Synthesis and utilization of Pt and Pd nanoparticle-decorated MoS2 nanocomposites for fabrication of electrochemical biosensor

doi:10.16085/j.issn.1000-6613.2020-1901

Abstract

Abstract:

Pd and Pt nanoparticle-decorated MoS₂nanocomposites (Pt-Pd/MoS₂) were synthesized and applied to prepare acetylcholinesterase (AChE) biosensors for organophosphorus pesticide detection. The nanoparticles were characterized by SEM, TEM and XPS. The AChE biosensor showed high affinity to acetylthiocholine chloride (ATCl) with K_m of 883μmol/L. The prepared biosensors exhibited high sensitivity towards malathion and parathion methyl, with a linear range of 1×10^-14mol/L to 1× 10^-5mol/L and a detection limit of 4.69×10^-14mol/L (S/N=3) and a linear range of 1×10^-15mol/L to 1×10^-5mol/L and a detection limit of 5.23×10^-15mol/L (S/N=3), respectively. Moreover, the AChE/Pt-Pd/MoS₂/GCE was used to detect OPs in real samples with the recovery of 91.4%—103%. Due to the synergistic effect of the highly dispersed bimetallic nanoparticles and the MoS₂ nanosheets, the Pt-Pd/MoS₂ nanocomposites provide a potential electrode material for biosensor fabrication.

Key words: noble metal, organophosphate pesticide, molybdenum disulfide (MoS₂), acetylcholinesterase, biosensor

摘要：

制备了Pt和Pd纳米颗粒修饰的单层MoS₂纳米片（Pt-Pd/MoS₂），通过扫描电镜（SEM）、透射电镜（TEM）和X射线光电子能谱（XPS）对Pt-Pd/MoS₂外部形貌、内部结构和组成进行表征分析，并基于Pt-Pd/MoS₂修饰玻碳电极，并于表面固定乙酰胆碱酯酶（AChE），制备AChE生物传感器。对比了Pt和Pd双金属纳米颗粒、商品化Pt/C及Pt-Pd/MoS₂的电化学性能，结果发现，Pt-Pd/MoS₂的电化学性能明显优于其他两种。测定电极表面酶催化反应的动力学参数K_m为883μmol/L；以马拉硫磷和甲基对硫磷为代表，考察制备电极的检测性能以及制备电极对有机磷农药的检测性能，马拉硫磷的检测范围是1×10^-14～1×10^-5mol/L，检测限为4.69×10^-14mol/L；甲基对硫磷的检测范围是1×10^-15～1×10^-5mol/L，检测限为5.23×10^-15mol/L（S/N=3）；并应用于真实样品检测OPs的回收率为91.4%～103%，显示出良好的回收率和准确性，可应用于实际样品的分析。Pt-Pd/MoS₂为二维纳米材料构建高效生物传感器提供了新思路。

关键词: 贵金属, 有机磷农药, 二硫化钼, 乙酰胆碱酯酶, 生物传感器

CLC Number:

TQ31

ZHOU Liya, ZHOU Xitong, ZHAO Congli, JIANG Yanjun, MA Li, He Ying. Synthesis and utilization of Pt and Pd nanoparticle-decorated MoS₂nanocomposites for fabrication of electrochemical biosensor[J]. Chemical Industry and Engineering Progress, 2021, 40(8): 4371-4380.

周丽亚, 周栖桐, 赵聪俐, 姜艳军, 马丽, 贺莹. 基于铂、钯负载的MoS₂纳米片构建生物传感器及应用[J]. 化工进展, 2021, 40(8): 4371-4380.

Figures/Tables 11

References 27

1	WANG Yihan, HUANG Kejing, WU Xu. Recent advances in transition-metal dichalcogenides based electrochemical biosensors: a review[J]. Biosensors and Bioelectronics, 2017, 97: 305-316.
2	LU Jiaying, CHEN Mingyue, DONG Lina, et al. Molybdenum disulfide nanosheets: from exfoliation preparation to biosensing and cancer therapy applications[J]. Colloids and Surfaces B: Biointerfaces, 2020, 194: 111162.
3	MA Jingwen, CAI An, GUAN Xinglong, et al. Preparation of ultrathin molybdenum disulfide dispersed on graphene via cobalt doping: a bifunctional catalyst for hydrogen and oxygen evolution reaction[J]. International Journal of Hydrogen Energy, 2020, 45: 9583-9591.
4	PISAL K B, THORAT A S, JAGTAP S S, et al. Synthesis and characterization of hydrothermally prepared molybdenum disulfide for supercapacitor application[J]. Materials Today: Proceedings, 2021, 43: 2707-2710.
5	VINITA, NIRALA N R, PRAKASH R. One step synthesis of AuNPs@MoS₂-QDs composite as a robust peroxidase-mimetic for instant unaided eye detection of glucose in serum, saliva and tear[J]. Sensors and Actuators B: Chemical, 2018, 263: 109-119.
6	SHOKHEN V, ZITOUN D. Platinum-group metal grown on vertically aligned MoS₂ as electrocatalysts for hydrogen evolution reaction[J]. Electrochimica Acta, 2017, 257: 49-55.
7	YOUSAF A B, IMRAN M, FAROOQ M, et al. Synergistic effect of Co-Ni co-bridging with MoS₂ nanosheets for enhanced electrocatalytic hydrogen evolution reactions[J]. RSC Advances, 2018, 8: 3374-3380.
8	WANG Xiaoyan, XIE Ying, CAI Zhicheng, et al. The sesame ball-like CoS/MoS₂ nanospheres as efficient counter electrode catalysts for dye-sensitized solar cells[J]. Journal of Alloys and Compounds, 2018, 739: 568-576.
9	CAO Jing, WANG Miao, YU He, et al. An overview on the mechanisms and applications of enzyme inhibition-based methods for determination of organophosphate and carbamate pesticides[J]. Journal of Agricultural and Food Chemistry, 2020, 68: 7298-7315.
10	JIANG Bo, LI Cuiling, IMURA M, et al. Multimetallic mesoporous spheres through surfactant-directed synthesis[J]. Advance Scicience, 2015, 2: 1500112.
11	YANG Guohai, LI Yongjie, RANA R K, et al. Pt-Au/nitrogen-doped graphene nanocomposites for enhanced electrochemical activities[J]. Journal of Materials Chemistry A, 2013, 1: 1754-1762.
12	ZHANG Dongzhi, JIANG Chuanxing, ZHOU Xiaoyan, Fabrication of Pd-decorated TiO2/MoS₂ ternary nanocomposite for enhanced benzene gas sensing performance at room temperature[J]. Talanta, 2018, 182: 324-332.
13	WU Minghong, LI Lin, XUE Yuancheng, et al. Fabrication of ternary GO/g-C₃N₄/MoS₂ flower-like heterojunctions with enhanced photocatalytic activity for water remediation[J]. Applied Catalysis B: Environmental, 2018, 228: 103-112.
14	ZHAO Hang, LI Jianlong, WU Hao, et al. Dopamine self-polymerization enables an N-doped carbon coating of exfoliated MoS₂ nanoflakes for anodes of lithium-ion batteries[J]. ChemElectroChem, 2018, 5: 383-390.
15	ZHANG Dongzhi, CHANG Hongyan, SUN Yan’e, et al. Fabrication of platinum-loaded cobalt oxide/molybdenum disulfide nanocomposite toward methane gas sensing at low temperature[J]. Sensors and Actuators B: Chemical, 2017, 252: 624-632.
16	XIA Dawei, GONG Feng, PEI Xudong, et al. Molybdenum and tungsten disulfides-based nanocomposite films for energy storage and conversion: a review[J]. Chemical Engineering Journal, 2018, 348: 908-928.
17	ZHENG Yingying, LIU Zhimin, JING Yanfeng, et al. An acetylcholinesterase biosensor based on ionic liquid functionalized graphene-gelatin-modified electrode for sensitive detection of pesticides[J]. Sensors and Actuators B: Chemical, 2015, 210: 389-397.
18	ARDUINI F, GUIDONE S, AMINE A, et al. Acetylcholinesterase biosensor based on self-assembled monolayer-modified gold-screen printed electrodes for organophosphorus insecticide detection[J]. Sensors and Actuators B: Chemical, 2013, 179: 201-208.
19	XUE Rui, KANG Tianfang, LU Liping, et al. Immobilization of acetylcholinesterase via biocompatible interface of silk fibroin for detection of organophosphate and carbamate pesticides[J]. Applied Surface Science, 2012, 258: 6040-6045.
20	KAUR N, THAKUR H, PRABHAKAR N. Conducting polymer and multi-walled carbon nanotubes nanocomposites based amperometric biosensor for detection of organophosphate[J]. Journal of Electroanalytical Chemistry, 2016, 775: 121-128.
21	SONG Dandan, LI Yan, LU Xiong, et al. Palladium-copper nanowires-based biosensor for the ultrasensitive detection of organophosphate pesticides[J]. Analytica Chimica Acta, 2017, 982: 168-175.
22	LIU Zhenhui, XIA Xin, ZHOU Guoxing, et al. Acetylcholinesterase-catalyzed silver deposition for ultrasensitive electrochemical biosensing of organophosphorus pesticides[J]. The Analyst, 2020, 145(6): 2339-2344.
23	BAO Jing, HUANG Ting, WANG Zhaonan, et al. 3D graphene/copper oxide nano-flowers based acetylcholinesterase biosensor for sensitive detection of organophosphate pesticides[J]. Sensors and Actuators B: Chemical, 2019, 279: 95-101.
24	LU Xiong, TAO Lu, SONG Dandan, et al. Bimetallic Pd@Au nanorods based ultrasensitive acetylcholinesterase biosensor for determination of organophosphate pesticides[J]. Sensors and Actuators B: Chemical, 2018, 255: 2575-2581.
25	JIANG Bin, DONG Pei, ZHENG Jianbin. A novel amperometric biosensor based on covalently attached multilayer assemblies of gold nanoparticles, diazo-resins and acetylcholinesterase for the detection of organophosphorus pesticides[J]. Talanta, 2018, 183: 114-121.
26	ZHOU Liya, ZHANG Xiaoning, MA Li, et al. Acetylcholinesterase/chitosan-transition metal carbides nanocomposites-based biosensor for the organophosphate pesticides detection[J]. Biochem. Eng. J, 2017, 128: 243-249.
27	MA Li, ZHOU Liya, HE Ying, et al. Mesoporous bimetallic PtPd nanoflowers as a platform to enhance electrocatalytic activity of acetylcholinesterase for organophosphate pesticide detection[J]. Electroanalysis, 2018, 30: 1801-1810.

构建电极	检测范围/mol·L^-1	检测限/mol·L^-1	参考文献
AChE/PEDOT-MWCNTs/FTO	1×10^-11~1×10^-9	1×10^-11	［20］
AChE-CS/Pd-Cu NWs/GCE	1.5×10^-13~3×10^-9 和1.5×10^-9~9×10^-9	4.5×10^-9	［21］
AChE-Ag	1×10^-11~1×10^-8	4.0 ×10^-12	［22］
AChE-CS/3DG-CuO NFs/GCE	3×10^-12~4.7×10^-8	9.2×10^-13	［23］
AChE-CS/Pd@Au NRs/GCE	3.6×10^-12~1×10^-7	3.6×10^-12	［24］
AChE/AuNPs/DAR/P-ABSA/GCE	1×10^-8~1×10^-12	5.12×10^-13	［25］
AChE/CS-Ti₃C₂T_x/GCE	1×10^-14~1×10^-8	0.3×10^-14	［26］
AChE/MPtPdN/GCE	1×10^-12~4.7×10^-6	2.6×10^-13	［27］
AChE/ Pt-Pd/MoS₂/GCE	1×10^-14~1×10^-5	5.23×10^-15	本文

构建电极	检测范围/mol·L^-1	检测限/mol·L^-1	参考文献
AChE/PEDOT-MWCNTs/FTO	1×10^-11~1×10^-9	1×10^-11	［20］
AChE-CS/Pd-Cu NWs/GCE	1.5×10^-13~3×10^-9 和1.5×10^-9~9×10^-9	4.5×10^-9	［21］
AChE-Ag	1×10^-11~1×10^-8	4.0 ×10^-12	［22］
AChE-CS/3DG-CuO NFs/GCE	3×10^-12~4.7×10^-8	9.2×10^-13	［23］
AChE-CS/Pd@Au NRs/GCE	3.6×10^-12~1×10^-7	3.6×10^-12	［24］
AChE/AuNPs/DAR/P-ABSA/GCE	1×10^-8~1×10^-12	5.12×10^-13	［25］
AChE/CS-Ti₃C₂T_x/GCE	1×10^-14~1×10^-8	0.3×10^-14	［26］
AChE/MPtPdN/GCE	1×10^-12~4.7×10^-6	2.6×10^-13	［27］
AChE/ Pt-Pd/MoS₂/GCE	1×10^-14~1×10^-5	5.23×10^-15	本文

样品	加入量 /mol·L^-1	检出量 /mol·L^-1	回收率 /%	相对标准偏差 /%
马拉硫磷
1^#	1.00×10^-9	0.932×10^-9	93.2	2.1
2^#	1.00×10^-10	0.943×10^-10	94.3	1.9
3^#	1.00×10^-11	0.999×10^-11	99.9	4.1
甲基对硫磷
1^#	1.00×10^-9	0.914×10^-9	91.4	4.5
2^#	1.00×10^-10	0.962×10^-10	96.2	3.3
3^#	1.00×10^-11	1.03×10^-11	103	4.2

样品	加入量 /mol·L^-1	检出量 /mol·L^-1	回收率 /%	相对标准偏差 /%
马拉硫磷
1^#	1.00×10^-9	0.932×10^-9	93.2	2.1
2^#	1.00×10^-10	0.943×10^-10	94.3	1.9
3^#	1.00×10^-11	0.999×10^-11	99.9	4.1
甲基对硫磷
1^#	1.00×10^-9	0.914×10^-9	91.4	4.5
2^#	1.00×10^-10	0.962×10^-10	96.2	3.3
3^#	1.00×10^-11	1.03×10^-11	103	4.2

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Synthesis and utilization of Pt and Pd nanoparticle-decorated MoS₂nanocomposites for fabrication of electrochemical biosensor

基于铂、钯负载的MoS₂纳米片构建生物传感器及应用

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