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Introduction
Our
tray sealing machines (table top series, rotary and conveyor type) support
gas flushing process to produce a Modified atmosphere
packaging (MAP) in a rapid period of time without the need to
use of vacuum pump (with the exemption of VG machines).
Modified
atmosphere packaging (MAP) is an increasingly popular food preservation
technique whereby the composition of the atmosphere surrounding the food is
different from the normal composition of air.
The
modification process often tries to lower the amount of oxygen (O2),
moving it from 20% to 0%, in order to slow down the growth of aerobic life forms
and the speed of oxidation reactions. The removed oxygen can be replaced with
nitrogen (N2), commonly acknowledged as an inert gas, or carbon
dioxide (CO2), which can lower the pH or inhibit the growth of
bacteria.
What is MAP?
MAP
is food packaging in which the earth’s normal breathable atmosphere has been
modified in some way. Usually combined with lowered temperatures, it is a highly
effective method for extending the shelf-life of food.
Shelf-life is prolonged in some applications by
creating a simple vacuum in the package (vacuum packaging) and in these cases
there is almost a complete absence of gas. In others, special permeable films
allow naturally respiring produce to form its own atmosphere without the
addition of external gases.
Once
a fruit, vegetable or animal product is harvested or slaughtered it remains a
suitable environment for bacteria which continue to function using the available
carbohydrate, protein, fat and nutrients. These continuing processes lead to
degradation including undesirable colour changes, loss of flavour and poor
texture. The action of enzymes also causes deterioration of foods. In Europe,
MAP mainly involves the use of three gases - carbon dioxide, nitrogen and
oxygen, although other gases are used where regionally acceptable. Products are
packed in a single gas or a combination of these three gases depending on the
physical and chemical properties of the food.
History of MAP
The
use of gases in the preservation of food products is by no means a new process.
Much of the original work was carried out in the early 1930s with the shipment
of beef and lamb carcasses from Australia and New Zealand to the UK under carbon
dioxide storage. During the 1940s and 1950s, sealed controlled atmosphere
storage warehouses were constructed to prolong the effective shelf-life of fresh
apples under refrigeration. Hence the commercial applications of gas
preservation were largely confined to the controlled atmosphere storage and
transport of bulk commodities such as meat and fruit. Now you see MAP used to
package anything from fresh salads and individual meat portions, to sandwiches
and snacks. Today it is a sophisticated technique with ever-increasing benefits
to both supplier and customer.
MAP – adding value to food
Food,
glorious food - in all its natural, eye-catching colour - is what the customer
expects from the food industry. And week in, week out, Modified Atmosphere
Packaging techniques help the retailer to deliver. Extended shelf-life, greater
choice and a reduction in food-related health hazards are some of the valuable
benefits of MAP but are not so apparent to the shopper as the presentation of
the food itself. This is where MAP adds even more value for the retailer
enabling food to look better for longer.
Why use MAP?
In the last 25 years, the change from an
industrialised base to a service economy has seen the emergence of new family
structures and work patterns which, in turn, has led the demand for more
convenient food.
The
creation of nationwide, European and international supermarket chains, has led
to a highly competitive trading environment, forcing quality up and operational
costs down
For the food industry, one of the important
effects of these significant social, economic and business changes has been to
open the door to MAP. Hundreds of food businesses have stepped through, using
MAP to form valuable new trading relationships with the multiples and other,
smaller chains and independents. Because Modified Atmosphere techniques are ever
changing and improving, that door of opportunity remains open. There is a great
deal of advice and support available from equipment and film manufacturers,
specialist gas suppliers such as BOC and Air Liquide in Australia and research
bodies such as Food Science Australia.
Extension of shelf-life
Depending
on product, shelf-life can be usefully extended by between 50% and 500% using
MAP techniques. This means that waste is minimised and re-stocking and ordering
can become more flexible.
As an example, a store turning over 100% of its
shoppers every 10 days will be able to offer a non-MAP food item with a
shelf-life of three days to just 30% of its customers. But the same food item
packaged with a suitable Modified Atmosphere to give it a 10-day shelf-life will
be available for purchase by ALL the store’s shoppers.
Minimisation of waste
If there is a greater chance that a product will
be sold, there is obviously less chance of it being thrown away. Even with
today’s sophisticated management systems it is still not possible to
accurately predict a supermarket's daily throughput. So having a greater
shelf-life available enables a store to order more efficiently and to reduce
wastage.
Quality
There are obvious quality advantages for both retailer and consumer in having
food that deteriorates at a much slower rate on its journey from production area
to store, and then onward to the domestic kitchen, refrigerator or freezer.
Presentation is another vital quality aspect.
Because MAP products cannot just be wrapped in cling film (they have to be
encased, usually in a tray which lends itself to an element of design on its
surface) retailers have taken the opportunity to package their food stuffs more
attractively. The visual appeal of food is another key quality area and here the
industry’s experience with red meat makes an interesting case study. After
slaughter and ageing, red meat quickly becomes a dullish, brown colour which is
unattractive to customers. Fresh, red colour is maintained longer using a
mixture of between 70% and 80% oxygen, (depending on the meat), and carbon
dioxide for the balance. Its remarkable effect on red meat is undeniable. In the
early days it was the introduction of this technique by Marks & Spencer to
its range of red meats that kick-started the use of MAP in the UK. Today, with
red meat coming under scrutiny by some consumers actively pursuing a healthier
lifestyle, the role of MAP is central to its survival on store butchery shelves.
Reduced need for artificial
preservatives
In a world which is becoming increasingly
“green” in its outlook, a world where every consumer is a watchdog for the
environment, there are points to be earned by the retailer who can get rid of as
many additives as possible and show that its food is basically fresh and
natural. In some cases, MAP means that artificial preservatives are no longer
required to achieve a reasonable shelf-life.
Increased distribution
possibilities
Because of the extended product shelf-life,
increased distribution is one of those areas in which the introduction of MAP is
more than just “another benefit”. For companies with the right product, the
potential to increase the range of delivery can produce exciting changes and
opens the door to a global market.
MAP gases – the basics
Carbon dioxide (CO2)
Carbon dioxide inhibits the growth of most
aerobic bacteria and moulds. Generally speaking, the higher the level of CO2,
the longer the achievable shelf-life. However, CO2 is readily
absorbed by fats and water - therefore, most foods will absorb CO2.
Excess levels of CO2 in MAP can cause flavour tainting, drip loss and
pack collapse. It is important, therefore, that a balance is struck between the
commercially desirable shelf-life of a product and the degree to which any
negative effects can be tolerated. When CO2 is required to control
bacterial and mould growth, a minimum of 20% is recommended.
Nitrogen (N2)
Nitrogen is an inert gas and is used to exclude
air and, in particular, oxygen. It is also used as a balance gas (filler gas) to
make up the difference in a gas mixture, to prevent the collapse of packs
containing high-moisture and fat-containing foods, caused by the tendency of
these foods to absorb carbon dioxide from the atmosphere. For modified
atmosphere packaging of dried snack products 100% nitrogen is used to prevent
oxidative rancidity.
Oxygen (O2)
Oxygen causes oxidative deterioration of foods
and is required for the growth of aerobic micro-organisms.
Generally, oxygen should be excluded but there
are often good reasons for it to be present in controlled quantities including:
- Maintain fresh, natural colour
(in red meats for example)
- To maintain respiration
(in fruit and vegetables)
- To inhibit the growth of anaerobic organisms
(in some types of fish and in vegetables)
Tray lidding to achieve MAP
A traysealer uses ready-made trays that are
sealed in much the same way as a thermoformer. The top web of packaging material
(lid film) covers the filled pockets/trays. The air is evacuated from the
sealing die and protective gas is added. Then the pack is sealed by the
application of heat and pressure. Tray lidding machines are available from
tabletop (manual) for the small producer, to fully automatic inline versions for
larger processors.
HACCP - The hazard analysis and critical control
point concept
Hazard
analysis and critical control point (HACCP) was developed in the 1960’s
primarily by the Pillsbury Company to assure the safety of food manufactured for
astronauts. It uses a proactive preventative approach to all stages of food
manufacture including storage, distribution and retail. This is potentially much
more effective than traditional end product testing in assuring safe food.
Internationally it has become the pre-eminent food safety management system. It
has become a legal requirement in many countries, particularly for fish and meat
products. Systems based on the principles of HACCP have been incorporated into
the EC food Hygiene directives. New regulations from the EU come into force on
1st January 2006; these will make systems based on HACCP a legal requirement for
all food businesses except those in primary production. HACCP is a basic
requirement of food standards, such as the BRC Global Standard-Food.
Prior
to developing a HACCP system a food business must have in place effective
prerequisite programmes, based upon Good Manufacturing Practice (GMP) and Good
Hygiene Practice (GHP). These will provide a firm foundation for the HACCP and
will manage the low risk food safety hazards as well as legal, quality and
commercial issues. These will be of site-wide relevance and not specific to a
particular step of the process, specific food safety hazards will be managed
through the HACCP system. Typical prerequisites would include cleaning
procedures, personal hygiene rules, pest control and maintenance procedures.
Effective prerequisite programmes enable the HACCP system to focus on
significant food safety hazards, particularly at the critical points of the
process.
Guidance on HACCP produced by the Codex
Alimentarius Commission in their Food Hygiene Basics Texts is widely used. Codex
defines 7 principles that should be followed by food businesses developing and
maintaining HACCP systems.
HACCP Principles
| PRINCIPLE
1 |
Conduct
a hazard analysis. Prepare a flow diagram of the steps in the process.
Identify and list the hazards with their causes and specify the control
measures. |
| PRINCIPLE
2 |
Determine the
critical control points (CCPs). A decision tree can be used. |
| PRINCIPLE
3 |
Establish
critical limit(s) which must be met to ensure that each CCP is under control. |
| PRINCIPLE
4 |
Establish a
system to monitor control of the CCP by scheduled testing or observations. |
| PRINCIPLE
5 |
Establish the
corrective action to be taken when monitoring indicates that a particular CCP is
not under control or is moving out of control. |
| PRINCIPLE
6 |
Establish
procedures for verification to confirm that the HACCP is working effectively, which
may include appropriate supplementary tests, together with a review. |
| PRINCIPLE
7 |
Establish
documentation concerning all procedures and records appropriate to these
principles and their application. |
N.B. The wording given in
italics is not included in the principles of HACCP as documented by the Codex
Alimentarius Commission but is included here as additional explanatory notes.
Key Stages of application
Codex also provides guidance on how to apply
these principles following a number of key stages. It has been suggested that
there are 14 key stages
| STAGE
1 |
Define
terms of reference/scope of the study |
| STAGE
2 |
Select the
HACCP team |
| STAGE
3 |
Describe the
product |
| STAGE
4 |
Identify
intended use |
| STAGE
5 |
Construct a
flow diagram |
| STAGE
6 |
On-site
confirmation of flow diagram |
| STAGE
7 |
List all
potential hazards associated with each process step, conduct a hazard analysis
and consider any measures to control |
| STAGE
8 |
Determine
CCPs |
| STAGE
9 |
Establish
critical limits for each CCP |
| STAGE
10 |
Establish a
monitoring system for each CCP |
| STAGE
11 |
Establish a
corrective action plan |
| STAGE
12 |
Verification
including validation |
| STAGE
13 |
Review the
HACCP system |
| STAGE
14 |
Establish
documentation and record keeping |
A food manufacturer will need to identify and
analyse potential and realistic hazards at all stages of their operation,
typically from intake of raw materials to at least despatch. Where relevant
biological, chemical and physical hazards should be considered. The business
will need to determine the measures it uses to control the significant food
safety hazards. Critical Control Points (CCPs) will be determined using
professional judgement and experience. Critical limits must be set for the
controls at the CCPs, these must be monitored at an appropriate frequency. A
corrective action plan must be developed to enable effective management of
situations where critical limits are not achieved. Procedures must be in place
to ensure the HACCP systems are working effectively and this must include
review. The business must prepare and use appropriate procedures and records.
Summary
of the achievable shelf life
with
and without MAP as advices by BOC
(on storage temperature of 0oC to +3oC)
|
Food
Products
|
without
MAP
|
With
MAP
|
|
Ready
Meals, Pasta Dishes, Goulash, Casseroles, Sauces, Soups containing meat, fish
and poultry...
|
2-5
days
|
5-21
days
|
|
Filled
Pasta, breaded poultry, meat or fish, pizzas, meat pies, stuffed pitta bread,
quiche, sausages, rolls, bouchee, chinese rolls...
|
4-7
days
|
7-21
days
|
Summary
of the achievable shelf life with and without MAP as advices by Air
Products (on storage temperature of 0oC
to +3oC)
|
Food
Products
|
without
MAP
|
With
MAP
|
| Ready
Meals and Other Cook-Chill Products |
2-5
days |
5-10
days |
| Fresh
Whole and Prepared Fruit and Vegetable Products |
2-7
days |
5-35
days |
| Dairy
Products |
1-4
weeks |
2-12
weeks |
| Cooked,
Cured and Processed Meat Products |
Cooked
and cured meats in 1-3 weeks, salami etc. 3-6 month
|
Cooked
and cured meats in 3-7 weeks, salami etc. 4-8 month |
| Raw,
low fat white Fish and Seafood / Crustaceans and Molluscs |
2-3
days |
4-6
days |
| Cooked
and Dressed Vegetable Products |
3-14
days |
7-21
days |
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