|
|
|
|
|
|
Rapid Determination of Amino Acids in Golden Tartary Buckwheat Based on Near Infrared Spectroscopy and Artificial Neural Network |
ZHU Li-wei, YAN Jin-xin, HUANG Juan, SHI Tao-xiong, CAI Fang, LI Hong-you, CHEN Qing-fu*, CHEN Qi-jiao* |
Research Center of Buckwheat Industry Technology, Guizhou Normal University, Guiyang 550001, China |
|
|
Abstract Buckwheat is rich in lysine, which is a lack in cereal crops, making it different from other cereal crops and has high economic value. Traditional determination of amino acids was time-consuming and expensive. In order to meet the needs of breeding of golden Tartary buckwheat, this study selected near-infrared spectroscopy combined with an artificial neural network algorithm to establish a near-infrared model for rapid determination of amino acid content in buckwheat leaves. A total of 255 samples with different amino acid contents were studied, and their chemical values were determined after scanning spectra. It was found that the content of threonine (Thr) in the samples ranged from 5.307 to 14.374 mg·g-1. Valine (Val) content ranged from 6.137 to 16.204 mg·g-1. The content of methionine (Met) ranged from 0.308 to 3.049 mg·g-1. The content of isoleucine (Ile) ranged from 5.259 to 14.134 mg·g-1. Leucine (Leu) content ranged from 9.730 to 26.061 mg·g-1. The content of phenylalanine (Phe) ranged from 5.936 to 17.223 mg·g-1. Lysine (Lys) content ranged from 6.640 to 17.280 mg·g-1. The content of glutamic (Glu) ranged from 10.984 to 27.740 mg·g-1. Aspartic (Asp) content ranged from 6.437 to 17.280 mg·g-1. Serine (Ser) content ranged from 3.467 to 8.312 mg·g-1. Arginine (Arg) content ranged from 4.937 to 14.772 mg·g-1. The content of Alanine (Ala) ranged from 3.329 to 6.885 mg·g-1. Histidine (His) content ranged from 1.946 to 4.798 mg·g-1. The content of glycine (Gly) ranged from 4.196 to 9.264 mg·g-1. Proline (Pro) content ranges from 1.024 to 5.672 mg·g-1. The content of tyrosine (Tyr) ranged from 0.176 to 1.173 mg·g-1. The content of cysteine (Cys) ranged from 0.422 to 1.926 mg·g-1. During each modeling, 50 samples were randomly selected and randomly divided into the training set and test set at a ratio of 4∶1. After data normalization, the neural network structure 1102-9-1 was used for model construction. The simulation results of Arg and Asp near-infrared models were the best, the correlation coefficient (R2) between the predicted value and the real value was greater than 0.97, and the average relative error (RSD) was less than 10%. Simulation test process found, Val, Tyr, Ile, Ser, Ala, Thr, His, Phe, Gly and Lys of model prediction and the real value of R2 are greater than 0.90, the RSD is less than 10%, models are available; When the models of Met and Cys were tested in simulation, the R2 between the predicted value and the true value were both greater than 0.78, but the RSD was greater than 10%, so the model was not available. The results showed that golden Tartary buckwheat leaves had a high content of essential amino acids and had high application value. The analysis method of near infrared spectroscopy combined with an artificial neural network could be used to predict the amino acid content of buckwheat, which provided convenience for the breeding of high-quality buckwheat.
|
Received: 2020-12-01
Accepted: 2021-03-14
|
|
Corresponding Authors:
CHEN Qing-fu, CHEN Qi-jiao
E-mail: cqf1966@163.com; qijiaochen@126.com
|
|
[1] LI Hong-li, WEN Dan-dan, ZHOU Mei-liang, et al(李红丽, 文丹丹, 周美亮, 等). Chinese Journal of Clinical Pharmacology and Therapeutics(中国临床药理学与治疗学), 2019, 24(7): 833.
[2] YANG Xi-wen, ZHANG Yan, LI Long-yun(杨玺文, 张 燕, 李隆云). Modern Chinese Medicine(中国现代中药), 2019, 21(6): 837.
[3] Chen Qingfu, Huang Xiaoyan, Li Hongyou, et al. Sustainability, 2018, 10(2): 1.
[4] HUANG Xiao-yan, HUANG Sha, CHEN Qing-fu(黄小燕, 黄 莎, 陈庆富). Journal of Anhui Agricultural University(安徽农业大学学报), 2015, 42(6): 854.
[5] HUANG Xiao-yan, HUANG Sha, CHEN Qing-fu(黄小燕, 黄 莎, 陈庆富). Modernization of Traditional Chinese Medicine and Materia Medica-World Science and Technology(世界科学技术-中医药现代化), 2015,(5): 981.
[6] Sytar O, Bruckova K, Kovar M, et al. Journal of Central European Agriculture,2017, 18(4): 864.
[7] Rebufa C, Pany I, Bombarda I. Food Chemistry,2018, 261: 311.
[8] TAO Lin-li, HUANG Wei, YANG Xiu-juan, et al(陶琳丽, 黄 伟, 杨秀娟, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2016, 36(9): 2766.
[9] Chang Xiangwei, Wei Dandan, Su Shulan, et al. Microchemical Journal, 2020, 153: 104500.
[10] Viyona M, Andasuryani, Putri R E, et al. Utilization of Artificial Neural Network (ANN) to Predict Fat Passion Fruit Seed Content (Passiflora Ligularis) Based on NIR-S Value. IOP Conference Series: Earth and Environmental Science, 2019, 327: 012017.
[11] CHEN Yong-jie, CHEN Xiao-wei, ZHANG Sha-sha, et al(程勇杰, 陈小伟, 张沙沙, 等). Science and Technology of Food Industry(食品工业科技), 2018, 39(6): 1.
[12] GAO Li-cheng, XIA Mei-juan, BAI Wen-ming, et al(高立城, 夏美娟, 白文明, 等). Acta Nutrimenta Sinica(营养学报), 2019, 41(6): 103.
[13] Bhinder S, Kaur A, Singh B, et al. Food Research International, 2019, 130(2): 108946. |
[1] |
XU Tian1, 2, LI Jing1, 2, LIU Zhen-hua1, 2*. Remote Sensing Inversion of Soil Manganese in Nanchuan District, Chongqing[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 69-75. |
[2] |
GAO Feng1, 2, XING Ya-ge3, 4, LUO Hua-ping1, 2, ZHANG Yuan-hua3, 4, GUO Ling3, 4*. Nondestructive Identification of Apricot Varieties Based on Visible/Near Infrared Spectroscopy and Chemometrics Methods[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 44-51. |
[3] |
LIANG Ye-heng1, DENG Ru-ru1, 2*, LIANG Yu-jie1, LIU Yong-ming3, WU Yi4, YUAN Yu-heng5, AI Xian-jun6. Spectral Characteristics of Sediment Reflectance Under the Background of Heavy Metal Polluted Water and Analysis of Its Contribution to
Water-Leaving Reflectance[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 111-117. |
[4] |
LIU Jia, ZHENG Ya-long, WANG Cheng-bo, YIN Zuo-wei*, PAN Shao-kui. Spectra Characterization of Diaspore-Sapphire From Hotan, Xinjiang[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 176-180. |
[5] |
BAO Hao1, 2,ZHANG Yan1, 2*. Research on Spectral Feature Band Selection Model Based on Improved Harris Hawk Optimization Algorithm[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 148-157. |
[6] |
LIANG Shou-zhen1, SUI Xue-yan1, WANG Meng1, WANG Fei1, HAN Dong-rui1, WANG Guo-liang1, LI Hong-zhong2, MA Wan-dong3. The Influence of Anthocyanin on Plant Optical Properties and Remote Sensing Estimation at the Scale of Leaf[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 275-282. |
[7] |
WU Hu-lin1, DENG Xian-ming1*, ZHANG Tian-cai1, LI Zhong-sheng1, CEN Yi2, WANG Jia-hui1, XIONG Jie1, CHEN Zhi-hua1, LIN Mu-chun1. A Revised Target Detection Algorithm Based on Feature Separation Model of Target and Background for Hyperspectral Imagery[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 283-291. |
[8] |
HAO Zi-yuan1, YANG Wei1*, LI Hao1, YU Hao1, LI Min-zan1, 2. Study on Prediction Models for Leaf Area Index of Multiple Crops Based on Multi-Source Information and Deep Learning[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3862-3870. |
[9] |
YANG Wen-feng1, LIN De-hui1, CAO Yu2, QIAN Zi-ran1, LI Shao-long1, ZHU De-hua2, LI Guo1, ZHANG Sai1. Study on LIBS Online Monitoring of Aircraft Skin Laser Layered Paint Removal Based on PCA-SVM[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3891-3898. |
[10] |
LIANG Ya-quan1, PENG Wu-di1, LIU Qi1, LIU Qiang2, CHEN Li1, CHEN Zhi-li1*. Analysis of Acetonitrile Pool Fire Combustion Field and Quantitative
Inversion Study of Its Characteristic Product Concentrations[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3690-3699. |
[11] |
CHENG Hui-zhu1, 2, YANG Wan-qi1, 2, LI Fu-sheng1, 2*, MA Qian1, 2, ZHAO Yan-chun1, 2. Genetic Algorithm Optimized BP Neural Network for Quantitative
Analysis of Soil Heavy Metals in XRF[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3742-3746. |
[12] |
HE Qing-yuan1, 2, REN Yi1, 2, LIU Jing-hua1, 2, LIU Li1, 2, YANG Hao1, 2, LI Zheng-peng1, 2, ZHAN Qiu-wen1, 2*. Study on Rapid Determination of Qualities of Alfalfa Hay Based on NIRS[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3753-3757. |
[13] |
HU Cai-ping1, HE Cheng-yu2, KONG Li-wei3, ZHU You-you3*, WU Bin4, ZHOU Hao-xiang3, SUN Jun2. Identification of Tea Based on Near-Infrared Spectra and Fuzzy Linear Discriminant QR Analysis[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3802-3805. |
[14] |
LIU Xin-peng1, SUN Xiang-hong2, QIN Yu-hua1*, ZHANG Min1, GONG Hui-li3. Research on t-SNE Similarity Measurement Method Based on Wasserstein Divergence[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3806-3812. |
[15] |
BAI Xue-bing1, 2, SONG Chang-ze1, ZHANG Qian-wei1, DAI Bin-xiu1, JIN Guo-jie1, 2, LIU Wen-zheng1, TAO Yong-sheng1, 2*. Rapid and Nndestructive Dagnosis Mthod for Posphate Dficiency in “Cabernet Sauvignon” Gape Laves by Vis/NIR Sectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(12): 3719-3725. |
|
|
|
|