Packaging meat in oxygen-permeable materials has beneficial effects with respect to the stability of meat colour, as oxygen helps formation of redcoloured oxygenated forms of myoglobin. On the other hand, as oxygen is available on the product surface, after sufficiently long storage the meat will undergo an aerobic type of microbial spoilage.

Chemical aspects

During aerobic spoilage, various meat compounds are degraded by meat enzymes (minor contribution) and microbial enzymes (major contribution), which can result in numerous end products having unpleasant sensory characteristics. Proteinaceous elements of meat are first degraded to lower molecule compounds in the order: proteins–polypeptides–peptides–free amino acids. Such changes occur normally during meat maturation (ageing) and, up to this stage, no negative effects on sensory qualities are noticeable. However, when the changes include degradation of free amino acids resulting in accumulation of compounds such as ammonia, hydrogen sulphide and amines, this produces characteristic, putrid off-odours (so-called putrefactive type of spoilage). In addition, protein degradation includes changes of myoglobin into oxidized forms, which results in a change of the red meat colour to grey, brown or green. On the other hand, if the meat contains more carbohydrates – natural or added – their degradation will result in accumulation of acids, which characterizes the so-called souring type of spoilage. Chemical changes during meat spoilage also include oxidation of fats, along the following chain of events: fats–free fatty acids–aldehydes/ketones. This results in rancidity.

Microbial aspects

Aerobic spoilage of chilled meat can be caused by a range of psychrophilic or psychrotrophic microorganisms. Nevertheless, at <5°C, Pseudomonas is normally a dominant spoilage organism, particularly if the meat pH is lower (e.g. beef). At refrigeration temperatures >5°C, however, Brochothrix thermosphacta can become more dominant, particularly if the meat pH is higher (e.g. pork, lamb). Signs of spoilage become noticeable at microbial levels between 10⁷/g (off-odour) and 10⁸/g (slime). Nevertheless, the composition of microflora and the metabolic patterns of dominant microorganisms are more relevant for spoilage than are the microbial numbers. Also, it seems that microbial metabolites from amino acids appear in higher-pH meat sooner (i.e. at microbial level of 10⁶/g) than in lower-pH meat (i.e. at level of 10⁸/g).

Sensory aspects

Comminuted meats

The general course of spoilage in comminuted, aerobically stored meat is similar to that of meat cuts, but is faster. The reasons for this includes poorer microbial status due to usually higher initial microbial levels, distribution of surface meat contamination throughout the product during mincing, and to the higher growth rate of bacteria due to damaged tissue membranes, finer structure and larger surface area in minced meat. Dominant spoilage organisms include Pseudomonas and psychrotrophic Enterobacteriaceae, but if the former is suppressed (e.g. by certain added preservatives) spoilage can be caused by Brochothrix thermosphacta.

Bone taint

Surface spoilage of aerobically stored joints is similar to spoilage of other raw meats, but spoilage can also develop in deep meat where anaerobic conditions exist even if the joint is stored aerobically. Deep meat spoilage (commonly called ‘bone taint’) is associated particularly with joints including cured – such as shoulder, gammon – and is characterized by off-odours in deep meat close to bones and/or in bone marrow. It occurs more frequently during summer and in higher-pH meat. The causes are not yet fully understood, but possible explanations include internal contamination (invasion) by bacteria during the agonal phase of pig slaughter and poor distribution of curing agents. Bone taint can take the course of either a souring- or a putrefaction-type of spoilage, and a range of bacteria – including particular types of psychrotrophic Clostridia – have been isolated from such meat.

Poultry

Generally, poultry meat is packaged only aerobically as its colour is more sensitive than that of red meats. Bacteria on poultry carcasses occur in feather holes and on cut surfaces, but their distribution on carcasses can vary considerably depending on the abattoir technology. Aerobic spoilage of chilled (<5°C) eviscerated poultry is very similar to that of red meat, but is usually faster.

Vacuum-packaging of raw meat and its spoilage

Packaging of raw meat in saturated (100%) carbon dioxide atmosphere and its spoilage

With this technology, gas-impermeable packaging materials – such as an aluminium-foil layer – are used. After removal of the air from the packaging by vacuum, the bag is filled with a sufficient volume of 100% CO₂ gas and sealed. A proportion of carbon dioxide dissolves in water on the meat surface (‘meat saturation’) and produces carbonic acid, which lowers the surface pH of the meat. This, in combination with CO₂-induced damage of bacterial cells’ membranes’ permeability and inhibition of bacterial enzymes, causes extension of the bacterial lag phase and generation times. Because of the lack of oxygen, the dominant microflora on saturated carbon dioxide-packaged meat include Lactobacillus, Leuconostoc and Carnobacterium (similar to vacuum packaging), producing lactic acid and having a more acceptable ‘cheesy’ odour. The net result is prevention of growth of aerobic spoilage flora, selection for lactic acid bacteria and extension of the meat shelf life. In addition, CO₂ eliminates oxidative rancidity of fats. Therefore, meat packaged in saturated carbon dioxide can be cold-stored incomparably longer (several months) than aerobically packaged meat (1–2 weeks), and significantly longer than vacuum-packaged meat (several weeks).

Packaging of raw meat in a modified atmosphere (MAP) and its spoilage

Modified atmosphere meat packaging technology is aimed at simultaneously using the advantages, and avoiding the disadvantages, of oxygen and carbon dioxide. Modified atmospheres in the packages comprise a gaseous mixture of lower concentrations of oxygen (to maintain red colour) and higher concentrations of carbon dioxide (to inhibit microflora), but also can contain certain proportion of inert gas(es) to maintain targeted concentrations of the former two. Meat companies usually find the atmosphere composition that suits their own products best through trial and error. Nevertheless, generally, MAPs for raw meat comprise 60–75% CO₂, 10–25% oxygen and 15–30% nitrogen. The type of dominant flora in MAP-packaged meat depends on the gas composition. If high levels of oxygen are used, meat spoilage will be similar to aerobically stored meat – putrefactive (Pseudomonas). If lower levels of oxygen, but higher levels of CO₂, are used, the meat spoilage will be caused by lactic acid bacteria – similar to vacuum-packaged meat.

‘Intelligent’ packaging of food

This type of packaging is aimed at incorporation of certain indicators either of meat spoilage or of health hazards, or of both, that would easily and visibly warn when the meat is no longer acceptable. A number of various indicators have been researched:

• storage time–temperature indicators;

• leak indicators (e.g. for oxygen);

• freshness indicators that detect microbial metabolites, e.g. diacetyl, amines, ammonia, ethanol, hydrogen sulphide;

• indicators for activity of microbial enzymes;

• indicators of consumption of certain nutrients by microflora;

• food safety indicators based on detection of microbes as such or their toxins.

Although ‘intelligent’ packaging of foods probably has a great potential, the technology is still largely in the research/development stage.

‘Active’ packaging of food

Freezing of meat

Freezing of meat in industrial abattoirs is normally carried out in so-called ‘freezing tunnels’ with air at temperatures of between −20 and −40°C, a relative humidity of 95–100% and a circulation of 2–4 m/s. These rooms must have effective insulation from the outside environment, and walls/doors made of appropriate materials to withstand freezing. Due to associated occupational health and safety risks, appropriate security measures are necessary in these rooms, including an appropriate locking system and door heaters which preventing their freeze-blockage in the shut position.

Meat freezes (cryoscopy points) at temperatures of between −1.5 and −1.8°C (muscle tissue) or –2.2°C (fatty tissue). Only the water in meat is actually frozen, and initially only a proportion of it. The concentration of various compounds dissolved in the water increases in the remaining unfrozen water which, in turn, decreases its freezing point. Consequently, approximately only 75% of water in meat is frozen at −5°C, around 90% at −30°C and 100% at −60°C.

Various freezing regimes are used in the meat industry, with freezing rates determined by factors such as air temperature and circulation, as well as by size, shape and fat content of the meat. The meat freezing rate can be expressed by at what depth, measured from the surface, meat becomes frozen within a given time unit. For example, air-mediated (convection-based) freezing regimes can be slow (freezing rate <1 cm/h), rapid (1–5 cm/h) or very rapid (>5 cm/h). In the case of contact freezing where the meat is in direct contact with cold plates (conduction-based), even higher freezing rates are achieved.

WET METHODS. With wet methods, salting or curing can be conducted by submerging the meat in a solution of salt/brine in water for certain periods of time (with refrigeration), allowing the salt/brine ingredients to diffuse from the solution into the meat. The process can be speeded up by using machines with multiple, hollow needles to inject a more concentrated solution deeply into the meat, followed by mechanical treatments of the meat (in ‘massaging’ or ‘tumbling’ machines). This further enhances the diffusion and uniform distribution of the salt/brine.

COMBINED METHODS. With combined methods, meat is first dry-salted/cured and then additionally treated by salt/cure solution.

Salting or curing preparations and roles of the ingredients

DRY SALT. Dry salt normally contains >95% sodium chloride. Its main role is to lower the water activity (a_w) of meat so as to inhibit spoilage and pathogenic microorganisms, as well as to achieve desirable taste. Optimal concentrations of salt targeted in the meat depend on the type of the intended meat product, and range from 1.5–2.2% in different types of cooked sausages or 2.5–7% in dry meat products.

DRY BRINE. Dry brine can comprise: (i) salt with 0.5–0.6% sodium nitrite; (ii) salt with 1–3% potassium nitrate; (iii) salt with 0.5–0.6% sodium nitrite and 1% potassium nitrate; or (iv) salt with 0.9–1.2% potassium nitrate. Dry brines are normally pre-mixed and are commercial products, rather than composed on the plant’s production line. Using commercial mixes avoids public health risks associated with either handling of concentrated toxic compounds (nitrites), their overdosing, or both, by the plant’s staff.

POTASSIUM NITRATE. Potassium nitrate (KNO₃) is much less toxic than nitrites and is a very weak inhibitor of microorganisms. It contributes to the desirable flavour of meat products, but in higher concentrations is bitter, so is not added to meat at levels greater than 0.5–0.6%. The main role of nitrates is to serve, through reduction of NO₃ to NO₂, as a source (precursor) for the formation of nitrites.

PHOSPHATES. Phosphates are chain molecules comprising two (diphosphates) or three (triphosphates) or several tens (polyphosphates) of phosphorus atoms linked with oxygen. Their role is to enhance both the water-holding capacity of meat proteins and the mixing of fat and water (emulsion). Therefore, phosphates are normally used for commercial/meat quality reasons in meat products that contain added water (e.g. hot dogs, cooked hams, etc.). There are numerous commercially available phosphate preparations that can be of a neutral, basic or acidic nature. Phosphates are added in concentrations of up to 0.3% (calculated as P₂O₃) in the finished product.

REDUCING AGENTS. Reducing agents include primarily sodium salts of ascorbic acid or isoascorbic acid. They are added to meat in concentrations of up to 500 mg/kg (i.e. 0.05%), normally towards the end of the production process. Their role is to reduce meat redox potential so to enhance both reduction of nitrites to nitrogen monoxide and the formation of nitrosylmyoglobin (i.e. the red colour) in cured meat.

SUGARS. Sugars, usually a mixture of dextrose, saccharose and starch, are added to some meat products with the aim of improving the taste/aroma, including masking saltiness or bitterness (from nitrates), to contribute to red colour formation, as a reducing agent, and to enhance the growth of useful microorganisms in some products such as fermented meats (e.g. salami).

Smoking of meat

Meat can be heat treated either for product quality- or for product safety-orientated purposes, but in most cases the two are combined.

Heating has multiple and complex effects on meat. Heat induces change in meat pigments typical for raw meat (myoglobin and oxymyoglobin, with Fe⁺⁺, to metmyoglobin, with Fe⁺⁺⁺), resulting in a change of meat colour from red (raw) to brown–grey (cooked), e.g. in well-cooked steak. Only if the meat was cured (nitrites) before cooking, will the product still have a red colour post-cooking, due to the presence of nitrosyl-myoglobin, e.g. in cooked ham.

On the other hand, heating denatures proteins and decreases their water-holding capacity. As a result, during cooking of untreated meat a significant proportion of water is released, with weight loss – depending on species, composition and pH of meat – of up to 40%. However, when meat has been treated with water-retaining additives (e.g. phosphates), the cooking weight loss is much reduced or prevented. Heat-induced changes in proteins also cause reduction of both length and diameter of myofibrils, resulting in a firmer texture of the cooked meat.

Heating meat also contributes to the formation of a large number of compounds and changes in both protein and lipids, resulting in taste, smell and aroma typical of cooked meat that is also meat species-specific. Compounds that particularly contribute to these sensory characteristics include products of the Maillard reaction (occurring between reduced sugars and amino-compounds), aliphatic (aldehydes, ketones, amines, carboxyl acids, etc.) and aromatic (lactones, furans, thiazoles, pyridines, pyroles, etc.) carbohydrates. At pasteurization temperatures (e.g. cooking in water at 60–95°C) mainly aliphatic, whilst at high temperatures (e.g. frying, roasting, barbecuing at 150–190°C) mainly aromatic compounds are formed. Heat treatments generally reduce the nutritional (biological) value of meat, but the reduction degree depends on the cooking temperature. This is primarily due to heat inactivation of vitamins (e.g. riboflavin by 80%, niacin by 75%) and of some amino acids such as methionine, cysteine, etc.

With respect to practical application of heat treatments of meat, they can be divided into:

1. Pasteurization in water or steam at temperatures <100°C as applied, for example, to various sausages (e.g. 70–80°C), canned hams (e.g. 62–68°C) and hot-smoked meats; this normally destroys all vegetative cells of psychrophilic and mesophilic microorganisms, but some vegetative cells of thermophilic bacteria – as well as all spores – can survive. Pasteurized products are stored with refrigeration.

2. Boiling in water at 100°C, with the temperature at the product’s centre reaching 80–90°C, e.g. with liver paté, black pudding, sausage, etc.; this kills all vegetative forms of microorganisms, but not spores. The products need refrigeration.

Numerous factors affect the competitiveness of starter cultures during meat fermentation, since fermentation is a sophisticated and complex food preservation process. In practice, the suitability of starter or protective cultures can be assessed according to critical criteria and desirable criteria, described below.

Critical criteria:

1. Effectively compete against indigenous bacteria.

2. Produce adequate quantities of lactic acid.

3. Tolerate at least 6% NaCl and 100 mg/kg NaNO₂.

4. Grow in the temperature range 15–40°C.

5. Homofermentative – do not produce gas or undesirable metabolites.

6. Non-proteolytic, thus avoiding production of free amino acids, resulting in the lowest possible biogenic amine levels.

7. Do not produce biogenic amines (moulds or yeasts must not produce mycotoxins or aflatoxins).

8. Do not produce large quantities of peroxides (H₂O₂). Peroxides oxidize fats and produce undesirable rancid flavours and odours; peroxides also produce free radicals, which are undesirable in modern diets. In addition, products ultimately resulting from rancidity may cause liver damage in consumers.

Desirable criteria:

1. Catalase positive, to ensure that any peroxide produced is largely destroyed.

2. Nitrate reducing.

3. Flavour enhancing.

4. Do not produce slime.

5. Antagonistic to pathogenic and undesirable organisms.

6. Synergistic with other components in the raw materials and starter.

7. Produce MAO or DAO.

Finally, although starter organisms have the potential to be genetically modified to reduce undesirable and enhance desirable characteristics, at the present time, this approach would not be supported by consumers.

Further Reading

Bauer, F. and Burt, S.A. (1995) Shelf Life of Meat and Meat Products: Quality Aspects, Chemistry, Microbiology, Technology. ECCEAMST Foundation, Utrecht, The Netherlands.

Davies, A. and Board, R. (1998) The Microbiology of Meat and Poultry. Blackie Academic, London.

Varnam, A.H. and Sutherland, J.P. (1995) Meat and Meat Products. Chapman and Hall, London.