Gabriel Duboz

Ripening and quality of Swiss-type cheese made from raw, pasteurized or microfiltered milk

Abstract Experimental mini-cheeses were made from raw (Ra), microfiltered (MF), pasteurized (Pa) (72 °C, 30s) or pasteurized mixed with microfiltration retentate (PR) milk to study the influence of the indigenous microflora and pasteurization on the quality of Swiss-type cheese. To estimate biochemical transformations during cheese ripening, several methods were used: nitrogen fractionation (water-soluble fraction and phosphotungstic acid (PTA)-soluble fraction), urea-polyacrylamide gel electrophoresis of caseins, reverse phase liquid chromatography of the water-soluble fraction, lactate and volatile fatty acids. Microbial populations were also enumerated. At the end of ripening, in comparison with MF and Pa milk cheeses, Ra and PR milk cheeses exhibited higher overall aroma intensity and pungency, characteristics which correlated with higher populations of facultatively heterofermentative lactobacilli (108 cfug−1), propionibacteria (108 cfug−1), and enterococci (106cfug−1). These cheeses had high levels of PTA-soluble N and acetic, propionic and isovaleric acids. MF and Pa milk cheeses, although somewhat different from one another, were very different from the two other types of cheese. Pa milk cheese had a lower pH than MF milk cheese, and contained a higher proportion of γ-caseins due to the activation of plasmin. Moreover, Pa milk cheese was more acidic, but demonstrated a higher overall aroma intensity. The addition of raw milk flora (retentate) to Pa milk restored almost all the biochemical and sensory characteristics of Ra milk cheese measured in this study.

Food processing increases casein resistance to simulated infant digestion.

The objective of this study was to determine whether processing could modify the resistance of casein (CN) to digestion in infants. A range of different dairy matrices was manufactured from raw milk in a pilot plant and subjected to in vitro digestion using an infant gut model. Digestion products were identified using MS and immunochemical techniques. Results obtained showed that CNs were able to resist digestion, particularly κ- and αs(2)-CN. Resistant areas were identified and corresponded to fragments hydrophobic at pH 3.0 (gastric conditions) and/or carrying post-translational modifications (phosphorylation and glycosylation). Milk processing led to differences in peptide patterns and heat treatment of milk tended to increase the number of peptides found in digested samples. This highlights the likely impact of milk processing on the allergenic potential of CNs.

Multiple interactions between Streptococcus thermophilus, Lactobacillus helveticus and Lactobacillus delbrueckii strongly affect their growth kinetics during the making of hard cooked cheeses.

In hard cooked cheeses, any interactions between the thermophilic starters as they grow during the cheese-making are critical, since they modify bacterial growth kinetics and acidification kinetics, so affecting the ripening process and the final characteristics of the cheese. Twenty-four experimental hard cooked cheeses were made under controlled conditions, the milk being inoculated with various combinations of thermophilic strains of Streptococcus thermophilus, Lactobacillus helveticus and Lactobacillus delbrueckii. Over the first day of manufacturing we recorded a wide range of different growth kinetics for each starter species used, and a wide range of pH kinetics, depending on the starter combination. Most of the bacterial variability could be statistically explained by the nature, quantity, and/or presence or absence of the different strains inoculated. Four main interactions between the three species were evidenced during cheese-making. There was antagonism between L. helveticus and L. delbrueckii. The lactobacilli had a positive effect on S. thermophilus, which was reciprocal for L. helveticus. L. helveticus had a negative effect on S. thermophilus cultivability. And the combination of S. thermophilus inoculated in large quantities and L. helveticus strain H2 had a negative effect on the growth of the L. delbrueckii strain D2. While the positive effect of L. delbrueckii on S. thermophilus probably corresponds to interactions in milk that have already been described and published, the other interactions were hitherto unknown. These interactions are of major importance for the growth kinetics of streptococci and thermophilic lactobacilli during cheese-making.

The Microbiology of Traditional Hard and Semihard Cooked Mountain Cheeses.

Traditional cheeses originate from complex systems that confer on them specific sensory characteristics. These characteristics are linked to various factors of biodiversity such as animal feed, the use of raw milk and its indigenous microflora, the cheese technology, and the ripening conditions, all in conjunction with the knowledge of the cheesemaker and affineur. In Europe, particularly in France, the preservation of traditional cheesemaking processes, some of which have protected designation of origin, is vital for the farming and food industry in certain regions. Among these cheeses, some are made in the Alps or Jura Mountains, including Comté, Beaufort, Abondance, and Emmental, which are made from raw milk. The principle of hard or semihard cooked cheese, produced in the Alps and Jura Mountains, was to make a product during the summer-a period during which the animals feed more and milk production is high-with a shelf life of several months that could be consumed in winter. Today, these traditional cheeses are produced according to a specific approach combining science and tradition in order to better understand and preserve the elements that contribute to the distinctiveness of these cheeses. To address this complex problem, a global approach to the role of the raw milk microflora in the final quality of cheeses was initially chosen. The modifications resulting from the elimination of the raw milk microflora, either by pasteurization or by microfiltration, to the biochemistry of the ripening process and ultimately the sensory quality of the cheeses were evaluated. This approach was achieved mainly with experimental hard cooked cheeses. Other types of traditional cheese made with raw and pasteurized milk are also considered when necessary. Besides the native raw milk microflora, traditional lactic starters (natural or wild starters) also participate in the development of the characteristics of traditional hard and semihard cooked mountain cheeses. After an initial description, their roles are described, mainly for Comté.

Phase transition of triglycerides in fat globules during semi-hard cheese ripening as studied by mid-infrared and front-face fluorescence spectroscopy

Texture is an important criteria used to evaluate the quality of cheeses. It is a reflection of their structure at the microscopic and molecular levels. Understanding the structure of cheeses, particularly protein and fat structures and the interactions betwen cheese components during and after manufacture, can provide information useful in determining what constitutes a quality product. It is well known that the cheese texture may change with the physical state of the fats depending on the storage temperature and time. Melting of the hundreds species of triacylglycerols of milk fat globule occurs over a large temperature range, ie, between -30 and +40 °C [1, 2]. Casal and Mantsch [3] have shown that the infrared bands appearing in the 3000–2800 cm-1 region are sensitive to the conformation and the packing of the phospholipid acyl chains. Frontface fluorescence spectroscopy allows investigation of the fluorescence of powdered, turbid and concentrated samples [4, 5, 6] and provides information on the presence of fluorescent molecules and their environment in samples such as food products.