Oils & Fats - FST663 Chapter 1 PDF

Summary

This document provides a general overview of oils and fats, and related topics including rancidity, frying, and novel oils and fats. The chapter explores the chemical changes that occur during deep frying and tests for heat abuse. It also covers topics like oxidative rancidity, photooxidation, and enzymatic oxidation

Full Transcript

OILS & FATS
Topics in Oils & Fats:
1. Rancidity – Photooxidation, Flavour
reversion, Enzymatic oxidation.
2. Frying – changes during frying,
stability of frying oils/fats.
3. Novel Oils & Fats – including Fat
Replacers.

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Learning Objectives

Able to explain and differentiate various types of
oxidative rancidity reactions (photooxidation,
flavour reversion and enzymatic oxidation) in oils
and fats.
Able to explain the mechanism of frying,
changes in physical and chemical properties of
the oil.
Able to describe the accelerated tests for
measurement of oil stability.
Able to describe the various novel oils and fats.
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RANCIDITY DEVELOPMENT
IN OILS & FATS
RANCIDITY
Definition:
Rancidity is the development of
disagreeable flavour in oils/fats which are
produced through specific chemical
reactions
Types of Rancidity:
i. Hydrolytic Rancidity
ii. Oxidative Rancidity
 OXIDATIVE RANCIDITY
a) Common oxidative rancidity, known
as Autooxidation (FST603)
b) Photooxidation - New
c) Flavour reversion - New
d) Enzymatic oxidation - New

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 b) Photooxidation
Photooxidation = Light induced oxidation
(visible/UV light)
Occurs from the reactivity of an excited state of
O2, known as singlet state oxygen (1O2)
Normal O2 or ground state O2 = triplet state
oxygen (3O2)
When 3O2 is converted to 1O2, energy (E) is taken
up (at 92 kJ/mol)
In the excited state, oxygen is much >
reactive. The reactivity of 1O2 1500 x
greater than that of 3O2
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Sensitizers
Production of 1O2 requires the presence of a sensitizer
Cmpds that act as sensitizers are widely occuring food
components:
Chlorophylls, Mb, riboflavin (vit B2) & heavy metals
A Sensitizer is activated by light & can:
i) react directly with substrate (called type I
sensitizer)
OR
ii) activate O2 to the singlet state (called type II
sensitizer)
In both cases, unsaturated FA residues are converted to
Hydroperoxides
Temp has an impt effect on photoxidation rates, but
freezing does not completely prevent the R
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 Most Sensitizers promote type II oxidation Rs. In type II
Rs:
i) the sensitizer is transformed into the activated state by light
ii) the activated sensitizer then reacts with oxygen to form
singlet oxygen, 1O2
hν
sen sen* (activated state of sensitizer)
sen* + 3O2 sen + 1O2

The 1O2 can react directly with unsaturated FAs, as
follows:
1
O2 + RH ROOH (Hydroperoxide / HP)

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 Singlet O2 attack on oleate (18:1) produces 2 HPs, while
linoleate (18:2) yields 4 HPs
Photooxidation has no Induction period, but the R on 18:1 can
be quenched by carotenoids that can effectively compete for
the 1O2 & bring it back to 3O2
Thus, carotenoids are widely used as quenchers. Another
quencher is ascorbyl palmitate.
Phenolic antioxidants do not protect oils/fats from
photooxidation (eg flavonoids, BHA, BHT etc.)
Photooxidation affects our palm oil industry if oil palm fruits
are not harvested at the mature stage ie. the oil palm fruits still
contain chlorophylls (which act as sensitizers)

Note: combination of light & sensitizers is also present in many foods displayed in
transparent containers in brightly lit supermarkets. Eg: light- induced flavour
deterioration of milk fat & SB oil (corn oil is least susceptible to singlet O2 attack) 9
 O2 Uptake versus Time

IP = Induction Period

IP = Period of time
before O2 uptake 18:3
becomes appreciable & 18:2
before odours become 18:1
detectable
O2
uptake

time
10 IP
 c) Flavour Reversion
Term used to describe the development of objectionable/
off flavours in oils containing 18:3 (linolenic A)
SB oil & other fats/ oils containing 18:3 (eg. fish oil,
rapeseed oil) show the reversion phenomenon when
they are exposed to air
Reverted flavour is a particular type of oxidised flavour
that develops at comparatively low levels of oxidation
The off-flavours may develop in oils that have a PV of 1
or 2 (other oils may not become rancid until the PV
reaches 100)
Flavours usu. associated: grassy, fishy, painty, raw
bean/beany
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 Origin of flavours:
Volatile oxidation pdts resulting from the terminal
pentene radical of 18:3:
CH3−CH2−CH=CH−CH2−
Flavour descriptions used Crude, Processed & Reverted
SB oil:
State of SB oil Flavour
Crude Grassy, beany
Freshly Processed Sweet, pleasant, nutty
Reverted Grassy, beany, buttery,
melony, tallowy, painty,
fishy

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Egs of Reverted aldehyde flavour
cmpds (obtained from the breakdown of HPs):

3-cis-hexenal – pronounced green bean odour.
1st perceptible reversion flavour found
2-trans-hexenal – green, grassy
2-trans-nonenal – rancid
2-trans-6-cis-nonadienal – cucumber flavour

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d) Enzymatic oxidation (by lipoxygenase)
Old name for lipoxygenase = lipoxidase

Enz. catalyses oxidation of unsaturated oils/fats

Enz. mainly found in legumes, soybeans,other beans & peas.
Peanuts, wheat, potatoes & radishes contain a smaller amt of
this enz.
2 types of enzymes:
o Type 1 lipoxygenase catalyses only FFAs with a high stereo-
& regioselectivity.
o Only reacts with oils/fats in food only after FFAs have
been formed by lipase action

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Type 1 lipoxygenase

o Enz is highly specific & attacks cis-cis-1,4-pentadiene grp, (at
optimum pH ~9): 6 7 8
C1 −CH=CH−CH2−CH=CH−
(methyl end)
cis cis

o Type II lipoxygenase is 43 ppm, discard oil
*Polar Compounds = All non-TG components of oils, the majority of which
are secondary oxidation pdts such as aldehydes, ketones, epoxides,
dimers and hydrolysis pdts such as FFAs, MGs and DGs
**ACM = Surfactants that are formed from the oxidative reactions in the oil.
ACM surfactants are formed naturally during oil degradation reactions
through the combination of FAs with metal ions
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4. NOVEL OILS & FATS
a) Modified Oils
New types of oils modified through plant breeding &
genetic engineering
Oils with different FA composition are developed to
produce oils with:
i) improved nutritional props
ii) improved oxidative stability
iii) improved physical & technological props
1st oil modified was Canola Oil with improved oxidative
stability ie low-linolenic canola oil (previously low-euricic
acid)
Also: low-linolenic SB oil, high oleic sunflower &
safflower oils
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b) Fat Replacers
Substances that are meant to replace fat (9 kcal/g),
either completely/partly
The ideal fat replacer will create the attributes of fat &
significantly reduce the fat & calorie content of food
They may consist of:
2. Protein/CHO
1. Fat-like substances that
cmpds that mimic
are not absorbed/partly OR
absorbed by humans the gustatory
qualities of fats

Olestra (type 1 above)
Olestra is a sucrose polyester with 6-8 acyl (FA) grps
derived from SB, corn, cottonseed or sunflower FAs
It is not absorbed by the human digestive system &
thus yield NO calories
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Olestra (a mixture of hexa-, hepta-, and octaesters. R = FA, C12-C20)

Stachyose fatty acid polyester

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 Olestra is a type of Sugar Esters (SE)/Sugar fatty acid
esters (SFAE)
SFAE = Sugars or related cmpds esterified with fatty acids
by means of chemical/enzymatic methods
i) Low *DS (1-3): hydrophilic, digestable, absorbable. ∴
used as surfactants/emulsifiers
ii) High DS (4-14): lipophilic, non- digestable, non-
absorbable. ∴used as non-calorie fat replacers

*DS = degree
of substitution
Sucrose monostearate (emulsifier)
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 Application of Sucrose fatty acid ester
®
(Olestra )
As a frying medium in savoury snack foods
Can also be used in baked pdts, as dough conditioner or
in food flavours
Approved by US FDA in Jan 1996
Packets of food containing Olestra® must be labelled

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 CARBOHYDRATE-BASED FAT REPLACERS
Carbohydrate Polymers:

consists of modified food starches (also acts as anti-staling for baked
goods), dextrin & maltodextrins.

created from cereal, grain and/or starches such as corn, potato &
tapioca.

also include polydextrose such as Litesse.

needs more liquid to be added.

a gelling reaction occurs that provides a thick, creamy mouthfeel.
 CARBOHYDRATE-BASED FAT REPLACERS
Hydrocolloids:
Gums, gel and fibres

Provides thickness

Stabilising, emulsifying and/or providing structure to foods

2 common foods – pureed prunes and apple sauce

Add bulk and flavor in baking
 CARBOHYDRATE-BASED FAT REPLACERS
Polyols (sugar alcohols or bulking agents)
Provide volume or bulk

Eg.Sorbitol, isomalt, lactitol, xylitol, mannitol, maltitol and
hydrogenated starch hydrolysates

Characteristics – sweeteners, viscosity, crystallization, absorb
moisture, laxative

In low-calorie foods (