipid – do not carry any charge • When 1 carbon is esterified with fatty acid → monogliseride, when 2 C’s esterified with fatty acid → digliseride, etc. • Glyserol has plane of symmetry (2 of 4 constituents around central carbon is identical) - monogliserides – 2 structures – enantiomeres (chiral) (Fig. 2.7, p. 47) • Saponification number: the reaction of a product with a weak acid / base • The basis of the soap-making industry • Saponification number (S.N.) – index of degree of esterification • The higher the degree of esterification, the higher the S.N. • Used as quality control tool in oils & fats industry • Lipids that do not have gliserides will not saponify • Lipids can thus also be classified into saponifiable and non-saponifiable

10. 4. Gliserides • Hydrogenation: Chemical reaction by addition of hydrogen to double bonds of unsaturated acyl groups • For conversion of oils to fats (e.g. production of margarine • Results in a decreased susceptibility to oxidative deterioration • Reaction: gaseous hydrogen + liquid oil + solid catalyst (Ni) react under agitation in closed vessel • Hydrogenation not usually completed • May be selective (H2 added first to most unsaturated fatty acid) or non-selective • Selectivity increased by increasing hydrogenation temp • Iodine number: reaction of iodine with double bonds • Amount of iodine used indicates the amount of unsaturation remaining

11. 5. Phospholipids • Present in animal fats (lard, beef tallow), crude vegetable oils (cottonseed, corn, soybean oil), fish • Can be removed from fats & oils by refining, neutralization, bleaching, deoderization → oil free from phospholipid • Phospholipid removed from soybean oil used as emulsifier (in chocolates!) • Carry a charged group • Components: • Diglyseride (fatty acids of diglyseride can vary in different sources) • Esterified to phosphate group (derived from strong acid - H3PO4) • Esterified to a nitrogen-containing base (choline, inositol, ethanolamine, serine) • Draw structures of phosphatidylcholine (lecitin), phosphatidylethanolamine (cephalin), phosphatidylserine, phosphoinesitides (p. 52) • Amphipathic: • Hydrophobic (lipophilic) portion (tail) - due to long fatty acid tails of diglyseride • Hydrophilic portion (head) - due to charged base & phosphate also partially charged

12. 6. Unsaponifiables • Unsaponifiable fractions in fats are: • Sterols (most NB) • phytosterol in plants & cholesterol in animals • Solids with high melting points • Flat molecules with all trans bonds • Are compounds containing perihydrocyclo-penteno-phenanthrene nucleus + rings • Cholesterol structure (fig. 2.12, p. 54) • Also terpenic alcohols, aliphatic alcohols, squaline, hydrocarbons

13. 7. Emulsions & emulsifiers • Emulsion: a heterogeneous system consisting of one immiscible liquid intimately dispersed in another one, in the form of droplets with diameter over 0.1µm (milk, salad dressing) • Usually 2 phases – oil & water • If water continuous phase & oil dispersed phase – oil-in-water (O/W) type • If reversed – W/O type • Most common - phospholipids • Emulsifiers • surface agents that give stability to emulsions • Reduce interfacial tension between air-liquid & liquid-liquid interfaces • Due to molecular structure – contain hydrophilic (polar) & hydrophobic (non-polar) properties • Action of emulsifiers enhanced by stabilizers • Macromolecules e.g. starch & proteins • HLB system – numerical value for relative simultaneous attraction of emulsifier for water & oil (e.g. low HLB tend to form W/O emulsions) • Additional functions: modify physical characteristics of potato products, pasta, antifirming effect to improve shelf life of bread

14. RAPID + heat + volume LIQUID SOLID - volume - heat SLOW 8. Physical properties of oils & fats • Oils & fats – mixtures of triglyserides • Fats semisolid at room temp – plastic fats • Solid characteristic is result of presence of some crystallized triglyserides • Fats have range of triglyserides at different melting points • Fat liquifies upon heating (all triglyserides in liquid state) • Upon cooling - higher melting fractions become crystallized, insoluble - ↑ in solid fat content

15. 8. Physical properties of oils & fats • Above changes used to determine • melting point • Affected by chain length, unsaturation, configuration around double bond • solidification temp, • solid fat content • Dependent on temperature • Measure with dilatometer by melting expansion of fats upon heating – gives approximation of solid fats contents – reported as SFI • Lately – measure with NMR (nuclear magnetic resonance) – gives true solid fat contents – reported as SFC • (Look at Fig. 2.39, p. 85) • Cooling • Slow cooling – nucleation min, large crystals form • Supercooling – nucleation high, small / mixed crystals form • Fats do not form a glassy state like water does! • Crystal size - 0.1-0.5µm, sometimes 50µm • large crystals are grainy, 3 dim. Network, giving rigidity to product, holds the liquid portion of the fat

16. 8. Physical properties of oils & fats • Polymorphism: • Existence of more than 1 crystal form ( , , ‘) • Cause – different patterns of molecular packing in fat crystals • Plastic range of fats: • in a relationship between SFC and hardness, there is narrow range of solids that results in a product that neither too hard nor too soft, e.g. shortening (requires extended plastic range)

17. 9. Cocoa butter • Natural fat with unusual physical properties • High content of monounsaturated triglyserides • 3 major fatty acids – palmitic, oleic, stearic • Chocolate has desirable ‘snap’, glossy, melt smoothly in mouth, no greasiness on palate • High SFC at room temp, steep decline as temp reaches human body temp → al liquified, no waxiness • Special tempering procedure needed to produce desired polymorphic form • 50-60°C for 1h → cool to 25-27°C, to initiate crystallization → heat to 29-31°C → cool to 5-10°C • After long storage / extreme temperatures – chocolate shows ‘bloom’ – greyish covering on surface (unsuitable for consumption) caused by most stale crystal • Confectionary / specialty fats can replace cocoa butter – CBS’s & CBI’s

18. 10. Heated fats - frying • Heating during processing (120-270°C) involve hydrogenation, physical refining, deodorization • Changes: • Randomization of glyseride structure • Dimer formation • Cis-trans isomerization • Formation of conjugated fatty acids of polyunsaturated fatty acids • No air contact, thus no oxidization • Deep frying (food heated by immersion in hot oil) @ 160-195°C • Lower temp → takes too long & food takes up too much oil • High temp → oil deterioration (food & oil being fried)

19. 10. Heated fats - frying • (NB - Fig. 2.23, p. 68 / notes!) • Steam given off – remove volatile antioxidants, free fatty acids, other volatiles • Presence of steam – hydrolysis → produce free fatty acids & partial glyserides • Air contact – autooxidation, formation of degradation products (free radical & proxide mechanism • Lipid soluble colour components of food lipids leach into the frying oil • Final products – aldehydes, alcohols, ketones, which eventually polimerise • Suitability of fat for frying depends on ‘inherent stability’ • Calculated from level of unsaturated fatty acids & relative reaction rate with O2 • The higher the inherent stability, the less suitable for frying • Oils used for deep frying must be of high quality • Harsh conditions during frying • Must provide long shelf life of product