家禽胚胎期性别鉴定技术研究与应用进展

doi:10.12398/j.issn.2096-7217.2023.01.003

智能化农业装备学报（中英文） ›› 2023, Vol. 4 ›› Issue (1): 26-35.DOI: 10.12398/j.issn.2096-7217.2023.01.003

家禽胚胎期性别鉴定技术研究与应用进展

韩国锋1, 2，柏宗春1, 2*，李延森3，李春梅3

1. Institute of Agricultural Facilities and Equipment, Jiangsu Academy of Agricultural Sciences, Nanjing 210014, China; 2. Key Laboratory for Protected Agriculture Engineering in the Middle and Lower Reaches of Yangtze River, Ministry of Agriculture and Rural Affairs, Nanjing 210014, China; 3. College of Animal Science and Technology, Nanjing Agricultural University, Nanjing 210095, China

出版日期:2023-02-15 发布日期:2023-02-15
通讯作者: 柏宗春，男，1981年生，江苏扬州人，博士，副研究员；研究方向为畜禽养殖环境工程与装备。E-mail: vipmaple@126.com
作者简介:韩国锋，男，1990年生，河南漯河人，博士，副研究员；研究方向为家禽孵化营养和环境调控。E-mail: hanguofeng@njau.edu.cn
基金资助:
江苏省农业科学院国际合作基金项目（0501305）；江苏省自主创新项目（CX（22）1008）；江苏省现代农机装备与技术示范推广项目（NJ2021—25）；苏北科技专项（XZ—SZ202119）

Current approaches and applications for in ovo sexing of eggs: A review

Han Guofeng1, 2, Bai Zongchun1, 2*, Li Yansen3, Li Chunmei3

1. Institute of Agricultural Facilities and Equipment, Jiangsu Academy of Agricultural Sciences, Nanjing 210014, China; 2. Key Laboratory for Protected Agriculture Engineering in the Middle and Lower Reaches of Yangtze River, Ministry of Agriculture and Rural Affairs, Nanjing 210014, China; 3. College of Animal Science and Technology, Nanjing Agricultural University, Nanjing 210095, China

Online:2023-02-15 Published:2023-02-15
Contact: Bai Zongchun.E-mail: vipmaple@126.com
About author:Han Guofeng.E-mail: hanguofeng@njau.edu.cn

摘要/Abstract

摘要： 性别鉴定是家禽生产的重要环节之一，目前通用的雏鸡翻肛鉴定法费时费工，家禽从业者和科研人员多年来致力于研发家禽孵化期胚胎性别鉴定技术，以提高性别鉴定效率、节能省工并避免淘汰公雏。总结现有家禽胚胎性别鉴定主要方法、最新研究进展和产业化应用情况，以及未来的发展建议，为家禽早期性别鉴定技术研究和应用提供参考。家禽胚胎性别分化由遗传物质决定，性腺的两性分化随着胚胎发育逐渐清晰，随之分泌性激素，导致胚胎雌雄性激素水平差异，随着胚胎的进一步发育，雌雄胚胎会出现其他差异性表观性状（羽色等）。基于上述鸡胚发育规律，可以通过检测雌雄胚胎遗传物质、性激素和其他表观性状的差异进行性别鉴定。利用聚合酶链式反应(polymerase chain reaction, PCR)或环介导等温扩增反应(loop-mediated isothermal amplification, LAMP)技术分析鸡胚性染色体上的特定基因（CHD、EE0.6、SWIM、Xho-I、DMRT等），可实现性别鉴定，该方法鉴定准确率为100%，但操作复杂，需要采集胚胎组织或血液等带遗传物质的样品，仅适用于科研领域或高价值家禽品种，难以产业化应用。使用ELISA(enzyme-linked immunosorbent assay)试剂盒测量鸡胚性激素含量，包括雌酮、雌二醇、睾酮、雄烯二酮和二氢睾酮等，可实现性别鉴定，该方法同样操作复杂，需要采集胚胎血液或尿囊液，但准确率较高，达98%以上。此外，利用光谱图像技术识别种蛋内物质成分和物理特性差异，借用机器学习建立雌雄胚胎识别光谱模型，也可实现鉴定，该方法为非侵入式，速度快，但准确率有限且通用性差。产业应用方面，德国SELEGGT公司开发了一种性激素快速检测试剂并推出一套商用鸡胚性别鉴定技术和装备，已实现产业化应用，准确率达98.5%，但是鉴定速度仅为3 600枚/h，远低于市场期望值；德国AAT公司也推出了一种基于高光谱图像技术的全自动鸡胚性别鉴定设备（CHEGGY），检测速度为20 000枚/h，鉴定准确率为96%，但仅适用于羽色自别系品种。从家禽产业应用需求角度看，基于光谱图像检测法的性别鉴定技术优势明显，产业化应用潜力最大，需要深入研究家禽胚胎发育期雌雄鸡胚间的生理差异和生理信号检测方法，为高效鸡胚性别鉴定技术和装备研发提供理论支撑。

关键词: 家禽, 孵化期, 性别鉴定, 光谱图像, 激素, 基因

Abstract: Sex identification is an important part of poultry production. The general method of vent sexing is time-consuming and labor-intensive. The poultry workers and researchers have been working on in ovo sexing technology for many years, in order to improve the efficiency of gender identification, save energy and labor, and avoid chick culling. This paper summarizes the main methods of in ovo sexing, the latest researches and application, as well as suggestions, and provides reference for the research and promotes application of in ovo sexing technology of poultry. The genetic materials determine the sex of chick embryos. The sex differentiation of gonads gradually becomes clear with the embryo development, and then sex hormones are secreted, resulting in the differences in sex hormones of embryos. With the further development of embryos, male and female embryos will have other differential epigenetic traits, like feather color etc. Thus, Based on the above-mentioned laws of chicken embryo development, the gender of embryos could be identified by detecting the differences of genetic materials, sex hormones, and epigenetic traits between male and female embryos. The in ovo sexing could be achieved by analyzing specific genes on the sex chromosomes with PCR (Polymerase Chain Reaction) or loop-mediated isothermal amplification (Loop-mediated isothermal amplification, LAMP) method. The identification accuracy rate of this method is 100%, but the operation is complicated, and samples with genetic material such as embryonic tissue or blood need to be collected. It is only suitable for scientific research or high-value poultry breeds, and is difficult for industrial application. The gender of embryos could also be identified by measuring the concentration of sex hormones, including estrone, estradiol, testosterone, androstenedione and dihydrotestosterone, etc., with ELISA (enzyme-linked immunosorbent assay) kit. This method is also complicated and needs to collect embryonic blood or allantoic fluid, and the accuracy rate reaches more than 98%. In addition, using spectral image technology to identify the differences in material composition and physical properties in eggs, and using machine learning to establish a spectral model for identifying male and female embryos, which is also a method for in ovo sexing. The method is non-invasive with high speed, but it has limited accuracy and poor generalizability. In terms of industrial applications, the SELEGGT company (Germany) has developed a rapid test reagent for sex hormones and launched commercial chicken embryo gender identification technology and equipment, which has been industrialized and applied with an accuracy rate of 98.5%. However, the identification speed is only 3 600 embryos/h, which is far lower than market expectations. Based on hyperspectral image technology, the AAT company (Germany) also launched a fully automatic chicken embryo gender identification equipment (CHEGGY). The identification speed reaches 20 000 embryos/h with an accuracy rate of 96%. However, it is only applicable to feather color self-differentiation layer breeds. From the perspective of the application requirements of the poultry industry in future, the gender identification technology based on the spectral image detection method has obvious advantages and the greatest potential for industrial application. It is necessary to clarify the physiological differences between male and female chicken embryos in the poultry embryonic development period and the physiological signal detection method, which will provide theoretical support for the development of high-efficiency in ovo sexing technology and equipment.

Key words: poultry, incubation, sex identification, spectral image, hormones, genes

中图分类号:

韩国锋, 柏宗春, 李延森, 李春梅. 家禽胚胎期性别鉴定技术研究与应用进展[J]. 智能化农业装备学报（中英文）, 2023, 4(1): 26-35.

Han Guofeng, , Bai Zongchun, , Li Yansen, Li Chunmei. Current approaches and applications for in ovo sexing of eggs: A review[J]. Journal of Intelligent Agricultural Mechanization, 2023, 4(1): 26-35.

参考文献

［1］杨宁. 全球家禽业发展趋势、挑战与技术对策［J］. 中国家禽, 2019, 41(1): 1-4. Yang Ning. Development trends, challenge and technical countermeasures of global poultry industry ［J］. China Poultry, 2019, 41(1): 1-4. ［2］李金祥. 中国畜牧业发展与科技创新［M］. 北京: 中国农业科学技术出版社, 2019. ［3］Thiruvenkadan A K, Panneerselvam S, Prabakaran R. Layer breeding strategies: An overview ［J］. World's Poultry Science Journal, 2010, 66(3): 477-502. ［4］樊宝良, 谢建国, 李剑, 等. 我国黄羽肉鸡产业现状及未来发展趋势［J］. 北方牧业, 2022(11): 17-19. ［5］魏晓冉, 王志强, 姜国松. 雏鸡雌雄翻肛鉴别技术要点［J］. 家禽科学, 2016(7): 30-32. ［6］Smith C A, Sinclair A H. Sex determination: Insights from the chicken ［J］. BioEssays, 2004, 26(2): 120-132. ［7］Pieau C. Temperature variation and sex determination in reptiles ［J］. BioEssays, 1996, 18(1): 19-26. ［8］Veterány L, Hluch S, Veterányová A. Effect of ultrasound on sex differentiation and embryonic mortality ［J］. Ceskoslovenska Fysiologie, 2001, 50(1): 31-34. ［9］Tzschentke B, Halle I. Influence of temperature stimulation during the last 4 days of incubation on secondary sex ratio and later performance in male and female broiler chicks ［J］. British Poultry Science, 2009, 50(5): 634-640. ［10］Gth A, Booth D T. Temperature-dependent sex ratio in a bird ［J］. Biology Letters, 2005(1): 31-33. ［11］Clinton M, Haines L, Belloir B, et al. Sexing chick embryos: A rapid and simple protocol ［J］. British Poultry Science, 2001, 42(1): 134-138. ［12］Mizuno H, Zuk P A, Zhu M, et al. Myogenic differentiation by human processed lipoaspirate cells ［J］. Plastic and Reconstructive Surgery, 2002, 109(1): 199-209. ［13］Smith C A. Rowley review. Sex determination in birds: A review ［J］. Emu, 2010, 110(4): 364-377. ［14］杨宇, 龚萍, 叶胜强, 等. 间接ELISA法鉴定鸭胚性别［J］. 中国家禽, 2017, 39(13): 58-60. ［15］Weissmann A, Reitemeier S, Hahn A, et al. Sexing domestic chicken before hatch: A new method for in ovo gender identification ［J］. Theriogenology, 2013, 80(3): 199-205. ［16］Woods J E, Brazzill D M. Plasma 17β-estradiol levels in the chick embryo ［J］. General and Comparative Endocrinology, 1981, 44(1): 37-43. ［17］Wang Y L, Jin G F, Ma M H, et al. Sex differences in serum steroid hormone levels during embryonic development in hen eggs ［J］. Poultry Science, 2019, 98(11): 6053-6062. ［18］Weissmann A, Frster A, Gottschalk J, et al. In ovo-gender identification in laying hen hybrids: Effects on hatching and production performance ［J］. European Poultry Science, 2014, 78. ［19］Close B, Banister K, Baumans V, et al. Recommendations for euthanasia of experimental animals: Part 1 ［J］. Laboratory Animals, 1996, 30(4): 293-316. ［20］Phelps P, Bhutada A, Bryan S, et al. Automated identification of male layer chicks prior to hatch ［J］. Worlds Poult Sci J, 2003, 59(1): 33-38. ［21］Tran H T, Ferrell W, Butt T R. An estrogen sensor for poultry sex sorting ［J］. Journal of Animal Science, 2010, 88(4): 1358-1364. ［22］Schmid M, Nanda I, Guttenbach M, et al. First report on chicken genes and chromosomes 2000 ［J］. Cytogenetic and Genome Research, 2000, 90(3-4): 169-218. ［23］Kasuga K, Higashi M, Yamada T, et al. The W-and Z-linked EE0.6 sequences used for molecular sexing of captive Japanese crested ibis on Sado Island ［J］. Animal Science Journal, 2012, 83(1): 83-87. ［24］Ito H, Endo C, Yamaji A, et al. Rapid, easy and reliable sexing method for falconiformes by PCR ［J］. Japanese Journal of Zoo and Wildlife Medicine, 2005, 10(2): 79-84. ［25］Audet J N, Ducatez S, Lefebvre L. Morphological and molecular sexing of the monochromatic Barbados bullfinch, Loxigilla barbadensis ［J］. Zoological Science, 2014, 31(10): 687-691. ［26］吴丽丽, 周延宾, 蔡思琪, 等. 基于CHD基因利用PCR技术进行鸡早期性别鉴定［J］. 热带农业工程, 2016, 40(3): 13-15. Wu Lili, Zhou Yanbin, Cai Siqi, et al. Chicken sexing in the early stage by PCR based on CHD gene ［J］. Tropical Agricultural Engineering, 2016, 40(3): 13-15. ［27］张小辉, 庞有志, 雷莹, 等. 鹌鹑性别的分子鉴定方法研究［J］. 中国家禽, 2020, 42(5): 20-23. Zhang Xiaohui, Pang Youzhi, Lei Ying, et al. Study on molecular sex identification in quail ［J］. China Poultry, 2020, 42(5): 20-23. ［28］王玲彩, 董萌萌, 王青, 等. 利用CHD基因鉴定鸽子性别的研究［J］. 畜牧与兽医, 2020, 52(8): 1-5. Wang Lingcai, Dong Mengmeng, Wang Qing, et al. Sex identification of pigeons using the CHD gene ［J］. Animal Husbandry & Veterinary Medicine, 2020, 52(8): 1-5. ［29］徐丽晶, 孙畅, 陆涛峰, 等. 应用PCR方法快速鉴定SPF金定鸭性别［J］. 实验动物与比较医学, 2017, 37(3): 249-251. Xu Lijing, Sun Chang, Lu Taofeng, et al. Application of PCR method for rapid sex determination in SPF Jinding duck ［J］. Laboratory Animal and Comparative Medicine, 2017, 37(3): 249-251. ［30］李巍, 杨卓, 陈明非, 等. LAMP法鸟类性别鉴定的研究与应用［J］. 现代畜牧兽医, 2017(3): 12-18. Li Wei, Yang Zhuo, Chen Mingfei, et al. Research and application of LAMP in bird sex identification ［J］. Modern Journal of Animal Husbandry and Veterinary Medicine, 2017(3): 12-18. ［31］He L Y, Martins P, Huguenin J, et al. Simple, sensitive and robust chicken specific sexing assays, compliant with large scale analysis ［J］. PloS One, 2019, 14(3): e0213033. ［32］宋科, 杨崇龙, 石永宏, 等. 基于可见—近红外高光谱技术对鸡种蛋性别鉴定的研究［J］. 食品安全质量检测学报, 2022, 13(17): 5518-5525. Song Ke, Yang Chonglong, Shi Yonghong, et al. Research on sex identification of chicken eggs based on visible-near infrared hyperspectral technology ［J］. Journal of Food Safety and Quality, 2022, 13(17): 5518-5525. ［33］潘磊庆, 张伟, 于敏莉, 等. 基于高光谱图像的鸡种蛋孵化早期胚胎性别鉴定［J］. 农业工程学报, 2016, 32(1): 181-186. Pan Leiqing, Zhang Wei, Yu Minli, et al. Gender determination of early chicken hatching eggs embryos by hyperspectral imaging ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2016, 32(1): 181-186. ［34］祝志慧, 洪琪, 吴林峰, 等. 基于紫外—可见透射光谱技术和极限学习机的早期鸡胚雌雄识别［J］. 光谱学与光谱分析, 2019, 39(9): 2780-2787. Zhu Zhihui, Hong Qi, Wu Linfeng, et al. Early identification of male and female embryos based on UV/Vis transmission spectroscopy and extreme learning machine ［J］. Spectroscopy and Spectral Analysis, 2019, 39(9): 2780-2787. ［35］Galli R, Preusse G, Schnabel C, et al. Sexing of chicken eggs by fluorescence and Raman spectroscopy through the shell membrane ［J］. PLoS One, 2018, 13(2): e0192554. ［36］Galli R, Preusse G, Uckermann O, et al. In ovo sexing of chicken eggs by fluorescence spectroscopy ［J］. Analytical and Bioanalytical Chemistry, 2017, 409(5): 1185-1194. ［37］Ghler D, Fischer B, Meissner S. In-ovo sexing of 14-day-old chicken embryos by pattern analysis in hyperspectral images (VIS/NIR spectra): A non-destructive method for layer lines with gender-specific down feather color ［J］. Poultry Science, 2017, 96(1): 1-4. ［38］Corion M, Keresztes J, De Ketelaere B, et al. In ovo sexing of eggs from brown breeds with a gender-specific color using visible-near-infrared spectroscopy: Effect of incubation day and measurement configuration ［J］. Poultry Science, 2022, 101(5): 101782. ［39］汤勇, 洪琪, 王巧华, 等. 基于血线纹理特征和GA-BP神经网络的鸡种蛋性别鉴定［J］. 华中农业大学学报, 2018, 37(6): 130-135. Tang Yong, Hong Qi, Wang Qiaohua, et al. Sex identification of chicken eggs based on blood line texture features and GA-BP neural network ［J］. Journal of Huazhong Agricultural University, 2018, 37(6): 130-135. ［40］Galli R, Preusse G, Uckermann O, et al. In ovo sexing of domestic chicken eggs by Raman spectroscopy ［J］. Analytical Chemistry, 2016, 88(17): 8657-8663. ［41］Rashidi H, Sottile V. The chick embryo: Hatching a model for contemporary biomedical research ［J］. BioEssays, 2009, 31(4): 459-465. ［42］Biau S, Bayle S, de Santa Barbara P, et al. The chick embryo: An animal model for detection of the effects of hormonal compounds ［J］. Analytical and Bioanalytical Chemistry, 2007, 387(4): 1397-1403. ［43］Salim H M, Lee H R, Jo C, et al. Effect of dietary zinc proteinate supplementation on growth performance, and skin and meat quality of male and female broiler chicks ［J］. British Poultry Science, 2012, 53(1): 116-124. ［44］Rose N, Constantin P, Leterrier C. Sex differences in bone growth of broiler chickens ［J］. Growth, Development, and Aging: GDA, 1996, 60(2): 49-59. ［45］Han G, Yang H, Bungo T, et al. In ovo L-leucine administration stimulates lipid metabolisms in heat-exposed male, but not female, chicks to afford thermotolerance ［J］. Journal of Thermal Biology, 2018, 71: 74-82. ［46］Reithmayer C, Muhoff O, Danne M. Alternatives to culling male chicksthe consumer perspective ［J］. British Food Journal, 2020. ［47］Seemann G. Organisational framework for hatcheries ［J］. World's Poultry Science Journal, 2003, 59(1): 59-61. ［48］谢艳华, 张磊, 秦佳莹, 等. 太行鸡雌雄鉴别智能技术的研究与应用［J］. 今日畜牧兽医, 2022, 38(10): 73-75. ［49］宋科, 韩璐, 杨崇龙, 等. 鸡胚性别鉴定方法研究进展［J］. 中国家禽, 2022, 44(10): 101-107. Song Ke, Han Lu, Yang Chonglong, et al. Research progress on methods for sex identification of chick embryos ［J］. China Poultry, 2022, 44(10): 101-107. ［50］祝志慧, 叶子凡, 何昱廷, 等. 基于RF-DS图谱信息融合的孵化早期鸡胚蛋性别无损检测［J］. 农业工程学报, 2022, 38(18): 308-315. Zhu Zhihui, Ye Zifan, He Yuting, et al. Gender identification of early chicken embryo based on RF-DS information fusion of spectroscopy and machine vision ［J］. Transactions of the Chinese Society of Agricultural Engineering, 2022, 38(18): 308-315. ［51］叶子凡. 基于光谱—图像信息的孵化早期鸡胚蛋性别无损检测研究［D］. 武汉: 华中农业大学, 2022. Ye Zifan. Non-destructive identification for gender of chicken eggs at the early stage of incubation based on spectroscopy and machine vision ［D］. Wuhan: Huazhong Agricultural University, 2022.

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家禽胚胎期性别鉴定技术研究与应用进展

Current approaches and applications for in ovo sexing of eggs: A review

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