The fate of Listeria monocytogenes during the manufacture of Camembert-type cheese: A comparison between raw milk and milk treated with high hydrostatic pressure

Camembert-type cheese was produced from: raw bovine milk; raw milk inoculated with 2 or 4 log CFU/ml Listeria monocytogenes; raw milk inoculated with L. monocytogenes and subsequently pressure-treated at 500 MPa for 10 min at 20 °C; or uninoculated raw milk pressure-treated under these conditions. Cheeses produced from both pressure-treated milk and untreated milk had the typical composition, appearance and aroma of Camembert. Curd and cheese made from inoculated, untreated milk contained large numbers of L. monocytogenes throughout production. An initial inoculum of 1.95 log CFU/ml in milk increased to 4.52 log CFU/g in the curd and remained at a high level during ripening, with 3.85 log CFU/g in the final cheese. Pressure treatment inactivated L. monocytogenes in the raw milk at both inoculum levels and the pathogen was not detected in any of the final cheeses produced from pressure-treated milk. Therefore high pressure may be useful to inactivate L. monocytogenes in raw milk that is to be used for the production of soft, mould-ripened cheese.

Industrial relevance

This paper demonstrates the potential of high pressure (HP) for treatment of raw milk to be used in the manufacture of soft cheeses. HP treatment significantly reduced the level of Listeria monocytogenes in the raw milk and so allowed the production of safer non-thermally processed camembert-like soft cheese.     

Camembert-type cheese quality and safety implications in relation to the timing of high-pressure processing during aging

Bloomy rind cheeses, including Brie, Camembert, and related varieties, are at high risk of contamination by environmental pathogens during manufacture and ripening. This risk is particularly high during ripening due to open-air exposure of the product. Currently, no kill step is applied after manufacture or post ripening to control food safety risks associated with Listeria monocytogenes contamination. Instead, cheesemakers must rely on sanitation and environmental monitoring to reduce this risk. High-pressure processing (HPP) is a nonthermal food-processing technology that can effectively reduce bacterial contaminants with minimal impact on the organoleptic properties of various foods. The objective of this study was to evaluate HPP as a potential intervention to maintain Camembert cheese quality and reduce risk associated with L. monocytogenes. Timing of HPP treatments (3, 11, and 45 d after manufacture) was based on the growth of L. monocytogenes during Camembert cheese ripening. High-pressure processing treatment of fully ripened cheeses (45 d) resulted in destruction of the surface mold, which caused browning and yellowing of the cheese rind. Applying HPP treatment earlier in the ripening process (11 d) resulted in a similar degradation of cheese appearance, which did not improve with continued ripening. Applying HPP treatment shortly after production (3 d; before the surface flora developed) delayed the development of the cheese rind and the textural ripening of the cheese. This early treatment time also resulted in free whey being expelled from the cheese, creating a firmer body. Applying HPP 11 d after manufacture resulted in >5 log reduction of L. monocytogenes at 450 and 550 MPa with holding times of 10 min. Although HPP was effective at reducing L. monocytogenes associated with bloomy rind cheeses, the quality deterioration would be unacceptable to consumers. Cheesemakers must continue to emphasize sanitation and environmental monitoring to reduce the risk of L. monocytogenes in bloomy rind cheeses.     

Properties of cholesterol‐reduced Camembert cheese made by crosslinked β‐cyclodextrin

The present study was designed to examine the physicochemical and sensory properties in cholesterol‐reduced Camembert cheese made by crosslinked β‐cyclodextrin (β‐CD). The composition of cholesterol‐reduced Camembert cheese was similar to the control and the cholesterol reduction reached 90.6%. No difference was found in the total amount of short‐chain free fatty acids between the cholesterol‐reduced cheese and the control at every ripening period. The release of butyric and capric acid mostly contributed to the increase of total amount of short‐chain free fatty acids in both groups. The cholesterol‐reduced cheese produced similar amounts of individual free amino acids to the control in all periods. The scores of all rheological characteristics except for springiness were continuously increased up to 2 weeks’ ripening and decreased thereafter. Mouldy characteristics in both appearance and flavour were increased dramatically through the ripening period in both cholesterol‐reduced and the control cheeses. Based on these results, no significant difference was found in most physicochemical and sensory properties between cholesterol‐reduced Camembert cheese and the control. Therefore, we may find it possible to develop cholesterol‐reduced Camembert cheese using crosslinked β‐cyclodextrin.     

Ripening of Camembert-type cheese made from caprine milk using calf rennet or kid rennet as coagulant

Camembert-type cheese was made from caprine milk using either calf rennet or kid 'Grandine' rennet as coagulant. The pH of all cheeses increased throughout ripening and levels of pH 4.6-soluble nitrogen increased from 8.1 to 18.2% of total nitrogen (TN) and from 6.9 to 20% TN for the cheeses made using calf rennet and kid rennet, respectively. Degradation of β-casein, measured by urea–polyacrylamide gel electrophoresis, and total and free amino acids were greater in the cheese made using kid rennet. Production of peptides, analysed by high performance liquid chromatography (HPLC), was slightly more extensive in the Camembert-type cheese made using calf rennet as coagulant. In general, a higher degree of proteolysis was found in Camembert-type cheese made from caprine milk using kid rennet than in cheese made using calf rennet as coagulant.     

Effect of modified atmosphere packaging on quality factors and shelf-life of surface mould ripened cheese: Part I constant temperature

In the present study, packaging of a surface mould ripened cheese under 2 atm: MAP-A (0% O₂, 27 ± 6% CO₂) and MAP-B (2 ± 1% O₂, 19 ± 2% CO₂) was studied at 12 °C and the results were compared with the existing commercial packaging system (wrapped with waxed paper and inserted in cardboard box). Quality parameters such as colour, texture, pH and moisture content were evaluated after 0, 7 and 14 days of storage, together with a sensory evaluation. Tuckey test and principal components analysis showed that after 14 days of storage, the best conditions for the preservation of the cheeses corresponded to MAP-B. The predicted shelf-life was found to be 14, 6 and 17 days for control, MAP-A and MAP-B respectively. It was concluded that modified atmosphere packaging of surface mould ripened cheese with low levels of O₂ (1-3%) and relatively high levels of CO₂ (17-21%) can be used to extend the shelf-life of soft cheese; however the package has to be suitably designed, as total loss of O₂ (as in MAP-A) would shorten the shelf-life.     

Enhancement of ester formation in Camembert cheese by addition of ethanol

Ethyl esters are often detected at trace levels in Camembert cheese. This study investigated how the addition of ethanol prior to cheesemaking influenced the composition, texture and flavour profile of Camembert compared to a control cheese manufactured under identical conditions without ethanol. No statistical differences were observed in the composition, microbes or textures of the experimental and control cheeses. However, more ethyl esters and a significantly enhanced fruity flavour perception were reported for the experimental cheeses compared to the control. The addition of 400–1200 μg/g of ethanol may be applied in the production of Camembert cheese to enhance fruity flavour.     

Sodium Chloride and Magnesium Chloride affected by Ripening of Camembert Cheese

Ripening of cheese with three kinds of salt treatment was studied using MgCl₂, NaCl or a mixture of the two. Proteolysis was followed by determination of TCA-soluble nitrogen and quantitative electrophoresis. A rapid one-step method for free fatty acids was used to determine short and long-chain fatty acids. In the presence of magnesium, proteolysis increased, even with NaCl, which seemed to delay the magnesium activation. Lipolysis was retarded by NaCl, which decreased the level of free fatty acids. An imbalance between proteolysis and lipolysis could be responsible for the unpleasant flavor of the cheese containing both MgCl₂ and NaCl.     

Short communication: Little change takes place in Camembert-type cheese water activities throughout ripening in terms of relative humidity and salt

Water activity (a_w) affects the growth and activity of ripening microorganisms. Moreover, it is generally accepted that a_w depends on relative humidity (RH) and salt content; these 3 variables were usually measured on a given day in a cheese without the microorganism layer and without accounting for a distinction between the rind, the underrind, and the core. However, a_w dynamics have never been thoroughly studied throughout cheese ripening. Experimental Camembert cheeses were ripened under controlled and aseptic conditions (temperature, gaseous atmosphere, and RH) for 14 d. In this study, only RH was varied. Samples were taken from the cheese (microorganism layer)–air interface, the rind, and the core. The a_w of the cheese–air interface did not change over ripening when RH varied between 91 and 92% or between 97 and 98%. However, on d 5, we observed a small but significant increase in a_w, which coincided with the beginning of growth of Penicillium camemberti mycelia. After d 3, no significant differences were found between the a_w of the cheese–air interface, the rind, and the core. From d 0 to 3, cheese rind a_w increased from 0.94 to 0.97, which was probably due to the diffusion of salt from the rind to the core: NaCl content in the rind decreased from 3.7 to 1.6% and NaCl content in the core increased from 0.0 to 1.6%. Nevertheless, a_w did not significantly vary in the core, raising questions about the real effect of salt on a_w.     

Camembert Cheese Water Loss through Absorbent Packaging

Moisture transport through packaging material developed for “Camembert” cheese was studied. The three-layer film contained a water absorber/desorber layer. A simulated cheese surface made the packaging material swell on water sorption. After a period of initial swelling, thickness became constant and the Total Water Desorption Rate (TWDR) from food to the atmosphere was measured. Water concentration and apparent water diffusivity in the packaging material and in the “Camembert” cheese were determined. A published algorithm for predicting TWDR was adapted to this system and validated experimentaly.