Kategoriak: All - hydrocolloids - fruit - dairy

arabera Nur Aqilah Binti Rosli 8 years ago

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Gums and Stabilizers

Pectin serves as a critical stabilizer in various food products, including fruit juices, jams, and dairy items, providing desired textures and mouthfeels. It appears in two primary forms:

Gums and Stabilizers

Gums and Stabilizers

Cellulose Derivatives

Use in fried foods in which they create a barrier to oil absorption, retard loss of moisture & improve adhesion of batter
Methylcellulose (MC) & HPMC gel when heated & return to their original liquid viscosities when cooled
Use for thickening, suspending, stabilizing & modify flow characteristics
Very clear solution & stable over pH 4 to 10
Examples: carboxymethylcellulose (CMC), hydroxypropylmethylcellulose (HPMC)

Source of Raw Materials

peel of citrus fruits (lemon, lime, orange) or apple pomace
Konjac Glucomannan
Armophophallus konjac, K. Koch tuber
Seed of Carob Bean
Carragenan
Seaweed
Acacia Senegal L

Main Classes of Hydrocolloids

Extract from plant parts
Extract from tubers
Microbial gums
Extract from seaweeds
Extract from seed
Derivatives from exudation or sap of trees

Factors Affect Gum Properties

Distribution of Side Chains
Number of Side Chains
Type of Side Chains
Monosaccharide Composition
Molecular Weight

Hydrocolloid Structure

Substituent will determine whether the gums are non-ionic or ionic (there are no cationic food gums)
High MW polymers consisting long chain sugar units with substituent protruding from the main chain

Gellation of Hydrocolloids

Others will form gel under acidic pH + high sugar concentration, some require pH and alkaline pH.
Some hydrocolloids form gel on heating/cooling; some require the presence of cations
Thermally Irreversible Gelling Agents
Examples: alginate, starch, konjac, HM pectin
Thermoreversible Gelling Agents
Examples: Gelatin, agar, - carrageenan, -carrageenan, LM pectin, gellan gum, methyl cellulose, HPMC.
Gel formed on heating or cooling and the process is reversible

What is Hydrocolloids?

Functions
Secondary Functions

Formation of Film

Encapsulation

Control of Crystallization

Suspension of particulates

Stabilisation of emulsions

Primary Functions

Gelling or texturizing agents

Thickening agents

Food Hydrocolloids
A range of polyssacharides and proteins also known as 'water-soluble gum', 'stabilizers' , 'gums'

Xanthan Gum

Use for thickening, suspending and stabilizing effects
Pseudoplastic – thin with shear recover their initial viscosity when shearing stops – important for good flavour release, mouthfeel.
Viscosity remain unchanged across the temp range of 0 – 100 C & pH 1 – 13
Excellent stability to heat & pH
Completely soluble in cold water and hot water produce high viscosity at low conc.
Cellulosic backbone with trisaccharide branches attached to every other glucose unit in the main chain
Polysaccharides produced from fermentation of CHO substrate with Xanthomonas campestris

Guar Gum

Very stable from pH 4 -10.
Nongelling – used primarily as a viscosity builder, stabilizer water binder
More highly substituted than LBG – more soluble & hydrates fully in cold water giving high viscosity
A linear chain of mannose with single galactose units attached as side chains

Locust Bean Gum (LBG)

Canned foods, sauces, desserts, beverages, ice cream, processed meats
Primary functions: thickening, stabilization of emulsions, inhibition of syneresis
LBG is non-ionic – stable over the pH range of 3.5 to 11.0
Does not form a gel by itself – but can gel when combined with xanthan gum
Insoluble in cold water & must be heated dissolve to max viscosity develop when heated to ~95C, then cooled.
Galactomannan gums – made up of mannose & galactose in a ratio of 4:1
Come from seeds of the leguminose Ceratonia siliqua (indigenous to Mediterranean countries)

Carrageenan

Gelation of Carrageenan
Cations are important in carrageenan gelation. It is believed that Ca2+ and K+ ions form bridges between adjacent double helices through an electrostatic binding to two adjacent sulfate groups, thus stabilizing and strengthening the network.
In a concentration as low as 0.5%, K- and I-carrageenan have the ability to form thermoreversible gelsvupon cooling of hot aqueous solutions containing various cations (e.g., K+); L-carrageenan does not form gel
types of carrageenan
Iota (-carrageenan)
Lambda (-carrageenan)
Kappa (-carrageenan)
structure is composed of linear galactan polysaccharides that have a sulfate content of 15-40%.
highly refined extract of seaweed from the rhodophyta family.

Gum Arabic

Uses
Function as an emulsifier & stabilizer in soft drink emulsion (30% of world supply)
Promote stabilization of foam in beer
Encapsulation agent - to encapsulate volatile flavour compounds
confectionery products – to retard sugar crystallization & to promote emulsification
Least viscous & the most soluble of all the hydrocolloids – up to 55% solid concentration can be used
Dissolve easily in hot/cold water
Complex structure – polysaccharide containing galactose, rhamnose, arabinopyranose, arabinofuranose, glucuronic acid.

Alginate

Applications
Propylene (esterified glycol alginate form of alginate) has emulsification property – commonly used as stabilizer in emulsions like mayonnaise/low-fat mayonnaise.
In beverages, alginate act as a thickener & stabilizer – e.g., in dry mix fruit drinks, alginate gives fast hydration & mouthfeel.
excellent stabilizing effect in frozen products; e.g., used in ice cream to avoid crystallization,
can form gel in cold water in the presence of Ca ion; the gel is thermo-irreversible.
ratio of M:G & the MW of polymer determine the solution and gelling properties of alginate
Made up of blocks of Dmannuronic acid (M-blocks) & Lguluronicvacid (G-block)
Derived brown seaweedv(Laminaria hyperborea)

Pectin

Typical Pectins Used
In fermented /directly acidified dairy products
As stabiliser

in fruit juices fruit drink concentrates – also to provide a “natural mouthfeel”

Jams, jellies & preserves

Jam with suspended fruit particles requires rapidset HM pectin

primary gelling agent in jams & jellies

Types of Pectin
Low Methoxy Pectin (LMP)

ALMP – very Ca2+ reactive : assist gelation in low sugar fruit preparations, e.g. low-sugar jams & jellies

LMP – less Ca2+ reactive than ALMP:used as a thickening agent in yoghurt fruit

form gel with Ca but lose gelling ability asDE increase

Form gels in the presence of Ca2+, with a low solids content & wide pH range (1-7) [but soluble solids can be up to 85%]

DE < 50% — two sub-groups:Conventional low methoxyl pectin (LMP),Amidated low methoxyl pectin (ALMP)

High Methoxy Pectin (HMP)

As DE increase, ability to form gel increase

gels at high solids & low pH

not heat reversible

firm & short structure, clear & transparent, excellent flavour release

Setting times vary from 1-3 min to > 1 h

Commercial high methoxy pectin: DE 58% to 75%

Natural form is called protopectin (insoluble)
Derived from the peel of citrus fruits (lemon, lime,orange), apple pomace, sugar beet, sunflower heads