|
|
|
|
|
|
| Quantitative Determination of Polyphenols in Aronia Melanocarpa (Michx.) Elliott. by Mid-Infrared Spectroscopy |
| YANG Cheng-en1, 2, GUO Rui-xue1, 3, XIN Ming-hao2, LI Meng4, LI Yu-ting2*, SU Ling1, 3* |
1. Engineering Research Center of Ministry of Education for Edible and Medicinal Fungi, Jilin Agricultural University, Changchun 130118, China
2. College of Life Science, Jilin Agricultural University, Changchun 130118, China
3. College of Plant Protection, Jilin Agricultural University, Changchun 130118, China
4. College of Modern Agriculture, Changchun Vocational Institute of Technology, Changchun 130504, China
|
|
|
|
|
Abstract Aronia melanocarpa (Michx.) Elliott. It is a berry from the Rosaceae Family rich in polyphenols, known as its main chemical components, including anthocyanins, flavonoid glycosides, tannins, etc., of A. melanocarpa. It has shown antioxidant, bacteriostatic, anti-tumor, anti-inflammatory, weight loss, glucose regulation, lipids, and other pharmacological activities. It has now been added to the list of new raw food materials. The polyphenol content of A. melanocarpa is closely related to its efficacy value. Therefore, improving their detection method is crucial to standardizing the raw material and product market from A. melanocarpa. However, the current detection method is cumbersome and time-consuming, and it is difficult to meet the industrial development needs of A. melanocarpa after it enters the list of new food raw materials. Thus, It is urgent to develop a method for rapidly determining polyphenol content. Mid-infrared spectroscopy established a rapid and quantitative determination method of polyphenol content in A. melanocarpa. The infrared spectral data of 750 samples from A. melanocarpa in 15 regions were collected for the spectral analysis, and the content of polyphenols in each sample was measured. The K-S sample division method was used to divide the sample into a correction set and verification set in the proportion of 4∶1. The grouped spectral information was pretreated by multiple scattering correction (MSC), standard normalization (SNV), smoothing (SG), first derivative (FD), second derivative (SD) and other spectral preprocessing methods. Compared with the original spectrum by random forest regression (RFR) modeling and prediction, the best spectral preprocessing method was determined as MSC. The competitive adaptive reweighting algorithm (CARS) and continuous projection algorithm (SPA) were used to select the optimal characteristic spectral wavelength of the polyphenols of A. melanocarpa. The spectral data selected by the two methods were combined with random forest regression (RFR), partial least squares regression (PLSR), limit learning machine (ELM), and support vector machine regression (SVR) for modeling and comparison to determine the optimal algorithm model. The results showed that the CARS algorithm can effectively reduce the redundancy of infrared spectral data and improve the accuracy and stability of model prediction. The CARS-RFR model had the best prediction performance. Its correction set Rc, RMSEC, verification set Rp, RMSEP, and RPD were 0.986 5, 0.073 2, 0.974 3, 0.100 6, and 6.235 6, respectively. The above results revealed that the combination of mid-infrared spectroscopy and chemometrics, especially the CARS-RFR model, can effectively, rapidly, and accurately detect the polyphenol content of A. melanocarpa. The research results can thus provide technical support for rapidly determining the polyphenol content of A. melanocarpa.
|
|
Received: 2023-06-09
Accepted: 2024-01-26
|
|
|
|
Corresponding Authors:
LI Yu-ting, SU Ling
E-mail: liyuting2002@163.com; suling0648@163.com
|
|
[1] SUN Yi, XING Li-ying, LI Yan-lin, et al(孙 怡, 邢丽颖, 李艳林, 等). Food Research and Development(食品研究与开发), 2022, 43(5): 8.
[2] CONG Long-jiao, SHI Rui, WU Peng, et al(丛龙娇, 史 锐, 吴 鹏, 等). Journal of Liaoning University of Traditional Chinese Medicine(辽宁中医药大学学报), 2021, 23(1): 4.
[3] Ni Dongdong, Smyth Heather E, Gidley Michael J, et al. Foods, 2022, 11(5): 711.
[4] Özbay Merve, Arslan Fatma Nur, Görür Gazi. Food Analytical Methods, 2022, 15(8): 2289.
[5] Ahmed Waseem, Veluthandath Aneesh Vincent, Rowe David J, et al. Murugan Ganapathy Senthil. Sensors, 2022, 22(5): 1744.
[6] Mairead C, Jordi O, Anastasios K, et al. Animal Feed Science and Technology, 2022, 285: 115239.
[7] Tziolas Nikolaos, Ordoudi Stella A, Tavlaridis Apostolos, et al. Sustainability, 2021, 13(12): 6588.
[8] TANG Wen-tao, XU Jia-feng, HU Dong, et al (汤文涛, 徐佳锋, 胡 栋, 等). Grain and Fat(粮食与油脂), 2022, 35(12): 158.
[9] YANG Cheng-en, WU Hai-wei, YANG Yu, et al(杨承恩, 武海巍, 杨 宇, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2022, 42(8): 2360.
[10] Li Lina, Guo Shangxing. Journal of Physics: Conference Series, 2021, 1813(1): 012002.
[11] Xu Xibo, Ren Mengyan, Cao Jianfei, et al. Spectroscopy Letters, 2020, 53(2): 88.
[12] MA Ming-zhu, ZHOU Yu-fang, MIAO Wen-hua, et al(马明珠, 周宇芳, 缪文华,等). Journal of Food Safety and Quality(食品安全质量检测学报), 2022, 13(21): 6932.
[13] SUN Yi-jian, WANG Ji-fen, ZHANG Zhen(孙一健, 王继芬, 张 震). China Oils and Fats(中国油脂), 2023, 48(1): 120.
[14] LONG Ruo-lan, LI Duo, LI Pei-pei, et al(龙若兰, 李 朵, 李佩佩,等). Food and Fermentation Industry(食品与发酵), 2023, 49(20): 274.
[15] Robert White. Chromatography/Fourier Transform Infrared Spectroscopy and Its Applications. Boca Raton: CRC Press, 2020.
|
| [1] |
YANG Cheng-en1, 2, LI Meng3, WANG Tian-ci1, 2, WANG Jin-ling4, LI Yu-ting2*, SU Ling1*. Identification of Aronia Melanocarpa Fruits From Different Areas by Mid-Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(04): 991-996. |
| [2] |
LI Cheng-ju1, 3, LIU Yin-du1, 3, QIN Tian-yuan1, 3, WANG Yi-hao1, 3, FAN You-fang1, 3, YAO Pan-feng2, 3, SUN Chao1, 3, BI Zhen-zhen1, 3*, BAI Jiang-ping1, 3*. Estimation of Chlorophyll Content in Potato Leaves Based on
Machine Learning[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(04): 1117-1127. |
| [3] |
XIA Yan-qiu1, XIE Pei-yuan1, NAY MIN AUNG1, ZHANG Tao1, FENG Xin1, 2*. The Improved Genetic Algorithm is Embedded Into the Classical
Classification Algorithm to Realize the Synchronous
Identification of Small Quantity and Multi Types of
Lubricating Oil Additives[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(03): 744-750. |
| [4] |
DUAN Dan-dan1, 2, LIU Zhong-hua1*, ZHAO Chun-jiang2, 3, ZHAO Yu2, 3, WANG Fan2, 3. Estimation of Leaf and Canopy Scale Tea Polyphenol Content Based on Characteristic Spectral Parameters[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(03): 814-820. |
| [5] |
WANG Kai, XUE Jian-xin*, LI Yao-di, ZHANG Ming-yue. Hyperspectral Study on Polyphenol Oxidase Content of Cauliflower at the Early Stages of Gray Mold Infection[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(02): 534-541. |
| [6] |
YANG Cheng-en1, 2, LI Meng3, LU Qiu-yu2, WANG Jin-ling4, LI Yu-ting2*, SU Ling1*. Fast Prediction of Flavone and Polysaccharide Contents in
Aronia Melanocarpa by FTIR and ELM[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2024, 44(01): 62-68. |
| [7] |
DUAN Ming-xuan1, LI Shi-chun1, 2*, LIU Jia-hui1, WANG Yi1, XIN Wen-hui1, 2, HUA Deng-xin1, 2*, GAO Fei1, 2. Detection of Benzene Concentration by Mid-Infrared Differential
Absorption Lidar[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(11): 3351-3359. |
| [8] |
LIU Bo-yang1, GAO An-ping1*, YANG Jian1, GAO Yong-liang1, BAI Peng1, Teri-gele1, MA Li-jun1, ZHAO San-jun1, LI Xue-jing1, ZHANG Hui-ping1, KANG Jun-wei1, LI Hui1, WANG Hui1, YANG Si2, LI Chen-xi2, LIU Rong2. Research on Non-Targeted Abnormal Milk Identification Method Based on Mid-Infrared Spectroscopy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(10): 3009-3014. |
| [9] |
LIU Si-qi1, FENG Guo-hong1*, TANG Jie2, REN Jia-qi1. Research on Identification of Wood Species by Mid-Infrared Spectroscopy Based on CA-SDP-DenseNet[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(03): 814-822. |
| [10] |
YANG Cheng-en1, SU Ling2, FENG Wei-zhi1, ZHOU Jian-yu1, WU Hai-wei1*, YUAN Yue-ming1, WANG Qi2*. Identification of Pleurotus Ostreatus From Different Producing Areas Based on Mid-Infrared Spectroscopy and Machine Learning[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(02): 577-582. |
| [11] |
LI Xiao1, CHEN Yong2, MEI Wu-jun3*, WU Xiao-hong2*, FENG Ya-jie1, WU Bin4. Classification of Tea Varieties Using Fuzzy Covariance Learning
Vector Quantization[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(02): 638-643. |
| [12] |
FENG Hai-zhi1, LI Long1*, WANG Dong2, ZHANG Kai1, FENG Miao1, SONG Hai-jiang1, LI Rong1, HAN Ping2. Progress of the Application of MIR and NIR Spectroscopies in Quality
Testing of Minor Coarse Cereals[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2023, 43(01): 16-24. |
| [13] |
BAI Zi-jin1, PENG Jie1*, LUO De-fang1, CAI Hai-hui1, JI Wen-jun2, SHI Zhou3, LIU Wei-yang1, YIN Cai-yun1. A Mid-Infrared Spectral Inversion Model for Total Nitrogen Content of Farmland Soil in Southern Xinjiang[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(09): 2768-2773. |
| [14] |
YANG Cheng-en1, WU Hai-wei1*, YANG Yu2, SU Ling2, YUAN Yue-ming1, LIU Hao1, ZHANG Ai-wu3, SONG Zi-yang3. A Model for the Identification of Counterfeited and Adulterated Sika Deer Antler Cap Powder Based on Mid-Infrared Spectroscopy and Support
Vector Machines[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(08): 2359-2365. |
| [15] |
ZHANG Yan-ru1, 2, SHAO Peng-shuai1*. Study on the Effects of Planting Years of Vegetable Greenhouse on the
Cucumber Qualties Using Mid-IR Spectroscopoy[J]. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(06): 1816-1821. |
|
|
|
|
