Hydrocolloids Structure and Properties The building blocks for structure Timothy J. Foster

ydrocolloids Structure and Properties The building blocks for structure Timothy J. Foster 18 month Meeting, Unilever Vlaardingen, March 29 31, 2010

Foams Manufactured Materials Emulsions Natural Materials This shows a layer of onion (Allium) cells.

Targeting ydrocolloids For Specific Applications: Approach Ingredient Material Properties Microstructure Process Oral Response

Packaging Distribution Storage Process Controlling Structure Process (mouth/gut) Controlled oral response (taste, flavour, texture) CONSTRUCTION DECONSTRUCTION Ingredient Designed texture/ appearance/ behaviour Ingredient (enzymes) In body functionality Interaction with body mucins (associative and new phase separation) Microstructure changes as a function of enzyme action Reconstruction Impact on / of starting materials / structures Re-assembly of structures as a function of digestion breakdown products and body secretions (micelle formation, delivery vehicles)

Single Biopolymer systems

ydrocolloid Structure/ Function Need: - define biopolymer primary structure - understand the nature of the interaction / rates - understand the solvent effects - measure material properties - test influence of primary structure variation and changes in environmental conditions on mechanical properties.

ydrocolloid Materials & Function Gelling Pectin Alginate Starch Agar Carrageenan Gellan Gelatin Milk proteins Egg proteins Thickening Pectin Alginate Starch LBG Guar gum Xanthan Emulsification Gelatin Milk proteins Egg proteins Soya proteins Pea proteins Gum Arabic

ydrocolloid Materials & Function Gelling Pectin Alginate Starch Agar Carrageenan Gellan Curdlan Celluosics Succinoglycan Scleroglucan Mixtures Thickening Pectin Alginate Starch LBG Guar Gum Xanthan lamda Carrageenan Cellulosics Beta Glucan Emulsification Gum Arabic Propylene glycol Alginate Sugarbeet pectin OSA starch

Protein structure A protein is a polymer of amino acids Primary structure amino acid sequence Secondary structure spatial structure through interactions between amino acids that are near along the amino acid chain (e.g. α helix, β sheet) Tertiary structure spatial structure through interactions between amino acids that are far away along the amino acid chain Quaternary structure association of different amino acid sequences (e.g. haemoglobin)

Protein Protein Structure: Backbone random coils beta sheet alpha helix Charge Determines Properties: Interfacial properties foams emulsions Gel forming

Structure of globular proteins β lactoglobulin (β lg) dimeric form at neutral p α lactalbumin (α la) bovine serum albumin (BSA) Color caption: α-elix β-sheets Cysteines

Turbid Gels

Carbohydrates what do they look like? O ow do they differ? 6C 2 O 5 4 1 O 3 2 O C 2 O O O Glucose Galactose C 2 O O C 2 O O O C 2 O O O O O O O O O O O O O O O Mannose O O O Gulose

Sugar Interactions Glycosidic linkage C 2 O O O O O O O O C 2 O O O O O C 2 O O O + 2 0 O O O C 2 O O O O

Polysaccharide Structure / Functionality

Botanical Sources of hydrocolloids starch, cellulose, galactomannans, pectin, gum arabic, karaya, tragacanth, beta glucan Seaweeds agar, carrageenan, alginate Animal gelatin, chitosan, hyaluronan Bacterial xanthan, gellan, dextran

Structural Features Linear (homo- and hetero-) Linear branched (homo- and hetero-) Branched (homo- and hetero-) Ordered helices (single, double, triple)

Polysaccharide thickeners The most efficient thickeners are; Linear, igh molecular mass Charged

Alternative ydrocolloids Cashew Gum Gum Karaya Okra Gum Caramania Gum (almond) Cassava Starch Chia Gum Cocoyam Flour Cowpea protein /starch Detarium microcarpum polysaccharide Flaxseed Gum sian-tsao Leaf gum (Taiwan/China) Lichenin Lupin Protein Moussul Gum (Plum) Portulaca Oleracea Psyllium gum Rice Flour Sassa Gum Soy Bean Polysaccharide Tara Gum Tropical Starches Yellow Mustard Gum Aloe Gum Gum Ghatti Oat gum Gum Tragacanth Cassia Gum Cherry Gum Chickpea Flour Combretum Gum Cyclodextrins Fenugreek gum Gleditsia macracantha Lesquerella Gum Lucaena galactomannan Manna Gum Opuntia Ficus Prickly Pear Quince seed gum Rye bran (beta d glucan / arabinoxylan) Sorghum flour Tamarind gum Tremella Aurantia Poysaccharide Yam

Typical Solution Properties

Need: ydrocolloid Structure/ Function - define biopolymer primary structure - understand the nature of the interaction / rates - understand the solvent effects - measure material properties - test influence of primary structure variation and changes in environmental conditions on mechanical properties.

Galactomannans Galactomannans include guar gum, locust bean gum (carob), fenugreek, cassia and tara gum. They have a high molecular mass (~ in excess of 500kDa) and consist of β 1,4 linked mannose residues with galactose units linked α 1,6. The M:G ratio is ~2:1 for guar, 3:1 for tara and 4:1 for locust bean gum. The galactose units are not evenly distributed along the chain.

LBG Structure / Functionality LBG can be fractionated wrt temperature of solubility. Cold soluble LBG (30C) has a higher G/ M than that soluble at high temperature (80C). LBG soluble at 80C has a galactose content of 16.6%, and gels at ambient temperature. Cold soluble LBG does NOT gel even when frozen & thawed. Not necessary for ice to be present, a non ionic interaction, dependent on solvent quality.

- The distribution of galactose sidechains is all important in dictating functionality. Gelation Rate Gelation Rate Gelation Rate 1.0 1.3 2.0 [LBG] 20 50 65 Sucrose (%) -8 10 Temperature - Self association is kinetically controlled as a function of the number of available junction zones

Load (KN). 0.06 0.05 0.04 0.03 0.02 0.01 Properties of ydrocolloids 3%Gelatin 3%Agar Typical polymer gel properties Dependent on Solvent quality, Polymer fine structure, Junction zone type / quantity 0 0 10 20 30 40 50 60 70 Strain (%).

Effect of Shear during Gelation: Fluid gel Particle formation Composite properties are dependent upon the number and size of particles produced. This in turn is dependent upon the polymer used, the polymer concentration and the shear field. G'(Pa) 1,000,000 100,000 Storage Modulus of Agar Gels Formed Quiescently and Under Shear Measurement Temperature = 10C Quiescent Sheared 10,000 1,000 100 POURABLE SPOONABLE SPREADABLE 10 0 1 2 3 4 5 [Agar]

Due to the colloidal nature of their properties they provide better dilution characteristics than their molecular counterparts. Viscosity (Pas) 1 Xanthan 0.1 Fluid gel 0.01 0.1 1 Level of Dilution

Mixed Biopolymers

Microstructure Aqueous-based two-phase systems o/w emulsion water-in-water emulsion 25 μm

Phase Separation phenomena is used in the creation of food products. 1.2 1.0 75% LBG / 25% PR 50% LBG / 50% PR 25% LBG / 75% PR 0.8 LBG (WT%) 0.6 0.4 0.2 * * * 0.0 0 2 4 6 8 10 12 14 16 18 20 MICELLAR CASEIN (WT%) Phase diagram measured at 5C

Aqueous-based two-phase systems Example: Aqueous mixture of gelatin and maltodextrin Top phase: Gelatin For charged polymers (polyelectrolytes) salt (type and concentration) as well as p are important parameters. Bottom phase: Maltodextrin

Influence of varying polymer characteristics

Phase separation driven by molecular ordering of one of the biopolymers. 12 10 Isothermal Binodal Evolution Owing to Ordering [L1] / % w/w 8 6 4 20 o C L1 / SA2 No Salt δ [SA2] / δt = 0.4 % / min 2 0 0 2 4 6 8 10 12 14 [SA2] / % w/w Schematic phase diagram showing the binodal as a function of ordering at 20 C

% elix % elix 16 14 12 10 8 6 4 2 0 16 14 12 10 8 6 4 2 20 o C % elix % elix 2 4 6 8 10 25 o C % elix Turbidity t / min Turbidity Turbidity 1.5 1.0 0.5 0.0 1.5 1.0 0.5 τ / cm -1 τ / cm -1 Process effects Structure induced phase separation. Measure of gelatin helices required to induce phase separation in a 4% L1e:4% SA2 mixture, in water, when quenched to 20 o C (top) and 25 o C (bottom). Morphology when quenched to 20 o C. 1min 4min 29min 0 0.0 10 20 30 40 50 t / min

Process effects on mixed biopolymer systems. Effect of shear during cooling / gelation of the gelatin Gelling biopolymer forms the dispersed phase.

Structures based on aqueous-based two-phase systems Scheme developed by Tolstoguzov * * V Tolstoguzov Journal of Texture Studies 11, 3 (1980) 199-215

Gel particle suspensions Modification of (shear) rheology: Effect of fibre alignment 10 relative viscosity 50 μm Dispersed phase volume: 20% 1 0.01 0.1 1 10 100 shear stress [Pa]

Deposition: Non-food example Gel particle suspensions κ-carragenan fibres deposited on a hair. Spherical particles of the same composition wash off during rinse. SEM micrograph by M Kirkland WO2003061607 A1

Ice Cream Milk Protein LBG Air Ice

Load (kn) 0.0016 0.0014 0.0012 0.001 0.0008 0.0006 0.0004 0.0002 0-0.0002 Comparative Properties 0 20 40 60 80 100 Displacement (mm) Conventional Formulation Maras Formulation Short texture ie. snaps GB 9930531 US 20010031304 Extensible texture ie. stretches

ydrocolloid functionality in Maras Ice Cream 160% % mean strain to failure 140% 120% 100% 80% 60% 40% 20% 0% Carrageenan Gelatin LBG CMC Xanthan Guar Sahlep All products here compared at 30% Overrun Prior Art formulations

Conclusion The fine structure of hydrocolloids plays a role in their properties (viscosity and gelation) Influence of process can alter the functionality (single and mixed systems) ydrocolloid:ydrocolloid interactions determine the gross properties of composites

Point of dilution STRUCTURE RETENTION 4000 3500 STRUCTURE CREATION 3000 Viscosity / cp 2500 2000 1500 1000 150 um 500 150 um 0 0 300 600 900 1200 1500 1800 2100 2400 2700 Time / s Acknowledge ALL past and present colleagues for support and stimulation