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ARS Home » Southeast Area » Athens, Georgia » U.S. National Poultry Research Center » Quality & Safety Assessment Research » Research » Publications at this Location » Publication #330137

Research Project: Rapid Assessment of Grain, Seed, and Nut Quality Attributes with Microwave Sensors

Location: Quality & Safety Assessment Research

Title: Assessing Chicken Meat Freshness through Measurement of Radio-Frequency Dielectric Properties

Author
item Trabelsi, Samir

Submitted to: American Society of Agricultural and Biological Engineers
Publication Type: Proceedings
Publication Acceptance Date: 6/10/2016
Publication Date: 7/17/2016
Citation: Trabelsi, S. 2016. Assessing Chicken Meat Freshness through Measurement of Radio-Frequency Dielectric Properties. American Society of Agricultural and Biological Engineers. ASABE Paper No. 162461534, American Society of Agricultural and Biological Engineers, St. Joseph, MI, 2016.

Interpretive Summary: Chicken meat freshness and other quality-related attributes are of interest to both producers and consumers. Currently, these attributes are assessed through measurement of several physical properties including color, pH, water holding capacity, drip loss, cook yield and texture. Procedures for determining these factors are tedious, time consuming, and involve various types of costly instrumentation. Therefore, there is a real need for methods and sensors for rapid assessment of the freshness and other quality-related attributes of chicken meat. Radio-frequency dielectric spectroscopy may have the potential to form the foundation for development of such methods and sensors. However, some challenges must be overcome before this can be achieved. A major challenge is how to correlate measured dielectric properties, which are intrinsic properties of the material, with quality attributes which are mostly empirical and subjective. Therefore, effects of chicken meat aging on its quality attributes were investigated through measurement of the dielectric properties at radio-frequencies between 200 MHz and 20 GHz. Results show decrease of the dielectric constant with the storage duration at all frequencies while the dielectric loss factor increased with storage duration at frequencies below 3.0 GHz and decreased slightly or remained constant at frequencies above that. Data analyzed at 500 MHz show that the dielectric loss factor and loss tangent increased nearly linearly with the storage duration. Similarly, the loss tangent increased with water loss. This indicates that the dielectric properties can be used for rapid and nondestructive assessment of the freshness of chicken meat, but further research will be needed to develop practically useful techniques of benefit to producers and consumers.

Technical Abstract: Change in freshness of chicken meat was assessed through measurement of the dielectric properties with a vector network analyzer and an open-ended coaxial-line probe between 200 MHz and 20 GHz at 23 oC. Chicken meat samples were stored in a refrigerator for 8 days at 4 oC. Changes in dielectric constant and loss factor were measured daily over an 8-day period. The dielectric constant decreased with frequency and storage duration with a slope change at about 4 GHz. The dielectric loss factor increased with storage duration for frequencies below 3 GHz and remained almost constant above that. The frequency dependence of the dielectric loss factor was dominated by the ionic conduction in the lower frequency range and dipolar relaxation of water above 3 GHz. Variations of the dielectric loss factor and the loss tangent with storage duration for frequencies at lower frequencies in the range studied show potential for use of dielectric spectroscopy for rapid and nondestructive assessment of the chicken meat freshness.