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Food Toxicology
Learning Objectives
Discuss the general principles behind food processing
and preparation.
Toxicants Formed During List the major natural processes modifying food.
Food Processing List the major food processing approaches.
Describe the physical chemistry background of
Food Toxicology toxicant formation in food
processing.
Instructor: Gregory Möller, Ph.D. Describe N-Nitrosamine
University of Idaho formation from nitrites.
Explain the formation of
polycyclic aromatic
2 hydrocarbons in cooking.
Food Toxicology Food Toxicology
Learning Objectives Food Processing and Preparation
Describe amino acid pyrolysates and their formation Conversion of raw vegetable, animal, or marine
in cooking. products into food for consumption.
Explain the formation of Maillard reaction products. Preservation of food is the most important reason.
Describe Lysinoalanine cross-linkage from – Usually by reducing or eliminating microbial contamination.
alkali/heat treatment of proteins. Can result in intermediate or final food products.
Explore the background and Involves labor, energy,
risk assessment of acrylamide machinery, and knowledge.
formation in foods prepared at Can be commercial or
high temperatures. consumer level.
3 4 Heldman& Hartel
Food Toxicology Food Toxicology
Food Processing and Preparation: Why Food Processing and Preparation: General
Preservation allows longer term availability of food. Addition of thermal energy and elevated
– Economic and food availability dimensions: shelf-life. temperatures (e.g. cooking, sterilization).
Major role in establishing and maintaining microbial Removal of thermal energy and reduced
food safety (e.g. pasteurization). temperatures (e.g. frozen foods). Encarta
Removal of water and reduced moisture content
Decreases toxicity of some foods (e.g. lectins beans). (e.g. dried fruit).
Conversion into new foods Use of packaging (e.g. canning).
(e.g. cheese, beer). Mixtures of ingredients
Supplementation, fortification (e.g. water).
of food (e.g. fortified milk). Addition of modifiers and
additives (e.g. salt, sugar,
Sensory, diversity, nutrition. starch).
5 6
1
Food Toxicology Food Toxicology
Natural Processes Modifying Food Food Processing Approaches
Spoilage and “available” Thermal processing.
microorganisms (e.g. wine yeasts). Blanching and pasteurization.
Atmospheric O2 oxidation. Sterilization.
Atmospheric CO2 pH buffering. Refrigerated storage.
Food enzyme release (e.g. cassava). Freezing and frozen food storage.
Post-harvest instability Liquid concentration.
(e.g. potato greening/sprouting).
Environmental equilibria. Dehydration.
– Thermal (ambient temperature). Physical processes.
– Moisture (ambient humidity). – Mechanical separation.
Contamination. –Extrusion.
– Water, insects, vessels, natural Irradiation.
7 products (green potatoes, weeds). 8
Food Toxicology Food Toxicology
Chemistry of Processing Toxicant Formation Food Processing Toxicants, Pro-Toxicants
Chemical thermodynamics and kinetics apply. Chemicals added or created during food processing
Non-spontaneous reactions can occur at higher can be anti-nutritive, toxicants, or pro-toxicants.
temperatures. Anti-nutritive chemicals or processes will block,
Gibbs free energy change of a chemical reaction. interfere, or destroy nutrient availability.
ΔG(J/mol) = ΔH(J/mol) - T(K) ΔS(J/molK) Toxic chemicals formed from food
– Importance of enzymes processing will be dose dependent
and catalysts. and subject to biotransformation,
Kinetics of quality change sequestration, and elimination.
are related to temperature. Pro-toxicants added or created
– Arrhenius equation. during food processing can
undergo toxication during
9 10digestion or biotransformation.
Food Toxicology Food Toxicology
Food Processing and Preparation Toxicants N-Nitrosamine Formation from Nitrites
N-Nitrosamine formation from nitrites. Nitrite used in curing meat and fish
Polycyclic aromatic hydrocarbons. products.
Amino acid pyrolysates. Has antimicrobial activity, sensory
Maillard reaction products. attributes, and reacts with myoglobin
and hemoglobin to form red nitrosyl
Food irradiation - unique radiolytic products (URPs) compounds.
from ionizing radiation. Nitrite reacts with 2º, 3º amines to form
Lipid oxidation products. stable nitrosoamines.
Lysinoalanine cross-linkage from High temperature processing
alkali/heat treatment of proteins. and protein degradation to
2º, 3º amines increase rate
Acrylamide formation in foods of formation.
prepared at high temperatures. Carcinogenic, mutagenic.
11 12
2
Food Toxicology Food Toxicology
Formation of Nitrosamine Nitrosamine: Alkylating Agent Formation
+ + RCH Shibamoto
NO +H HONO NO +HO 2 Bjeldanes
2 2 N N O Dialkylnitrosamine
R NH R' CH2
2 Enzymatic -hydroxylation
α
H+ +RNNO RCH
2 2
N N O -Hydroxynitrosamine
N-Nitrosamine formation α
R' CH
NO NO OH R' CHO Aldehyde
H O HNO N O
N 2 N RCH
+CO 2
2 N N O Monoalkylnitrosamine
OH OH H
Proline Nitrosopyrrolidine H
R C N N R H CNN OH
Diazoalkane 2
Diazohydroxide
- + Alkyldiazonium
O N RCHN N
O N N
N
N + +
2 RCHAlkylcarboniumion
13 Dimethylnitrosamine Diethylnitrosamine 14 2
Food Toxicology Food Toxicology
Polycyclic Aromatic Hydrocarbons (PAH) Polycyclic Aromatic Hydrocarbons
Formed in the high temperature pyrolysis of
carbohydrates in grilling and smoking of meats.
Endogenous food sources and environmental
contamination are also important.
– Products of combustion. Benzo[a]pyrene
Carcinogenic, mutagenic. Benzo[b]fluoranthrene
Chrysene
15 16 Benzo[a]anthracene
Food Toxicology Food Toxicology
PAH Carcinogenic Activation Protein Reaction: Processing and Storage
Bayregion 11 Marquardt Hurrell
10 Oxidizing Lipids Reducing Sugars
9
8 Treatments Polyphenols
7 O
7,8-Epoxide Protein
O
Organoleptic Nutritional Possible
HO HO Changes Changes Toxicity
OH OH
7,8-Diol-epoxide 7,8-Diol
(reactive) Tryptophan
Lysine Methionine Cystine
17 DNA 18
3
Food Toxicology Food Toxicology
Simplified Scheme of the Maillard Reactions Maillard Reaction: Non-Enzymatic Browning
Reducing Sugar + Amino Compound Coffee
CH DEOXYKETOSYLCOMPOUND
3 STRECKER Bread Desirable color,
CO HC DEGRADATION Cocoa flavor and aroma
methyl O aminoacid+ Cooked meats (pyrazines, aldehydes)
COdicarbonyl C O dicarbonyl
intermediates 3-Deoxyhexosone Beer
CHOH CH2 intermediates
CHOH Strecker Milk Nutritional losses
Fission aldehyde + Infant food Undesirable color, flavor
DEHYDRATION aminocompound+
CO
yields short chain 2
carbonyls, dicarbonyls
yields 5-hydroxy
methyl-2-furaldehyde
MELANOIDINFORMATION
bythe polymerization of intermediate
19 Hurrell compounds, production of N-heterocyclics 20 Hurrell
Food Toxicology Food Toxicology
Amino Acid Pyrolysates Formation of β-Carbolines
Heterocyclic aromatic amines (HCAs) formed during Free Friedman
Tryptophan HO
broiling of meat, fish, or other high protein-rich foods. O Carbonylamine C O
High temperature thermal degradation products of OH
tryptophan (β-carbolines) and other amino acids NH HEAT H NH N
2 N C N
(imidazo-quinoline or imidazo-quinoxalin-2-amine N H R H C
H H OH H R
derivatives - IQ compounds). R C
Also formed from the reaction O HO
of Maillard products (pyridines C O
or pyrazines, and aldehydes) -CO2
with creatinine. N NH
N C N C
Mutagenic (form DNA adducts). H H R
R H
Β - Carboline Schiff-base
21 Erbersdobler 22
Food Toxicology Food Toxicology
Imidazo-Quinolines & Imidazo-Quinaxolines Imidazo-Quinolines & Imidazo-Quinaxolines
Hexose Amino acid Creatine Friedman NH
NH N 2
NH3+ N
C H O + OH N
6 12 6 CH O- H N N N
R 2 Y Z N IQ
Strecker O O
Degradation
X N N
R 2-amino-3-methylimidazo
Y Z O N (4,5-f)quinoline
CR O
++
H HN N
X N H NH
2
Z=CHPyridine Aldehyde Creatinine N
Z=NPyrazine MeIQx
X Y Z R N N
IQ H H CH H
MeIQ H H CH Me N
MeIQx H Me N H 2-amino-3,8-dimethylimidazo
23 7, 8 diMeIQx Me Me N H 24 (4,5-f)quinoxaline
4, 8 diMeIQx H Me N Me
4
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