Advanced Certificate in Nutrition - Foodborne illness and food preservation - PDF

Summary

This document discusses foodborne illness caused by viruses, molds, and protozoa, along with methods of food preservation, including physical, chemical, and biological techniques. It also covers pasteurization and sterilization as methods for food safety.

Full Transcript

Advanced Certificate in Nutrition

Foodborne illness:
Virus, Mold, and Protozoa

Dr. Rachel Ching
[email protected]
1

Learning outcome
• Recognize the characteristics, reservoir, mode of transmission,
associated illness of the microorganisms (virus, mold, and protozoa)
that commonly cause foodborne illness

2

Viral foodborne illnesses
• Virus
§ Microscopic parasite
§ Generally, much smaller than bacteria
§ Only replicate inside the living cells of organisms
§ Infect host cells to reproduce

• Human usually get infected with virus via
§ Ingestion and then shed in feces
§ Contaminated water sources
§ Flies (not important)

3

Viral foodborne illnesses
• Food contamination
1. Primary contamination
• Food can be naturally contaminated during
primary production
§ E.g. Filter-feeding shellfish most common food
contaminated at water source
§ E.g. Fruit or vegetable contaminated with
polluted water during irrigation

2. Secondary contamination
• Contamination caused by food handlers, carriers or
the contaminated food preparation area
4

Common viruses causing foodborne illness
1. Norovirus
2. Rotavirus
3. Hepatitis A virus

1. Norovirus 諾如病毒
Characteristics

RNA virus
• 3 - 35nm in diameter
• Account for almost one-third of the non-bacterial gastroenteritis
• Also known as “winter vomiting bug”

Growth

•
•

Relatively resistant to heat, disinfection and pH changes
Survive freezing and high temperature (up to 60°C)

Types of illness

•

Infection

Reservoir

•

Human

Mode of transmission

•
•
•
•
•

Mainly transmitted between hand and mouth contact (e.g. Fecal-oral transmission)
Direct contact (like shaking hand) with the infected persons
Touch the contaminated surface
Raw or inadequate cooked shellfish especially bivalve mollusks (e.g. oyster)
Salad made with contaminated fruits and vegetables

Onset time

1-2 days

Symptoms

•
•
•
•
•
•

Vomiting
Diarrhea
Mild fever
Nausea
Stomach pain
Easily infect children and elderly people

6

7

2. Rotavirus 輪狀病毒
Characteristics

RNA virus
• 70nm in diameter
• Major cause of gastroenteritis in infants and children

Growth

•

Relatively resistant to heat, disinfection and pH changes

Types of illness

•

Infection

Reservoir

•

Human

•
•
•
•

Fecal-oral transmission
Person-to-person transmission
Food and waterborne
Caused by cross contamination of food handlers in preparing ready-to-eat foods e.g. salad, finger
foods, etc

Mode of transmission
Onset time

1-3 days

Symptoms

•
•
•
•
•

Vomiting
Diarrhea
Nausea
Fever
Death only found in severe cases
9

3. Hepatitis A Virus 甲型肝炎病毒
Characteristics

RNA virus
• 27nm in diameter
• Cause viral liver infection - common around the world

Growth

•

Relatively resistant to heat, disinfection and pH changes

Types of illness

•

Infection

Reservoir

•

Human

Mode of transmission

•
•
•

Fecal-oral transmission
Person-to-person transmission
Raw or undercooked shellfish

Onset time

12-50 days
•

Symptoms

•

First phase
• Fatigue, diarrhea with liver symptoms e.g. yellowing of the skin and the whites of your eyes,
pale-colored feces, dark urine
Second phase
• Extensive liver damage, associated with colonization of liver

10

Mold toxins occurring in foods
• Molds
§ Primarily soil organism
§ Many produce toxins – called mycotoxins
§ Food spoiled by molds may contain mycotoxins

Molds

• Mycotoxin related foodborne illness
1. Ergot poisoning
2. Aflatoxin poisoning

12

1. Ergot poisoning ⿆⾓中毒
• Ergot
§ A group of molds produce toxins that affect neurons
• Genus Claviceps

§ Claviceps purpurea
• Plant pathogen
• Grows inside rye 黑麥 and sometimes wheat kernels
• Forms sclerotium (fruiting structure)
§ Lightly curved, black to purple kernel
§ Contain neuron toxin

13

1. Ergot poisoning ⿆⾓中毒
• Ergot poisoning
§ Toxin is absorbed in the intestines
§ Transported to neurons
§ Peripheral neuron degenerate à tissue degenerate

• Illness
§ Ergotism

• Symptoms
§ Vision problems, confusion, unconsciousness, and
gangrene in toes and fingers

14

2. Aflatoxin poisoning
Aspergillus flavus and other Aspergillus species
§ Grow in grains and nuts to produce toxins
• Damp and warm condition

§ Aflatoxin
• Lipid soluble
• Not destroyed by normal cooking conditions
• Carcinogenic

§ Present in animals' feeds (e.g. cottonseed, corn, rice,
soybean) as well as food sources of human (e.g.
peanuts, livestock, cow milk)

15

2. Aflatoxin poisoning
• Mode of transmission
§ Contaminated animal feeds (e.g. cottonseed, corn, rice, soybean)
§ Contaminated food sources of human (e.g. peanuts, livestock, cow milk)

• Symptom
§ Liver degeneration
§ Liver tumor
§ Stunted growth in children

16

Common protozoa causing foodborne illness
• Ciguatera food poisoning: A foodborne illness caused by eating
reef fish (e.g. tiger grouper contaminated with toxins
called Ciguatoxins
• Ciguatoxin

Parasites (Protozoa)

§ Heat-stable
§ Lipid-soluble neurological toxin
§ Accumulated in fish tissues

• Toxin produced by dinoflagellate Gambierdiscus toxicus

17

Common protozoa causing foodborne illness
• Symptoms
§ Appear within 3-5 hours after consumption
§ Death is uncommon
§ Gut illness: Vomiting, diarrhea, abdominal pain
§ Weakness
§ Muscle pain
§ Itching
§ Headache
§ Sweating
§ Dizziness
§ Neurological numbness and tingling around lips,
hands, feet
18

Advanced Certificate in Nutrition

Food preservation

Dr. Rachel Ching
[email protected]
19

Learning outcome
• Recognize the objectives of food preservation
• Understand the mechanism of different food preservation methods, and
how each method manipulates the factors necessary for the growth of
microorganisms
• Recognize the differences between pasteurization and sterilization
• Recognize the kinetics of thermal destruction of microorganisms

20

Food preservation
• The process of treating and handling food to stop or slow down food
spoilage, loss of quality, edibility, or nutritional value and thus allow for
longer food storage

21

The objectives of food preservation
• Prevent spoilage of food and food products and extend their shelf life
§ Minimize or inactivate spoilage microorganisms

• Ensure the safety of food products
§ Inactivate harmful pathogens present in the food

22

Principles of food preservation
• Elimination or inactivation of microorganisms
§ E.g. using heat to kill the microorganisms in food

• Stopping the action of enzymes
§ To reduce the self-decomposition of food

• Prevention of oxidation
§ To reduce the rate of lipid oxidation

23

Methods of food preservation
• Food preservation methods
§ Manipulating one or more intrinsic or extrinsic factors
§ Slowing down microbial growth or inactivating (killing) microorganisms

24

How to control microbial growth
• Intrinsic factors
§ Water activity
§ pH
§ Redox potential
§ Nutrient content

• Extrinsic factors
• Temperature
• Atmosphere
• Relative humidity

Which factors can be manipulated?

25

Methods of food preservation
A. Physical methods
•
•
•
•
•
•

Heating
Low temperature
Dehydration
Modified atmosphere packaging
Radiation
Filtration

B. Chemical methods
•
•
•
•

Addition of acid
Addition of salt
Addition of sugar
Other food preservatives

C. Biological methods
• Fermentation

26

A. Physical methods of food preservation

27

Heat treatment - 1. Pasteurization
• Pasteurization is a thermal process used to inactivate
enzymes and eliminate viable pathogenic microorganisms
from heat sensitive food
§ E.g. Milk, fruit juice, wine, egg

• Relatively mild heat treatment
• Food is heated to < 100˚C for a definite length of time, and
then cooled immediately to slow down microbial growth in
food
• Refrigeration storage needed with 2-3 weeks shelf life

28

Heat treatment - 1. Pasteurization
• The process involves two steps: heating and cooling
• Different time-temperature combination
§ Low temperature pasteurization
• 63˚C for 30 minutes

§ High temperature short time (HTST) pasteurization
• E.g. 72˚C for 15 seconds
• Shorten the heating time can better retain nutritional and sensory quality

29

Heat treatment - 1. Pasteurization
A. HTST pasteurization of raw milk
§ Or called traditional pasteurization
§ Heating the milk briefly to 72 °C for about 15 seconds, to kill disease-causing
microbes (e.g. Salmonella, Escherichia coli O157, Campylobacter) that can be found
in raw milk
§ Followed by rapid cooling (4 °C)
§ Refrigeration storage needed

Link - production of pasteurized milk 30

Heat treatment - 1. Pasteurization
B. Ultra-high temperature (UHT) pasteurization of raw milk
§ Heating milk to ~138 °C for 2-3 seconds, then rapidly cooling it down
§ Milk is packaged in sterile, hermetically-sealed container (Aseptic packaging)
§ Refrigeration is NOT required until opened
§ Shelf stable for 6 months
§ Undesirable effect on the taste of milk – cooked, burnt taste

31

Heat treatment - 1. Pasteurization

72˚C

UHT milk

32

Heat treatment – 2. Sterilization
• Sterilization
§ A process completely kills or removes all life forms, including bacteria and other
organisms (E.g. endospores) in the material or an object
§ Heating is the most commonly used method of sterilization
• E.g. Wet heating at 121°C for 15-20 minutes

§ Sterilized food products are shelf stable for > 6 months

33

Heat treatment – 2. Sterilization
• Commercial sterilization
§ Combine heat and vacuum seal to destroy all spoilage and
pathogenic microorganisms
§ Kill endospores of Clostridium botulinum
§ A treatment used to produce canned food

• Canning (or called retort processing)
§ Food is filled into the containers (e.g. metal cans)
§ Heat sealed cans to destroy bacteria and spores

34

Heat treatment – 2. Sterilization
• Canning
§ Commercial sterilization of low acid foods
• Heating the product at 121°C for a duration
• Sufficient to inactivate Clostridium botulinum spores by 12 log

§ Commercial sterilization of high acid foods
• Heating the product at ~ 100°C
• To destroy both vegetative cells and spores of spoilage microorganisms (particularly
fungal spores)

35

Heat treatment – 2. Sterilization
• One log reduction = 90%
reduction or 10-fold reduction
• 12 log reduction = 12 cycles of log
reduction

Number of
microorganisms

Log of microbial
population

Log reduction
(from original)

1,000,000

106

0

100,000

105

1

10,000

104

2

1,000

103

3

100

102

4

10

101

5

1

100

6

0.1

10-1

7

0.01

10-2

8

0.001

10-3

9

0.0001

10-4

10

0.00001

10-5

11

0.000001

10-6

12

36

Heat treatment – Thermal destruction of microorganism
• Bacterial populations killed by heat or chemicals tend to die at constant rates
§ E.g. 90% every minute

• Microbial Death rate curve, plotted logarithmically (log), shows this constant
death as a straight line

E.g. If heating causes 90% death rate per
minute, it means
• 90% of microorganism is destroyed in the
1st min of heating
• 90% of the remaining population is
destroyed in the 2nd min of heating and
so on
39

Heat treatment – Thermal destruction kinetics
• Three important values used to measure the thermal-killing
efficiency
§ D value
§ Z value
§ F value

40

Heat treatment – Thermal destruction kinetics
• D value (decimal reduction time)
§ The time needed to reduce the number of a given microorganism by 90% (or 1 log
cycle) at a specific temperature
Microbial Death Rate Curve

41

Heat treatment – Thermal destruction kinetics
• D value (decimal reduction time)
§ related to the temperature used in the
process
• D value decreases as the temperature
increases

§ related to the heat resistance of
microorganism
• D values differ for different microbial species
• Higher D value indicates greater heat
resistance

43

Heat treatment – Thermal destruction kinetics
• D values (decimal reduction time)
§ How to express D value ?
• Always express D value with a thermal value (i.e. processing temperature)
• Give the temperature as a subscript to the D
• E.g. D121 = Time required to kill 90% of bacterial population at 121˚C

Q: If microorganism A population is reduced by 90% after exposure to
temperatures of 150˚C for 2 minutes, what is its D value?

45

Heat treatment – Thermal destruction kinetics
• D-value can be estimated from the Death Rate Curve

Heat treatment – Thermal destruction kinetics
Q: What is the D100 for microorganism C?

No. of surviving microorganism C

Death rate curve of microorganism C at 100oC
10000

1000

100

10

1
0

2

4

6

8

10

Time (mins)

12

14

16

18
48

Heat treatment – Thermal destruction kinetics
• Z value
§ The increase in temperature required to reduce D value by ten-fold (or 90%)
§ It can be obtained from a Thermal Death Time (TDT) curve
• Plot the logarithms of D-values (heating time) against temperature

50

Heat treatment – Thermal destruction kinetics
• Z-value can be estimated from the Thermal Death Time (TDT) curve

• E.g. Z value = 10˚C à 10˚C increases in temperature (e.g. from 105 ˚C to
115 ˚C) can reduce the D value by 90% (e.g. from 100 minutes to 10
minutes)
51

Heat treatment – Thermal destruction kinetics
Q: What is the Z value for heated Bacillus spores?
Thermal Death Time curve of heated Bacillus spores

Log of D-value (min)

1000

100

10

1
80

82

84

86

88

90

92

94

Temperature (℃)

96

98

100

102

104
52

Heat treatment – Thermal destruction kinetics
• Z value - Implication of TDT curve
§ Time – temperature combination is important for killing microorganism
• The higher the temperature used, the shorter the killing time is

§ D105 = 100 minutes and D115 = 10 minutes
§ 100 minutes at 105˚C has the same lethal effect as 10 minutes at 115˚C
At 105 ˚C, D value = 100min
à Using 100min to kill 90% of
microbes

At 115 ˚C, D value = 10min
à Using 10min to kill 90% of
microbes
54

Heat treatment – Thermal destruction kinetics

55

Heat treatment – Thermal destruction kinetics
• F value (thermal death time)
§ The time in minutes required at a given temperature to reduce the microbial
population to desired sterility level
§ F value can be estimated from Death Rate Curve
T = temperature for sterilization

Sterility level
57

Low temperature
• Refrigeration (or called Chilling)

§ Holding food below ambient temperature and above
freezing (2-8˚C)
§ Retard the growth and metabolic activity of most food
microorganisms
§ Psychrophiles can grow
• E.g. Pseudomonas spp., Listeria monocytogenes

• Freezing

§ Temperature ≤ -18°C
§ Stop the growth and metabolic activity of most food
microorganisms
§ Water unavailable due to ice formation
§ Cell injury
59

Dehydration
• Removal of water from food
• Inhibit microbial growth by decreasing water activity
• Methods
§ Conventional drying (heat-induced)
• Water removal by evaporation
§ Freeze-drying
• Water removal by sublimation
• Retain the food shape, color, and nutrients

60

Dehydration
• Freeze-drying
• Freeze and dehydrate of frozen food (under vacuum state)

61

Modified atmosphere packaging (MAP)
• Altered gaseous environment applied to food enclosed in a gas barrier material
§ Combinations of carbon dioxide, nitrogen, and oxygen

• Inhibit aerobes and delay growth of facultative anaerobes
§ E.g. Pseudomonas, Acinetobacter, and Moraxella
• Retain the moisture content and freshness of food
• Preservation of fruits, meat, poultry, and vegetables
§ Often in conjunction with refrigerated storage

62

Radiation
• Various forms of radiation are used in the preservation
of foods by destruction of microorganisms or inhibition
of biochemical changes
• They include α, β, γ, X-ray, free electron, etc.
• The reactive ions produced by irradiation can destroy
the microorganisms through:
§ changing the structure of cell membrane
§ affecting metabolic enzyme activity
§ affect DNA or RNA in cell-nuclei

• Irradiated food does not become radioactive
• Poultry, red meats, flour, spices, potatoes, fruits,
vegetables, grains can be irradiated
63

Filtration
• Membrane filtration
§ To remove undesirable solids and microorganisms from liquid foods by using a
porous membrane / filter
§ E.g. Water, wine, beer, juice, soft drinks

64

B. Chemical methods of food preservation

65

Addition of acids
• Pickling
§ Increase acidity of foods
i.
ii.

Non-fermented pickling - Immersion of food in
vinegar
Fermented pickling - Natural anaerobic
fermentation in brine (salt solution)
• Produce lactic acid to increase acidity

§ Inhibit the growth of microorganism
§ The resulting food is called a pickle, made from a
mixture of vegetable and fruit

66

Addition of salt
• Curing
§ Or called Salting / Salt curing
§ Addition of salt (sodium chloride) or salt solution
§ Inhibit microbial growth
• Dehydration
§ Draw out water from food by osmosis
• Decrease water activity
§ High concentration of salt binds to water in food
making it unavailable to microorganisms

§ E.g. meat and fish

67

Addition of sugar
• Preservation of fruits with sugar
• This sugar can be solid form, or
high sugar density liquid such as honey, syrup
• Inhibit microbial growth
§ Dehydration (by osmosis)
§ Decrease water activity

• E.g. jams, jellies, and canned fruits

68

Other food preservatives
• Antimicrobial food additives
§ Chemical compounds added to foods
§ Inhibit the growth of microorganism
§ Chemical antimicrobial agents
• Not “natural”
• Controversial
§ E.g. nitrate (NO3-) and nitrite (NO2-) in cured
meat
• A main ingredient in curing salt
• It gives a desirable pink color to meat and
inhibits the growth of microorganisms
• Formation of nitrosamine à carcinogenic

69

Other food preservatives

70

C. Biological methods of food preservation

72

Fermentation
• Fermentation is an incomplete oxidation of sugars
initiated by microorganisms in the anaerobic
condition producing lactic acid, carbon dioxide
and ethanol
• Fermentation by lactic acid bacteria
§ Production of organic acids
• Lower the pH which inhibits the growth of undesirable
microorganisms

§ Production of bacteriocins
• Inhibit the growth of some microorganisms
§ E.g. Nisin – against Gram positive bacteria
73

Self-check exercises
1. What are the purposes of food preservation?
2. Give two principles of food preservation.
3. What is the similarity and difference between pasteurization and
sterilization?
4. Z value is derived from thermal death time curve / death rate curve
(Circle the correct answer)
5. What is curing? How does curing preserve the meat?

74

Self-check exercises
6. State True or False for the following statements regarding
the D value of microorganism C.
§ The D100 of microorganism C is constant if the heating temperature
is unchanged.
§ If the heating temperature is increased, the D value of
microorganism C will be reduced.
§ D value is the time required to reduce 10% of microorganism.

75