Kitchen hygiene in daily life

More and more data are available indicating that numerous (infectious) diseases are related to the home environment. Airborne microorganisms (bacteria, fungi), mites (in sheets or carpets), and (parts of) insects and beetles may be the cause of respiratory diseases such as asthma. In Europe and North America, more than half of the registered food infections appear to be contracted in the home. Then there is the development of new pathogens or the adaptation of microorganisms to extreme conditions. In many cases, the occurrence of adapted or resistant microorganisms is a reaction to the changing environment. Examples of this are the growth of Listeria monocytogenes in refrigerated food products and the presence of Legionella pneumophila in systems containing stagnant water. The main sources of infection in the domestic environment are people, pests, pets, and contaminated food and water. Germs are transmitted by direct contact with people or animals, by contaminated food, water, surfaces and air. Under circumstances favourable to microorganisms, the cells are able to survive or multiply into large numbers. Especially in places which stay moist for a long time considerable amounts of microorganisms are found, among with pathogenic types. The phrase 'home hygiene' does not merely refer to cleaning the house (daily). In practice, cleaning is not the only important issue; knowing how to prevent contamination is just as crucial. Domestic hygiene is the total sum of the measures used to prevent (insofar as possible) contamination with pathogens, and thus decreasing the number of infectious diseases. The hygiene measures required can be divided into three groups: Hygiene during food preparation. Personal and sanitary hygiene. Domestic environment. This contribution will focus on food storage, food preparation and the effect of 'hygienic cleaners' in the domestic kitchen. (C) 2003 Elsevier Science Ltd. All rights reserved

Kruisbesmetting in de keuken

Onjuiste voedselbereiding in de huishoudelijke keuken levert een aanmerkelijke bijdrage aan het vóórkomen van voedselinfectie

Survival of foodborne pathogens on stainless steel surfaces and cross-contamination to foods

The retention of bacteria on food contact surfaces increases the risk of cross-contamination of these microorganisms to food. The risk has been considered to be lowered when the surfaces are dry, partly because bacterial growth and survival would be reduced. However, some non-spore-forming bacteria might be able to withstand dry conditions on surfaces for an extensive period of time. In this study the survival of Salmonella enteritidis, Staphylococcus aureus and Campylobacter jejuni on stainless steel surfaces at different initial levels was determined at room temperature. The transfer rates of these pathogens from kitchen sponges to stainless steel surfaces and from these surfaces to foods were also investigated. Staph. aureus was recovered from the surfaces for at least 4 days when the contamination level was high (10(5) CFU/cm(2)) or moderate (10(3) CFU/cm(2)). At low levels (10 CFU/cm(2)), the surviving numbers decreased below the detection limit (4 CFU/100 cm(2)) within 2 days. S. enteritidis was recovered from surfaces for at least 4 days at high contamination levels, but at moderate level, the numbers decreased to the detection limit within 24 h and at low level within 1 h. C jejuni was the most susceptible to slow-air-drying on surfaces; at high contamination levels, the numbers decreased below the detection limit within 4 h. The test microorganisms were readily transmitted from the wet sponges to the stainless steel surfaces and from these surfaces to the cucumber and chicken fillet slices, with the transfer rates varied from 20% to 100%. This study has highlighted the fact that pathogens remain viable on dry stainless steel surfaces and present a contamination hazard for considerable periods of time, dependent on the contamination levels and type of pathogen. Systematic studies on the risks of pathogen transfer associated with surface cleaning using contaminated sponges provide quantitative data from which a model of risks assessment in domestic setting could lead. (C) 2002 Elsevier Science B.V. All rights reserved

Effects of antibacterial dishwashing liquid on foodborne pathogens and competitive microorganisms in kitchen sponges

In response to increasing concern about home hygiene, the use of antibacterial products to reduce microorganisms in kitchen sponges and cleaning cloths is strongly promoted by some producers of detergent for domestic use. The effects of an antibacterial dishwashing liquid on Escherichia coli, Salmonella Enteritidis, Staphylococcus aureus, and Bacillus cereus were investigated in a modified suspension test and in used sponges with and without food residues under laboratory conditions. A limited study was conducted in households to assess the efficacy of antibacterial dishwashing liquid as used by the consumer. In the suspension tests, S. aureus and B. cereus were shown to be susceptible to low concentrations of antibacterial dishwashing liquid (0.5Œ whereas E. coli and Salmonella Enteritidis maintained their initial numbers for at least 24 h at 25°C. At higher concentrations (2 to 4Œ all test organisms decreased to below the detection limit after 24 h. Over a 24-h period, the antibacterial dishwashing liquid did not significantly reduce these organisms in used sponges in which food residues were present. The antibacterial product did not reduce the competitive microorganisms either. Similar results were found for sponges involved in daily household use. The results of this study demonstrate that the antibacterial dishwashing liquid was effective in reducing pathogens in the suspension test but not in the used sponges. This finding indicates that to determine the efficacy of antibacterial products, their use in a household setting must be considered

A quantitative analysis of cross-contamination of Salmonella and Campylobacter spp. via domestic kitchen surfaces

Epidemiological data indicate that cross-contamination during food preparation in the home contributes noticeably to the occurrence of foodborne diseases. To help prevent such occurrences, the inclusion of a cross-contamination model in exposure assessments would aid in the development and evaluation of interventions used to control the spread of pathogenic bacteria. A quantitative analysis was carried out to estimate the probability of contamination and the levels of Salmonella and Campylobacter spp. on salads as a result of cross-contamination from contaminated chicken carcasses via kitchen surfaces. Data on the prevalence and numbers of these bacteria on retail chicken carcasses and the use of unwashed surfaces to prepare foods were collected from scientific literature. The rates of bacterial transfer were collected from laboratory experiments and literature. A deterministic approach and Monte Carlo simulations that incorporated input parameter distributions were used to estimate the contamination of the product. The results have shown that the probability of Campylobacter spp. contamination on salads is higher than that of Salmonella spp., since both the prevalence and levels of Campylobacter spp. on chicken carcasses are higher than those of Salmonella spp. It is realistic to expect that a fraction of the human exposure to Campylobacter spp., in particular, originates from cross-contamination in private kitchens during food handling. The number of human campylobacteriosis cases could be reduced either by reducing the degree of Campylobacter spp. contamination on chicken carcasses or by improving the hygiene in private kitchens. To eliminate the cross-contamination route, it is important to use separate surfaces or to properly wash the surfaces during the preparation of raw and cooked foods or ready-to-eat foods

A quantitative analysis of cross-contamination of Salmonella and Campylobacter spp. via domestic kitchen surfaces

Epidemiological data indicate that cross-contamination during food preparation in the home contributes noticeably to the occurrence of foodborne diseases. To help prevent such occurrences, the inclusion of a cross-contamination model in exposure assessments would aid in the development and evaluation of interventions used to control the spread of pathogenic bacteria. A quantitative analysis was carried out to estimate the probability of contamination and the levels of Salmonella and Campylobacter spp. on salads as a result of cross-contamination from contaminated chicken carcasses via kitchen surfaces. Data on the prevalence and numbers of these bacteria on retail chicken carcasses and the use of unwashed surfaces to prepare foods were collected from scientific literature. The rates of bacterial transfer were collected from laboratory experiments and literature. A deterministic approach and Monte Carlo simulations that incorporated input parameter distributions were used to estimate the contamination of the product. The results have shown that the probability of Campylobacter spp. contamination on salads is higher than that of Salmonella spp., since both the prevalence and levels of Campylobacter spp. on chicken carcasses are higher than those of Salmonella spp. It is realistic to expect that a fraction of the human exposure to Campylobacter spp., in particular, originates from cross-contamination in private kitchens during food handling. The number of human campylobacteriosis cases could be reduced either by reducing the degree of Campylobacter spp. contamination on chicken carcasses or by improving the hygiene in private kitchens. To eliminate the cross-contamination route, it is important to use separate surfaces or to properly wash the surfaces during the preparation of raw and cooked foods or ready-to-eat foods