电化学传感器应用于植物活性小分子检测综述

doi:10.12133/j.smartag.SA202502023

摘要/Abstract

摘要：

【目的/意义】 植物活性小分子在调节植物生长及抵御环境胁迫等方面起到关键作用，对其进行精准检测对于实现农业的精准管理、推动智慧农业发展具有重要意义。多种检测方法已被用于植物活性小分子检测。其中，电化学传感器以其灵敏、便携及低成本等特点而备受关注。 【进展】 通过检索相关文献，本文深入分析了电化学传感器在植物活性小分子检测领域的研究现状，详细分析了每种传感器的感知原理、信号放大策略及应用潜力等，探讨了传感器从离体检测到活体、原位检测的发展趋势，纳米材料在感知过程中的重要作用，与柔性电子、人工智能技术的结合情况等。 【结论/展望】 总结了目前电化学传感器在植物活性小分子检测领域所面临的技术挑战，并分析了下一步的发展方向，包括传感性能的提升、电解质材料的优化，以及传感器与微电子、人工智能技术的融合等。本研究可为植物小分子电化学传感器的技术研发和应用提供参考。

关键词: 电化学传感器, 植物活性小分子, 离体检测, 活体检测, 人工智能, 传感器

Abstract:

[Significance] Plant active small molecules play an indispensable role in plants. They form the basis of the core physiological mechanisms that regulate the plant growth and development and enhance resilience to environmental stress. Achieving highly precise quantitative analysis of these active small molecules is therefore vital for promoting precise management practice in the agricultural and accelerating the development of smart agriculture. Currently, various technologies exist for the detection and analysis of these small molecules in plants. Among them, electrochemical sensing platforms have attracted extensive attention due to their significant advantages, including high sensitivity, excellent selectivity, and low cost. These advantages enable them to effectively detect trace levels of various active small molecules in plant samples. They also have the potential for real-time and in-situ detection. [Progress] Based on a comprehensive review of relevant academic literature, this article systematically summarizes the current research progress and status of electrochemical sensors applied in detecting plant active small molecule. Based on this, the article further analyzes the core sensing mechanisms of different electrochemical sensors types, signal amplification technologies for enhancing detection performance, and their huge potential in practical applications. Furthermore, this paper explores a notable development direction in this field: Sensor technology is evolving from the traditional in vitro detection mode to more challenging in vivo detection and in-situ real-time monitoring methods. Meanwhile, the article particularly emphasizes and elaborates in detail the indispensable and significant role of nanomaterials in key links such as constructing high-performance sensing interfaces and significantly enhancing detection sensitivity and selectivity. Finally, it prospectively discusses the innovative integration of electrochemical sensors with cutting-edge flexible electronic technology and powerful artificial intelligence (AI)-based data analysis, along with their potential for broad application. [Conclusions and Prospects] This article comprehensively identifies and summarizes the core technical challenges that electrochemical sensors currently face in detecting plant active small molecule. In terms of environmental detection, due to the influence of the complex matrix within plants, the response signal of the sensor is prone to drift, and its stability and sensitivity show a decline. Regarding electrolytes, the external application of liquid electrolytes dilutes the target molecules concentration in plant samples, lowering the detection accuracy. Furthermore, the transition from principle development to mature productization and industrialization of electrochemical sensors is relatively lengthy, and there are few types of sensors available for the detection of plant physiological indicators: Limiting their application in actual agricultural production. On this basis, the article prospectively analyzes the key directions of future research. First, continuously improving sensor performance indicators such as sensitivity, selectivity and reliability. Second, exploring and optimizing electrolyte material systems with stronger adaptability to significantly improve detection accuracy and long-term stability. Third, promoting deeper integration and innovation of sensor technology with advanced micro-nano electronic technology and powerful AI algorithms. The core objective of this review is to provide a theoretical guidance framework for in-depth research and systematic performance optimization of electrochemical sensing technology for plant active small molecules, as well as practical guidance for the actual application of related sensors in complex plant substrate environments.

Key words: electrochemical sensor, plant active small molecules, in vitro detection, in vivo detection, artificial intelligence, sensor

中图分类号:

TP212.2

张乐, 李爱学, 陈立平. 电化学传感器应用于植物活性小分子检测综述[J]. 智慧农业(中英文), 2025, 7(3): 69-88.

ZHANG Le, LI Aixue, CHEN Liping. Electrochemical Sensors for Plant Active Small Molecule Detection: A review[J]. Smart Agriculture, 2025, 7(3): 69-88.

图/表 10

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表1

植物活性小分子离体检测的电化学传感器及性能

目标分子	工作电极	检测范围	LOD	检测样品	参考文献
吲哚-3-乙酸	Pd-ZnO/h-BN/GCE	0.5—50.0 μM	0.13 μM	绿豆	［21］
吲哚-3-乙酸	ZnO NRs/CPE	0.3—5.0 μM	0.017 μM	豆类、小麦	［22］
吲哚-3-乙酸	Au-3DGR/SPCE	1.25—120.00 μmol/L，135—500 μmol/L	0.15 μmol/L	绿豆	［23］
吲哚-3-乙酸	AuNPs-anti/GA/PAMAM/GA/AET/Au	10 pg/mL—10 μg/mL	4.62 pg/mL	向日葵幼苗茎部	［52］
水杨酸	ERGO-SPCE	0.05—25.00 μM	——	橙汁	［27］
水杨酸	LIPG/PI	0.5—500.0 μM	0.16 μM	生菜、西瓜汁	［28］
水杨酸	PADs（Pencils-carbon tape/ITO）	1—100 μM	0.1 μM	番茄	［65］
赤霉素	EPBA/ PVP/ PGE	15—225 nmol/L	4.97 nmol/L	小麦、大米	［29］
赤霉素	MIP-ECL	0.04—70.00 pmol/L	0.016 4 pmol/L	——	［63］
激动素	eGr/GCE	0.5—100.0 μM	150 nmol/L	生菜	［30］
异戊烯腺嘌呤	FCA-AHK4-BSA-GA	50—400 nM	1.5 nM	绿豆芽	［31］
葡萄糖	NPPt/ GO/Gox/ Nafion	0.1—20.0 mmol/L	13 μmol/L	番茄、黄瓜	［32］
葡萄糖	NiCo₂O₄-nafion-GCE	0.1—10.0 mM	1 nM	芥菜叶	［33］
维生素C	Gel-g-PS/SPE	0.2—5.0 μg/L和20—600 μg/L	0.03 μg/L	柠檬、橙子等	［34］
缬氨酸	Iron modified SPEs	0.1—0.5 M	1 mM	——	［35］
丝氨酸		0.1—0.5 mM	2.3 mM
苯丙氨酸		0.1—0.4 mM	2 mM
柠檬酸	ZnO/CuO NCs/GCE	0.15—1.05 mM	21.78 μM	橙子、黄瓜等	［36］
没食子酸	MB-GOF-GC	50—1 000 μM	49.2 μM	大戟	［37］
咖啡酸	ZnO-L-BPDC/RGO/SG-2@GCE	0.008—40.000 μM	0.96 nM	樱桃、蓝莓等	［38］
槲皮素	NiCo-LDH/ Ti₃C₂ T_x Mxenes/GCE	0.1—20.0 μM	23 nM	洋葱、黄柏	［39］
槲皮素	GCE	0.1—15.0 μM	3.1 nM	苹果汁、梨汁等	［45］
槲皮素	TrpMA@QUE/MIP-GCE	1—25 pM	0.235 pM	野草莓等	［60］
木犀草素	Co@NCF/MoS₂-MWCNTs/GCE	0.1 nM—1.3 μM	0.071 nM	菊花、花生壳、金银花	［40］
木犀草素	Chi/TiO2-Lac/MWCNTs-BSA /GCE	80 nM—6 μM	11 nM	蒲公英	［41］
木犀草素	AgNPs@UiO-66/GCE	0.07 μM—40.00 μM	0.017 μM	花生壳	［46］
熊果酸	G-CN、CHIT/G-CN、（Co（II）TPP）/G-CN	——	——	云杉	［42］
过氧化氢	MWCNT-Ti₃C₂T_x-Pd/GCE	0.05—18.00 mM	3.83 μM	拟南介	［43］
丹参酮I	AuPd-NW/CFME	0.02—0.80 μmol/L	20.324 nmol/L	丹参	［49］
隐丹参酮	AuPd-NW/CFME	0.1—4.0 μmol/L	8.261 nmol/L	丹参	［49］
长春新碱	BSA/Ab/MWCNTs/GCE	0.2—50.0 nM	0.08 nM	长春花	［51］
脱落酸	BSA/ ABA-Ab / GR-COOH-SA /SPE	10 pmol/L—1 µmol/L	10 pmol/L	脐橙	［53］
茉莉酸甲酯	BSA/Anti-MeJA/Fc-GR-MWNT/SPE	100 fM—100 µM	31.26 fM	葡萄、橙子	［54］
茉莉酸甲酯	BSA/anti-MeJA/Cu-MOFs–COOH-GO/SPE	10 pM—100 μM	0.35 pM	葡萄	［55］
芹菜素	API/ZnONPs/TrpMA@MIP-GCE	0.1 pM—1.0 pM	0.0247 pM	芹菜、欧芹	［60］
色氨酸	BSA/apt/graphene-COP/GCE	0.1 fM—500.0 nM	0.03 fM	苹果汁	［64］
单宁酸	TiO₂-PMS/CdTe QDs/Nf	0.2—200.0 µmol/L	60 nmol/L	——	［62］

表1

图7

图8

图9

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