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

Abstract

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 Kackavalj, Kackavalj Krstas, 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 degrees C and on cooling from 90 to 25 degrees 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 Kackavalj cheeses had relatively high levels of salt-in-moisture and pH 4.6 soluble N and low protein-to-fat ratio and levels of alpha(s1)-CN (f24-199). They fractured during compression to 75%; had relatively low values of cohesiveness, chewiness, and springiness; melted at 70 to 90 degrees C; reached maximum LT at 90 degrees C; and congealed at 58 to 63 degrees C. Conversely, the Kackavalj Krstas 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 degrees C), attained maximum fluidity at a lower temperature (72-78 degrees C), and congealed at 54 to 69 degrees 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 degrees C provides a potentially useful means of designing ingredient cheeses, with the desired attributes when heated and cooled under customized specification.