One unresolved challenge in the egg industry is how to efficiently and non-invasively detect unfertilized eggs prior to incubation. This detection ability would not only significantly improve hatching rates and reduce costs but also conserve incubator space and prevent poor-quality embryos from contributing to the spread of infections. This study demonstrates a procedure for distinguishing between fertilized and unfertilized eggs prior to incubation by studying the respiratory differences between fertilized and unfertilized eggs using the Non-invasive Micro-test Technique (NMT). A customized micro-testing examination platform, NMT Egg Testing System (NMT-ETS) was constructed for the real-time monitoring of the intensity and rate of oxygen exchange between the egg and its external environment. The results from this study revealed that at room temperature, there is a significant difference in gas exchange rates between fertilized and unfertilized eggs. The results indicate that the oxygen flux of fertilized eggs exceed 20 pmol/(cm2•s), whereas unfertilized eggs show a much lower oxygen flux. Based on the results, the NMT method can be used to effectively distinguish between fertilized and unfertilized chicken eggs.
Keywords: oxygen flux, gas exchange rates, fertilized eggs, unfertilized eggs, non-invasive micro-test technique
DOI: 10.25165/j.ijabe.20171004.2606

Citation: Wang Q H, Fu D D, Ma M H, Zhang T. Differentiating between fertilized and unfertilized eggs prior to incubation based on oxygen flux measurement. Int J Agric & Biol Eng, 2017; 10(4): 243–251.

oxygen flux, gas exchange rates, fertilized eggs, unfertilized eggs, non-invasive micro-test technique

Ma M H. Processing technology and quality safety control strategy of egg products. China Poultry, 2009; 31: 1–5. (in Chinese)

Joseph M M. Factors affecting the hatchability and hatching. China Poultry, 2002; 24: 27–32. (in Chinese)

Das K, Evans M D. Detecting fertility of hatching eggs using machine vision II: Neural network classifiers. Transactions of the ASAE, 1992; 35: 2035–2041.

Bamelis F R, Tona K, de Baerdemeaker J G. Detection of early embryonic development in chicken eggs using visible light transmission. British Poultry Science, 2002; 43: 204–212.

Smith D P, Lawewnce K C, Park B. Detection of fertility and early development of hatching eggs with hyperspectral imaging. Proc. 11th European Symposium on the Quality of Eggs and Egg Products Netherlands: World’s Poultry Science Association, 2005; pp.176–180.

Jones S T, Shattuck R E. Detection of Early Embryonic Development in hatching eggs: a hyperspectral imaging systems and neural network approach. Johns Hopkins Applied Physics Laboratory Technical Digest, 2005; 1: 67–73.

Bamelis F, Kemps B, Mertens K, Tona K, de Ketelaere B, Decuypere E, et al. Non-destructive measurements on eggs during incubation. Avian and Poultry Biology Reviews, 2004; 15: 3–4.

Liu L, Ngadi M. Detecting fertility and early embryo development of chicken eggs using near-infrared hyper-spectral imaging. Food and Bio-process Technology, 2013; 6: 9.

Kerstin W A. Seymour R S. Effect of regional changes to shell conductance on oxygen consumption and growth of chicken embryos. Respiration Physiology, 2002; 129(3): 385–395.

Sunder L M,Tompkins D M, Hudson P J. The role of oxygen availability in the embryo nation of Heterakis gallinarum eggs. International Journal for Parasitology, 2000; 30: 1481–1485.

Pearson J T, Haque M A, Hou P C, Tazawa H. Developmental patterns of O2 consumption, heart rate and O2 pulse in unturned eggs. Respiration Physiology, 1996; 103: 83–87.

Seymour R S, Kerstn W A. Non-invasive measurement of oxygen partial pressure, lateral diffusion and chorioallantoic blood flow under the avian eggshell. Comparative Bio-chemistry and Physiology, Part A, 2008; 150: 258–264.

Kuhtreiber W M, Laffe L F. Detection of extracelluar calcium gradients with a calcium-specific vibrating electrode. Journal of Cell Biology, 1990; 110: 1565–1573.

Bakst M R, Gupta S K, Potts W, Akuffo V. Gross appearance of the turkey blastoderm at oviposition. Poultry Science, 1998; 77(8): 1228–1233.

Wang Q H, Zhang T, Ma M H. Oxygen respiratory regularity of eggs in storage period monitoring by non-invasive micro-test technique. Transactions of the CSAE, 2014; 3(5): 255–261.

Chwalibog A, Tauson A H, Ali A, Matthiesen C, Thorhayge K, Thorbek G. Gas exchange, heat production and oxidation of fat in chicken embryos from a fast or slow growing line. Comparative Biochemistry and Physiology, Part A, 2007; 146: 305–309.

Jacopo P M, Katherine L. Oxygen consumption of the chicken embryo: interaction between temperature and oxygenation, science direct. Respiratory Physiology & Neurobiology, 2005; 146: 97–106.

Wang Q H, Zhang T, Ma M H, Li X M. Study on the Relationship between egg O2 respiration and eggshell ultra structure. Advance Journal of Food Science and Technology, 2015; 9(3): 159–166.