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Edit Comment Close Premium member Presentation Transcript Meat Chemistry - Importance of Compositional Components and Chemistry of Each in Processed Meats: Meat Chemistry - Importance of Compositional Components and Chemistry of Each in Processed Meats 1. Water present in greatest quantity in most products important to eating quality and economics remember: water is both a meat component and a non-meat (added) ingredient Functions of water: Functions of water a. palatability juiciness initial juiciness impression contributes to tenderness b. yields / economics must provide water expected to be lost in cooking binding mechanisms for water become important to yields c. universal solvent: c. universal solvent dispersion and distribution of ingredients i.e. nitrite 3% added water allowed in fresh sausage “to facilitate mixing” also critical as a protein solventd. temperature control: d. temperature control improved protein solubility bacterial control thermal capacity, especially ice, is very largeThermal capacity: Thermal capacity Specific heat of water - 1 BTU/lb/oF ice - 0.5 BTU / lb/oF latent heat of crystallization - 144 BTU/lb Example of effects: 10 lbs of cold (32oF) water added to frankfurter emulsion chopped from 32oF to 55oF = 10 lbs x 23oF x 1 BTU/lb/oF = 230 BTU Thermal capacity (continued) Specific heat of water - 1 BTU/lb/oF ice - 0.5 BTU/lb/oF latent heat of crystallization - 144 BTU/lb: Thermal capacity (continued) Specific heat of water - 1 BTU/lb/oF ice - 0.5 BTU/lb/oF latent heat of crystallization - 144 BTU/lb Example of effects: 10 lbs of ice (32oF) added to emulsion at 32oF & chopped to 55oF = 10 lbs x 144 BTU/lb = 1440 BTU (conversion to water) plus 10 lbs x 23oF x 1 BTU/lboF = 230 BTU 1670 BTU (7.5 x that of cold water alone) Temperature control is a major advantage to using frozen meat but frozen meat has less functional protein and thermal capacity is less than ice : Temperature control is a major advantage to using frozen meat but frozen meat has less functional protein and thermal capacity is less than ice Thermal capacity 0.8 BTU/lb/oF (fresh) 0.4 BTU/lb/oF (frozen)Water in meat systems: Water in meat systems Bound by proteins to understand water in meat systems it is necessary to understand water : protein interactions - and- water : water interactionsWater is a unique compound with a unique structure:: Water is a unique compound with a unique structure: two positive poles and two negative poles +H H+ O - - H2OStructure and charged poles create intermolecular “H bonding”: Structure and charged poles create intermolecular “H bonding” Each molecule binds 4 others --- one at each pole therefore water attracts water = water : water interaction Meat also has a variety of polar groups --- due to proteins: Meat also has a variety of polar groups --- due to proteins this is a critical property of proteins and is a unique “fingerprint” for each protein. Why?Proteins are composed of amino acids: Proteins are composed of amino acids amino acids each have polar / non-polar properties and charges combination of amino acids determines protein properties such as protein : water interaction Slide13: R C COOH H NH2Meat proteins first bind water directly to the charged amino acid groups: Meat proteins first bind water directly to the charged amino acid groups This is a small amount of water 5 - 10 g/100 g protein very tightly bound “Bound water”Bound water attracts other water molecules : Bound water attracts other water molecules Another 2 - 3 molecule layer around protein groups (50 - 60 g/100 g protein) = “Immobilized water” Bound water and immobilized water are considered as one in terms of water movement and changes in meat products. : Bound water and immobilized water are considered as one in terms of water movement and changes in meat products. Which leaves water attracted weakly to the bound and immobilized water. = “Free water” (~ 300 g/100 g protein)“Free” water is loosely held and very dependent upon capillary space between and within proteins. : “Free” water is loosely held and very dependent upon capillary space between and within proteins. Muscle structure therefore becomes a determinant of water binding ability Anything which will alter protein structure and spacing will affect water retentionThus, it is myofibrillar proteins that are most important ----- have most polar and charged amino acids. : Thus, it is myofibrillar proteins that are most important ----- have most polar and charged amino acids. 70 -75% - myofibrillar ~ 20% - sarcoplasmic < 10% - stromal (connective tissue) This is why lean muscle is most desirable for processed meats. - and - we need to know how to manipulate proteins to change water binding Three fundamental ways to manipulate water binding ability of meat : Three fundamental ways to manipulate water binding ability of meat 1. pH - concentration of H+ 2. Salt Na+ Cl– 3. Phosphates PO4 (– = )Effects of pH on water binding : Effects of pH on water binding water binding is minimal at about pH 5.0 - 5.2 water binding increases above or below this pH protein – – – + – + – + –: protein – – – + – + – + – pH 6.0 net charge = –3protein – H+ – – + – +H + – + H+–: protein – H+ – – + – +H + – + H+– pH 5.1 net charge = 0 Isoelectric Point +3H +protein H+ – H+ – – + – H+ + H+ – + H+–: protein H+ – H+ – – + – H+ + H+ – + H+– pH 4.5 net charge = +2 +2H +Slide31: + + + + H2O H2O H2O pH 6.0 pH 5.1 pH 4.5Note: Isoelectric Point [Know this]: Note: Isoelectric Point [Know this] pH at which charge on protein = 0 minimum water binding dependent on amino acid composition i.e. will be different for different proteins Effects of salt on water binding: Effects of salt on water binding Shifts isoelectric point curve to the left raises water binding at all typical meat pH’sprotein – – – + – + – + –: protein – – – + – + – + – pH 6.0 net charge = 3 protein – – – + Cl ¯ – + – Cl ¯ + –: protein – – – + Cl ¯ – + – Cl ¯ + – pH 6.0 net charge = –5 + Na Cl Na+ Cl ¯ Note:: Note: salt increases the net negative charge on meat proteins which increases protein repulsion and water binding because more H+ are needed to completely neutralize the negative charges, the pH must be lower to reach the isoelectric point Effects of phosphates on water binding : Effects of phosphates on water binding phosphates are basic and raise the pH of meat phosphates are anions (-) and may create a chloride effect on charges solubilize structural proteins to “loosen” myosin and actinEffects of Phosphates(cont’d): Effects of Phosphates(cont’d) chelate cations such as Ca++ that can crossbridge proteinsprotein + – – – – +: protein + – – – – + + – – – – + + Ca +After pH, salt and phosphate effects are maximized, then other ingredients can be considered for further increases in water binding : After pH, salt and phosphate effects are maximized, then other ingredients can be considered for further increases in water binding i.e. proteins: soy whey caseinate collagen carbohydrates: corn syrup maltodextrins starch hydrocolloids: carrageenan xanthan gumMeasurement of water holding capacity (WHC) : Measurement of water holding capacity (WHC) 1. Drip loss suspend intact muscle sample inside bag or container measure drip weight/drip loss after fixed time period 2. Press method sample placed on dried filter paper and submitted to pressure between two plates separated “water ring” measured with planimeter. Ratio of water ring area to meat ring area is a relative measure of WHC Measurement of water holding capacity (WHC) (continued): Measurement of water holding capacity (WHC) (continued) 3. Centrifuge method muscle sample or blended sample (with water, salt, etc.) centrifuged and separated water measured. 4. Yields after heating samples heated at fixed time/temperature weight loss/water loss measured 5. Nuclear magnetic resonance (NMR) measures relative “freedom” of water molecules to move in magnetic field Increasing WHC is not always desirable i.e. dry sausage, jerky, etc. : Increasing WHC is not always desirable i.e. dry sausage, jerky, etc. Concerns for water : Concerns for water 1. Hard water decreases WHC due to minerals Mg++, Fe++, etc. may reduce effectiveness of phosphates - reaction with mineral cations may cause product discoloration Fe++, Cu+, NO3- may induce rancidity developments from metals like Fe++ or Cu+ can induce “scum” when making injection “pickle” and make other ingredients such as phosphates hard to dissolve2. Nitrate can be a health risk at 10 ppm or more especially for babies : 2. Nitrate can be a health risk at 10 ppm or more especially for babies methemoglobinemiaSlide51: 7/7/2001Hard water = 10 grains/gal or more (175 pmm) : Hard water = 10 grains/gal or more (175 pmm) Ames ground water = 24 grains/gal You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
D ChemistryofWater 4 Cubemiddle Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 188 Category: Entertainment License: All Rights Reserved Like it (1) Dislike it (0) Added: January 01, 2008 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... By: roubeen (29 month(s) ago) thank you for good ppt Saving..... Post Reply Close Saving..... Edit Comment Close Premium member Presentation Transcript Meat Chemistry - Importance of Compositional Components and Chemistry of Each in Processed Meats: Meat Chemistry - Importance of Compositional Components and Chemistry of Each in Processed Meats 1. Water present in greatest quantity in most products important to eating quality and economics remember: water is both a meat component and a non-meat (added) ingredient Functions of water: Functions of water a. palatability juiciness initial juiciness impression contributes to tenderness b. yields / economics must provide water expected to be lost in cooking binding mechanisms for water become important to yields c. universal solvent: c. universal solvent dispersion and distribution of ingredients i.e. nitrite 3% added water allowed in fresh sausage “to facilitate mixing” also critical as a protein solventd. temperature control: d. temperature control improved protein solubility bacterial control thermal capacity, especially ice, is very largeThermal capacity: Thermal capacity Specific heat of water - 1 BTU/lb/oF ice - 0.5 BTU / lb/oF latent heat of crystallization - 144 BTU/lb Example of effects: 10 lbs of cold (32oF) water added to frankfurter emulsion chopped from 32oF to 55oF = 10 lbs x 23oF x 1 BTU/lb/oF = 230 BTU Thermal capacity (continued) Specific heat of water - 1 BTU/lb/oF ice - 0.5 BTU/lb/oF latent heat of crystallization - 144 BTU/lb: Thermal capacity (continued) Specific heat of water - 1 BTU/lb/oF ice - 0.5 BTU/lb/oF latent heat of crystallization - 144 BTU/lb Example of effects: 10 lbs of ice (32oF) added to emulsion at 32oF & chopped to 55oF = 10 lbs x 144 BTU/lb = 1440 BTU (conversion to water) plus 10 lbs x 23oF x 1 BTU/lboF = 230 BTU 1670 BTU (7.5 x that of cold water alone) Temperature control is a major advantage to using frozen meat but frozen meat has less functional protein and thermal capacity is less than ice : Temperature control is a major advantage to using frozen meat but frozen meat has less functional protein and thermal capacity is less than ice Thermal capacity 0.8 BTU/lb/oF (fresh) 0.4 BTU/lb/oF (frozen)Water in meat systems: Water in meat systems Bound by proteins to understand water in meat systems it is necessary to understand water : protein interactions - and- water : water interactionsWater is a unique compound with a unique structure:: Water is a unique compound with a unique structure: two positive poles and two negative poles +H H+ O - - H2OStructure and charged poles create intermolecular “H bonding”: Structure and charged poles create intermolecular “H bonding” Each molecule binds 4 others --- one at each pole therefore water attracts water = water : water interaction Meat also has a variety of polar groups --- due to proteins: Meat also has a variety of polar groups --- due to proteins this is a critical property of proteins and is a unique “fingerprint” for each protein. Why?Proteins are composed of amino acids: Proteins are composed of amino acids amino acids each have polar / non-polar properties and charges combination of amino acids determines protein properties such as protein : water interaction Slide13: R C COOH H NH2Meat proteins first bind water directly to the charged amino acid groups: Meat proteins first bind water directly to the charged amino acid groups This is a small amount of water 5 - 10 g/100 g protein very tightly bound “Bound water”Bound water attracts other water molecules : Bound water attracts other water molecules Another 2 - 3 molecule layer around protein groups (50 - 60 g/100 g protein) = “Immobilized water” Bound water and immobilized water are considered as one in terms of water movement and changes in meat products. : Bound water and immobilized water are considered as one in terms of water movement and changes in meat products. Which leaves water attracted weakly to the bound and immobilized water. = “Free water” (~ 300 g/100 g protein)“Free” water is loosely held and very dependent upon capillary space between and within proteins. : “Free” water is loosely held and very dependent upon capillary space between and within proteins. Muscle structure therefore becomes a determinant of water binding ability Anything which will alter protein structure and spacing will affect water retentionThus, it is myofibrillar proteins that are most important ----- have most polar and charged amino acids. : Thus, it is myofibrillar proteins that are most important ----- have most polar and charged amino acids. 70 -75% - myofibrillar ~ 20% - sarcoplasmic < 10% - stromal (connective tissue) This is why lean muscle is most desirable for processed meats. - and - we need to know how to manipulate proteins to change water binding Three fundamental ways to manipulate water binding ability of meat : Three fundamental ways to manipulate water binding ability of meat 1. pH - concentration of H+ 2. Salt Na+ Cl– 3. Phosphates PO4 (– = )Effects of pH on water binding : Effects of pH on water binding water binding is minimal at about pH 5.0 - 5.2 water binding increases above or below this pH protein – – – + – + – + –: protein – – – + – + – + – pH 6.0 net charge = –3protein – H+ – – + – +H + – + H+–: protein – H+ – – + – +H + – + H+– pH 5.1 net charge = 0 Isoelectric Point +3H +protein H+ – H+ – – + – H+ + H+ – + H+–: protein H+ – H+ – – + – H+ + H+ – + H+– pH 4.5 net charge = +2 +2H +Slide31: + + + + H2O H2O H2O pH 6.0 pH 5.1 pH 4.5Note: Isoelectric Point [Know this]: Note: Isoelectric Point [Know this] pH at which charge on protein = 0 minimum water binding dependent on amino acid composition i.e. will be different for different proteins Effects of salt on water binding: Effects of salt on water binding Shifts isoelectric point curve to the left raises water binding at all typical meat pH’sprotein – – – + – + – + –: protein – – – + – + – + – pH 6.0 net charge = 3 protein – – – + Cl ¯ – + – Cl ¯ + –: protein – – – + Cl ¯ – + – Cl ¯ + – pH 6.0 net charge = –5 + Na Cl Na+ Cl ¯ Note:: Note: salt increases the net negative charge on meat proteins which increases protein repulsion and water binding because more H+ are needed to completely neutralize the negative charges, the pH must be lower to reach the isoelectric point Effects of phosphates on water binding : Effects of phosphates on water binding phosphates are basic and raise the pH of meat phosphates are anions (-) and may create a chloride effect on charges solubilize structural proteins to “loosen” myosin and actinEffects of Phosphates(cont’d): Effects of Phosphates(cont’d) chelate cations such as Ca++ that can crossbridge proteinsprotein + – – – – +: protein + – – – – + + – – – – + + Ca +After pH, salt and phosphate effects are maximized, then other ingredients can be considered for further increases in water binding : After pH, salt and phosphate effects are maximized, then other ingredients can be considered for further increases in water binding i.e. proteins: soy whey caseinate collagen carbohydrates: corn syrup maltodextrins starch hydrocolloids: carrageenan xanthan gumMeasurement of water holding capacity (WHC) : Measurement of water holding capacity (WHC) 1. Drip loss suspend intact muscle sample inside bag or container measure drip weight/drip loss after fixed time period 2. Press method sample placed on dried filter paper and submitted to pressure between two plates separated “water ring” measured with planimeter. Ratio of water ring area to meat ring area is a relative measure of WHC Measurement of water holding capacity (WHC) (continued): Measurement of water holding capacity (WHC) (continued) 3. Centrifuge method muscle sample or blended sample (with water, salt, etc.) centrifuged and separated water measured. 4. Yields after heating samples heated at fixed time/temperature weight loss/water loss measured 5. Nuclear magnetic resonance (NMR) measures relative “freedom” of water molecules to move in magnetic field Increasing WHC is not always desirable i.e. dry sausage, jerky, etc. : Increasing WHC is not always desirable i.e. dry sausage, jerky, etc. Concerns for water : Concerns for water 1. Hard water decreases WHC due to minerals Mg++, Fe++, etc. may reduce effectiveness of phosphates - reaction with mineral cations may cause product discoloration Fe++, Cu+, NO3- may induce rancidity developments from metals like Fe++ or Cu+ can induce “scum” when making injection “pickle” and make other ingredients such as phosphates hard to dissolve2. Nitrate can be a health risk at 10 ppm or more especially for babies : 2. Nitrate can be a health risk at 10 ppm or more especially for babies methemoglobinemiaSlide51: 7/7/2001Hard water = 10 grains/gal or more (175 pmm) : Hard water = 10 grains/gal or more (175 pmm) Ames ground water = 24 grains/gal