1 / 19

OBJECTIVES 1. Stability of vitamins; 2. Changes during food storage and treatment;

VITAMINS – STABILITY AND THERMAL TRANSFORMATIONS. OBJECTIVES 1. Stability of vitamins; 2. Changes during food storage and treatment; 3. Chemical reactions of vitamins - examples; 4. Ascorbic acid in Maillard reaction. VITAMINS – STABILITY AND THERMAL TRANSFORMATIONS. 1. !.

garyo
Télécharger la présentation

OBJECTIVES 1. Stability of vitamins; 2. Changes during food storage and treatment;

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS OBJECTIVES 1. Stability of vitamins; 2. Changes during food storage and treatment; 3. Chemical reactions of vitamins - examples; 4. Ascorbic acid in Maillard reaction.

  2. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 1 ! • Roles of the vitamins 1.1. As coenzymes or their precursors; 1.2. As a components of the defensive antioxidant systems; 1.3. As a factors of the genetic regulation; 1.4. Special functions (vitamin A – vision, ascorbate anion participates In reactions of hydroxylation).

  3. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 2 2. Stability

  4. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 3 2. Stability of vitamins added to breakfast cereal products

  5. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 5 3. General factors influencing availability, loss and stability of vitamins 3.2. Changes after harvesting -enzymatic -chemical – in results of treatment with chemical reagents (pineapple, banana – augmentation of polyphenols; tomato – increase ofcarotenoids (lycopene, β-carotene) 3.3. Influence of the initial treatment – chopping, peeling, washing, milling etc. -peeling (industrially) – often accompanied with alkaline treatment; loss of folic acid (vitamin B9, vitamin С, thiamin; negligible losses; -washing– loss of water soluble vitamins;

  6. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 7 3. General factors influencing availability, loss and stability of vitamins 3.4. Blanching and thermal treatments Blanching – inactivation of the enzymes, microorganisms reduction (positive effect on the vitamins stability) 10 minutes

  7. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 8 3. General factors influencing availability, loss and stability of vitamins 3.4. Blanching and thermal treatments Thermal treatment – influence of lot of parameters on the vitamins stability (рН, aw (moisture content), cations, oxygen, type of the raw material, presence of other compounds, etc.)

  8. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 9 3. General factors influencing availability, loss and stability of vitamins 3.5. Storage – compared to thermal treatment, less losses of vitamins

  9. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 10 3. General factors influencing availability, loss and stability of vitamins 3.6. Influence of other compounds added - oxidants – hypochlorite, ozone (degradation of vitamins С, В1) - SO2 – protective effect on vitamin С, but destructive for thiamin, vitamin В6 - nitrites – used as preservatives and for better look of meat; to avoid formation of nitrosamines vitamins C and E is added (due to the oxidation of vitamins is formed NO, but not a N2O3 – the primary nitrosating agent) - acidity regulators(acidulants) – improving stability of vitamin C, thiamin etc.

  10. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 11 4. Thermal transformations 4.1. Vitamin A:

  11. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 12 4. Thermal transformations 4.2. Vitamin В6 – anemia; reactions ofdecarboxylation, transamination, racemization, С-С split etc.)

  12. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 13 4. Thermal transformations 4.2. Vitamin В6 Case study: Influence of the chemical structure of the vitamin on the thermal stability and availability (50ths of the XIX century in USA) – milk products consumed by children; Observation – part of the kids suffer from convulsive seizures; Solution: changing the pyridoxal with pyridoxine(reason – the thermal treatment of the milk during sterilization about 60% of the B6 (pyridoxal form) is destroyed but the pyridoxine is stable).

  13. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 14 4. Thermal transformations Other possibility – binding to proteins (formation of amide bonds) Interaction with free radicals (obtained during degradation of vitamin C, lipid peroxidation, light absorption etc.) – degradation and loss of vitamin activity.

  14. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 15 4. Thermal transformations 4.3. Vitamin C (E300) Reducing agent in foodstuffs Biological activity Antioxidant in foodstuffs L-ascorbic acid Inhibitor of the enzymatic browning Inhibitor of the non-enzymatic browning Carbonyl component in Maillard reaction Role of the L-ascorbic acid in foods

  15. ! VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 16 4. Thermal transformations 4.3. Vitamin C (E300) Lactone of 2-keto-L-gulonic acid L-ascorbic acid D-ascorbic acid L-isoascorbic acid D-isoascorbic acid - Easily oxidized – formation of ascorbate anion and dehydroascorbic acid

  16. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 17 4. Thermal transformations 4.3. Vitamin C (E300) Transformations and degradation of vitamin C Tree major type products are formed: - polymeric products; - unsaturated carboxylic acids with 5 or 6 C atoms; - products of fragmentation with 5 or less C atoms.

  17. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 19 4. Thermal transformations 4.3. Vitamin C (E300) - Carbonyl component in the Maillard reaction;

  18. ! VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 20 4. Thermal transformations 4.3. Vitamin C (E300) Carbonyl component in the Maillard reaction – participate as reductone; participates in Strecker degradation (formation of sorbamic acid)

  19. VITAMINS – STABILITY AND THERMALTRANSFORMATIONS 21 4. Thermal transformations 4.3. Vitamin C (E300) Carbonyl component in the Maillard reaction – participate as reductone; participates in Strecker degradation (formation of sorbamic acid) Sorbamic acid DHA – dehydroascorbic acid

More Related