Abstract
Freshness is an important index of egg quality. In this study, a synchronous fluorescence spectral technique was employed to determine the freshness of an intact egg. Synchronous fluorescence spectra of intact eggs were acquired using a fluorescence spectrometer supported by a laboratory fluorescence acquisition device and egg freshness (Haugh Unit) was obtained using destructive methods. Eggs feature fluorescence signals were mainly concentrated in two regions: A (excitation wavelength of 290 nm over the emission wavelength range of 320-380 nm) and B (excitation wavelength range of 380-570 nm over the emission wavelength range of 610-735 nm). The two regions were selected as regions of interest, which include 2581 Excitation-Emission (Ex-Em) wavelengths; stepwise discrimination analysis was performed on the 2581 Ex-Em wavelengths to choose optimal Ex-Em wavelength combinations. A Multiple Linear Regression (MLR) prediction model was built using fluorescence signals based on the optimal Ex-Em wavelength combinations. The results revealed that the freshness of an egg could be accurately predicted with Rp2 of 0.8879 and a root mean square error estimated by validation (SEP) of 6.2896. This work demonstrates that the synchronous fluorescence spectral technique has high potential for nondestructive sensing of egg freshness.
Highlights
Eggs contain many kinds of nutrients that the human body needs and are an important food for human beings
We found that there were some prominent peaks, which were seen in the excitation wavelength of 290 nm over the emission wavelength range of 320-380 nm and in the excitation wavelength range of 380570 nm over the emission wavelength range of 610-735 nm
Freshness is a comprehensive index of egg quality, the two regions were selected as Regions Of Interest (ROI)
Summary
Eggs contain many kinds of nutrients that the human body needs and are an important food for human beings. Freshness is an important index of egg quality; the freshness of eggs affects the taste of eggs and their products and directly determines the absorption of protein and other nutrients. Fluorescence spectroscopy, which depends on sensing the contents of naturally occurring fluorescent compounds, has shown potential for rapid analysis of the quality of food products (Schneider et al, 2005; Aït-Kaddou et al, 2011). Fluorescence spectra can provide information about the fluorescent groups in foods, such as proteins, amino acids, heterocyclic aromatic amines and so on (Aït-Kaddou et al, 2011; Brøndum et al, 2000). Fluorescence spectra technology can be used in food quality and safety study. Traditional fluorescence technology has been widely used in meat quality and safety testing.
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