Impact of the proteolysis due to lactobacilli on the stretchability of Swiss-type cheese

Richoux, Romain; Aubert, L; Roset, Grégory; Kerjean, Jean-René

doi:10.1051/dst:2008030

Cited by 22 publications

(21 citation statements)

References 14 publications

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“…lactis alone or in combination with L. helveticus, the ability to stretch was at least decreased by a factor of two. It was not correlated to the total amount of peptides but to a balance between hydrophobic and hydrophilic peptides (Richoux et al 2009). The relation with the number and/or activities of L. helveticus CEP and the ability of strains to lyse and to release their intracellular peptidases was a determinant in the stretchability, and differences in strand length between strains of more than 100 mm were observed (Sadat-Mekmene et al 2013).…”

Section: Stretchabilitymentioning

confidence: 96%

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Strain-to-strain differences within lactic and propionic acid bacteria species strongly impact the properties of cheese–A review

Thierry

Valence

Deutsch

et al. 2015

Dairy Sci. & Technol.

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Lactic acid bacteria (LAB) and propionic acid bacteria (PAB) are widely used in the manufacture of cheeses and other fermented dairy products. Bacterial species used as starters are mainly chosen according to their intrinsic properties: the milk acidifying capacity for LAB starters and the aromatizing properties of PAB, for example. Beyond the general characteristics of a bacterial species, many key phenotypic traits determining their interest for dairy applications depend on the strain within a given species. Through some examples, this review illustrates how the choice of a bacterial strain with specific technological characteristics, within a given species of LAB or PAB, can determine the final properties in the end product. This concerns the technological properties of cheeses, such as flavour, texture, and opening formation, and their functional properties, such as inhibition of undesirable microorganisms and health properties. When known, the genetic determinants of the diversity are presented. This review emphasizes the importance of preserving and exploring microbial resources at the intraspecific level, as an unending source of diversity for innovation in food fermentation.

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Section: Stretchabilitymentioning

confidence: 96%

“…In contrast, stretching properties were higher in cheeses made with L. helveticus Prt − strain, compared to the Prt + strain. In Emmental cheese, Richoux et al (2009) compared the stretchability of three strains of L. helveticus or L. delbrueckii subsp. lactis.…”

Section: Stretchabilitymentioning

confidence: 99%

Strain-to-strain differences within lactic and propionic acid bacteria species strongly impact the properties of cheese–A review

Thierry

Valence

Deutsch

et al. 2015

Dairy Sci. & Technol.

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“…The FF and EW were highest for C5, lowest for C3 and C4, and intermediate for cheeses C1, C2, and C6. The high values for C5, which reflect a high level of toughness of molten extended cheese, are likely to be associated with the combined effects of a low degree of primary proteolysis (Figure 2; Table 3) and the relatively high protein content and protein-to-fat ratio (Guinee et al, 2000a;Richoux et al, 2009). Yet, the statistically different EW or FF values of cheeses C2 and C3, which had similar levels of pH 4.6-soluble N, or the similar EW and FF values for cheeses C3 and C4 despite having notably different levels of pH 4.6 soluble N, indicate the importance of factors other than total level of primary proteolysis on the extensibility characteristics of the cheese.…”

mentioning

confidence: 99%

“…Yet, the statistically different EW or FF values of cheeses C2 and C3, which had similar levels of pH 4.6-soluble N, or the similar EW and FF values for cheeses C3 and C4 despite having notably different levels of pH 4.6 soluble N, indicate the importance of factors other than total level of primary proteolysis on the extensibility characteristics of the cheese. It is likely that extensibility characteristics (EW and FF) are also influenced by factors that promote casein interaction such as high protein content, high calcium-to-casein ratio, high protein-to-fat ratio, reducing S/M in the range 6 to 0.2% or increasing S/M to ≥6%, or increasing the concentration of hydrophobic peptides (for a given level of overall primary proteolysis) through selective use of starter cultures, enhance cross-linking of the casein molecules and thereby increase EW and FF (Guo et al, 1997;Richoux et al, 2009;Everett et al, 2014). Conversely, reduction in the level of free fat in the molten cheese by homogenization of cheese milk significantly reduces the length of strings obtained on extending baked Cheddar cheese at a fixed velocity of 0.066 m/s (Guinee et al, 2000b).…”

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confidence: 99%

Textural and cooking properties and viscoelastic changes on heating and cooling of Balkan cheeses

Guinee

Pudja

Miočinović

et al. 2015

Journal of Dairy Science

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The growth in food service and prepared consumer foods has led to increasing demand for cheese with customized textural and cooking characteristics. The current study evaluated Kačkavalj, Kačkavalj Krstaš, and Trappist cheeses procured from manufacturing plants in Serbia for texture profile characteristics, flow and extensibility of the heated cheese, and changes in viscoelasticity characteristics during heating and cooling. Measured viscoelastic parameters included elastic modulus, G', loss modulus, G″, and loss tangent, LT (G″/G'). The melting temperature and congealing temperature were defined as the temperature at which LT=1 during heating from 25 to 90°C and on cooling from 90 to 25°C. The maximum LT during heating was as an index of the maximum fluidity of the molten cheese. Significant variation was noted for the extent of flow and extensibility of the heated cheeses, with no trend of cheese type. As a group, the Kačkavalj cheeses had relatively high levels of salt-in-moisture and pH 4.6-soluble N and low protein-to-fat ratio and levels of αs1-CN (f24-199). They fractured during compression to 75%; had relatively low values of cohesiveness, chewiness, and springiness; melted at ~70 to 90°C; reached maximum LT at 90°C; and congealed at 58 to 63°C. Conversely, the Kačkavalj Krstaš and Trappist cheeses had low levels of primary proteolysis and salt-in-moisture content and a high protein-to-fat ratio. They did not fracture during compression, had high values for cohesiveness and chewiness, melted at lower temperatures (56-62°C), attained maximum fluidity at a lower temperature (72-78°C), and congealed at 54 to 69°C. There was a hysteretic dependence of G' and LT on temperature for all cheeses, with the LT during cooling being higher than that during heating, and G' during cooling being lower or higher than the equivalent values during heating depending on the cheese type. Monitoring the dynamic changes in viscoelasticity during heating and cooling of the cheese in the temperature range 25 to 90°C provides a potentially useful means of designing ingredient cheeses, with the desired attributes when heated and cooled under customized specification.

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“…Richoux et al . () produced experimental Emmental cheese with a weight of 800 g to investigate the impact of proteolysis due to Lactobacilli bacterial strains on stretchability of Swiss‐type cheeses.…”

Section: Introductionmentioning

confidence: 99%

Influence of manufacturing conditions on thermo‐physical properties of ripened experimental Emmental‐type cheese and comparison with commercial Emmental cheese

Hartmann

Reicherter

Hinrichs

2016

Int J of Dairy Tech

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Experimental Emmental cheese was produced at pilot plant scale with varied process conditions, and the ripened cheeses were analysed in terms of thermo‐physical properties. The amount of propionic acid and the temperature at tan δmax ( loss factor) were significantly influenced by varied process parameters. Experimental cheeses were compared to commercial Emmental cheese by the application of principal component analysis. Commercial Emmental cheese was clearly discriminated from experimental Emmental cheese mainly due to the melting behaviour. The results allow the establishment of a small‐scale process for Emmental cheese production to promote product development on a time and cost‐saving level.

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Impact of the proteolysis due to lactobacilli on the stretchability of Swiss-type cheese

Cited by 22 publications

References 14 publications

Strain-to-strain differences within lactic and propionic acid bacteria species strongly impact the properties of cheese–A review

Strain-to-strain differences within lactic and propionic acid bacteria species strongly impact the properties of cheese–A review

Textural and cooking properties and viscoelastic changes on heating and cooling of Balkan cheeses

Influence of manufacturing conditions on thermo‐physical properties of ripened experimental Emmental‐type cheese and comparison with commercial Emmental cheese

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