Characterization of a traditional ripened cheese, Kurdish Kope: Lipolysis, lactate metabolism, the release profile of volatile compounds, and correlations with sensory characteristics

doi:10.1111/1750-3841.15830

Review

. 2021 Aug;86(8):3303-3321.

doi: 10.1111/1750-3841.15830. Epub 2021 Jul 19.

Characterization of a traditional ripened cheese, Kurdish Kope: Lipolysis, lactate metabolism, the release profile of volatile compounds, and correlations with sensory characteristics

Peiman Esmaeilzadeh¹, Mohammad Reza Ehsani¹, Maryam Mizani¹, Mohammad Hadi Givianrad²

Affiliations

¹ Department of Food Science and Technology, Science and Research Branch, Islamic Azad University, Tehran, Iran.
² Department of Chemistry, Science and Research Branch, Islamic Azad University, Tehran, Iran.

PMID: 34287875
DOI: 10.1111/1750-3841.15830

Review

Characterization of a traditional ripened cheese, Kurdish Kope: Lipolysis, lactate metabolism, the release profile of volatile compounds, and correlations with sensory characteristics

Peiman Esmaeilzadeh et al. J Food Sci. 2021 Aug.

. 2021 Aug;86(8):3303-3321.

doi: 10.1111/1750-3841.15830. Epub 2021 Jul 19.

Authors

Peiman Esmaeilzadeh¹, Mohammad Reza Ehsani¹, Maryam Mizani¹, Mohammad Hadi Givianrad²

Affiliations

¹ Department of Food Science and Technology, Science and Research Branch, Islamic Azad University, Tehran, Iran.
² Department of Chemistry, Science and Research Branch, Islamic Azad University, Tehran, Iran.

PMID: 34287875
DOI: 10.1111/1750-3841.15830

Abstract

Kope cheese has been characterized based on gross chemical composition, free fatty acids (FFAs), organic acids (OAs), volatile compounds (VCs), and sensory attributes (SAs) during 187 days of the ripening period. C16:0, C18:1cisΔ9, and C14:0 were the most abundant FFAs. Lactic and acetic acids were the most prevalent OAs affecting sensory properties. principal component analysis (PCA) indicated that butanoic acid, butyl hexanoate, and 2,3-butanediol were as key VCs. Protein contents, pH (based on FFA and OA), salt in the moisture (S/M), and water activity (a_w ) (based on VC and SA) were highly correlated with PC2, resulted in two distinct groups. Based on lipolysis and glycolysis studies, early-ripened cheese samples showed lipolysis and lactate metabolism more intensely compared to medium and old-ripened ones. Based on the data of VC and SA, the samples may be classified into three groups: (1) early-ripened cheeses with a salty taste, waxy to cheesy odor, and rubbery texture, (2) medium-ripened cheese with a sweet taste and cheesy odor, and (3) old-ripened cheese with a bitter taste, cheesy to pungent odor, a firm and fragile texture. Textural attributes were highly correlated with proteolysis indices and pH. The results of sensory desirability indicated a significant correlation with pungency, bitterness, and OAs. The cheese samples ripened on the day 127 were selected as the most desirable product. Ripening time had a significant effect on the chemical composition, especially on S/M, pH, and a_w parameters, which determine the pattern as well as the intensity of biochemical pathways and the final sensory attributes. PRACTICAL APPLICATION: The current study intends to characterize and develop a standardized procedure for producing a traditional cheese called "Kope cheese" by determining the appropriate duration time for the ripening process, determining the main chemical/biochemical compounds that are highly correlated with its unique flavor and texture and distinguishing the key processing factors (such as curd salting, pH values during brining) that have to be altered or controlled carefully during the manufacturing process. The data would help cheese manufacturers determine the optimum time of ripening in order to achieve the best flavor and texture attributes in the final product.

Keywords: Kope cheese; free fatty acid; organic acid; principle component analysis; ripening; sensory evaluation.

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References

REFERENCES

1. AOAC 2012.13. (2012). Determination of labeled fatty acids content in milk products and infant formula: capillary gas chromatography - first action. Rockville, MD, USA: Association of Official Analytical Chemists (AOAC) International.
1. Bárcenas, P., Elortondo, F. P., & Albisu, M. (2003). Comparison of free choice profiling, direct similarity measurements and hedonic data for ewes’ milk cheeses sensory evaluation. International Dairy Journal, 13(1), 67-77.
1. Bertuzzi, A. S., McSweeney, P. L., Rea, M. C., & Kilcawley, K. N. (2018). Detection of volatile compounds of cheese and their contribution to the flavor profile of surface-ripened cheese. Comprehensive Reviews in Food Science and Food Safety, 17(2), 371-390.
1. Bontinis, T. G., Mallatou, H., Pappa, E., Massouras, T., & Alichanidis, E. (2012). Study of proteolysis, lipolysis and volatile profile of a traditional Greek goat cheese (Xinotyri) during ripening. Small Ruminant Research, 105(1-3), 193-201.
1. Bouzas, J., Kantt, C., Bodyfelt, F., & Torres, J. (1993). Time and temperature influence on chemical aging indicators for a commercial Cheddar cheese. Journal of Food Science, 58(6), 1307-1313.

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[1] AOAC 2012.13. (2012). Determination of labeled fatty acids content in milk products and infant formula: capillary gas chromatography - first action. Rockville, MD, USA: Association of Official Analytical Chemists (AOAC) International.

[2] AOAC 2012.13. (2012). Determination of labeled fatty acids content in milk products and infant formula: capillary gas chromatography - first action. Rockville, MD, USA: Association of Official Analytical Chemists (AOAC) International.

[3] Bárcenas, P., Elortondo, F. P., & Albisu, M. (2003). Comparison of free choice profiling, direct similarity measurements and hedonic data for ewes’ milk cheeses sensory evaluation. International Dairy Journal, 13(1), 67-77.

[4] Bárcenas, P., Elortondo, F. P., & Albisu, M. (2003). Comparison of free choice profiling, direct similarity measurements and hedonic data for ewes’ milk cheeses sensory evaluation. International Dairy Journal, 13(1), 67-77.

[5] Bertuzzi, A. S., McSweeney, P. L., Rea, M. C., & Kilcawley, K. N. (2018). Detection of volatile compounds of cheese and their contribution to the flavor profile of surface-ripened cheese. Comprehensive Reviews in Food Science and Food Safety, 17(2), 371-390.

[6] Bertuzzi, A. S., McSweeney, P. L., Rea, M. C., & Kilcawley, K. N. (2018). Detection of volatile compounds of cheese and their contribution to the flavor profile of surface-ripened cheese. Comprehensive Reviews in Food Science and Food Safety, 17(2), 371-390.

[7] Bontinis, T. G., Mallatou, H., Pappa, E., Massouras, T., & Alichanidis, E. (2012). Study of proteolysis, lipolysis and volatile profile of a traditional Greek goat cheese (Xinotyri) during ripening. Small Ruminant Research, 105(1-3), 193-201.

[8] Bontinis, T. G., Mallatou, H., Pappa, E., Massouras, T., & Alichanidis, E. (2012). Study of proteolysis, lipolysis and volatile profile of a traditional Greek goat cheese (Xinotyri) during ripening. Small Ruminant Research, 105(1-3), 193-201.

[9] Bouzas, J., Kantt, C., Bodyfelt, F., & Torres, J. (1993). Time and temperature influence on chemical aging indicators for a commercial Cheddar cheese. Journal of Food Science, 58(6), 1307-1313.

[10] Bouzas, J., Kantt, C., Bodyfelt, F., & Torres, J. (1993). Time and temperature influence on chemical aging indicators for a commercial Cheddar cheese. Journal of Food Science, 58(6), 1307-1313.

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Characterization of a traditional ripened cheese, Kurdish Kope: Lipolysis, lactate metabolism, the release profile of volatile compounds, and correlations with sensory characteristics

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Characterization of a traditional ripened cheese, Kurdish Kope: Lipolysis, lactate metabolism, the release profile of volatile compounds, and correlations with sensory characteristics

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