Visible/NIR Spectral Inversion of Malondialdehyde Content in JUNCAO Based on Deep Convolutional Gengrative Adversarial Network

doi:10.12133/j.smartag.SA202307011

Abstract

Abstract:

[Objective] JUNCAO, a perennial herbaceous plant that can be used as medium for cultivating edible and medicinal fungi. It has important value for promotion, but the problem of overwintering needs to be overcome when planting in the temperate zone. Low-temperature stress can adversely impact the growth of JUNCAO plants. Malondialdehyde (MDA) is a degradation product of polyunsaturated fatty acid peroxides, which can serve as a useful diagnostic indicator for studying plant growth dynamics. Because the more severe the damage caused by low temperature stress on plants, the higher their MDA content. Therefore, the detection of MDA content can provide instruct for low-temperature stress diagnosis and JUNCAO plants breeding. With the development of optical sensors and machine learning technologies, visible/near-infrared spectroscopy technology combined with algorithmic models has great potential in rapid, non-destructive and high-throughput inversion of MDA content and evaluation of JUNCAO growth dynamics. [Methods] In this research, six varieties of JUNCAO plants were selected as experimental subjects. They were divided into a control group planted at ambient temperature (28°C) and a stress group planted at low temperature (4°C). The hyperspectral reflectances of JUNCAO seedling leaves during the seedling stage were collected using an ASD spectroradiomete and a near-infrared spectrometer, and then the leaf physiological indicators were measured to obtain leaf MDA content. Machine learning methods were used to establish the MDA content inversion models based on the collected spectral reflectance data. To enhance the prediction accuracy of the model, an improved one-dimensional deep convolutional generative adversarial network (DCAGN ) was proposed to increase the sample size of the training set. Firstly, the original samples were divided into a training set (96 samples) and a prediction set (48 samples) using the Kennard stone (KS) algorithm at a ratio of 2:1. Secondly, the 96 training set samples were generated through the DCGAN model, resulting in a total of 384 pseudo samples that were 4 times larger than the training set. The pseudo samples were randomly shuffled and sequentially added to the training set to form an enhanced modeling set. Finally, the MDA quantitative detection models were established based on random forest (RF), partial least squares regression (PLSR), and convolutional neural network (CNN) algorithms. By comparing the prediction accuracies of the three models after increasing the sample size of the training set, the best MDA regression detection model of JUNCAO was obtained. [Results and Discussions] (1) The MDA content of the six varieties of JUNCAO plants ranged from 12.1988 to 36.7918 nmol/g. Notably, the MDA content of JUNCAO under low-temperature stress was remarkably increased compared to the control group with significant differences (P<0.05). Moreover, the visible/near-infrared spectral reflectance in the stressed group also exhibited an increasing trend compared to the control group. (2) Samples generated by the DCAGN model conformed to the distribution patterns of the original samples. The spectral curves of the generated samples retained the shape and trends of the original data. The corresponding MDA contented of generated samples consistently falling within the range of the original samples, with the average and standard deviation only decreased by 0.6650 and 0.9743 nmol/g, respectively. (3) Prior to the inclusion of generated samples, the detection performance of the three models differed significantly, with a correlation coefficient (R²) of 0.6967 for RF model, that of 0.6729 for CNN model, and that of 0.5298 for the PLSR model. After the introduction of generated samples, as the number of samples increased, all three models exhibited an initial increase followed by a decrease in R² on the prediction set, while the root mean square error of prediction (RMSEP) first decreased and then increased. (4) The prediction results of the three regression models indicated that augmenting the sample size by using DCGAN could effectively enhance the prediction performance of models. Particularly, utilizing DCGAN in combination with the RF model achieved the optimal MDA content detection performance, with the R² of 0.7922 and the RMSEP of 2.1937. [Conclusions] Under low temperature stress, the MDA content and spectral reflectance of the six varieties of JUNCAO leaves significantly increased compared to the control group, which might due to the damage of leaf pigments and tissue structure, and the decrease in leaf water content. Augmenting the sample size using DCGAN effectively enhanced the reliability and detection accuracy of the models. This improvement was evident across different regression models, illustrating the robust generalization capabilities of this DCGAN deep learning network. Specifically, the combination of DCGAN and RF model achieved optimal MDA content detection performance, as expanding to a sufficient sample dataset contributed to improve the modeling accuracy and stability. This research provides valuable insights for JUNCAO plants breeding and the diagnosis of low-temperature stress based on spectral technology and machine learning methods, offering a scientific basis for achieving high, stable, and efficient utilization of JUNCAO plants.

Key words: JUNCAO, visible/NIR, deep convolutional generative adversarial network (DCAGN), low temperature stress, machine learning

YE Dapeng, CHEN Chen, LI Huilin, LEI Yingxiao, WENG Haiyong, QU Fangfang. Visible/NIR Spectral Inversion of Malondialdehyde Content in JUNCAO Based on Deep Convolutional Gengrative Adversarial Network[J]. Smart Agriculture, 2023, 5(3): 132-141.

Figures/Tables 10

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References 31

1	林占熺. 菌草学概论[M]. 北京: 中国农业出版社, 2019.
	LIN Z X. Introductory JUNCAO science[M]. Beijing: China agriculture press, 2019.
2	林占熺, 苏德伟, 林辉, 等. 黄河菌草生态安全屏障建设的研究与应用[J]. 福建农林大学学报(自然科学版), 2019, 48(6): 803-812.
	LIN Z X, SU D W, LIN H, et al. Constructing an ecological barrier by JUNCAO along the Yellow River and its industrial application[J]. Journal of Fujian agriculture and forestry university (natural science edition), 2019, 48(6): 803-812.
3	林兴生. 菌草产业发展的几个关键技术研究[D]. 福州: 福建农林大学, 2013.
	LIN X S. Study on several key technology of JUNCAO industry development[D]. Fuzhou: Fujian Agriculture and Forestry University, 2013.
4	周晶, 林兴生, 林辉, 等. 菌草研究与应用进展[J]. 福建农林大学学报(自然科学版), 2020, 49(2): 145-152.
	ZHOU J, LIN X S, LIN H, et al. Advances on JUNCAO research and application[J]. Journal of Fujian agriculture and forestry university (natural science edition), 2020, 49(2): 145-152.
5	PEARCE R S, FULLER M P. Freezing of barley studied by infrared video thermography[J]. Plant physiology, 2001, 125(1): 227-240.
6	王连喜, 肖玮钰, 李琪, 等. 中国北方地区主要农作物气象灾害风险评估方法综述[J]. 灾害学, 2013, 28(2): 114-119, 130.
	WANG L X, XIAO W Y, LI Q, et al. Summary of risk assessment methods of main crops meteorological disasters in North China[J]. Journal of catastrophology, 2013, 28(2): 114-119, 130.
7	ASLAM M, FAKHER B, ASHRAF M A, et al. Plant low-temperature stress: Signaling and response[J]. Agronomy, 2022, 12(3): ID 702.
8	MANASA S L, PANIGRAHY M, PANIGRAHI K C S, et al. Overview of cold stress regulation in plants[J]. The botanical review, 2022, 88(3): 359-387.
9	格桑曲珍, 王景升, 曹凯丽, 等. 耐寒高产饲草的西藏引种试验研究[J]. 高原农业, 2022, 6(6): 593-598, 607.
	GESANGQUZHEN, WANG J S, CAO K L, et al. Study on the introduction of cold-tolerant and high-yielding herbage in Tibet[J]. Journal of plateau agriculture, 2022, 6(6): 593-598, 607.
10	JANKŮ M, LUHOVÁ L, PETŘIVALSKÝ M. On the origin and fate of reactive oxygen species in plant cell compartments[J]. Antioxidants, 2019, 8(4): ID 105.
11	DE DIOS ALCHÉ J. A concise appraisal of lipid oxidation and lipoxidation in higher plants[J]. Redox biology, 2019, 23: ID 101136.
12	WENG H Y, WU M Y, LI X B, et al. High-throughput phenotyping salt tolerance in JUNCAOs by combining prompt chlorophyll a fluorescence with hyperspectral spectroscopy[J]. Plant science, 2023, 330: ID 111660.
13	JANERO D R. Malondialdehyde and thiobarbituric acid-reactivity as diagnostic indices of lipid peroxidation and peroxidative tissue injury[J]. Free radical biology and medicine, 1990, 9(6): 515-540.
14	ZHANG W W, KASUN L C, WANG Q J, et al. A review of machine learning for near-infrared spectroscopy[J]. Sensors, 2022, 22(24): ID 9764.
15	严正兵, 刘树文, 吴锦. 高光谱遥感技术在植物功能性状监测中的应用与展望[J]. 植物生态学报, 2022, 46(10): 1151-1166.
	YAN Z B, LIU S W, WU J. Hyperspectral remote sensing of plant functional traits: Monitoring techniques and future advances[J]. Chinese journal of plant ecology, 2022, 46(10): 1151-1166.
16	王鹏新, 田惠仁, 张悦, 等. 基于深度学习的作物长势监测和产量估测研究进展[J]. 农业机械学报, 2022, 53(2): 1-14.
	WANG P X, TIAN H R, ZHANG Y, et al. Crop growth monitoring and yield estimation based on deep learning: State of the art and beyond[J]. Transactions of the Chinese society for agricultural machinery, 2022, 53(2): 1-14.
17	郭志明, 王郡艺, 宋烨, 等. 果蔬品质劣变传感检测与监测技术研究进展[J]. 智慧农业(中英文), 2021, 3(4): 14-28.
	GUO Z M, WANG J Y, SONG Y, et al. Research progress of sensing detection and monitoring technology for fruit and vegetable quality control[J]. Smart agriculture, 2021, 3(4): 14-28.
18	SU X, WANG Y, MAO J, et al. A review of pharmaceutical robot based on hyperspectral technology[J]. Journal of intelligent & robotic systems, 2022, 105(4): ID 75.
19	PHUPHAPHUD A, SAENGPRACHATANARUG K, POSOM J, et al. Prediction of the fiber content of sugarcane stalk by direct scanning using visible-shortwave near infrared spectroscopy[J]. Vibrational spectroscopy, 2019, 101: 71-80.
20	CHANDA S, HAZARIKA A K, CHOUDHURY N, et al. Support vector machine regression on selected wavelength regions for quantitative analysis of caffeine in tea leaves by near infrared spectroscopy[J]. Journal of chemometrics, 2019, 33(10): ID e3172.
21	张亚坤, 罗斌, 宋鹏, 等. 基于近红外光谱的大豆叶片可溶性蛋白含量快速检测(英文)[J]. 农业工程学报, 2018, 34(18): 187-193.
	ZHANG Y K, LUO B, SONG P, et al. Rapid determination of soluble protein content for soybean leaves based on near infrared spectroscopy[J]. Transactions of the Chinese society of agricultural engineering, 2018, 34(18): 187-193.
22	岑海燕, 朱月明, 孙大伟, 等. 深度学习在植物表型研究中的应用现状与展望[J]. 农业工程学报, 2020, 36(9): 1-16.
	CEN H Y, ZHU Y M, SUN D W, et al. Current status and future perspective of the application of deep learning in plant phenotype research[J]. Transactions of the Chinese society of agricultural engineering, 2020, 36(9): 1-16.
23	CHEN D, LIU S J, KINGSBURY P, et al. Deep learning and alternative learning strategies for retrospective real-world clinical data[J]. NPJ digital medicine, 2019, 2: ID 43.
24	RADFORD A, METZ L, CHINTALA S. Unsupervised representation learning with deep convolutional generative adversarial networks[EB/OL]. arXiv: 1511.06434, 2015.
25	董永生, 范世朝, 张宇, 等. 生成对抗网络的发展与挑战[J]. 信号处理, 2023, 39(1): 154-175.
	DONG Y S, FAN S C, ZHANG Y, et al. Development and challenge of generative adversarial network[J]. Journal of signal processing, 2023, 39(1): 154-175.
26	GUI J, SUN Z N, WEN Y G, et al. A review on generative adversarial networks: Algorithms, theory, and applications[J]. IEEE transactions on knowledge and data engineering, 2023, 35(4): 3313-3332.
27	李玖荣, 郑焕, 林辉, 等. 5种芦竹属菌草的耐寒性分析[J]. 福建农林大学学报(自然科学版), 2023, 52(1): 17-20.
	LI J R, ZHENG H, LIN H, et al. Analysis of cold tolerance of 5 species of Arundo JUNCAO[J]. Journal of Fujian agriculture and forestry university (natural science edition), 2023, 52(1): 17-20.
28	ZAHIR S A D M, OMAR A F, JAMLOS M F, et al. A review of visible and near-infrared (Vis-NIR) spectroscopy application in plant stress detection[J]. Sensors and actuators A: Physical, 2022, 338: ID 113468.
29	徐若涵, 杨再强, 申梦吟, 等. 苗期低温胁迫对“红颜”草莓叶绿素含量及冠层高光谱的影响[J]. 中国农业气象, 2022, 43(2): 148-158.
	XU R H, YANG Z Q, SHEN M Y, et al. Effects of low temperature stress at seedling stage on chlorophyll content and canopy hyperspectral of 'hongyan' strawberry[J]. Chinese journal of agrometeorology, 2022, 43(2): 148-158.
30	任鹏, 冯美臣, 杨武德, 等. 冬小麦冠层高光谱对低温胁迫的响应特征[J]. 光谱学与光谱分析, 2014, 34(9): 2490-2494.
	REN P, FENG M C, YANG W D, et al. Response of winter wheat (Triticum aestivum L.) hyperspectral characteristics to low temperature stress[J]. Spectroscopy and spectral analysis, 2014, 34(9): 2490-2494.
31	ZHANG Y N, LUAN Q F, JIANG J M, et al. Prediction and utilization of malondialdehyde in exotic pine under drought stress using near-infrared spectroscopy[J]. Frontiers in plant science, 2021, 12: ID 735275.

网络层	卷积核大小	卷积核数量	Padding	激活函数
Conv1	3	16	same	ReLU
Conv2	3	32	same	ReLU

样本类型	数量	最小值/（nmol·g^-1）	最大值/（nmol·g^-1）	平均值/（nmol·g^-1）	标准差/（nmol·g^-1）
原始样本	144	12.1988	36.7918	21.5571	5.8438
生成样本	384	13.2523	34.5608	20.8921	4.8695

模型选择	添加样本数量	训练集		预测集
模型选择	添加样本数量	R_c ²	RMSEC	R_P ²	RMSEP	RPD
PLSR	134	0.8376	1.8781	0.7566	2.5263	2.0269
RF	248	0.8716	1.9817	0.7922	2.4063	2.1937
CNN	192	0.7512	2.7107	0.7484	2.6298	1.9936

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