Introduction to Manufacturing and Processing Technology in Food PDF

Summary

This document provides an introduction to manufacturing and processing technology in food, along with module descriptions, learning outcomes, overview lecture, and general objectives for learning the subject. The document also discusses topics such as the food industry in Ireland, relevant legislation, trade associations, and food labeling requirements.

Full Transcript

Introduction to
Manufacturing and Processing Technology
in
Food
 Module Description

 Description: Introduces a the range of manufacturing
processes/equipment used in industrial scale food production.
 Learning Outcomes:
 On successful completion of this module the learner will be able to
 1. Describe the structure of the food industry in Ireland
 2. Illustrate the processing steps involved in manufacture of
commercial food items.
 3. Demonstrate a detailed knowledge of the unit operations
involved in the processing of food products.
 4. Describe the equipment used in the food industry and its
operation
 5. Describe ancillary operations and services associated with the
food industry
Overview Lecture
 Objectives

1. To be able to describe the food industry

2. To understand the outline of the process of introducing
new products

3. To be able to discuss the history of preservation of food

4. To be able to describe some new technologies that may
impact on food production and processing.

5. Use of biotechnology and nanotechnology in food
Introduction
 Objectives

1. To be able to describe the food industry

2. To understand the outline of the process of introducing
new products

3. To be able to discuss the history of preservation of food

4. To be able to describe some new technologies that may
impact on food production and processing.

5. Use of biotechnology and nanotechnology in food
 Regulatory Body

 The FSAI is the authority with responsibility for the
enforcement of Irish food safety legislation
 The Food Safety Authority of Ireland (FSAI) was
established under the Food Safety Authority of Ireland
Act, 1998.
 The principal function of the Food Safety Authority of
Ireland is to take all reasonable steps to ensure that food
produced, distributed or marketed in the State meets the
highest standards of food safety and hygiene reasonably
available and to ensure that food complies with legal
requirements, or where appropriate with recognised codes
of good practice
 Legislation

 The FSAI legislation section covers Irish and International
Food Acts and Laws. Food legislation section contains a
comprehensive list of food legislation in Ireland.
 Information on FSAI consultations on new legislation is
available in our Consultation section.
 Food law in Ireland dates back to the early 1800’s and has
been continually augmented and amended over the years.
Today, most if not all of our national food legislation
derives from Ireland’s membership of the European Union.
 The Food Safety Authority of Ireland is the single,
regulatory authority with responsibility for the
enforcement of food safety legislation in Ireland.
 Trade Association

 Food and Drink Industry Ireland (FDII) is the main
trade association for the food and drink industry in
Ireland.
 It represents the interests of over 150 food, drink
and non-food grocery manufacturers and suppliers in
three main categories: Consumer Foods, Dairy and
Meat.

 FDII is committed to ensuring an environment exists
which is conducive to the success and further growth
of the food and drink industry in Ireland
 Food Labeling

 The Food and Drug
Administration (FDA) is a  Food labels are required to include
government agency that information about nutritional facts
regulates the food industry. (Recommended Daily Allowances) of
the product based on serving sizes.
 The U.S. Food and Drug
Administration requires
that certain labeling be
placed on food products
that are packaged for
consumption.

 Labels also tell the
consumer about the natural
and additive substances in
the foods.

10
 The Role of Government in
the Food Industry

 The food business is a
complex system of
marketers, buyers, and
transporters that
orchestrate how food gets
from the processor to the
grocery store shelf.
 Government agencies
regulate and inspect all
phases of food production
to ensure that consumers
have food that is both
wholesome and safe.

11
 Future outlook

 The sector faces a challenging environment with a range
of factors – energy costs, currency, commodity costs,
consumer demand, labour costs, regulatory burden etc. –
having an effect on competitiveness.

 Changes to the Common Agricultural Policy, WTO
agreements and climate change will also continue to
cause significant change to the business environment.
 The growth potential of the sector, an increase in
exports to €12 billion, as targeted in Food Harvest
2020, can be achieved if these challenges can be
addressed and the industry remains competitive and
innovative.
What is Food Science?
 What is Food Science

 Food science is defined as the discipline of applying chemistry,
engineering, microbiology, medicine, and molecular biology to create,
prepare, and process foods.
 Food scientists use science and engineering to produce, process,
evaluate, package, and distribute foods that are nutritious,
palatable, and safe.
 Methods that food scientists employ include basic research, product
development, quality control, processing, packaging, labeling,
technical sales, and market research.
 Technological advances in genetics, soil science, food processing and
purification, and marketing have helped produce food for the world.

14
 What is Food Technology?

Food Technology is the
application of food science
to the selection,
preservation, processing,
packaging, distribution, and
use of safe, nutritious, and
wholesome food.

15
 What does a Food Scientist do?

A Food Scientist studies the physical, microbiological, and
chemical makeup of food. Depending on their area of
specialization, Food Scientists may develop ways to process,
preserve, package, or store food, according to industry and
government specifications and regulations.
 Careers in Food Processing

 Job Titles:  Responsibilities:
 Process Engineer  Process design
 Engineer  Bench-top process
 Employers: development

 Food processors  Testing

 Ingredient  Plant scale-up
manufacturers/suppliers  Commercialization
 Academia (Higher  Troubleshooting
Education)
 Contract research
laboratories/development
firms
 Self-employed/Consultant

17
 Careers in Product Development

 Job Titles:  Responsibilities:
 Product Development  Bench-top development
Scientist  Testing
 Scientist  Plant scale-up
 Employers:  Commercialization
 Food processors  Troubleshooting
 Ingredient
manufacturers/suppliers
 Academia (Higher
Education)
 Contract research
laboratories/development
firms
 Self-employed/Consultant
18
 Food Processing

 Food processing is the set of methods and techniques
used to transform raw ingredients into food for
consumption.
 Examples of food processing methods include:
 Chopping
 Mixing
 Homogenizing
 Cooking
 Pastuerizing
 Emulsifying
 Spray-drying
 Food Processing

From Farm To Table

?
Whey protein, a by-product
of cheese manufacturing, is
used in energy bars and 20
drinks!
 The Path Food Takes to Get to YOU!

Producer Harvester Packer/Processor

Distributor Consumer
Wholesaler Retailer
2
 Harvesting

 Taking a product from a plant where it was grown or
produced
 It is important that the crop be harvested in a timely
and careful manner
 The crop must be at the correct stage of maturity to
ensure that it is not over or underripe
 Processing and Handling

 The steps involved in turning raw agricultural products
into an attractive and consumable food
 Processing factories and plants clean, dry, weigh,
refrigerate, preserve, store and turn a commodity into a
variety of other products
 Transporting

 Variety of transportation is used by the food industry
 Transportation of fresh and processed food products makes up 5.5%
of the marketing cost within the food industry in the United States
 Timing and the distance that foods must travel contribute to the
ultimate cost of the foods.
 Efficiency of transportation influences food quality in terms of
freshness and spoilage
 Insulated and refrigerated trucks enable food products to move in
fresh form to most parts of the country year-round.
 This luxury is not available to most people in the world.
 Approx. 90% of our perishable food is shipped by truck
 Much of the less perishable foods such as wheat, potatoes and beets
are shipped by rail
 Air transportation allows us to enjoy perishable foods from distant
regions and countries
 For example: pineapples and papayas
 Where Food is Grown?

 Food is grown all over the WORLD!
 Climatic conditions once dictated where certain foods were grown
 Technology has allowed us to grow foods where they once never
would
 For example food production in the US has always been
influenced by geography and climate
 Since early times when humans traveled and traded foods have
been introduced outside the areas where they were grown
naturally
 For example, the soybean has origins in China and is still
produced and consumed there.
 However, the major soybean producers of today are the
United States, Brazil and western Europe
 The Food Industry of the Future

 Ever changing
 New food products
 New processing and preserving techniques
 New equipment for harvesting labor-intensive crops
 Improved harvesting equipment for products
such as grapes is being tested to lower labor
cost of such crops.
 Convenience foods will continue to play a larger role
in the food chain
 Development of Healthier Food products
 Agencies will continue vigilance regarding food
safety and nutritional standards at all steps of the
food chain
 Exercise

 Soybeans are a globally important crop, providing oil and
protein. Soybean products do, however, appear in a large
variety of processed foods.
 Soybeans are one of the "biotech food" crops that have
been genetically modified, and genetically modified
soybeans are being used in an increasing number of
products.

 Can you investigate the products they are used in?
 How are they grown?
 What are the conditions?
 The last 50 years

 Two recent major developments since World War II have
changed the way in which food is produced and manufactured
today.
 Technology has allowed advances in food processing, such as
freeze drying and introduced ‘new’ food ingredients.
 The use of biotechnology and nanotechnology is increasing.
 Greater consumer awareness of nutrition, diet and health has led
to new areas of food manufacture, and the formulation of food
products with modified nutritional composition, for example, low
fat spreads, low fat dairy products and low calorie drinks.
 Genetic modification of ingredients has also been increasing.
 Concern for the welfare of animals and humans in food
production have also influenced the types of foods available
and how they are produced.
 Factors affecting food technology

Factors affecting food technology
Factors affecting food technology
include: also include:
 domestication of animals and  electricity
crops  discovery and use of raw
 preservation methods materials
 understanding of scientific
 development of villages and principles
towns  research and development of
 changes of land ownership food ingredients
 transport and travel  increasing technological
capabilities
 war
 economic understanding and
 religion and culture trade
 famine  changes in society, e.g. the
 drought, flood, disease changing role of women
 changes in retailing
 mechanisation
29
Food Manufacture and Quality
 Objectives

1. To be able to describe the food industry

2. To understand the outline of the process of introducing
new products

3. To be able to discuss the history of preservation of food

4. To be able to describe some new technologies that may
impact on food production and processing.

5. Use of biotechnology and nanotechnology in food
 Introduction

 CAD and CAM are industrial methods of designing
and making foods to high specifications in large
quantities
 Most of the food you buy in a supermarket will have
been processed or made on an industrial level.
 Food = Big business! From 2008 to 2009 Tesco
took £1 Billion a week in revenues worldwide!
 Methods of production

The main methods of production are:
 ‘One-off’ or jobbing production, e.g. a wedding cake.
 Batch production, e.g. a fixed number of products
such as bread making in a supermarket.
 Mass production or continual flow production where
machinery runs 24 hours a day to make items such as
crisps.
 Batch production

 This process is used when a small or
fixed number of products are
needed to be identical.
 Specialist machinery is used to
make the product.
 All machinery would need to be
cleaned between each production
run.
 The cost of batch production is
more economical than one-off
because more ingredients are
required and can be bought in bulk.
 Machines automate the process.

34
 Continuous flow

 Continuous production methods  It is more cost effective to
are highly automated at every keep the factory and
stage of production from input machinery running in
of raw materials, through continuous production than
production to output and
packaging.
to close down.
 Most processes include  The machinery has to be
computer control therefore kept in good working order
few people are involved in because the manufacturer
production. needs to keep the plant
 Production goes on 24 hours a running all the time to make
day, 7 days a week with staff a profit.
working in shift systems.  Continuous production is
uniform. It is used for
example by sugar and soft
drinks companies.
 The cost of setting up is
high for the specialized
plant and machinery but
once running, production 35
costs are relatively cheap.
 Food production

Food production involves the following
stages:

INPUT
 Ingredients

PROCESS
Shape
 Mix
Bake
 Beat
Question: What are the
OUTPUT Inputs, processes and
 Bread: golden brown, same size outputs for making
and shape bread?
 Computer Aided Manufacture (CAM)

 CAM is the use of computers by manufacturers to help them
monitor and control automatic production of food products.
 The computer aids the production process based on a set of
specifications and tolerances.
 Electronic sensors are used to test the following:
 Weight changes.
 Temperature changes in mixers, ovens, blast chillers and
freezers.
 Changes in colour.
 Tolerances in weight and overall dimensions.
 Moisture content of the product.
 Humidity of cooling ovens.
 How is CAM used in the food industry?

 Machines can take over complex operations previously done by
hand.
 Reduce food wastage through efficient manufacture.
 Improve product consistency.
 Reduction in overheads, e.g. labour costs.
 Increased production.
 Easier to monitor and control production.
 No fatigue from repetitive manufacturing demands.
 Improved safety and hygiene standards.
 Enhanced quality control.
 Automatic production

 Many processes involving a
computer in food production
are automatic.
 An example is bread production
where specific temperatures
are important throughout the
production process.
 Heat sensors inform the
computer of any changes and
the system adjusts the
temperature automatically.

39
 Robotics

 A robot is a piece of
equipment that is computer
driven and mimics the skills
of people.
 They are used for ‘pick and
place’ operations such as
gripping small, hot, soft or
fragile component parts.
 In the food industry they
are used for e.g. packing
biscuits into trays or
stacking full boxes of food
products.

40
 Computer Integrated Manufacture (CIM)

 When all the stages of a food production process are
integrated and controlled by computer systems, this is known
as CIM.
 The computers are linked together in a network and control
the machinery and the flow of production.
 The mass production of products such as bread, cereals and
crisps use CIM systems.
 CIM is essential in mass production because it enables
manufacturers to produce high volume products quickly and
accurately giving a consistent product.
 Quality control checks (1)

 Quality control is the system used by the manufacturer to
ensure the quality of product is maintained throughout the
process.
 It involves several checks to ensure each stage is reaching
the required standard.
 The final product is then checked against the original
specification.
 Many checks are carried out by specialist machinery and
production workers.
 Some examples of checks are:
 Raw materials – manufacturers often buy ingredients to a
specification and they will need to be checked at the
delivery stage.
 Weight checks – computer controlled scales usually check
weight at different stages of the manufacturing process.
 Quality control checks (2)
 Temperature checks
 control of the temperature of raw and finished ingredients is
essential when manufacturing food products. The core
temperature is measured using a temperature probe.
 Time checks
 strict schedules and deadlines have to be met.
 Metal detection
 this is used to check if fragments of metal have fallen into food
indicating a problem with a machine.
 Microbiological testing
 this can be done at the plant but it is often done in a specialist
laboratory. Results are then sent back to the manufacturer.
 Other checks
 manufacturers may use sensors to check humidity, moisture
content, size, shape and consistency of colour.
 Checking the final product

 Although computers can carry out many quality control checks
there is still a place for people to carry out visual checks like
grading and sorting ingredients.
 Sensory testing is also carried out by people.
 It is important to carry out quality checks throughout the
manufacture at every critical control point.
 Problems need to be identified and rectified quickly as
products that do not meet the required standard are
rejected, and this is wasteful.
 Stages of Product Development

Product development is the
process of creating new or
modified food products.
The aim of product
development is to increase
sales and maintain a
company’s competitiveness.
The products should fill a
gap in the market. In
addition, consumers must
be tempted to buy the new
products in preference to
similar products.
45
 Test kitchen

Research is carried out, to formulate a number of
recipes and specify the ingredients to be used.
Several versions of the product are usually made, using
slightly different ingredients or processes
i.e. the products are prototyped in the company’s
test kitchen often by a professional chef or food
consultant.
A small number of staff, experienced in sensory
evaluation, test the products and evaluate them
informally.
On some occasions, if a company does not have a
test kitchen, an initial concept for a product is sent
to an independent developer.
 Pilot plant

When an acceptable product has been made in the
kitchen it is then produced using pilot scale equipment.
A pilot plant is a small version of the equipment used in
manufacture. Many manufacturers have these facilities.
They produce the product on a small scale, but in the
same way as it would happen during large scale
manufacture.
This allows them to judge whether the product can
be successfully produced on a large scale, and
whether it meets the original specification.
Enough product must be made for market research
and sensory evaluation to be undertaken.
 Product specification / Scale up

After testing and modifying the product on the pilot plant, a final
product is created. This details exact ingredients and precise
methods of production.
The specification is very important as it will be used for the
production of each batch of the product to ensure consistency.
Once the company is confident that the product is likely to succeed,
it is ready for large scale manufacture to begin.
The manufacturing process is sometimes organised in unit
operations, such as size reduction, mixing and cooking. These are
controlled to maintain consistent product quality, safeguard, staff
health, food safety standards and to avoid problems that may stop
the production line running, which would result in ‘down-time’.
 Large-scale production planning

 Time
 The manufacturer will have deadlines to meet and the
product must be produced on time, but storage of the
finished product is expensive.

 Purchase and storage of materials
 Buying ingredients in bulk is cheaper, but they have to be
stored and used while they are still fresh. If they are not,
wastage increases.

 Use of equipment and resources
 Equipment is expensive to buy and needs to be used to its
full capacity whenever possible.
 Workers still have to be paid if they have nothing to do, so
this must not happen.
Food Preservation
 Objectives

1. To be able to describe the food industry

2. To understand the outline of the process of introducing
new products

3. To be able to discuss the history of preservation of food

4. To be able to describe some new technologies that may
impact on food production and processing.

5. Use of biotechnology and nanotechnology in food
 Food Preservation

 Food preservation is the process of treating and
handling food in such a way as to stop or greatly slow
down spoilage to prevent foodborne illness and extend
its shelf-life.
 Food processing methods that are used to preserve
foods include:
 Refrigeration and freezing
 Canning
 Irradiation
 Dehydration
 Freeze-drying
 Pickling
 Pasteurizing
 Fermentation
 Food Preservation

 How a food is processed
can affect its IQF or Individual Quick
Freezing
appearance, odor, flavor,
has improved the quality
and texture. of frozen fruits and
 Over the years many vegetables
food preservation
methods have been
improved to increase the
shelf-life of foods while
minimizing changes to the
quality and nutritional
content. 53
 Food Preservation

 So, how does food  Temperature
preservation work?  Water Activity
 All of the food preservation  pH
processes work by slowing
down the activity and
growth of disease causing
bacteria, or by killing the
bacteria all together.
 They also slow down or stop
the action of enzymes which
can degrade the quality of the
food.

54
 Food Preservation

 How a food is packaged also influences its shelf-life.
 It is also important that foods are handled properly by
the consumer at home.
 Check “Use By” or expiration dates.
 Follow storage or preparation instructions.
History and Trends of Food Preservation
 Food Preservation

 Methods of treating foods to  Retard or reduce the growth of
delay the deterioration of the undesirable microorganisms,
food. mold and bacteria.
 Changing raw products into  Do not affect the food texture
more stable forms that can be or taste.
stored for longer periods of  Safe for human consumption.
time.  Extend shelf-life of food.
 Allows any food to be available  Shelf-life
any time of the year in any
length time before a
area of the world.
food product begins to
spoil.
 Food preservation is needed,
especially today with the large
world population
57
 Historical Methods of Food Preservation

 Drying  Sugaring
 Used to preserve fruit,  Used to preserve fruits for the
vegetables, meats, and winter.
fish.  Jams and jellies.
 Mainly used in the south  Pickling
– warmer climate.  Fermenting
 Causes the loss of many  Used to preserve vegetables.
natural vitamins.  Use mild salt and vinegar brine.
 Salting  Increases the salt content and
 Used extensively for reduces the vitamin content of the
pork, beef, and fish. food.
 Costly due to high price  Cold storage
of salt.  Used extensively in the northern
 Done mainly in cool U.S.
weather followed by  Root cellars were used to store
smoking vegetables at 30-40 degrees F.
 Root cellars were replaced by ice
58
boxes in the mid 1800’s.
 Factors that Changed
Food Science Technology

 Canning – revolutionized food preservation and
made it more available.
 Commercial freezing and refrigeration – allowed
preservation of meats.
 Refrigerated rail cars and trucks – increased the
availability of fresh fruits, vegetables and meats.
 Food preservatives.
New technologies in food production and
processing
 Objectives

1. To be able to describe the food industry

2. To understand the outline of the process of introducing
new products

3. To be able to discuss the history of preservation of food

4. To be able to describe some new technologies that may
impact on food production and processing.

5. Use of biotechnology and nanotechnology in food
 Advances in food technology

 Food technology advanced in the early
19th century with the invention of the
canning process.

 Since then the range of technologies
used to process and preserve foods has
expanded and uses a range of physical
and chemical techniques. There have also
been many technological changes in the
home.
refrigerators became widely used from
the mid-1950s;
domestic freezers in the 1970s;
microwave ovens in the 1980s.
 Advances in food technology

In recent years demand has increased for minimally processed
foods which retain their freshness.
New techniques have replaced methods that rely on heating
and drying. Can you think of any examples?
Modified atmosphere packaging is a way of extending
the shelf life of fresh food products.
The technology substitutes the air inside a package
with a protective gas mix. The gas in the package
helps ensure that the product will stay fresh for as
long as possible.
New packaging technologies are available and will
continue to be developed to help extend the shelf life
and quality of food. This aims to reduce food waste.
 Advances in food technology

A new type of packaging is a bio-degradable and
compostable film.
It is designed to significantly increase the shelf
life of fresh produce, including sensitive, high
respiration products like strawberries and
potatoes.
This could save consumers money by significantly
reducing the amount of food they throw away.
It could also save the fruit and vegetable industry large
sums of money in wastage costs by extending the
amount of time products stay fresh on shelves.
 Types of Food Processing

 Heating
 Blanching
 Vacuum Packaging
 Drying
 Refrigeration
 Freezing
 Chemicals
 Heating

 Started in 1800’s.
 Known as canning – putting hot food in jars to seal.
 Food is cooked to extremely high temperatures, put
into jars and lids are placed on them.
 Lids are sealed from the heat and this prevents
bacteria from growing and spoiling the food.
 Blanching

 Used for vegetables.  Shrinks the product,
 Heat the food with better for filling the
steam or hot water to container.
180-190 ◦F.  Destroys enzymes in
 This prevents bacteria the food.
from growing.  Fixes the natural
 Hot food is cooled in color of vegetables –
ice water. holds their color

67
 Vacuum Packaging

 Removes oxygen.
 Oxygen reacts with food causing
undesirable changes in color and flavor.
 Drying

 Oldest form of food preservation.
 Methods
 Sun drying
 Hot air drying – mechanical dehydrator
 Fluidized-bed drying
 Drum drying – milk, fruit, veg. juices, cereals
 Spray drying – milk, eggs, coffee, syrups
 Freeze drying
 Puff drying – Fruit or vegetable juices
 Refrigeration

 Early time, ice and snow was used.
 Now the most popular method of food
preservation.
 85% of all foods are refrigerated.
 Greatly changed our eating habits.
 Freezing

 Used by Eskimos and Indians
 Frozen foods are a staple in every
American home.
 Chemicals

 Salt was first chemical used to
preserve foods.
 NaCl – salt; makes water unavailable to
microorganisms.
 Changes the pH of the food not
allowing microorganisms to live.
 Chemical Additives

 Examples of additives
 sodium nitrate
 fatty acids
 sulfur dioxide
 sorbic acid
 diethyl pyrocarbonate
 oxidizing agents
 benzoates
 antibiotics
 antioxidants
Biotechnology and Nanotechnology
 Objectives

1. To be able to describe the food industry

2. To understand the outline of the process of introducing
new products

3. To be able to discuss the history of preservation of food

4. To be able to describe some new technologies that may
impact on food production and processing.

5. Use of biotechnology and nanotechnology in food
 What is Biotechnology?

Biotechnology is the industrial use of biological processes to make products.
Its major uses are in the production or preservation of food.

For many centuries the process of fermentation has used micro-organisms
(yeasts and bacteria) to make
Beer
Yogurt
cheese.
Bread making,
beer brewing and
pickling
all use naturally occurring micro-organisms in the production of food and
drink.

The basis of the fermentation process is the conversion of glucose (sugar)
to alcohol or to lactic acid by enzymes in the micro-organisms.
 Traditional Biotechnology

Traditional biotechnology mainly involves the
production of foods, such as cheese, bread and wine.

The fermentation process:
offers a method of preservation, e.g. by producing
acid which lowers the pH (converting a perishable
food into one that has a longer shelf-life);
can be used to change the nutritional value of
food products, e.g. converting milk to cheese;
can create or improve sensory characteristics of
foods (flavour, aroma and texture).
 Food production

 Cheese – rennet (from the enzyme renin) is used to
coagulate milk, forming curds and whey.

 Alcoholic beverages – glucose is fermented by
yeast enzymes.

 Bread – enzymes within the flour break down
starch, eventually producing glucose. This is
fermented by enzymes present in yeast producing
alcohol and carbon dioxide.
 Improving crops and livestock

Improving varieties of crops or livestock by
introducing or modifying specific genes is fast and
more accurate than traditional breeding.

If the gene can be identified and modified the
following changes may be possible:
plant crops may have a longer shelf-life, be more
resistant to pests or disease, be more nutritious,
have a better taste or give a higher yield;
animals may be made more resistant to disease,
produce less fatty meat, grow faster or be more
fertile.
 Genetic modification

A number of ethical and safety issues need to be
considered with genetic modification.

Some concerns expressed by consumers include
fears that the results of genetic modification could
harm the environment and pose a danger to humans.
 Genetically modified (GM) food

Foods which have been produced from genetically
modified organisms (GMOs) are likely to appear no
different from food produced by traditional means.

A series of laboratory tests would be needed to
show that genes had been changed.

The Government has set up a series of controls to
protect consumers, the environment and people who
work with genetically modified organisms (GMOs)
which take account of these concerns.
 Genetically modified (GM) food labelling

Food is labelled if it contains genes that would not
be expected to be there and which might cause
concern to some people on ethical grounds.

Labelling is not considered necessary for foods in
which the inserted gene has been destroyed by
processing, and is therefore not present in the
food at the time it is sold.
 Genetically modified (GM) food labelling

Food from genetically modified organisms needs to
be labelled:

if it contains a copy gene originally derived
from a human being;

if it contains a copy gene originally derived
from an animal which is restricted by some
religions, e.g. pigs for Muslims or Jews;

if it is a plant or microbial food and contains a
copy gene originally derived from any animal.
Nanotechnology
 What is Nanotechnology?

Nanotechnology is the manufacture and use of materials
and structures at the nanometre scale (a nanometre is
one millionth of a millimetre).

It offers a wide range of opportunities for the
development of innovative products and applications for
food packaging.

Nanotechnology and nanomaterials are a natural part of
food processing and conventional foods, because the
characteristic properties of many foods rely on
nanometer sized components (such as nanoemulsions and
foams).
 What is nanotechnology?

 Nanotechnology is the ability to create and manipulate
atoms and molecules on the smallest of scales. ‘Nano’
comes from the Greek word for dwarf.
 A nanometer (nm) is one-billionth of a metre, smaller
than the wavelength of visible light and a hundred-
thousandth the width of a human hair.
 Nanotechnology deals with anything measuring between
1 and 100 nm.
 Eg Using sunscreen as an example, many of them
contain nanoparticles of zinc oxide or titanium oxide.
 Older sunscreen formulas use larger particles, which
is what gives most sunscreens their whitish color.
 Nanotechnology

 Nanotechnology offers a wide range of
opportunities for the development of innovative
products and applications for food packaging.

 Nanotechnology and nanomaterials are a natural
part of food processing and conventional foods,
because the characteristic properties of many
foods rely on nanometer sized components (such as
nanoemulsions and foams).
 Food examples

Nanoparticles are being used to deliver vitamins or
other nutrients in food and drinks without affecting
the taste or appearance.
These nanoparticles encapsulate the nutrients
and carry them through the stomach into the
bloodstream.
Nanoparticle emulsions are being used in ice
cream and various spreads to improve the
texture and uniformity.
 Packaging examples

 Researchers have produced smart packages that can
tell consumers about the freshness of milk or meat.
 When oxidation occurs in the package, nanoparticles
indicates the colour change and the consumer can
see if the product is fresh or not.
 Incorporation of nanoparticles in packaging can
increase the barrier to oxygen and slow down
degradation of food during storage.
 Packaging examples

 Bottles made with nanocomposites minimise the
leakage of carbon dioxide out of the bottle.
 This increases the shelf life of fizzy drinks without
having to use heavier glass bottles or more
expensive cans.
 Food storage bins have silver nanoparticles
embedded in the plastic. The silver nanoparticles
kill bacteria from any food previously stored in the
bins, minimising harmful bacteria.
 Nano in nature

 Gecko feet are covered with nano-size hairs that
use intermolecular forces, allowing the lizards to
stick firmly to surfaces.

 By replicating this scientists have developed an
adhesive that can seal wounds or patch a hole
caused by a stomach ulcer. The adhesive is elastic,
waterproof and made of material that breaks down
as the injury heals.
 The future of nanotechnology

 Research is being carried out to develop
nanocapsules containing nutrients that would be
released when nanosensors detect a deficiency in
your body.
 Nanomaterials are being developed to improve the
taste, colour, and texture of foods. For example
“interactive” foods are being developed that would
allow you to choose which flavour and colour a food
has!
 Objectives

1. To be able to describe the food industry

2. To understand the outline of the process of introducing
new products

3. To be able to discuss the history of preservation of food

4. To be able to describe some new technologies that may
impact on food production and processing.

5. Use of biotechnology and nanotechnology in food