FOOD CHEMISTRY FSTC 312/313, 3+1 Credits Instructor: Dr. Steve Talcott Office: 220F Centeq A Phone: 862-4056 E-mail: stalcott@tamu.edu www.ift.org IFT Definition of Food Science Food science is the discipline in which biology, chemistry, physical sciences and engineering are used to study: The nature of foods The causes of their deterioration The principles underlying food processing. Food Science: An Interdisciplinary Field of Study Microbiology Biology Chemistry Food Science Physics Engineering Nutrition Dimensions of Food Science and Technology •Food processing and manufacture •Food preservation and packaging •Food wholesomeness and safety •Food quality evaluation •Food distribution •Consumer food preparation and use Other Components Growing/Harvesting Packaging Marketing/Retail Food Service Consumer Services Components of Food Science Food Chemistry Food Microbiology Food Processing Regulations Nutrition Others Food Chemistry Basis of food science Water Carbohydrates Proteins Lipids Micronutrients Phytochemicals Others Lipids in Peanuts Opened jar peanut butter: chemical reaction in the oil phase Oxidation of the unsaturated fatty acids in the peanut oil results in production of a rancid odor. Peanut butter represents a special food system called an emulsion H C H oxygen H C H C H C H Hydrocarbon chain Solutions and Emulsions Solutions are homogeneous mixtures in which solute particles are small enough to dissolve within solvent Solute examples: salt, sugar, vitamin C, other small solid particles Solute liquid examples: water, ethanol; gas examples: CO2 Droplets of dispersed phase within the continuous phase Examples of colloids MILK Dispersions (colloidal dispersions) are mixtures in which solutes do not dissolve (too large) milk protein (casein) egg white protein (albumen) gelatin protein pectin polysaccharide Ca and Mg (minerals) What is an emulsion? Mixture of two immiscible liquids oil Surface tension acts to keep the liquids from mixing H2O Result: oil “sits” on top of the water phase Stable food emulsions = addition of emulsifiers lecithin, sucrose esters, MAG, DAG, etc are “amphiphiles” O/W emulsion milk ice cream mayo W/O emulsion Margarine butter Foods Are Made of Chemicals Single elements Chemically bonded elements (compounds) Electrons Distributed via Energy Layers Common Chemical Bonds in Foods Covalent Ionic Sharing 1 or more pairs of electrons Very strong bonds, not easily broken in foods C-C or C=C bonds Filling of orbitals through the transfer of electrons Cations (+) and Anions (-); Na+ + Cl- => NaCl Hydrogen Compounds containing O or N with bound hydrogen Very weak bonds; C-H or N-H Functional Groups in Foods Exams and Grading 3 hourly exams Material is not “cumulative”, but material will build upon itself. 2 class assignments Multiple choice, short answer, short essay format Short term paper Literature review Topic of special interest etc Several announced or unannounced quizzes Beginning or end of class University excused absence policy will be followed The “Basics” of Food Chemistry Functional Groups in Foods SOME FOOD MOLECULES important in food chemistry H–O–H Na H CO3 CH3 – COOH C6H12O6 NH2 – CH2 - COOH O=C=O NaCl CH3 – (CH2)n - COOH SOME FOOD MOLECULES important in food chemistry WATER sodium bicarbonate The amino acid “glycine” acetic acid glucose carbon dioxide sodium chloride general structure of a fatty acid A Few Food Functional Groups: ACID GROUP: “carboxylic acid” COOH acids donate (lose) protons COOH COO(-) + H(+) This means acids form ions (charged species) anion has (-) charge cation has (+) charge Vinegar contains acetic acid CH3COOH Tartaric acid found in grapes is a di-carboxylic acid – what does this mean? Citric acid is tri-carboxylic acid. AMINO GROUP: NH2 Derived from ammonia (NH3) Amines are “basic” – means they gain protons methyl amine: CH3 – NH2 trimethylamine is found in fish, and is responsible for “fishy odor” CH3 – CH – COOH NH2 Alanine, an amino acid Alcohol group - OH “hydroxyl group” Methyl alcohol = methanol: CH3- OH Ethanol C2H5OH is produced during the fermentation of sugars; it is water-soluble and is called “grain alcohol” because it is obtained from corn, wheat, rice, barley, and fruits. Yeasts use sugars for food – they ferment simple carbohydrates and produce ethanol and CO2: STARCH hydrolysis C6H12O6 2 C2H5OH + 2 CO2 Glucose Ethanol Carbon Dioxide Other food molecules that contain OH groups: cholesterol (a lipid), tocopherol (a vitamin), retinol (a vitamin), & calciferol (a vitamin) Aldehyde group - CHO There is actually a double bond between two atoms in this group: -C–H O formaldehyde HCHO: H–C–H O Aldehydes can be formed from lipid oxidation, and generally have very low sensory thresholds. For example, fresh pumpkin has the smell of acetaldehyde; fresh cut grass the small of hexenal. We have already talked generally about covalent, ionic, and hydrogen bonds: Covalent: Sharing of electrons, strong bonds, C-C or C=C bonds Ionic: Transfer of electrons, NaCl Hydrogen: Weak bonds with O or N with bound hydrogen There are 3 other important bonds in foods: (1) An ester bond (linkage) in lipids (2) A peptide bond (linkage) in proteins (3) A glycosidic bond (linkage) in sugars An ester bond (linkage) in lipids: In food fats, fatty acids are attached to glycerol molecules, through what is called an ester linkage O Glycerol “Acyl” linkage C O Ester linkage fatty acid Glycerol is a small molecule, containing only 3 carbons But, to each carbon atom of glycerol, one fatty acid can attach, via an ester bond. A mono-, di-, or tri-esterified fatty acid to a glycerol is: A MONOACYLGLYCEROL. A fat molecule that has ONE fatty acid attached (“esterified”) to glycerol. A DIACYLGLYCEROL. A fat molecule that has TWO fatty acids esterified to glycerol. A TRIACYLGLYCEROL. A fat molecule that has THREE fatty acids esterified to glycerol. H H H–C–OH H–C–OH H–C–OH O H – C – O – C - (CH2)n – CH3 H–C–OH “I’m a fatty acid chain” H–C–OH H H a monoglyceride Glycerol What do peptide bonds (linkages) in proteins look like? In food proteins, or “polypeptides”, individual amino acids are attached to each other through what is called a peptide linkage Amino acid Peptide linkage Amino acid. . . repeat AMINO ACIDS contain both the amino (NH2) and the acid (COOH) group in their structure. In the formation of a peptide bond, one of the amino acids loses one H atom, and the other loses O and H. H O H O NH2 C – C - O – H ------------- NH2 C – C - O – H R is any Side chain “R” Acid group of the amino acid “R” Amino group The formation of peptide bond N-C-C-N A glycosidic linkage in sugars connects sugar units into larger structures Glycosidic linkage glucose O glucose MALTOSE, a disaccharide composed of 2 glucose units Structures of sugar disaccharides Alpha 1,4 glycosidic bond Beta 1,4 glycosidic bond Alpha 1,4 glycosidic bond Polymeric Linkages CH 2 OH O O OH CH 2 OH O O OH OH OH Amylose Cellulose Alpha 1,4 Linkage Digestible Beta 1,4 Linkage Indigestible Organic Acids in Foods Application of functional groups Acids in Foods Organic acids Citric (lemons), Malic (apples), Tartaric (grapes), Lactic (yogurt), Acetic (vinegar) Food acids come in many forms, however: Proteins are made of amino acids Fats are made from fatty acids Fruits and vegetables contain phenolic acids Organic acids are characterized by carboxylic acid group (R-COOH); not present in “mineral acids” such as HCl and H3PO4 Chemical Structures of Common Organic Acids Acids in Foods Add flavor, tartness Aid in food preservation by lowering pH Acids donate protons (H+) when dissociated Strong acids have a lot of dissociated ions Weak acids have a small dissociation constant Acids dissociate based on pH As the pH increases, acid will dissociate pKa is the pH equilibrium between assoc/dissoc Titration Curve for Acetic Acid Acids in Foods Weak acids are commonly added to foods Citric acid is the most common When we eat a food containing citric acid, the higher pH of our mouth (pH 7) will dissociate the acid, and giving a characteristics sour flavor pH and Titratable Acidity pH measures the amount of dissociated ions TA measures total acidity (assoc and dissoc) The type of food process is largely based on pH They also have other roles in food Control pH Preserve food (pH 4.6 is a critical value) Provide leavening (chemical leavening) Aid in gel formation (i.e. pectin gels) Help prevent non-enzymatic browning Help prevent enzymatic browning Synergists for antioxidants (for some, low pH is good) Chelate metal ions (i.e. citric acid) Enhance flavor (balance sweetness) Acids in Foods In product development you can use one acid or a combinations of acids -flavor -functionality - synergy - Naturally occurring blends - Food additives Acidity is important chemically -Denaturation and precipitiation of proteins -Modify carbohydrates and hydrolysis of complex sugars -Hydrolysis of Generally fatty acids from TAG’s under alkaline conditions Inversion of sugars (sucrose to glu + fru) Functional Groups and Bonds Acids Amino Alcohol Aldehydes Ester Peptide Glycosidic Application: Organic Acids Control pH Preserve food (pH 4.6 is a critical value) Provide leavening (chemical leavening) Aid in gel formation (i.e. pectin gels) Help prevent non-enzymatic browning Help prevent enzymatic browning Synergists for antioxidants (for some, low pH is good) Chelate metal ions (i.e. citric acid) Enhance flavor (balance sweetness) Acidity is important chemically Denaturation and precipitiation of proteins Modify carbohydrates and hydrolysis of complex sugars Hydrolysis Generally of fatty acids from TAG’s under alkaline conditions Inversion of sugars (sucrose to glu + fru) Chemical Reactions in Foods (1) Enzymatic (2) Non-enzymatic Generically applied to: Carbohydrates Lipids Proteins CARBOHYDRATE chemical reactions: Enzymatic browning Non-enzymatic browning Hydrolysis Fermentation Oxidation/reduction Starch gelatinization PROTEIN chemical reactions: Buffering Non-enzymatic browning Hydrolysis Condensation Oxidation Denaturation Coagulation LIPID chemical reactions Oxidation Hydrolysis Hydrogenation Chemical Bonds to Chemical Rxns Chemical Reactions in Foods Enzymatic Enzymes are proteins that occur in every living system Enzymes can have beneficial and detrimental effects Bacterial fermentations in cheese, pickles, yogurt Adverse color, texture, flavor, and odor High degree of specificity (Enzyme – Substrate) Non-enzymatic Those reactions that do not require enzymes Addition, redox, condensation, hydrolysis The Active Site of the ES Complex Enzyme Reactions Enzymatic reactions can occur from enzymes naturally present in a food Or as part of food processing, enzymes are added to foods to enable a desired effect Enzymes speed up chemical reactions (good or bad) and must be controlled by monitoring time and temperature. Typically we think of enzymes as “breaking apart” lipids, proteins, or carbs; but ther are are several enzyme categories sucrase sucrose “invertase” glucose + fructose Enzyme Class Characterizations 1. Oxidoreductase 1. 2. Transferase 1. 3. Catalyze the formation of double bonds, often in dehydration reations Isomerase 1. 6. Catalyze bond breaking using water (ie. protease, lipase) Lyase 1. 5. Transfer of one molecule to another (i.e. functional groups) Hydrolase 1. 4. Oxidation/reduction reactions Catalyze intramolecular rearrangement of molecules Ligase 1. Catalyze covalent attachment of two substrate molecules Common Enzyme Reactions (some reactions can also occur without enzymes) HYDROLYSIS Food molecules split into smaller products, due to the action of enzymes, or other catalysts (heat, acid) in the presence of water OXIDATION / REDUCTION: Reactions that cause changes in a food’s chemical structures through the addition or removal of an electron (hydrogen). Oxidation is the removal of an electron Reduction is the addition of an electron Oxidation vs Oxidized The removal of an electron is oxidation (redox reactions). When a food system is oxidized, oxygen is added to an active binding site For example, the result of lipid oxidation is that the lipid may become oxidized. In the food industry, we common speak of “oxidizing agents” versus “reducing agents”. Both are used in foods. Reducing agents are compounds that can donate an electron in the event of an oxidation reaction. L-ascorbic acid is an excellent reducing agent as are most antioxidants Oxidizing agents induce the removal of electrons Benzoyl peroxide is commonly added to “bleached” wheat flour Lets put Enzymes and Chemical Reactions into Perspective Enzymes Living organisms must be able to carry out chemical reactions which are thermodynamically very unfavorable Break and/or form covalent bonds Alter large structures Effect three dimensional structure changes Regulate gene expression They A common biological reaction can take place without enzyme catalysis do so through enzyme catalysis …but will take 750,000,000 years With an enzyme….it takes ~22 milliseconds Even improvement of a factor of 1,000 would be good Only 750,000 years Living system would be impossible Effect of Enzymes A bag of sugar can be stored for years with very little conversion to CO2 and H2O This conversion is basic to life, for energy When consumed, it is converted to chemical energy very fast Both enzymatic and non-enzymatic reactions Enzymes are highly specialized class of proteins: Specialized to perform specific chemical reactions Specialized to work in specific environments Enzymes • Food quality can be changed due to the activity of enzymes during storage or processing • Enzymes can also be used as analytical indicators to follow those changes • Enzyme-catalyzed reactions can either enhance or deteriorate food quality • Changes in color, texture, sensory properties Enzyme Applications in the Food Industry Carbohydrases: making corn syrup from starch Proteases: Meat tenderizers Lipases: Flavor production in chocolate and cheese Pectinases Glucose oxidase Flavor enzymes Lipoxygenase Polyphenol oxidase Rennin (chymosin) Water in Foods Water Content of Foods Tomatoes, lettuce -- 95% Apple juice, milk -- 87% Potato -- 78% H Meats -- 65-70% O H Bread -- 35% Honey -- 20% Rice, wheat flour -- 12% Shortening -- 0% H O H Water Works Water must be “available” in foods for the action of both chemical and enzymatic reactions. The “available” water represents the degree to which water in a food is free for: Chemical reactions Enzymatic reactions Microbial growth Quality characteristics Related to a simple loss of moisture Related to gel breakdown Food texture (gain or loss) Water Works Very important (#1 ingredient in many foods) Structure Polar nature, hydrogen bonding Can occur in many forms (S,L,V) Acts as a dispersing medium or solvent Solubility Hydration Emulsions Gels Colloids Water Works The amount of “free” water, available for these reactions and changes is represented by Water Activity. As the percentage of water in a food is “bound” changing from its “free” state, the water activity decreases Water Activity is represented by the abbreviation: Aw Aw = P/ Po P = Vapor pressure of a food Po = Vapor pressure of pure water (1.0) Vapor pressure can be represented as equilibrium RH Is based on a scale of 0.0 to 1.0 Any food substance added to water will lower water activity….so, all foods have a water activity less than 1.0 Water Free vs. bound Water activity (Aw) Measured by vapor pressure of food This value is directly correlated to the growth of microorganisms and the chemical reactions 3 Forms of Water Free water (capillary water or Type III) Water that can be easily removed from a food Water that is responsible for the humidity of a food Water from which water activity is measured Bound water (adsorbed or Type II) Water that is tied up by the presense of soluble solids Salts, vitamins, carbohydrates, proteins, emsulifiers, etc. Water of hydration (Structured or Type I) Water held in hydrated chemicals . Na2SO4 10H2O Water Sorption Isotherm Type I Hydration 0 0.1 0.2 Type II Absorbed 0.3 0.4 0.5 0.6 Water Activity Type III Free 0.7 0.8 0.9 1 Water Sorption Isotherm Type I Hydration 0 0.1 0.2 Type II Absorbed 0.3 0.4 0.5 0.6 Water Activity Type III Free 0.7 0.8 0.9 1 Moisture sorption isotherm (MSI) How to Use the Isotherm Moisture sorption isotherms Shows the relationship between water activity and moisture at a given temperature (the two are NOT equivalent) Represent moisture content at equilibrium for each water activity Allow for predictions in changes of moisture content and its potential effect on water activity If the temperature is altered, then the relationships can not be compared equivalently Each reaction is governed by its own temperature-dependence Acid hydrolysis reactions are faster at high temperatures Enzyme-catalyzed reactions cease to function at high temperatures Influences on Water Activity Foods will naturally equilibrate to a point of equilibrium with its environment Therefore, foods can adsorb or desorb water from the environment Desorption is when a “wet” food is placed in a dry environment Analogous to dehydration; but not the same Desorption implies that the food is attempting to move into equilibrium (ie. in a package) Dehydration is the permanent loss of water from a food In both cases, the Aw decreases Desorption is generally a slow process, with moisture gradually decreasing until it is in equilibrium with its environment. Adsorption is when a “dry” food is placed in a wet environment As foods gain moisture, the Aw increases The term “hygroscopic” is used to describe foods or chemicals that absorb moisture A real problem in the food industry (lumping, clumping, increases rxn rates) Water Activity in Practice Bacterial growth and rapid deterioration High water activity in meat, milk, eggs, fruits/veggies 1.0-0.9 Yeast and mold spoilage Intermediate water activity foods such as bread and cheese 0.75-0.9 Analogous to a pH < 4.6, an Aw < 0.6 has the same preservation effect Aw in Low Moisture Foods Water activity and its relationship with moisture content help to predict and control the shelf life of foods. Generally speaking, the growth of most bacteria is inhibited at water activities lower than 0.9 and yeast and mold growth prevented between 0.80 and 0.88. Aw also controls physiochemical reactions. Water activity plays an important role in the dehydration process. Knowledge of absorption and desorption behavior is useful for designing drying processes for foods. How to “Control” water The ratio of free to bound water has to be altered You can either remove water (dehydration or concentration) Or you can convert the free water to bound water Can change the physical nature of the food Alter is color, texture, and/or flavor Addition of sugars, salts, or other water-soluble agents You can freeze the food This immobilizes the water (and lowers the Aw) However, not all foods can be or should be frozen Frozen foods will eventually thaw, and the problem persists Water Water contains intramolecular polar covalent bonds Effects Boiling point Freezing point Vapor pressure Easy formation of H bonds with food molecules Properties of Water The triple point is the temperature and pressure at which three phases (liquid, ice, and vapor) coexist at equilibrium, and will transform phases small changes in temperature or pressure. The dashed line is the vapor pressure of supercooled liquid water. Chemical and functional properties of water Solvation, dispersion, hydration Water activity and moisture Water as a component of emulsions Water and heat transfer Water as an ingredient Freezing Foods Controlling Water Freezing Greatly influenced the way we eat Freezing curves Water Freezes “Pure” Frozen Foods Must be super-cooled to below 0°C Crystal nucleation begins Temperature rises to 0°C as ice forms Freezing Foods Temperature 40 35 Freezing Point 30 25 20 15 Super-cooling Latent heat of Crystallization 10 5 0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 30 Freezing Time Freezing Freezing Food Require lower temp. to continue freezing Last portion of water is very hard to freeze Unfrozen water is a problem ***As long as unfrozen water is present in a food, the temperature will remain near 0°C due to the latent heat of crystallization. Freezing Quality changes during freezing Concentration effect = small amount of unfrozen water Excess solutes may precipitate Proteins may denature pH may decrease Gases may concentrate (i.e. oxygen) Freezing Quality changes during freezing Damage from ice crystals Puncture Large cell membranes crystals cause more problems Fast freezing much more desirable Less concentration effect Smaller ice crystals Freezing Final storage temperature -18°C is standard Safe microbiologically Limits enzyme activity Non-enzymatic changes are slow Can maintain fairly easily Good overall shelf-life Freezing Intermittent thawing Partial thawing, then refreezing Complete thawing does not have to occur Get concentration effect Get larger ice crystals as water re-freezes Freezing Factors determining freezing rate: Food composition Fat and air have low thermal conductivity, slow down freezing This is a “buffering” effect. Freezing Ways to speed up freezing Thinner foods freeze faster Greater air velocity More intimate contact with coolant Use refrigerant with greater heat capacity High Pressure Effects-Speeding it Up Freezing is regarded as one of the best methods for long term food preservation. The benefits of this technique are primarily from low temperatures rather than ice formation. The application of pressure lowers the melting point of ice. About 0.55ºC per 80 atm of pressure down to about -22ºC at 2,700 atm. Pressure (and friction) help ice to melt under the blades of ice skates. Pressure (Atm) Freezing Pt (C) 1 0 1,000 -10 2,045 -22 3,420 -17 6,160 0 7,390 10 9,800 25 13,970 50 23,000 100 36,500 175 Potential applications in cryonics Increase pressure to 2,000 atm (get really cold) Suddenly increase pressure to >20,000 atm Results: Frozen so fast that ice crystals will not form Freezing Foods Freezing can be damaging to food systems To reduce the chemical and mechanical damage to food systems during freezing, technologies have been developed to freeze foods faster or under high pressures. Benefits include: Higher density ice (less “space” between crystals from air or solids) Increased rate of freezing Smaller ice crystal formation Uniform crystal formation HP freezing generally involves cooling an unfrozen sample to -21C under high pressures (300MPa) causing ice formation to occur. 1 MPa ~ 145 psi or ~10 atm Another method involves pressure shift freezing where the food is cooled under high pressures without causing freezing. Once the pressure is released, the sample freezes instantly. Dehydration and Concentration of Foods Controlling Water Dehydration and Concentration Factors affecting drying rates Surface area Temperature Air velocity Humidity Pressure (vacuum) Solute concentration Amount of free and bound water Moisture Content Drying Curve of a Food 4.5 4 3.5 3 2.5 2 1.5 1 0.5 0 Water that is easily removed Water that is difficult to remove 0 1 2 3 4 5 6 7 Time (Hrs) 8 9 10 11 12 Dehydration and Concentration Quality changes Browning Enzymes - sulfite will prevent Carmelization - lower temps. will limit Maillard reaction - reaction of sugars and amino acids - lower temps will limit Acrylamide…??? Flavor changes Methods of Drying Air drying methods Cabinet Tunnel Concurrent flow Countercurrent flow Continuous Fluidized bed Spray Drum Carbohydrates in Foods A general overview CARBOHYDRATES Classifications for the main categories of food carbohydrates are based on their degree of polymerization. Types of Carbohydrates CARBOHYDRATES Carbohydrates are carbon compounds that contain many hydroxyl groups. The simplest carbohydrates also contain either an aldehyde (these are termed polyhydroxyaldehydes) or a ketone (polyhydroxyketones). All carbohydrates can be classified as either monosaccharides, disaccharides, oligosaccharides or polysaccharides. An oligosaccharide is anywhere from about two to ten monosaccharide units, linked by glycosidic bonds. Polysaccharides are much larger, containing hundreds of monosaccharide units. The presence of the hydroxyl groups (–OH) allows carbohydrates to interact with the aqueous environment and to participate in hydrogen bonding, both within and between chains. CARBOHYDRATES SUGARS contain 2 important and very reactive Functional groups: -OH (hydroxyl group) Important for solubility and sweetness -C=O (carbonyl group) Important for reducing ability and Maillard browning GLUCOSE is an ALDOSE sugar with one C atom external to the 6-membered ring FRUCTOSE is a KETOSE hexose with two carbon atoms external to the 6-membered ring Monosaccharides The monosaccharides commonly found in foods are classified according to the number of carbons they contain in their backbone structures. The major food monosaccharides contain six carbon atoms. Carbohydrate Classifications Hexose = six-carbon sugars Glucose, Galactose, Fructose Fischer Projection of a-D-Glucose Haworth Projection of a-D-Glucose Chair form of a-D-Glucose Disaccharides Bonds between sugar units are termed glycosidic bonds, and the resultant molecules are glycosides. The linkage of two monosaccharides to form disaccharides involves a glycosidic bond. The important food disaccharides are sucrose, lactose, and maltose. Sucrose: prevalent in sugar cane and sugar beets, is composed of glucose and fructose through an α-(1,2) glycosidic bond. Lactose: is found exclusively in the milk of mammals and consists of galactose and glucose in a β-(1,4) glycosidic bond. Maltose: Is the major degradation product of starch, and is composed of 2 glucose monomers in an α-(1,4) glycosidic bond. Polysaccharides Most of the carbohydrates found in nature occur in the form of high molecular weight polymers called polysaccharides. The monomeric building blocks used to generate polysaccharides can be varied; in all cases, however, the predominant monosaccharide found in polysaccharides is D-glucose. When polysaccharides are composed of a single monosaccharide building block, they are termed homopolysaccharides. Starch Starch is the major form of stored carbohydrate in plant cells. Its structure is identical to glycogen, except for a much lower degree of branching (about every 20-30 residues). Unbranched starch is called amylose Branched starch is called amylopectin. FUNCTIONAL PROPERTIES OF CARBOHYDRATES Reducing sugars Browning reactions (caramelization and Maillard) Sweetness and flavors Crystallization Humectancy Inversion Oxidation and reduction Texturizing Viscosity Gelling (gums, pectins, other hydrocolloids) Gelatinization (Starch) Aldose (aldehyde) and Ketose (ketone) Properties of Glucose C1 of glucose is the carbonyl carbon Glucose has 4 chiral centers Non-super-imposable Carbons on its mirror image 2, 3, 4, 5 are chiral carbons The carbonyl carbon (C1) is also the site of many reactions involving glucose They have two enantiomeric forms, D and L, depending on the location of the hydroxyl group at the chiral carbons. Sugar Reactions Reduction of Monosaccharide In this reaction the carbonyl group is reduced to an alcohol by a metal catalyzed reaction of hydrogen gas under pressure. Sugar Alcohols Not commonly found in nature Generally lower in calories (2 to 3 kcal/g) A CHO for labeling purposes Not digested by oral bacteria “does not promote tooth decay” – Xylitol (from xylose) – Sorbitol (from glucose) – Mannitol (from mannose) – Lactitol (from lactose) – Maltitol (from maltose) Sugar Sweetness Fructose 173 Sucrose 100 Xylitol 100 Glucose 74 Sorbitol 55 Mannitol 50 Maltose 32 Lactose 15 Sweetness is but one of a variety of functional characteristics of importance in food chemistry, food product development, and product quality Functionality FUNCTIONAL PROPERTIES OF CARBOHYDRATES Reducing sugars Browning reactions (caramelization and Maillard) Sweetness and flavors Crystallization Humectancy Inversion Oxidation and reduction Texturizing Viscosity Gelling (gums, pectins, other hydrocolloids) Gelatinization (Starch) Sucrose Where does sucrose come from? Invert sugar Invert sugar is a liquid carbohydrate sweetener in which all or a portion of the sucrose present has been inverted: The sucrose molecule is split and converts to an equimolar mixture of glucose and fructose. Invert sugars have properties from sucrose; they help baked goods retain moisture, and prolong shelf-life. Candy manufacturers use invert sugar to control graining. Invert sugar is different from high fructose sweeteners SUCROSE + invertase enzyme glucose + fructose Corn syrups Corn syrups are manufactured by treating corn starch with acids or enzymes. Corn syrups, used extensively by the food industry and in the home kitchen, contain primarily glucose (dextrose) but other sugars as well. High-fructose corn syrup (HFCS) is made by treating dextrose-rich corn syrup with enzymes (isomerase). The resulting HFCS is a liquid mixture of dextrose and fructose used by food manufacturers in soft drinks, canned fruits, jams and other foods. HFCS contains 42, 55, 90 or 99 percent fructose. PROCESSING OF CORN STARCH HFCS Corn starch is treated with α-amylase, of bacterial origin, to produce shorter chains of sugars (dextrins) as starch fragments. Next, an enzyme called glucoamylase, obtained from the fungus Aspergillus niger, breaks the fragments down even further to yield the simple sugar glucose. A third enzyme, glucose isomerase, is expensive, and converts glucose to varous amounts of frutose. HFCS-55 has the exact same sweetness intensity as sucrose (cola) HFCS-42 is less sweet, used with fruit-based beverages and for baking Glucose isomerase is so expensive that it is commonly immobilized on a solid-based “resin” bead and the glucose syrup passed over it. Can be used many times over before it slowly looses its activity. HFCS HFCS is selected for different purposes. Selection is based on specific desired properties: Retain moisture and/or prevent drying out Control crystallization Produce a higher osmotic pressure (more molecules in solution) than for sucrose Control microbiological growth Provide a ready yeast-fermentable substrate Blend easily with sweeteners, acids, and flavorings Provide a controllable substrate for browning and Maillard reaction. Impart a degree of sweetness essentially = to invert liquid sugars High sweetness Low viscosity Reduced tendency toward crystallization Costs less than liquid sucrose or corn syrup blends Retain moisture and/or prevent drying out of food product HFCS HFCS has the exact same sweetness and taste as an equal amount of sucrose from cane or beet sugar. Despite being a more complicated process than the manufacture of sugar, HFCS is actually less costly. It is also very easy to transport, being pumped into tanker trucks. Two of the enzymes used, α-amylase and glucose-isomerase, are genetically modified to make them more thermostable. This involves exchanging specific amino acids in the primary sequence so that the enzyme is resistant to unfolding or denaturing. This allows the industry to use the enzymes at higher temperatures without loss of activity. Starch Starches- #1 Hydrocolloid Hydrocolloids are substances that will form a gel or add viscosity on addition of water. Most are polysaccharides and all interact with water. The most common is starch Starch is a mixture of amylose and amylopectin. The size distribution of these hydrocolloids is the most important factor in the texture and physical features of foods STARCH Polymers of glucose AMYLOSE linear chain of glucose Glucose polymer linked α-1,4 AMYLOPECTIN branched polymer of glucose Amylose Amylopectin AMYLOSE Linear polymer of glucose α 1 - 4 linkages Digestable by humans (4 kcal/g) 250-350 glucose units on average Corn, wheat, and potato starch ~10-30% amylose AMYLOPECTIN Branched chain polymer of glucose α 1 - 4 and α 1 - 6 glycosidic linkages Fully digestable by humans 1,000 glucose units is common Branch points every ~15-25 units Starch Amylopectin (black) Amylose (blue) Modified Starches Gelatinization is the easiest modification Heated in water then dried. Acid and/heat will form “dextrins” α-Amylase β-Amylase hydrolyzes α (1-4) linkage random attack to make shorter chains Also attacks α (1 - 4) linkages Starts at the non-reducing end of the starch chain Gives short dextrins and maltose Both enzymes have trouble with α (1 - 6) linkages DEXTRINS are considered to be hydrolysis products of incompletely broken down starch fractions Polysaccharide Breakdown Products What’s the difference between…? Maltose Maltitol Maltodextrins Dextrins Dextrans Maltose = glucose disaccharide Maltitol = example of a “polyol” Maltodextrins = enzyme converted starch fragments Dextrins = starch fragments (α-1-4) linkages produced by hydrolysis of amylose Dextrans = polysaccharides made by bacteria and yeast metabolism, fragments with mostly α (1 - 6) linkages Maltodextrins and enzyme-converted starch: STARCH fermentation SUGARS ETHANOL MODIFIED STARCHES GELATINIZED STARCH alpha amylase Maltodextrins Corn Syrups Sugars The smaller the size of the products in these reactions, the higher the dextrose equivalence (DE), and the sweeter they are Starch DE = 0 Glucose (dextrose) DE = 100 Maltodextrin (MD) DE is <20 Corn syrup solids (CS) DE is >20 Low DE syrup alpha amylase MD beta amylase High DE Syrup Hydrocolloids Binding water with carbohydrates “Gums” “Vegetable gum” polysaccharides are substances derived from plants, including seaweed and various shrubs or trees, have the ability to hold water, and often act as thickeners, stabilizers, or gelling agents in various food products. Plant gums - exudates, seeds Marine hydrocolloids - extracts from seaweeds Microbiological polysaccharides - exocellular polysaccharides Modified, natural polysaccharides FUNCTIONS IN FOOD Gelatin Viscosity Suspension Emulsification and stability Whipping Freeze thaw protection Fiber (dietary fiber) Gut health Binds cholesterol STRUCTURAL CONSIDERATIONS Electrical charge, pH sensitive Interactions with oppositely charged molecules Salts Low Chain pH effects length Longer Linear chains are more viscous vs Branched chains Inter-entangled, enter-woven molecules Gums GUAR (Guran Gum) Most used, behind starch, low cost Guar bean from India and Pakistan Cold water soluble, highly branched galactomannan Stable over large pH range, heat stable Thickening agent, not a gel Often added with xanthan gum (synergistic) XANTHAN Extracellular polysaccharide from Xanthomonas campestris Very popular, inexpensive from fermentations Forms very thick gels at very low concentrations Gums LOCUST BEAN Branched galactomannan polymer (like guar), but needs hot water to solubilize Bean from Italy and Spain Jams, jellies, ice cream, mayonnaise SEAWEED EXTRACTS Carrageenans (from Kappa red seaweed) (gel) Iota (gel) Lambda (thickener only) Milk, baking, cheese, ice cream Agar Alginates “Structural” Polysaccharides Cellulose Polymer of glucose linked ß-1,4 Hemicellulose Similar to cellulose Consist of glucose and other monosaccharides Arabinose, xylose, other 5-carbon sugars Pectin Polymer of galacturonic acid MODIFIED CELLULOSES Chemically modified cellulose Do not occur naturally in plants Similar to starch, but β-(1,4) glycosidic bonds Carboxymethyl cellulose (CMC) most common Acid treatment to add a methyl group Increases water solubility, thickening agent Sensitive to salts and low pH Fruit fillings, custards, processed cheeses, high fiber filler PECTINS Linear polymers of galacturonic acid Susceptible to degrading enzymes Gels form with degree of methylation of its carboxylic acid groups Many sources, all natural, apple and citrus pomace Polygalacturonase (depolymerize) Pectin esterases (remove methyl groups) Longer polymers, higher viscosity Lower methylation, lower viscosity Increase electrolytes (ie. metal cations), higher viscosity pH an soluble solids impact viscosity PECTIC SUBSTANCES: cell cementing compound; fruits and vegetables; pectin will form gel with appropriate concentration, amount of sugar and pH. Basic unit comprised of galacturonic acid. Composition: polymer of galacturonic acids; may be partially esterified. Pectic Acid Pectin Molecule Pectins Pectins are important because they form gels Mechanism of gel formation differs by the degree of esterification (DE) of the pectin molecules DE refers to that percentage of pectin units with a methyl group attached Free COOH groups can crosslink with divalent cations Sugar and acid under certain conditions can contribute to gel structure and formation LM pectin “low methoxyl pectin” has DE < 50% ; gelatin is controlled by adding cations (like Ca++ and controlling the pH) HM pectin “high methoxyl pectin” has DE >50% and forms a gel under acidic conditions by hydrophobic interactions and Hbonding with dissolved solids (i.e. sugar) Hydrophobic attractions between neighboring pectin polymer chains promote gelation BETA-GLUCANS Extracts from the bran of barley and oats Long glucose chains with mixed ß-linkages Very large (~250,000 glucose units) Water soluble, but have a low viscosity Can be used as a fat replacer Responsible for the health claims (cholesterol) for whole oat products Formulated to reduce the glycemic index of a food Others CHITIN Polymer of N-Acetyl-D-glucosamine Found in the exoskeleton of insects and shellfish Many uses in industry, food and non-food. INULIN Chains of fructose that end in a glucose molecule Generally a sweet taste Isolated from Jerusalem artichokes and chicory Act as a dietary fiber Potentially a pre-biotic compound COMPONENTS OF DIETARY FIBER COMPONENT SOURCE Cellulose All food plants Hemicellulose All food plants, especially cereal bran Pectin Mainly fruit Lignin Mainly cereals and 'woody' vegetables Gums and some food thickeners Food additives in processed foods HYDROCOLLOIDS A key attribute of gums is to produce viscous dispersions in water Viscosity depends on: Gum type Temperature Concentration of gum Degree of polymerization of gum Linear or branched polymers Presence of other substances in the system Solubility (dispersability in water) varies among gums Agar is insoluble in cold water; dissolves in boiling water Methylcellulose is insoluble in hot water, but soluble in cold ! Our First Browning Reaction Caramelization BROWNING REACTIONS in CARBOHYDRATES There are 2 different kinds of browning reactions with carbohydrates: Caramelization Maillard (or non-enzymatic) browning CARAMELIZATION occurs when sucrose is heated >150-170°C (high heat!) via controlled thermal processing Dehydration of the sugar, removal of a water molecule The structure of caramelized sugar is poorly understood but can exist in both (+) and (-) species Commonly used as a colorant (+) charged caramel = promotes brown color in brewing and baking industries (-) charged caramel in beverage/ soft drink industry (cola and root beer) CARAMELIZATION What is referred to as “caramel pigment” consists of a complex mixture of polymers and fragments of indefinite chemical composition Caramelans (24, 36, or 125 carbon lengths) Since caramel is a charged molecule, to be compatible with phosphoric acid in colas the negative form is used Caramel flavor is also due to these and other fragments, condensation, and dehydration products. diacetyl, formic acid, hydroxy dimethylfuranone Carbohydrates in Foods Gums GUAR (Guran Gum) Most used, Cold water soluble, Stable, Thickening agent XANTHAN Polysaccharide from Xanthomonas campestris Popular, inexpensive Thick gels LOCUST BEAN Hot water to soluble Jellies, ice cream, mayonnaise PECTINS Linear polymers of galacturonic acid Susceptible to degrading enzymes Gels form with degree of methylation of its carboxylic acid groups Many sources, all natural, apple and citrus pomace Polygalacturonase (depolymerize) Pectin esterases (remove methyl groups) Longer polymers, higher viscosity Lower methylation, lower viscosity Increase electrolytes (ie. metal cations), higher viscosity pH an soluble solids impact viscosity Hydrophobic attractions between neighboring pectin polymer chains promote gelation BETA-GLUCANS Extracts from the bran of barley and oats Long glucose chains with mixed ß-linkages Very large (~250,000 glucose units) Water soluble, but have a low viscosity Can be used as a fat replacer Responsible for the health claims (cholesterol) for whole oat products Formulated to reduce the glycemic index of a food Others CHITIN Polymer of N-Acetyl-D-glucosamine Found in the exoskeleton of insects and shellfish Many uses in industry, food and non-food. INULIN Chains of fructose that end in a glucose molecule Generally a sweet taste Isolated from Jerusalem artichokes and chicory Act as a dietary fiber Potentially a pre-biotic compound COMPONENTS OF DIETARY FIBER COMPONENT SOURCE Cellulose All food plants Hemicellulose All food plants, especially cereal bran Pectin Mainly fruit Lignin Mainly cereals and 'woody' vegetables Gums and some food thickeners Food additives in processed foods HYDROCOLLOIDS A key attribute of gums is to produce viscous dispersions in water Viscosity depends on: Gum type Temperature Concentration of gum Degree of polymerization of gum Linear or branched polymers Presence of other substances in the system Solubility (dispersability in water) varies among gums Agar is insoluble in cold water; dissolves in boiling water Methylcellulose is insoluble in hot water, but soluble in cold ! Our First Browning Reaction Caramelization BROWNING REACTIONS in CARBOHYDRATES There are 2 different kinds of browning reactions with carbohydrates: Caramelization Maillard (or non-enzymatic) browning CARAMELIZATION occurs when sucrose is heated >150-170°C (high heat!) via controlled thermal processing Dehydration of the sugar, removal of a water molecule The structure of caramelized sugar is poorly understood but can exist in both (+) and (-) species Commonly used as a colorant (+) charged caramel = promotes brown color in brewing and baking industries (-) charged caramel in beverage/ soft drink industry (cola and root beer) CARAMELIZATION What is referred to as “caramel pigment” consists of a complex mixture of polymers and fragments of indefinite chemical composition Caramelans (24, 36, or 125 carbon lengths) Since caramel is a charged molecule, to be compatible with phosphoric acid in colas the negative form is used Caramel flavor is also due to these fragments and condensation/dehydration products. diacetyl, formic acid, hydroxy dimethylfuranone Artificial and Alternative Sweeteners Sweeteners Non-nutritive (no calories) Cyclamate (banned in 1969) Saccharin (Sweet ‘N Low, 300-fold) Aspartame (warning label) = aspartic acid and phenylalanine (180-fold) Acesulfame-K (Sunette, 200-fold) Alitame (Aclame, 2,000-fold) Sucralose (Splenda, 600-fold) Sucralose The perception of sweetness is proposed to be due to a chemical interaction that takes place on the tongue Between a tastant molecule and tongue receptor protein THE AH/B THEORY OF SWEETNESS A sweet tastant molecule (i.e. glucose) is called the AH+/B“glycophore”. It binds to the receptor B-/AH+ site through mechanisms that include H-bonding. AH+ / B- γ B Glycophore Hydrophobic interaction AH AH B γ Tongue receptor protein molecule For sweetness to be perceived, a molecule needs to have certain requirements. It must be soluble in the chemical environment of the receptor site on the tongue. It must also have a certain molecular shape that will allow it to bond to the receptor protein. Lastly, the sugar must have the proper electronic distribution. This electronic distribution is often referred to as the AH, B system. The present theory of sweetness is AH-B-X (or gamma). There are three basic components to a sweetener, and the three sites are often represented as a triangle. Identifying the AH+ and Bregions of two sweet tastant molecules: glucose and saccharin. Gamma (γ) sites are relatively hydrophobic functional groups such as benzene rings, multiple CH2 groups, and CH3 WHAT IS SUCRALOSE AND HOW IS IT MADE? Sucralose, an intense sweetener, approximately 600 times sweeter than sugar. In a patented, multi stage process three of the hydroxyl groups in the sucrose molecule are selectively substituted with 3 atoms of chlorine. This intensifies the sugar like taste while creating a safe, stable sweetener with zero calories. Sucralose Developers found that selective halogenations changed the perceived sweetness of a sucrose molecule, with chlorine and bromine being the most effective. Chlorine tends to have a higher water solubility, so chlorine was picked as the ideal halogen for substitution. Sucrose portion Fructose portion Sucralose Splenda 1998, approved for table-top sweetener and use in various foods Approved already in UK, Canada before US Only one “made from sugar” There was a law suit last year of this claim Splenda lost….not a natural compound and not really made from sugar….a bit of a deceptive marketing. Clean, sweet taste and no undesirable off-flavor Saccharin Sweet’n Low, The 1st artificial sweetener Accidentally found in 1879 by Remsen and Fahlberg Saccharin use increased during wars due to sugar rationing By 1917, common table-top sweetener in America Banned in 1977 due to safety issue 1991, withdrawal banning, but remained warning label 2000, removed warning label Intensely sweet, but bitter aftertaste Aspartame Nutrasweet, Equal Discovered in 1965 by J. Schlatter Composed of aspartic acid and phenylalanine 4 kcal/g, but 200 times sweeter Approved in 1981 for table-top sweetener and powdered mixes Safety debating 1996, approved for use in all foods and beverage Short shelf life, not stable at high temperature Acesulfame K Sunette, Sweet One Discovered in 1967 by Hoechst 1992, approved for gum and dry foods 1998, approved for liquid use Blending with Aspartame due to synergistic effect Stable at high temperature and long shelf life (34 years) Bitter aftertaste Neotame Brand new approved sweetener (Jan. 2000) 7,000 ~ 13,000 times sweeter than sugar Dipeptide methyl ester derivative structurally similar to Aspartame Enhance sweetness and flavor Baked goods, non-alcoholic beverages (including soft drinks), chewing gum, confections and frostings, frozen desserts, processed fruits and fruit juices, toppings and syrups. Safe for human consumption Wheat Bran Removed Whole Wheat Corn Milled, Polished Rice Cereals Cereals Starch, protein, fiber Water Lysine Structure Husk (inedible) Bran (fiber) Endosperm (starch, protein, oil) Germ (oil) Wheat Kernel Endosperm Starch Protein Oil Endosperm Bran Bran Fiber Germ Germ Oil Protein Cereal Grain Composition of Cereals Grain Water Carbo. Protein Fat Fiber Corn 11 72 10 4 2 Wheat 11 69 13 2 3 Oats 13 58 10 5 10 Sorghum 11 70 12 4 2 Barley 14 63 12 2 6 Rye 11 71 12 2 2 Rice 11 65 8 2 9 Buckwheat 10 64 11 2 11 Wheat 2 types of wheat HARD = higher protein (gluten), makes elastic dough, used for bread-making Higher “quality” High water absorption SOFT = lower protein (gluten), make weak doughs/batters, used for cakes, pastries, biscuits, cakes, crackers, etc. Lower “quality” due to lower protein content and useful applications Wheat Wheat Milling To produce flour Cleaned with air (dust, bugs, chaff) Soaked to 17% moisture - optimum for milling Remove husk Crack seeds - frees germ from endosperm Wheat Wheat Milling Rollers- two metal wheels turning in opposite direction of each other Endosperm is brittle and breaks Germ and bran form flat flakes and are removed by screens or sieves Endosperm = flour Less Whole color and less nutrients as milling continues wheat flour = do not remove all of the bran and/or germ Wheat Mill Grinding Rolls Wheat Milling Sifters Wheat Wheat Enrichment Add B-vitamins and some minerals to most white flours (since missing the bran) Uses of flour Cakes, breads, etc. Pasta, noodles, etc. Course flour, not leavened Rice Processing Rice Rice Milling Most rice is "whole grain" Remove husk, bran, germ by rubbing with abrasive disks or rubber belts Polish endosperm to glassy finish Brown rice = very little milling Rice Rice Enrichment Add some vitamins, minerals Coat rice with nutrients (folic acid) Parboiling or steeping (converted rice) Boil rice before milling (~10 hrs, 70°C) Nutrients, vitamins and minerals, will migrate into endosperm (no fortification) Rice Rice Other rice products Quick cooking (instant) = precooked, dried Rice flour Sake (15-20% alcohol) Advantages/Disadvantages of Milling Rice Brown Rice Minimal milling Higher in lipid (shortens shelf-life) Higher in minerals (not removed in milling) White (Milled) Rice Extreme milling Vitamins and minerals removed (Thiamin) Fortification to prevent Beriberi disease Anatomy of Corn Corn Corn Some fresh/frozen/canned corn, but most is milled Dry milling (grits, meal, flour) Adjust moisture to 21%- optimum for "dry" milling Loosen hull (pericarp) and germ by rollers Dry to 15% moisture Remove husk with air blast; germ and bran by sieving Continue grinding endosperm to grits, meal or flour Process very similar to wheat milling at this point. Grits = large particle size Meal = medium particle size Flout = small particle size Grain Processing Wet milling (corn starch, corn syrups) Soak corn Grind with water into a wet "paste" Slurry is allowed to settle and the germ and hulls float to top (high in oil) Remainder is endosperm (starch/protein) Centrifuged or filtered to remove/collect the starch Grain Processing Wet milling (cont'd.) Dried starch = corn starch Can produce corn syrups from starch Use enzymes (amylase) to break starch into glucose (corn syrup) Use another enzyme (isomerase) to convert glucose into fructose (HFCS) Can also produce ethanol from corn syrup Products from Corn Grain Usage Other grains- mostly for animal feed Barley = used in beer Rye = can not use alone (poor protein quality) Oats = oatmeal, flakes Breakfast cereals Made from many different grains Proteins From the Greek “proteios” or primary. Proteins Many important functions Functional Nutritional Biological Enzymes Structurally complex and large compounds Major source of nitrogen in the diet By weight, proteins are about 16% nitrogen Protein Content of Foods Beef -- 16.5% Pork -- 10% Chicken -- 23.5% Milk -- 3.6% Eggs -- 13% Bread -- 8.5% Cooked beans -- 8% Potato -- 2% Proteins Proteins are polymers of amino acids joined together by peptide bonds Structure, arrangement, and functionality of a protein is based on amino acid composition All amino acids contain nitrogen, but also C, H, O, and S Protein Structure The formation of peptide bond N-C-C-N Proteins Proteins are composed of amino acids which are carboxylic acids also containing an amine functional group. The amino acids are linked together by peptide bonds (amide bonds) forming long chains Short chains of amino acids are commonly called polypeptides (eg. dipeptide, tripeptide, hexapeptide, etc) Longer chains of amino acids normally called proteins. Proteins Peptide bonds are strong covalent bonds that connect 2 amino acids Dipeptide- 2 amino acids joined together by a peptide bond Polypeptide- 3 or more amino acids joined together by peptide bonds in a specific sequence 20 Amino Acids Alanine (Ala) Arginine (Arg) Asparagine (Asn) Aspartic acid (Asp) Cysteine (Cys) Glutamine (Gln) Glutamic acid (Glu) Glycine (Gly) Histidine (His) Isoleucie (Ile) Leucine (Leu) Lysine (Lys) Methinine (Met) Phenylalanine (Phe) Proline (Pro) Serine (Ser) Threonine (Thr) Tryptophan (Trp) Tyrosine (Try) Valine (Val) Proteins Composed of amino acids 20 common amino acids Polymerize via peptide bonds Essential vs. non-essential amino acids Essential must come from diet Essential amino acids: "Pvt. T.M. Hill” phenylalanine, valine, threonine, tryptophan, methionine, histidine, isoleucine, leucine, lysine Properties of Amino Acids Aliphatic chains: Gly, Ala, Val, Leucine, Ile Hydroxy or sulfur side chains: Ser, Thr, Cys, Met Aromatic: Phe, Trp, Try Basic: His, Lys, Arg Acidic and their amides: Asp, Asn, Glu, Gln Properties of Amino Acids: Aliphatic Side Chains Sulfur Side Chains Aromatic Side Chains Acidic Side Chains Properties of Amino Acids: Zwitterions are electrically neutral, but carry a “formal” positive or negative charge. Give proteins their water solubility The Zwitterion Nature Zwitterions make amino acids good acid-base buffers. For proteins and amino acids, the pH at which they have no net charge in solution is called the Isoelectric Point of pI (i.e. IEP). The solubility of a protein depends on the pH of the solution. Similar to amino acids, proteins can be either positively or negatively charged due to the terminal amine -NH2 and carboxyl (-COOH) groups. Proteins are positively charged at low pH and negatively charged at high pH. When the net charge is zero, we are at the IEP. A charged protein helps interactions with water and increases its solubility. As a result, protein is the least soluble when the pH of the solution is at its isoelectric point. Physical Nature of Proteins Protein Structures Primary = sequence of amino acids Secondary = alpha helix, beta pleated sheets Tertiary = 3-D folding of chain Quaternary = “association” of subunits and other internal linkages Primary Sequence Secondary protein structure The spatial structure the protein assumes along its axis (its “native conformation” or min. free energy) This gives a protein functional properties such as flexibility and strength Tertiary Structure of Proteins 3-D organization of a polypeptide chain Compacts proteins Interior is mostly devoid of water or charge groups 3-D folding of chain Quaternary Structure of Proteins Non-covalent associations of protein units Shape Interactions of Proteins Protein Structure Globular - polypeptide folded upon itself in a spherical structure – polypeptide is arranged along a common straight axis Fibrous Classification of simple proteins Composed of amino acids and based on solubility. Every food has a mixture of these protein types in different ratios. Albumins – soluble in pure water Globulins – Soluble in salt solutions at pH 7.0, but insoluble in pure water Glutelins – soluble in dilute acid or base, but insoluble in pure water Prolamins – soluble in 50-90% ethanol, but insoluble in pure water Scleroproteins – insoluble in neutral solvents and resistant to enzymatic hydrolysis Histones – soluble in pure water and precipitated by ammonia; typically basic proteins Protamines – extremely basic proteins of low molecular weight Classification of complex proteins A protein with a non-protein functional group attached Glycoproteins- carbohydrate attached to protein Lipoproteins – lipid material attached to proteins Phosphoproteins- phosphate groups attached Chromoprotein- prosthetic groups associated with colored compounds (i.e. hemoglobin) Emulsoids and Suspensiods Proteins should be thought of as solids Not in true solution, but bond to a lot of water Can be described in 2 ways: Emulsoids- have close to the same surface charge with many shells of bound water Suspensoids- colloidal particles that are suspended by charge alone Functional Properties of Proteins 3 major categories Hydration properties Structure formation Protein to water interactions Dispersibility, solubility, adhesion, Water holding capacity, viscosity Protein to protein interactions Gel formation, precipitation, Aggregation Surface properties Protein to interface interactions Foaming, emulsification Proteins and peptide chains are “directional”. That means the chain has a free alpha amino group and a free carboxyl group. The Amino Terminus (N-Terminus) is the end of the chain containing the free alpha amino function. The Carboxy Terminus (C-Terminus) is the end of the chain containing the free carboxyl group. NH3 N C HOOC Proteins: more than just energy “Functional” properties Emulsifier Foaming = egg whites Gel formation = jello Water binding or thickening Participation in browning reactions Enzymes (more on this next week) Enzymes Proteins that act as catalysts Can be good or bad Ripening of fruits, vegetables Meat tenderization Destruction of color, flavor Heat preservation, inactivates Blanching, cooking Proteins Changes in structure Denaturation Breaking of any structure except primary Reversible or irreversible, depending on severity of the denaturation process Examples: Heat - frying an egg High salt content High alcohol content Low or High pH Extreme physical agitation Enzyme action (proteases) Protein Structure (part of the tertiary structure) Globular - polypeptide folded upon itself in a spherical structure – polypeptide is arranged along a common straight axis (beta-pleated sheet) Fibrous Classification of simple proteins Composed of amino acids and based on solubility. Every food has a mixture of these protein types in different ratios. Albumins – soluble in pure water Globulins – Soluble in salt solutions at pH 7.0, but insoluble in pure water Glutelins – soluble in dilute acid or base, but insoluble in pure water Prolamins – soluble in 50-90% ethanol, but insoluble in pure water Scleroproteins – insoluble in neutral solvents and resistant to enzymatic hydrolysis Histones – soluble in pure water and precipitated by ammonia; typically basic proteins Protamines – extremely basic proteins of low molecular weight Classification of complex proteins A protein with a non-protein functional group attached Glycoproteins- carbohydrate attached to protein (i.e. ovomucin) Lipoproteins – lipid material attached to proteins (i.e. HDL and LDL) Phosphoproteins- phosphate groups attached (i.e. casein) Chromoprotein- prosthetic groups associated with colored compounds (i.e. hemoglobin) Emulsoids and Suspensiods Proteins should be thought of as solids Not all in a true solution, but bond to a lot of water Can be described in 2 ways: Emulsoids- have close to the same surface charge, with many “shells” of bound water Suspensoids- colloidal particles that are suspended by charge alone Functional Properties of Proteins 3 major categories Hydration properties Protein to water interactions Structure formation Dispersion, solubility, adhesion, viscosity Water holding capacity Protein to protein interactions Gel formation, precipitation, aggregation Surface properties Protein to interface interactions Foaming and emulsification 1. Hydration Properties (protein to water) Most foods are hydrated to some extent. Behavior of proteins are influenced by the presence of water and water activity Dry proteins must be hydrated (food process or human digestion) Solubility- as a rule of thumb, denatured proteins are less soluble than native proteins Many proteins (particularly suspensoids) aggregate or precipitate at their isoelectric point (IEP) Viscosity- viscosity is highly influenced by the size and shape of dispersed proteins Influenced by pH Swelling of proteins Overall solubility of a protein 2. Structure Formation (protein to protein) Gels - formation of a protein 3-D network is from a balance between attractive and repulsive forces between adjacent polypeptides Gelation- denatured proteins aggregate and form an ordered protein matrix Plays major role in foods and water control Water absorption and thickening Formation of solid, visco-elastic gels In most cases, a thermal treatment is required followed by cooling Yet a protein does not have to be soluble to form a gel (emulsoid) Texturization – Proteins are responsible for the structure and texture of many foods Meat, bread dough, gelatin Proteins can be “texturized” or modified to change their functional properties (i.e. salts, acid/alkali, oxidants/reductants) Can also be processed to mimic other proteins (i.e. surimi) 3. Surface Properties (protein to interface) Emulsions- Ability for a protein to unfold (tertiary denaturation) and expose hydrophobic sites that can interact with lipids. Alters viscosity Proteins must be “flexible” Overall net charge and amino acid composition Foams- dispersion of gas bubbles in a liquid or highly viscous medium Solubility of the protein is critical; concentration Bubble size (smaller is stronger) Duration and intensity of agitation Mild heat improves foaming; excessive heat destroys Salt and lipids reduce foam stability Some metal ions and sugar increase foam stability Quick Application: Food Protein Systems Milk- Emulsoid and suspensoid system Classified as whey proteins and caseins Casein - a phosphoprotein in a micelle structure Suspensoid - coagulates at IEP (casein) Egg (Albumen) – Emulsoid Surface denatures very easily Heating drives off the structural water and creates a strong protein to protein interaction Cannot make foam from severely denatured egg white, requires bound water and native conformation Factors Affecting Changes to Proteins Denaturation Aggregation Salts Gelation Changes to Proteins Native State The natural form of a protein from a food The unique way the polypeptide chain is oriented There is only 1 native state; but many altered states The native state can be fragile to: Acids Alkali Salts Heat Alcohol Pressure Mixing (shear) Oxidants (form bonds) and antioxidants (break bonds) Changes to Proteins Denaturation Any modification to the structural state The structure can be re-formed If severe, the denatured state is permanent Denatured proteins are common in processed foods Decreased water solubility (i.e. cheese, bread) Increased viscosity (fermented dairy products) Altered water-holding capacity Loss of enzyme activity Increased digestibility Changes to Proteins Temperature is the most common way to denature a protein Both hot and cold conditions affect proteins Heating affects the tertiary structure Every tried to freeze milk? Eggs? Mild heat can activate enzymes Hydrogen and ionic bonds dissociate Hydrophobic regions are exposed Hydration increases, or entraps water Viscosity increases accordingly Changes to Proteins We discussed protein solubility characteristics Solubility depends on the nature of the solution Water-soluble proteins generally have more polar amino acids on their surface. Less soluble proteins have less polar amino acids and/or functional groups on their surface. Isoelectric Precipitations Proteins ---++ have no net charge at their IEP ----++ -++ -- ++ ++ ++ ++ ++ ++ Strong Repulsion (net negative charge) -- -- -- --- Aggregation (net neutral charge) Strong Repulsion (net positive charge) ++ -++ ++ ++ ++ --++ -++ ++ ++ Isoelectric Precipitations Proteins -- --- -- -- -- Na+ can be “salted out”, adding charges Na+ Na+ Aggregation (net neutral charge) ++ ++ ++ ++ ++ ++ ClCl- Cl- Measuring IEP Precipitations Empirical measurements for precipitation A protein is dispersed in a buffered solution Add salt at various concentrations Add alcohols (disrupt hydrophobic regions) Change the pH Add surfactant detergents (i.e. SDS) Centrifuge and The measure quantitatively pellet will be insoluble protein The supernatant will be soluble protein Gel Formation Many foods owe their physical properties to a gel formation. Influences quality and perception. Cheese, fermented dairy, hotdogs, custards, etc As little as 1% protein may be needed to form a rigid gel for a food. Most protein-based gels are thermally-induced Thermally irreversible gels are most common Cause water to be entrapped, and a gel-matrix formation Gel formed during heating, maintained after cooling Will not reform when re-heated and cooled Thermally reversible gels Gel formed after heating/cooling. Added heat will melt the gel. Gel Formation Many foods owe their physical properties to a gel formation. Influences quality and perception. Cheese, fermented dairy, hotdogs, custards, etc As little as 1% protein may be needed to form a rigid gel for a food. Most protein-based gels are thermally-induced Thermally irreversible gels are most common Cause water to be entrapped, and a gel-matrix formation Gel formed during heating, maintained after cooling Will not reform when re-heated and cooled Thermally reversible gels Gel formed after heating/cooling. Added heat will melt the gel. Processing and Storage Decreases Loss of nutritional value in some cases Severity Loss spoilage of foods, increases shelf life of processing of functionality Denatured Both proteins have far fewer functional aspects desirable and undesirable flavor changes Processing and Storage Proteins are affected by Heat Extremes in pH (remember the freezing example?) Oxidizing conditions Oxidizing additives, lipid oxidation, pro-oxidants Reactions with reducing sugars in browning rxns Processing and Storage Mild heat treatments May slightly reduce protein solubility Cause some denaturation Can inactive some enzyme Improves digestibility of some proteins Severe heat treatments (for example: >100°C) Some sulfur amino acids are damaged Deamination can occur Release of hydrogen sulfide, etc (stinky) Release of ammonia (stinky) Very high temperatures (>180°C) Some of the roasted smells that occur with peanuts or coffee Enzyme Influencing Factors Enzymes are proteins that act as biological catalysts They are influenced in foods by: Temperature pH Water activity Ionic strength (ie. Salt concentrations) Presence of other agents in solution Meta chelators Reducing agents Other inhibitors Enzyme Influencing Factors Temperature-dependence of enzymes Every enzyme has an optimal temperature for maximal activity The effectiveness of an enzyme: Enzyme activity For most enzymes, it is 30-40°C Many enzymes denature >45°C Each enzyme is different, and vary by isozymes Often an enzyme is at is maximal activity just before it denatures at its maximum temperature pH Like temp, enzymes have an optimal pH where they are maximally active Generally between 4 and 8 with Most many exceptions have a very narrow pH range where they show activity. This influences their selectivity and activity. Water Activity Enzymes need free water to operate Low Aw foods have very slow enzyme reactions Ionic Strength Some ions may be needed by active sites on the protein Ions may be a link between the enzyme and substrate Ions change the surface charge on the enzyme Ions may block, inhibit, or remove an inhibitor Others, enzyme-specific Common Enzymes in Foods Polyphenol oxidase Plant cell wall degrading enzymes Proteases Lipases Peroxidase/Catalase Amylase Ascorbic acid oxidase Lipoxygenase