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Near-Infrared Prediction Models for Quality Parameters of Culture Broth in Seed Tank During Citric Acid Fermentation |
MU Liang-yin1, ZHAO Zhong-gai1*, JIN Sai2, SUN Fu-xin2, LIU Fei1 |
1. Key Laboratory for Advanced Process Control of Light Industry of Ministry of Education, Jiangnan University, Wuxi 214122, China
2. Jiangsu Guoxin Union Energy Co., Ltd., Wuxi 214122, China
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Abstract The quality of the bacterial strain cultivation in the seed tank during the citric acid fermentation process directly affects the fermentation level. Hence, it is crucial to accurately and rapidly detect the quality parameters of the culture solution in the seed tank. However, these parameters are currently largely measured manually, which does not meet real-time monitoring and precise control requirements. This paper builds a chemometric model for measuring the total acidity (TA) and reducing sugars (RS) in the seed tank's culture solution, based on near-infrared spectroscopy. Initially, the original spectra were analyzed, and to eliminate random noise and reduce batch variability effects on the sample spectra, the SG-DT method of smoothing (SG) and detrending (DT) were sequentially used for spectral preprocessing. Then, the Interval Partial Least Squares (iPLS) method was used for feature wavelength selection, the effect of different division intervals on the selection result was discussed, and the optimal division interval number for the target quality parameter of TA was determined to be 21, with 495 feature wavelengths. For RS, it was 20, with 361 feature wavelengths. Subsequently, the correlation between spectral variables and quality parameter variables was analyzed. A BP network was introduced to establish the calibration model for TA, and both PLSR and BP networks were used to establish the calibration model for RS, and model prediction effects were compared to determine the optimal model. Finally, the optimal prediction model for TA based on the BP network had an R2p of 0.808 5 and an RMSEP of 0.123 4. The model prediction effect of RS based on the BP network was superior to the PLSR model, with an R2p of 0.964 7 and RMSEP of 0.173 9. This paper has realized online prediction of multiple quality parameters during the bacterial strain cultivation process in the complex citric acid fermentation system, providing a basis for real-time intelligent control of the fermentation process.
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Received: 2023-08-09
Accepted: 2023-12-18
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Corresponding Authors:
ZHAO Zhong-gai
E-mail: gaizihao@jiangnan.edu.cn
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[1] WANG Bao-shi, CHEN Jian, SUN Fu-xin, et al(王宝石, 陈 坚, 孙福新, 等). Food and Fermentation Industries(食品与发酵工业), 2016, 42(9): 251.
[2] REN Dong, QU Fang-fang, LU An-xiang(任 东, 瞿芳芳, 陆安详). Near-Infrared Spectroscopy Analysis Techniques and Applications(近红外光谱分析技术与应用). Beijing: Science Press(北京:科学出版社), 2017.
[3] Mahsa Mohammadi, Mohammadreza Khanmohammadi Khorrami, Ali Vatani, et al. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2021, 245: 118945.
[4] Andrés Cruz-Conesa, Joan Ferré, Anna M Pérez-Vendrell, et al. Animal Feed Science and Technology, 2022, 283: 115169.
[5] Matan Birenboim, David Kengisbuch, Daniel Chalupowicz, et al. Phytochemistry, 2022, 204: 113445.
[6] ZHOU Xin-qi, ZHENG Qi-wei, LIU Yan, et al(周新奇, 郑启伟, 刘 妍, 等). Journal of Instrumental Analysis(分析测试学报), 2020, 39(11): 1358.
[7] HAO Chao, ZHAO Zhong-gai, LIU Fei(郝 超, 赵忠盖, 刘 飞). Food and Fermentation Industries(食品与发酵工业), 2020, 46(20): 214.
[8] ZHANG Meng, ZHAO Zhong-gai(张 萌, 赵忠盖). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2020, 40(8): 2512.
[9] Jin Sai, Sun Fuxin, Hu Zhijie, et al. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy, 2023, 285: 121842.
[10] Tian Han, Zhang Linna, Li Ming, et al. Infrared Physics & Technology, 2018, 95: 88.
[11] NI Zhen, HU Chang-qin, FENG Fang(尼 珍, 胡昌勤, 冯 芳). Chinese Journal of Pharmaceutical Analysis(药物分析杂志), 2008, 28(5): 6.
[12] Jasper Engel, Jan Gerretzen, Ewa Szymańska, et al. TrAC Trends in Analytical Chemistry, 2013, 50: 96.
[13] Biswanath Mahanty, Soon-Uk Yoon, Chang-Gyun Kim. Chemometrics and Intelligent Laboratory Systems, 2016, 154: 16.
[14] Maurílio Gustavo Nespeca, Weslei Diego Pavini, José Eduardo de Oliveira. Vibrational Spectroscopy, 2019, 102: 97.
[15] Lin Weilu, Hang Haifeng, Zhuang Yingping, et al. Chemometrics and Intelligent Laboratory Systems, 2018, 183: 113.
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