LIPIDS

1. LIPIDS Learning Objectives: • Understand lipid terminology and classifications • Understand the digestion and absorption of lipids • Learn about the function of lipids in the diet, and how they relate to health issues

2. WHAT ARE THE LIPIDS? • A broad range of organic compounds that dissolve easily in organic solvents, but range in their solubility in water • Hydrophobic – “water-fearing” • Lipophilic – “fat-loving”

3. CLASSES of LIPIDS SIMPLE LIPIDS • Fatty Acids • Triglycerides • Waxes COMPOUND LIPIDS • Phospholipids DERIVED LIPIDS • Sterols

4. FATTY ACIDS • Key building blocks for lipids • Chains of carbon atoms with a carboxyl group at one end, and a methyl group at the other • May be “free” or attached to another compound • Determine the characteristics of the fat

6. FATTY ACIDS CHAIN LENGTH • Short chain = less than 6 carbons • Medium chain = 6-10 carbons • Long chain = 12 or more carbons • The shorter the carbon chain, the more liquid the fatty acid is

7. FATTY ACIDS SATURATION • SATURATED FATTY ACID =If all the carbon atoms in the chain are joined with single bonds, and the remaining bonds are attached to hydrogen

9. FATTY ACIDS SATURATION • UNSATURATED FATTY ACID = If adjoining carbons are joined by double bonds

11. FATTY ACIDS UNSATURATED • One double bond = monounsaturated fatty acid • Two or more double bonds = poly- unsaturated fatty acid

13. FATTY ACIDS • Long-chain saturated fatty acids stack tightly and form solids at room temperature • Monounsaturated and polyunsaturated fatty acids don’t stack compactly and are liquid at room temperature • Short-chain saturated fatty acids are also liquid at room temperature • Figure 5.6

16. FATTY ACIDS TWO TYPES OF BOND FORMATION: • CIS - hydrogens on the carbons joined by a double bond are on the same side = the carbon chain is bent • TRANS – hydrogens on the carbons joined by a double bond are on the opposite side = the carbon chain is straighter

18. FATTY ACIDS • Omega-3 Fatty Acid – double bond at carbon 3 • Omega-6 Fatty Acid – double bond at carbon 6 • Omega-9 Fatty Acid – double bond at carbon 9 • *count carbons from the methyl (omega) end

19. Omega 3 • Omega 6 • Omega 9

20. FATTY ACIDS NOMENCLATURE • Alpha and Omega • 18:0, 18:1, etc.

21. FATTY ACIDS • Nonessential Fatty Acids – our body can make certain fatty acids so they are not required in the diet • Essential Fatty Acids – our bodies cannot make C-C double bonds before the 9th carbon from the methyl end, so we must get these fatty acids from our diet • EFAS = omega-6 linoleic acid & omega-3 alpha-linolenic acid

22. FATTY ACIDS • Omega-3: Alpha-Linolenic Acid (ALA), Eicosapentaenoic Acid (EPA), Docosahexaenoic Acid (DHA) • Omega-6: Linoleic Acid, Arachidonic Acid

23. Sources of Omega-3 Fatty Acids • Flaxseed, soybean oil, walnuts, some leafy dark green vegetables (ALA) • Fatty fish: salmon, tuna, and mackerel, fish oils (EPA and DHA)

24. Sources of Omega-6 Fatty Acids • Seeds, nuts, common vegetable oils: corn, safflower, cottonseed, sunflower seed, peanut (linoleic acid) • Meat (arachidonic acid)

26. FATTY ACIDS EICOSANOIDS • A small percentage of fatty acids become eicosanoids • They contain 20 or more carbons and are important in the inflammatory process, blood vessel dilation and constriction, and blood clotting

27. EICOSANOIDS Omega-6s • Linoleic acid is converted to arachidonic acid and eicosanoids are formed. • Overall effect: constricting blood vessels, promoting inflammation and blood clotting

28. EICOSANOIDS Omega-3s • Alpha-linolenic acid is converted to eicosapentanoic acid (EPA) and docosahexanoic acid (DHA) and eicosanoids are formed • Overall effect: dilating blood vessels, discouraging blood clotting, and reducing inflammation

29. TRIGLYCERIDES STRUCTURE • Triglyceride - three fatty acids attached to a glycerol backbone • Diglyceride – two fatty acids +glycerol • Monoglyceride – one fatty acid +glycerol

30. Triglyceride Fatty Acids

31. TRIGLYCERIDES FUNCTIONS • Major lipid in the body and diet • Stored fat provides about 60% of the body’s resting energy needs – compactly! • Insulation and protection • Carrier of fat-soluble compounds • Sensory qualities – flavor and texture

32. Compound Lipids: PHOSPHOLIPIDS • Contain a glycerol bonded to two fatty acids • The phosphate group is hydrophilic while the fatty acids groups are lipophilic • Because of this structure, phospholipids are ideal emulsifiers, and the perfect structure for cell membranes

34. Functions Cell Membranes • Phosholipids are the major component of cell membranes • Fatty acids, choline, as well as other substances are bound in the phospholipid layer Lipid Transport • In the stomach • In the intestine • In the bloodstream, and the lymphatic system

35. Protein Channel • Hydrophilic • Hydrophobic • Hydrophilic

36. Functions Emulsifiers Lecithins are used by the food industry to: • Combine foods that wouldn’t normally mix • Increase dispersion and reduce fat separation • Increase shelf-life, prolong flavor release, and prevent such products as gum from sticking to teeth

37. Phospholipids in Foods • A typical diet contains only about 2 grams per day • Lecithin (phosphatidylcholine) is the major phospholipid and is found in: • Liver, egg yolk, soybeans, peanuts, legumes, spinach, and wheat germ • Usually lost during food processing

38. Derived Lipids: STEROLS • Sterols are hydrocarbons with a multiple ring structure • They are hydrophobic and lipophilic • Contain no fatty acids • Cholesterol is the best-known sterol, found only in animal products

40. CHOLESTEROL: Functions • Major component of cell membranes (especially abundant in nerve and brain tissue) • Precursor molecule: Example - Vitamin D and estrogen are synthesized from cholesterol • Important in the synthesis of bile acids

41. CHOLESTEROL: Synthesis • The liver manufactures most of the cholesterol in our bodies • The intestine and all cells contribute a small amount • Overall, the body produces about 1000 mg per day • Serum cholesterol levels are homeostatically controlled (set-point)

42. DIGESTION • Mouth: chewing, lingual lipase, and dietary phospholipids • Stomach: gastric lipase • Small Intestine: CCK = bile, Secretin = pancreatic juice (pancreatic lipase) • Micelles: tiny emulsified fat packets that can enter intestinal cells (enterocytes)

43. DIGESTIBILITY • Abnormal to find more than 6 or 7% of ingested lipids still intact in the feces • Steatorrhea indicates fat malabsorption • Breast milk • Medium-Chain Trigylcerides • Short-Chain Fatty Acids

44. ABSORPTION • Most fat absorption takes place in the duodenum or jejunum – micelles carry monoglycerides and free fatty acids to the brush border where they diffuse into enterocytes • Bile salts are absorbed in the ileum (enterohepatic circulation) • Once in the enterocytes, monoglycerides and free fatty acids are reformed into triglycerides • The triglycerides, cholesterol, phospholipids, and protein carriers form LIPOPROTEIN

45. ABSORPTION • Once these lipoproteins leave the cell, they become CHYLOMICRONS and enter the lymph system • MCTs, short-chain fatty acids and glycerol are absorbed directly into bloodstream. They do not enter the lymph system. • Cholesterol and other sterols are poorly absorbed. Overall, about 50% of dietary cholesterol is absorbed. • Dietary fat increases cholesterol absorption • Fiber (especially soluble fiber) and phytosterols decrease cholesterol absorption

47. triglycerides

48. Lipids in the Body • Chylomicrons • Very-Low-Density Lipoprotein • Intermediate-Density Lipoprotein • Low-Density Lipoprotein • High-Density Lipoprotein

49. Chylomicrons are lipoproteins

50. Heart Disease • More than 58 million Americans have at least one form of CVD – stroke, hypertension, or coronary heart disease • 1 in 9 women, and 1 in 6 men aged 45-64 years of age have some form of heart disease • Myocardial Infarction (heart attack) is the leading cause of death in American men and women