Carbohydrates of Physiologic Significance

2. Carbohydrates of Physiologic Significance CARBOHYDRATES ARE ALDEHYDE OR KETONE DERIVATIVES OF POLYHYDRIC ALCOHOLS (1) Monosaccharidesare those carbohydrates that cannot be hydrolyzed into simpler carbohydrates: They may be classified as trioses, tetroses, pentoses, hexoses, or heptoses, depending upon the number of carbon atoms; and as aldoses or ketoses depending upon whether they have an aldehyde or ketone group. Examples are listed in Table 13–1. (2) Disaccharides are condensation products of two monosaccharide units. Examples are maltose and sucrose. (3) Oligosaccharides are condensation products of two to ten monosaccharides; maltotriose* is an example. (4) Polysaccharides are condensation products of more than ten monosaccharide units; examples are the starches and dextrins, which may be linear or branched polymers. Polysaccharides are sometimes classified as hexosans or pentosans, depending upon the identity of the constituent monosaccharides

11. Anomers

16. Epimerisation

19. Important Disaccharides

21. starch

24. Glycosaminoglycans(mucopolysaccharides) are complex carbohydrates characterized by their content of amino sugars and uronic acids.When these chains are attached to a protein molecule, the result is a proteoglycan.Proteoglycans provide the ground or packing substance of connective tissues.

28. Structure of proteoglycanfrom cartilage

30. Structures of A, B,andOoligosaccharide antigen

31. Carbohydrates Can Be Linked to Proteins Through Asparagine (N-Linked) or Through Serine or Threonine (O-Linked) Residues

33. What are these moleculs ?

34. What are these moleculs?

35. Lipids of Physiologic Significance (1) relatively insoluble in water and (2) soluble in nonpolar solvents such as ether and chloroform.

36. LIPIDS ARE CLASSIFIED AS SIMPLEOR COMPLEX

37. Fatty Acids Are Named After Corresponding Hydrocarbons Saturated Fatty Acids Contain No Double Bonds Unsaturated Fatty Acids Contain One or More Double Bonds Fatty acids may be further subdivided as follows: (1) Monounsaturated (monoethenoid, monoenoic) acids, containing one double bond. (2) Polyunsaturated (polyethenoid, polyenoic) acids, containing two or more double bonds. (3) Eicosanoids: These compounds, derived from eicosa- (20-carbon) polyenoicfattyacids, comprise the prostanoids, leukotrienes (LTs), and lipoxins (LXs). Prostanoids include prostaglandins (PGs), prostacyclins (PGIs), and thromboxanes (TXs).

38. The General Structure of Fatty Acids • The general structure of a fatty acid is a long hydrocarbon chain with a carboxyl group on carbon 1 (C1).

39. CH3- methyl or omega end acid or alpha end -COOH = double bonds

40. A fatty acid (Palmitate 16:0) Hydrophilic carboxylate head Hydrophobic hydrocarbon tail

41. Space Filled Models of FFAs

42. Common unsaturated fatty acids

46. w-3 (n-3) unsaturated fatty acids ALA 18:3 (all cis) D9,12,15 alpha-linolenic acids EPA 20:5 (all cis) D5,8,11,14,17 DHA 22:6 (all cis) D4,7,10,13,16,19

47. Diagram Of A Triglyceride GLYCEROL fatty acids TRIGLYCERIDE

49. saturated = no double bonds Polyunsaturated = 2 or more double bonds

50. BIOACTIVE LIPIDS: MEMBRANE SPHINGOLIPIDS and GANGLIOSIDES