Shelf-life determination and challenge testing 263 permitted organic acids. Again, it is crucial that where ph is used as a key preservative factor, the ph of each batch of product should be monitored to ensure that the target level is achieved 10.2.3 Assembly of product In complex and multi-component products, contact between components may result in migration of flavourings, colourings, moisture or oil from one component to another. This may limit shelf-life due to quality changes, e.g.in multi-layered trifles where the visual appearance is impaired by the migration of colouring components from one layer to another, and in fruit pies where migration of moisture from the filling to the pastry crust leads to a loss of texture. Alternatively, migration brings together substrates for chemical reactions, and it is the products of these reactions which influence product shelf-life. Pizza toppings containing unblanched green peppers may be susceptible to rancid off-flavours as a result of the enzyme lipoxygenase in the green peppers coming into contact with fatty acid substrates in the pizza base or in the cheese The way in which multi-component products are assembled can have major effects on the microbiological safety of the product. If components which are stable due to low Aw or low pH are placed in contact with components which are inherently unstable due to a high Aw or high pH, there will be a layer formed between the two components where the Aw and ph is now suitable for microbial growth. Any microorganisms in the stable component could grow in this layer igration or contact between components can be limited to extend shelf-life and needs to be considered during product development. Where migration and contact are detrimental to product quality, the use of edible films or packaging in eparate compartments could be considered 10.2.4 Processing Processing encompasses a wide range of treatments that may be given to food from simply chopping or washing, (e.g. ready-to-eat chilled salads), to hea processing, acidification, addition of preservatives, fermentation or salting Processing exerts a considerable effect on the microflora, chemical, biochemical and sensory properties of a food. In some cases, the purpose of food processing may be primarily intended to achieve the desired characteristics of the produc e.g. fermented salads, and can res In change reducing pH. In other cases, processing may be specifically selected to influence shelf-life limiting factors, e.g. heat processing to inactivate microorganisms and deleterious food enzymes. If a process is used to achieve product shelf-life, there should be an awareness that small changes in the processing conditions can have a marked effect on shelf-life. Any stages of product manufacture which are essential for the safe shelf-life of the product should be identified during a hazard analysis and suitably controlled during routine production
permitted organic acids. Again, it is crucial that where pH is used as a key preservative factor, the pH of each batch of product should be monitored to ensure that the target level is achieved. 10.2.3 Assembly of product In complex and multi-component products, contact between components may result in migration of flavourings, colourings, moisture or oil from one component to another. This may limit shelf-life due to quality changes, e.g. in multi-layered trifles where the visual appearance is impaired by the migration of colouring components from one layer to another, and in fruit pies where migration of moisture from the filling to the pastry crust leads to a loss of texture. Alternatively, migration brings together substrates for chemical reactions, and it is the products of these reactions which influence product shelf-life. Pizza toppings containing unblanched green peppers may be susceptible to rancid off-flavours as a result of the enzyme lipoxygenase in the green peppers coming into contact with fatty acid substrates in the pizza base or in the cheese. The way in which multi-component products are assembled can have major effects on the microbiological safety of the product. If components which are stable due to low Aw or low pH are placed in contact with components which are inherently unstable due to a high Aw or high pH, there will be a layer formed between the two components where the Aw and pH is now suitable for microbial growth. Any microorganisms in the stable component could grow in this layer. Migration or contact between components can be limited to extend shelf-life and needs to be considered during product development. Where migration and contact are detrimental to product quality, the use of edible films or packaging in separate compartments could be considered. 10.2.4 Processing Processing encompasses a wide range of treatments that may be given to food from simply chopping or washing, (e.g. ready-to-eat chilled salads), to heat processing, acidification, addition of preservatives, fermentation or salting. Processing exerts a considerable effect on the microflora, chemical, biochemical and sensory properties of a food. In some cases, the purpose of food processing may be primarily intended to achieve the desired characteristics of the product, e.g. fermented salads, and can result in changes that extend the shelf-life by reducing pH. In other cases, processing may be specifically selected to influence shelf-life limiting factors, e.g. heat processing to inactivate microorganisms and deleterious food enzymes. If a process is used to achieve product shelf-life, there should be an awareness that small changes in the processing conditions can have a marked effect on shelf-life. Any stages of product manufacture which are essential for the safe shelf-life of the product should be identified during a hazard analysis and suitably controlled during routine production. Shelf-life determination and challenge testing 263
64 Chilled foods 10. 2.5 Hygiene Poor hygienic control during preparation, processing and packaging can result in a high level of organisms being introduced into the product; for example, poor cleaning of meat slicing equipment results in an increase in the microbiological count. This may have adverse effects on the safety and quality of the product, which would affect shelf-life. The shelf-life for a particular product can only of variables that were included in th Consistent hygienic control during subsequent production runs is essential if product with the assigned shelf-life is to be produced(see Chapters 13 and 14) 10.2.6 Packaging Packaging prevents contamination by microorganisms, protects against physical damage and can be used to isolate the product from adverse environmental factors such as light, atmospheric oxygen or humidity. Packaging materials can be used to filter out light of specific wavelengths to prevent or reduce photocatalysed reactions that would result in oxidation or nutrient degradation Products sensitive to oxidation by atmospheric oxygen can be protected by selection of packaging materials with the appropriate barrier properties oxygen ingress and, similarly, selection of barrier properties with respect to moisture can be used to prevent the product from drying out or retain the humidity within the pack Modified atmosphere packaging extends the shelf-life of meats and vegetables either by directly affecting the critical quality factor(as in the case of fresh red meat, where the bright red colour is maintained by a high oxygen atmosphere), or by influencing the rate at which reactions leading to adverse quality changes proceed. In addition, active packaging, e.g. O2/CO2/H2O absorbers, or ethanol emitters may extend shelf-life(see Chapter 6) Where the atmosphere within the package is modified, i.e. is not the normal atmospheric composition, then the effects on microorganisms should be considered. Excluding oxygen from packs will prevent the normal growth of poilage organisms of air-packed chilled foods, i.e. Pseudomonas spi Therefore, foods may become unsafe due to growth of anaerobic pathogens such as C. botulinum(Anon. 1992), but these products may appear to be organoleptically stable(Betts 1996) 10.2.7 Storage and distribution The conditions applied to the final product during storage and distribution can ave a marked effect on shelf-life. Temperature, lighting and humidity influence which microorganisms grow, which biochemical reactions and physical changes take place and the rate they occur. To make an assessment of the shelf-life of the final product, the conditions that the product is likely to encounter and the effects that they will have on the product need to be known or determined Limited numbers of time-temperature surveys of chilled products during storage
10.2.5 Hygiene Poor hygienic control during preparation, processing and packaging can result in a high level of organisms being introduced into the product; for example, poor cleaning of meat slicing equipment results in an increase in the microbiological count. This may have adverse effects on the safety and quality of the product, which would affect shelf-life. The shelf-life for a particular product can only reflect the range of variables that were included in the testing procedures. Consistent hygienic control during subsequent production runs is essential if product with the assigned shelf-life is to be produced (see Chapters 13 and 14). 10.2.6 Packaging Packaging prevents contamination by microorganisms, protects against physical damage and can be used to isolate the product from adverse environmental factors such as light, atmospheric oxygen or humidity. Packaging materials can be used to filter out light of specific wavelengths to prevent or reduce photocatalysed reactions that would result in oxidation or nutrient degradation. Products sensitive to oxidation by atmospheric oxygen can be protected by selection of packaging materials with the appropriate barrier properties to oxygen ingress and, similarly, selection of barrier properties with respect to moisture can be used to prevent the product from drying out or retain the humidity within the pack. Modified atmosphere packaging extends the shelf-life of meats and vegetables either by directly affecting the critical quality factor (as in the case of fresh red meat, where the bright red colour is maintained by a high oxygen atmosphere), or by influencing the rate at which reactions leading to adverse quality changes proceed. In addition, active packaging, e.g. O2/CO2/H2O absorbers, or ethanol emitters may extend shelf-life (see Chapter 6). Where the atmosphere within the package is modified, i.e. is not the normal atmospheric composition, then the effects on microorganisms should be considered. Excluding oxygen from packs will prevent the normal growth of spoilage organisms of air-packed chilled foods, i.e. Pseudomonas spp. Therefore, foods may become unsafe due to growth of anaerobic pathogens such as C. botulinum (Anon. 1992), but these products may appear to be organoleptically stable (Betts 1996). 10.2.7 Storage and distribution The conditions applied to the final product during storage and distribution can have a marked effect on shelf-life. Temperature, lighting and humidity influence which microorganisms grow, which biochemical reactions and physical changes take place and the rate they occur. To make an assessment of the shelf-life of the final product, the conditions that the product is likely to encounter and the effects that they will have on the product need to be known or determined. Limited numbers of time-temperature surveys of chilled products during storage, 264 Chilled foods
Shelf-life determination and challenge testing 265 transportation, retailing and handling in the home have been performed, some of which have been summarised by Bogh-Soresen and Olsson(1990) Currently, the UK Food Safety Temperature Regulations (Food Safety Temperature Control) Regulations 1995 SI No 2200)allow a maximum of 8C during distribution and retail display of chilled products. It is important that this is considered when the shelf-life of products is determined, as any assessments done at lower temperatures will be affected by use of a higher temperature(see Section 10.4). 10.2.8 Consumer handling Consumer handling of chilled products can affect the quality and the safety of the product. Factors such as the time taken to carry the product home, consumer perceptions of chilled foods and domestic storage conditions need to be taken into consideration when setting up the time and temperature regime to be used in storage trials. This is perhaps the part of the chill chain that is most variable and over which the manufacturer has least influence and control. A survey of consumer handling of chilled foods in the UK(Evans 1998)indicated that most consumers shopped at least once a week for quantities of chilled foods. In the majority of cases, transport to the home was by car or foot(83%), taking an average of 43 minutes to get food from the retail store into the home refrigerator The temperature of the foods generally ranged from 4-20oC. Domestic efrigerator temperatures were found to have an overall mean temperature of 6.C with a range of -l"C to +llC On average, only 30% of refrigerators were operating below 5C. Of the refrigerators included in the survey, 7.3%were running at average temperatures of greater than 9oC, though positional temperature differences, particularly in fridge-freezers and larder freezers, indicate this figure to be higher if product is stored in the top of these refriger ators. Evans(1998)has also provided additional data on consumer practices Whilst such information gives an indication of the temperatures and times that are likely to be needed in shelf-life trials to simulate consumer handling, there is still the decision to be made with respect to what is a reasonable worst case to use. If theworst case temperatures and holding times that have been recorded were used in shelf-life tests, few of the products currently in the market-place would achieve the target shelf-life. The manufacturer has to estimate where reasonable abuse ends and unreasonable' abuse begins Consumer handling of products may not be as intended or envisaged by the manufacturer. Many chilled products are purchased on the basis of the fresh image, but then frozen at home. Opening and partial use of vacuum or modified atmosphere packaged products invalidates the shelf-life information with respect to the remaining product. A survey of consumer perceptions of the shelf-life of chilled foods has indicated that whilst consumers believe that most chilled foods should be stored for two days or less, in reality the same householders were storing certain chilled foods for considerably longer periods of time(Evans et al
