Post on 19-Dec-2014
description
Triglycerides and Chemistry of Fatty acids
CHM4201:SPECIAL TOPIC IN ORGANIC CHEMISTRY
Group Members:
Nur Fatihah binti Abas (154120)Faridah binti Sulaiman (154603)Wan Fatihah Nasuha binti Wan Nor (154115)
Lecturer’s Name:
Prof. Mawardi Rahmadi
Learning outcomes:
1) To understand about fatty acid and triglycerides.
2) To know the physical and chemical properties of fatty acid and triglycerides.
3) To distinguish between fatty acid and triglycerides.
Fatty Acids
• Long straight-chain carboxylic acids
▫no branching
• Most common chains range from 10–20 carbons in length
• Usually, an even number of carbons in the chain,
including the carboxyl carbon
• Can be saturated or unsaturated, but usually no other
functional groups present
▫Any fatty acid that cannot be synthesized by the body is
called an essential fatty acid
Structure of fatty acids
• A fatty acid is nothing more than a long C-H chain with a carboxyl group (COOH) on the end.
• The COOH gives it an acid property.
• The 3….dots represent the chain is very long.
Physical Properties of Fatty Acids
•Solubility>Longer chains
• more hydrophobic, less soluble.>Double bonds increase solubility.•Melting points
• Depend on chain length and saturation• Double bonds lead chain disorder and low melting
temperature.• Unsaturated FAs are solids at Room Temperature.
Fatty Acids•The most common fatty acids.
Unsaturated Fatty Acids
Saturated Fatty Acids
20:418:318:218:116:1
20:018:016:014:012:0
Carbon Atoms:Double Bonds
Melting Point(°C)
Common Name
-49-11-5161
7770635844
Arachidonic acidLinolenic acidLinoleic acidOleic acidPalmitoleic acid
Arachidic acidStearic acidPalmitic acidMyristic acidLauric acid
Higher mp
Lower mp
Types of fatty acids
• long-chain• medium-chain• short-chain
The Length of the Carbon
Chain
• saturated• unsaturated
The Degree of
Unsaturation
• omega-3 fatty acid• omega-6 fatty acid
The Location of Double
Bonds
Medium-chain Fatty Acid(6-10 carbons)
Long-chain Fatty Acid(12 or more carbons)
Short-chain Fatty Acid(less than 6 carbons)
The Length of the Carbon Chain
The Degree of
Unsaturation
saturated
Unsaturated(cis or trans
configuration)
monounsaturated
polyunsaturated
Saturated and Unsaturated FAs
•Saturated FAs have no double bonds. (C-C) Double bonds lower the melting temperature
•Unsaturated FAs have at least one double bond (C=C) in one of the fatty acids
Saturated Fatty Acid
All single bonds between carbons
Monounsaturated Fatty Acid
One carbon-carbon double bond
Polyunsaturated Fatty Acid
More than one carbon-carbon double bond
Structure
•Stearic acid: a typical saturated fatty acid with 18 carbons in the chain
•Oleic acid: a typical unsaturated fatty acid with 18 carbons in the chain
Cis-fatty acid: H’s on same side of the double bond; fold into U-like formation; naturally occurring.
Trans-fatty acid: H’s on opposite side of double bond; more linear; occur in partially hydrogenated foods
Location of Double Bonds
•Polyunsaturated fatty acid (PUFA) are identified by position of the double bond nearest the methyl end (CH3) of the carbon chain; this is described as a omega number.
• If PUFA has first double bond 3 carbons away from the methyl end => omega 3 FA
•6 carbons from methyl end => omega 6 FA
Omega-3
Omega-6
Fatty Acid Nomenclature
•Nomenclature reflects location of double bonds
•Also used are common names (e.g: oleic, stearic, palmitic)
•Linoleic is also known as 18:2 n-6•This means the FA is 18 carbons in length, has
2 double bonds, the first of which is on the 6th carbon
•Arachidonic => 20:4 n-6
Classification and Structure-Saturated Fatty Acids
Common Name Systematic Name Formula
Butyric acid n-butanoic
Caproic acid n-hexanoic
Caprylic acid n-octanoic
Capric acid n-decanoic
Lauric acid n-dodecanoic
CH3(CH2)2CO
OH
CH3(CH2)4CO
OH
CH3(CH2)6CO
OH
CH3(CH2)8CO
OH
CH3(CH2)10CO
OH
Common Name Systematic Name Formula
Myristic acid n-tetradecanoic
Palmitic acid n-hexadecanoic
Stearic acid n-octadecanoic
Arachidic acid n-eicosanoic
Behenic acid n-docosanoic
Lignoceric acid n-tetracosanoic
CH3(CH2)12CO
OH
CH3(CH2)14CO
OH
CH3(CH2)16CO
OH
CH3(CH2)18CO
OH
CH3(CH2)20CO
OH
CH3(CH2)22CO
OH
Naming for Unsaturated FAs
H C H 2 C H 2 C H 2 C H 2 C H 2 C H 2 C O H
O
C H 3 ( C H 2 ) 7 H C C 1 9
C 2 H
10 9 8 7 6 5 4 3 2 1
Δ 9, 10 - Octadecenoic acid
9 - Octadecenoic acid
Common Name of Fatty Acids
Common Name Systematic Name
Myristoleic 9-tetradecenoic acid
Palmitoleic 9-hexadecenoic acid
Oleic 9-octadecenoic acid
Vaccenic 11-octadecenoic acid
Erucic 13-docosenoic acid
Chemical Reactions of Fatty Acids
Esterification reacts fatty acids with alcohols to form esters and water
Fatty Acid Hydrolysis
•Acid Hydrolysis reverses esterification▫Fatty acids are produced from esters
Saponification•Saponification is the base-catalyzed hydrolysis of
an ester•Products of the reaction are
▫An alcohol ▫An ionized salt which is a soap
Soaps have a long uncharged hydrocarbon tail Also have a negatively charged carboxylate group at
end Form micelles that dissolve oil and dirt particles
Reaction at the Double Bond
•Hydrogenation is an addition reaction•Unsaturated fatty acids can be converted to
saturated fatty acids•Hydrogenation is used in the food industry
2 H2, Ni
CH3 CH2 C
O
OH16
CH2CH CH CH2 C
O
OHCH3 CH2 CH CH4 7
Hydrogenation
•An ester of glycerol with three fatty acids.
•Also known as triacylglycerols
•One type of lipid categorised as simple lipid.
Triglycerides
Structure of Triglycerides
•Glycerides are lipid esters•A triglyceride places fatty acid chains at each
alcohol group of the glycerol
CH2
CH
CH2
O
O
O CO
CO
CO
R1
R2
R3
Glycerolpart Fatty acid
chains
Glycerol
•Glycerol Always looks the same
•3 C’s with 3 OH’s and everything else H’s.
Formation of Triglycerides
Example of triglycerides▫Triglyceride derived from one molecule each of
palmitic acid, oleic acid, and stearic acid, the three most abundant fatty acids in the biological world.
CH2OC(CH2)14CH3
CH2OC(CH2)16CH3
CH3(CH2)7CH=CH(CH2)7COCH
O
O
O
oleate (18:1)
stearate (18:0)
palmitate (16:0)
Physical properties of triglycerides
•Physical properties depend on the fatty acid components.▫Melting point increases as the number of carbons in
its hydrocarbon chains increases and as the number of double bonds decreases.
▫Oils: Triglycerides rich in unsaturated fatty acids are generally liquid at room.
▫Fats: Triglycerides rich in saturated fatty acids are generally semisolids or solids at room temperature.
Physical properties of triglycerides
▫Hydrocarbon chains of saturated fatty acids can lie parallel with strong dispersion forces between their chains; they pack into well-ordered, compact crystalline forms and melt above room temperature.
▫Because of the cis configuration of the double bonds in unsaturated fatty acids, their hydrocarbon chains have a less ordered structure and dispersion forces between them are weaker; these triglycerides have melting points below room temperature.
Chemical Properties
Triglycerides have typical ester and alkene chemical properties as they are composed of these two groups:-
▫Saponification: replace H with salt from a strong base
▫Hydrolysis: produces the fatty acids and glycerol, a reverse of formation
▫Hydrogenation: saturates the double bonds
Triglyceride Reactions
•Triglycerides undergo three basic reactions•These reactions are identical to those studied in
carboxylic acids
Triglyceride
GlycerolFatty Acids
GlycerolFatty Acid Salts
More saturatedtriglyceride
H2O, H+
NaOH
H2, Ni
Hydrolysis
Saponification
Hydrogenation
QUIZ
What’s What?
•Identify the glycerol molecule
•The fatty acids
THANK YOU