Abstract
India has achieved its food security through the green revolution and technological revolution, although food safety is still not realized. Subsequently, agricultural runoffs, industrial wastes and domestic sewages continuously contaminate the water and the associated livelihood through several contaminants. Pesticides and their residues, which function as endocrine disrupting chemicals (EDCs), influence the food web through water resources, among other things. The gold standard conventional procedures are used to identify these pesticide residues. However, the introduction of the technology revolution necessitates the use of screening instruments to conduct a pre-inspection of drinkable commodities in order to achieve a better health economy. In the recent decade, microelectronics-based highly sensitive instruments enabled with real-time measurement of pesticide residues is now possible. In addition, the introduction of novel nanosensors and biosensors into revolutionary microelectronics-based devices has improved the performance of these portable instruments in terms of detecting trace-level pesticide residues. Comprehensive assessments of microelectronics-based sensors with comparative benefits, on the other hand, are rare. Herein we review the critical advanced sensory techniques. The significant points are as follows: (1) the state-of-the-art focuses on rapid, portable, and cost-effective optical and electrochemical biosensory tools for pesticide detection in water; (2) a quick overview of commercially available portable devices has been summarized as potential to become next-generation screening tools.
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Abad J, Pariente F, Hernandez L, Abruna H, Lorenzo E (1998) Determination of organophosphorus and carbamate pesticides using a piezoelectric biosensor. Anal Chem 70:2848–2855
Alexandratos N, Bruinsma J (2012) World agriculture towards 2030/2050: the 2012 revision. Retrieved 20/11/2021, 2021, from https://ageconsearch.umn.edu/record/288998/
Andreou VG, Clonis YD (2002) A portable fiber-optic pesticide biosensor based on immobilized cholinesterase and sol–gel entrapped bromcresol purple for in-field use. Biosens Bioelectron 17:61–69
Andres RT, Narayanaswamy R (1997) Fibre-optic pesticide biosensor based on covalently immobilized acetylcholinesterase and thymol blue. Talanta 44:1335–1352
Apilux A, Isarankura-Na-Ayudhya C, Tantimongcolwat T, Prachayasittikul V (2015) Based acetylcholinesterase inhibition assay combining a wet system for organophosphate and carbamate pesticides detection. EXCLI J 14:307
Arisekar U, Shakila RJ, Jeyasekaran G, Shalini R, Kumar P, Malani AH, Rani V (2019) Accumulation of organochlorine and pyrethroid pesticide residues in fish, water, and sediments in the Thamirabarani river system of southern peninsular India. Environ Nanotech, Monitoring & Management 11:100194
Arjmand M, Saghafifar H, Alijanianzadeh M, Soltanolkotabi M (2017) A sensitive tapered-fiber optic biosensor for the label-free detection of organophosphate pesticides. Sens Actuators, B Chem 249:523–532
Bachmann TT, Leca B, Vilatte F, Marty J-L, Fournier D, Schmid RD (2000) Improved multianalyte detection of organophosphates and carbamates with disposable multielectrode biosensors using recombinant mutants of Drosophila acetylcholinesterase and artificial neural networks. Biosens Bioelectron 15:193–201
Bala R, Dhingra S, Kumar M, Bansal K, Mittal S, Sharma RK, Wangoo N (2017) Detection of organophosphorus pesticide–malathion in environmental samples using peptide and aptamer based nanoprobes. Chem Eng J 311:111–116. https://doi.org/10.1016/j.cej.2016.11.070
Bao J, Hou C, Dong Q, Ma X, Chen J, Huo D, Yang M, Abd El Galil KH, Chen W, Lei Y (2016) ELP-OPH/BSA/TiO2 nanofibers/c-MWCNTs based biosensor for sensitive and selective determination of p-nitrophenyl substituted organophosphate pesticides in aqueous system. Biosens Bioelectron 85:935–942
Bala R, Swami A, Tabujew I, Peneva K, Wangoo N, Sharma RK (2018) Ultra-sensitive detection of malathion using quantum dots-polymer based fluorescence aptasensor. Biosens Bioelectron 104:45–49. https://doi.org/10.1016/j.bios.2017.12.034
Barbieri MV, Postigo C, Guillem-Argiles N, Monllor-Alcaraz LS, Simionato JI, Stella E, … de Alda ML (2019) Analysis of 52 pesticides in fresh fish muscle by QuEChERS extraction followed by LC-MS/MS determination Sci Total Environ 653 958 967. https://doi.org/10.1016/j.scitotenv.2018.10.289
Bao J, Huang T, Wang Z, Yang H, Geng X, Xu G, Samalo M, Sakinati M, Huo D, Hou C (2019) 3D graphene/copper oxide nano-flowers based acetylcholinesterase biosensor for sensitive detection of organophosphate pesticides. Sens Actuators, B Chem 279:95–101
Behal A (2020) The green revolution and a dark Punjab. Access date: 20-11-2021 https://www.downtoearth.org.in/blog/agriculture/the-green-revolution-and-a-dark-punjab-72318
Bera S (2020) Agriculture ministry proposal to ban 27 pesticides faces resistance. Access date: 20-11-2021 https://www.livemint.com/industry/agriculture/agriculture-ministry-proposal-to-ban-27-pesticides-faces-resistance-11593190614176.html
Besombes J-L, Cosnier S, Labbé P, Reverdy G (1995) A biosensor as warning device for the detection of cyanide, chlorophenols, atrazine and carbamate pesticides. Anal Chim Acta 311:255–263
Bhardwaj R, Rao RP, Mukherjee I, Agrawal PK, Basu T, Bharadwaj LM (2020) Layered construction of nano immuno-hybrid embedded MOF as an electrochemical sensor for rapid quantification of total pesticides load in vegetable extract. J Electroanal Chem 873:114386
Bilal M (2019) Persistence of pesticides-based contaminants in the environment and their effective degradation using laccase-assisted biocatalytic systems Sci Total Environ 695. https://doi.org/10.1016/j.scitotenv.2019.133896
Bolygó E, Atreya NC (1991) Solid-phase extraction for multi-residue analysis of some triazole and pyrimidine pesticides in water. Fresenius’ J Anal Chem 339:423–430
Brouwer M, Huss A, van der Mark M, Nijssen PC, Mulleners WM, Sas AM, Van Laar T, de Snoo GR, Kromhout H, Vermeulen RC (2017) Environmental exposure to pesticides and the risk of Parkinson’s disease in the Netherlands. Environ Int 107:100–110
Buvaneswari G, Thenmozhi R, Nagasathya A, Thajuddin N, Kumar P (2018) GC-MS and molecular analyses of monocrotophos biodegradation by selected bacterial isolates. African J Microbiol Res 12:52–61
Cesarino I, Moraes FC, Lanza MR, Machado SA (2012) Electrochemical detection of carbamate pesticides in fruit and vegetables with a biosensor based on acetylcholinesterase immobilised on a composite of polyaniline–carbon nanotubes. Food Chem 135:873–879
Chandrakar C, Shakya S, Jain T, Ali S, Patyal A, Kumar P (2020) Occurrence of carbaryl, DDT and deltamethrin residues in bovine milk in Chhattisgarh, India and risk assessment to human health. J Anim Res 10:291–297
Cheng W, Zheng Z, Yang J, Chen M, Yao Q, Chen Y, Gao W (2019) The visible light-driven and self-powered photoelectrochemical biosensor for organophosphate pesticides detection based on nitrogen doped carbon quantum dots for the signal amplification. Electrochim Acta 296:627–636
Chronopoulou EG, Vlachakis D, Papageorgiou AC, Ataya FS, Labrou NE (2019) Structure-based design and application of an engineered glutathione transferase for the development of an optical biosensor for pesticides determination. Biochimica et Biophysica Acta (BBA)- General Subjects. 1863:565–576
Ciucu AA, Negulescu C, Baldwin RP (2003) Detection of pesticides using an amperometric biosensor based on ferophthalocyanine chemically modified carbon paste electrode and immobilized bienzymatic system. Biosens Bioelectron 18:303–310
Cui H-F, Wu W-W, Li M-M, Song X, Lv Y, Zhang T-T (2018) A highly stable acetylcholinesterase biosensor based on chitosan-TiO2-graphene nanocomposites for detection of organophosphate pesticides. Biosens Bioelectron 99:223–229
Dar AI, Walia S, Acharya A (2016) Citric acid-coated gold nanoparticles for visual colorimetric recognition of pesticide dimethoate. J Nanopart Res 18:233
de Souza PA, da Rocha GO, de Andrade JB (2011) A SDME/GC–MS methodology for determination of organophosphate and pyrethroid pesticides in water. Microchem J 99:303–308
Dhull V (2020) A Nafion/AChE-cSWCNT/MWCNT/Au-based amperometric biosensor for the determination of organophosphorous compounds. Environ Technol 41:566–576
Du D, Huang X, Cai J, Zhang A (2007) Amperometric detection of triazophos pesticide using acetylcholinesterase biosensor based on multiwall carbon nanotube–chitosan matrix. Sens Actuators, B Chem 127:531–535
Fidalgo-Used N, Montes-Bayón M, Blanco-González E, Sanz-Medel A (2005) Determination of organophosphorus pesticides in spiked river water samples using solid phase microextraction coupled to gas chromatography with EI-MS and ICP-MS detection. J Anal at Spectrom 20:876–882
Folmar LC, Denslow ND, Rao V, Chow M, Crain DA, Enblom J, Guillette LJ Jr (1996) Vitellogenin induction and reduced serum testosterone concentrations in feral male carp (Cyprinus carpio) captured near a major metropolitan sewage treatment plant. Environ Health Perspect 104:1096–1101. https://doi.org/10.1289/ehp.961041096
FSSAI (2020) Food safety and standards (contaminants, toxins and residues) Regulations, 2011. Access date: 20-11-2021 https://www.google.com/url?sa=t&rct=j&q=&esrc=s&source=web&cd=&cad=rja&uact=8&ved=2ahUKEwiMgpzzvsDsAhWEILcAHR_4Dz8QFjAFegQIFBAC&url=https%3A%2F%2Farchive.fssai.gov.in%2Fdam%2Fjcr%3A592ff0e4-6897-44a4-b28e-5d69f9955c77%2FCompendium_Contaminants_Regulations_20_05_2019.pdf&usg=AOvVaw0Bm_ZKpi_tWcGsG4GE1qfr
Gannavarapu KP, Ganesh V, Dandamudi RB (2019) Zirconia nanocomposites with carbon and iron (iii) oxide for voltammetric detection of sub-nanomolar levels of methyl parathion. Nanoscale Advances 1:4947–4954
Goel P, Arora M (2018) Fabrication of chemical sensor for organochlorine pesticide detection using colloidal gold nanoparticles. MRS Communications 8:1000–1007. https://doi.org/10.1557/mrc.2018.125
Guilbault GG, Hock B, Schimid R (1992) A piezoelectric immunobiosensor for atrazine in drinking water. Biosens Bioelectron 7:411–419
Habedank F, Abraham M, Tardel H, Feldhusen F, Schulz-Bull DE (2017) Determination of organophosphate pesticides in sea and surface water with ultrasound-assisted dispersive liquid–liquid micro-extraction coupled to GC-MS/MS analysis. Int J Environ Anal Chem 97:819–830
Harshit D, Charmy K, Nrupesh P (2017) Organophosphorus pesticides determination by novel HPLC and spectrophotometric method. Food Chem 230:448–453
HINOTEK (2020) NY-1D Pesticide residue meter. Access date: 20-11-2021 https://www.hinotek.com/lab/ny-1d-pesticide-residue-meter/
Hondred JA, Breger JC, Alves NJ, Trammell SA, Walper SA, Medintz IL, Claussen JC (2018) Printed graphene electrochemical biosensors fabricated by inkjet maskless lithography for rapid and sensitive detection of organophosphates. ACS Appl Mater Interfaces 10:11125–11134
Inc AT (2020a) ACE I rapid pesticide test for military use (Access date: 20-11-2021) https://www.anptinc.com/ace-products
Inc AT (2020b) ACE III rapid pesticide test for home and personal use. Access date: 20-11-2021 https://www.anptinc.com/ace-products
Inc AT (2020c) ASDR ACE-II rapid pesticide test for professional use. Access date: 20-11-2021 https://www.anptinc.com/ace-products
Ismail HM, Kumar V, Singh RP, Williams C, Shivam P, Ghosh A,… Coleman M (2016) Development of a simple dipstick assay for operational monitoring of DDT PLoS Negl Trop Dis 10. https://doi.org/10.1371/journal.pntd.0004324
ITRI (2020) Handheld pesticide residue detector. Access date: 20-11-2021 https://www.itri.org.tw/ListStyle.aspx?DisplayStyle=01_content&SiteID=1&MmmID=1036233376062425763&MGID=711017231006163542
Jin H, Qin Y, Liang H, Wan L, Lan H, Chen G, Liu R, Zheng L, Chiang P, Hong Z (2017). A mobile-based high sensitivity on-field organophosphorus compounds detecting system for IoT-based food safety tracking. Journal of Sensors 2017:13.
Iheanacho JUI, Onyeka PIK, Udujih HI, Udujih OG, Okoroigbo FI, Amaechi AA, Okafor AI (2020) Sub-lethal study of Organophosphorus (Chlorpyrifos) toxicity on reproductive biomarkers in Female Wistar Rats. ASJ: International Journal of Health, Safety and Environments (IJHSE) 6(2):499–505
Kamel RM (2020) Facile luminescent sensing trace levels of pesticides azinphos ethyl, diazinon, chlorfenviphos and isofenphos. Inorg Chem Commun 111:107662
Kant R (2020) Surface plasmon resonance based fiber–optic nanosensor for the pesticide fenitrothion utilizing Ta 2 O 5 nanostructures sequestered onto a reduced graphene oxide matrix. Microchim Acta 187:8
Kavruk M, Özalp VC, Öktem HA (2013). Portable Bioactive Paper-Based Sensor for Quantification of Pesticides. Journal of analytical methods in chemistry 2013: 932946.
Kaur R, Kaur R, Rani S, Malik AK, Kabir A, Furton KG (2019a) Application of fabric phase sorptive extraction with gas chromatography and mass spectrometry for the determination of organophosphorus pesticides in selected vegetable samples. J Sep Sci 42:862–870
Kaur R, Kaur R, Rani S, Malik AK, Kabir A, Furton KG, Samanidou VF (2019) Rapid monitoring of organochlorine pesticide residues in various fruit juices and water samples using fabric phase sorptive extraction and gas chromatography-mass spectrometry. Molecules 24:1013
Khan IU, Dubey W, Gupta V (2017) Preponderance of bioactive medicinal compounds and ATR-FTIR spectroscopy of coriander and mustard floral honey from Apis mellifera. Indonesian Journal of Chemistry 17:376–384
Khilare R, KHURANA R, Narang G, Jadhav V (2016) Occurrence of some organochlorine pesticide residues in poultry feed and meat. Haryana Vet 55:120–124
Köck-Schulmeyer M, Postigo C, Farré M, Barceló D, de Alda ML (2019) Medium to highly polar pesticides in seawater: analysis and fate in coastal areas of Catalonia (NE Spain). Chemosphere 215:515–523. https://doi.org/10.1016/j.chemosphere.2018.10.049
Korram J, Dewangan L, Karbhal I, Nagwanshi R, Vaishanav SK, Ghosh KK, Satnami ML (2020) CdTe QD-based inhibition and reactivation assay of acetylcholinesterase for the detection of organophosphorus pesticides. RSC Adv 10:24190–24202. https://doi.org/10.1039/D0RA03055D
Koureas M, Tsakalof A, Tsatsakis A, Hadjichristodoulou C (2012) Systematic review of biomonitoring studies to determine the association between exposure to organophosphorus and pyrethroid insecticides and human health outcomes. Toxicol Lett 210:155–168
Lang Q, Han L, Hou C, Wang F, Liu A (2016) A sensitive acetylcholinesterase biosensor based on gold nanorods modified electrode for detection of organophosphate pesticide. Talanta 156:34–41
Li C, Zhang G, Wu S, Zhang Q (2018) Aptamer-based microcantilever-array biosensor for profenofos detection. Anal Chim Acta 1020:116–122. https://doi.org/10.1016/j.aca.2018.02.072
Liang B, Wang G, Yan L, Ren H, Feng R, Xiong Z, Liu A (2019) Functional cell surface displaying of acetylcholinesterase for spectrophotometric sensing organophosphate pesticide. Sens Actuators, B Chem 279:483–489. https://doi.org/10.1016/j.snb.2018.09.119
Lin Y, Lu F, Wang J (2004) Disposable carbon nanotube modified screen printed biosensor for amperometric detection of organophosphorus pesticides and nerve agents. Electroanalysis An International J Devoted to Fundamental and Practical Aspects of Electroanalysis 16:145–149
Liu G, Lin Y (2005) Electrochemical sensor for organophosphate pesticides and nerve agents using zirconia nanoparticles as selective sorbents. Anal Chem 77:5894–5901
Liu G, Lin Y (2006) Biosensor based on self-assembling acetylcholinesterase on carbon nanotubes for flow injection/amperometric detection of organophosphate pesticides and nerve agents. Anal Chem 78:835–843
Liu Y, He M, Chen B, Hu B (2015) Solidification of floating organic drop microextraction combined with gas chromatography-flame photometric detection for the analysis of organophosphorus pesticides in water samples. Anal Methods 7:6182–6189
Liu Z, Xia X, Zhou G, Ge L, Li F (2020) Acetylcholinesterase-catalyzed silver deposition for ultrasensitive electrochemical biosensing of organophosphorus pesticides. Analyst 145:2339–2344
Lu X, Tao L, Song D, Li Y, Gao F (2018) Bimetallic Pd@ Au nanorods based ultrasensitive acetylcholinesterase biosensor for determination of organophosphate pesticides. Sens Actuators, B Chem 255:2575–2581
Lukaszewicz-Hussain A (2010) Role of oxidative stress in organophosphate insecticide toxicity–short review. Pestic Biochem Physiol 98:145–150
Luo D, Zhou T, Tao Y, Feng Y, Shen X, Mei S (2016) Exposure to organochlorine pesticides and non-Hodgkin lymphoma: a meta-analysis of observational studies. Sci Rep 6:25768
Mahajan R, Chatterjee S (2018) A simple HPLC–DAD method for simultaneous detection of two organophosphates, profenofos and fenthion, and validation by soil microcosm experiment. Environ Monit Assess 190:327
Martorell D, Cespedes F, Martinez-Fabregas E, Alegret S (1994) Amperometric determination of pesticides using a biosensor based on a polishable graphie-epoxy biocomposite. Anal Chim Acta 290:343–348
Marvin CH, Brindle ID, Hall CD, Chiba M (1990) Development of an automated high-performance liquid chromatographic method for the on-line pre-concentration and determination of trace concentrations of pesticides in drinking water. J Chromatogr A 503:167–176
Maurya P, Malik D (2016) Accumulation and distribution of organochlorine and organophosphorus pesticide residues in water, sediments and fishes, Heteropneustis fossilis and Puntius ticto from Kali River, India. J Toxicol and Environ Health Sci 8:30–40
Mehrpour O, Karrari P, Zamani N, Tsatsakis AM, Abdollahi M (2014) Occupational exposure to pesticides and consequences on male semen and fertility: a review. Toxicol Lett 230:146–156
Mehta J, Dhaka S, Paul AK, Dayananda S, Deep A (2019) Organophosphate hydrolase conjugated UiO-66-NH2 MOF based highly sensitive optical detection of methyl parathion. Environ Res 174:46–53
Minunni M, Mascini M (1993) Detection of pesticide in drinking water using real-time biospecific interaction analysis (BIA). Anal Lett 26:1441–1460
Mishra A, Kumar J, Melo JS (2017) An optical microplate biosensor for the detection of methyl parathion pesticide using a biohybrid of Sphingomonas sp. cells-silica nanoparticles. Biosens Bioelectron 87:332–338
Mondal R, Mukherjee A, Biswas S, Kole RK (2018) GC-MS/MS determination and ecological risk assessment of pesticides in aquatic system: a case study in Hooghly River basin in West Bengal, India. Chemosphere 206:217–230
Mukherjee S, Pal S, Pal A, Ghosh D, Sarkar S, Bhand S, Sarkar P, Bhattacharyya N (2019) UIISScan 1.1: a field portable high-throughput platform tool for biomedical and agricultural applications. J Pharm Biomed Anal 174:70–80
Mukherjee S, Pal S, Paria P, Bhattacharyya S, Ghosh K, Pal A, Ghosh D, Sarkar P, Behera BK, Das SCS (2021) On-spot biosensing device for organophosphate pesticide residue detection in fruits and vegetables. Current Research in Biotechnology 3:308–316
Mulla SI, Ameen F, Talwar MP, Eqani SAMAS, Bharagava RN, Saxena G, Tallur PN, Ninnekar HZ (2020) Organophosphate pesticides: impact on environment, toxicity, and their degradation. Bioremediation of Industrial Waste for Environmental Safety 265–290. Springer
Mulchandani P, Mulchandani A, Kaneva I, Chen W (1999) Biosensor for direct determination of organophosphate nerve agents. 1. Potentiometric Enzyme Electrode Biosensors and Bioelectronics 14:77–85
Mulchandani P, Chen W, Mulchandani A, Wang J, Chen L (2001) Amperometric microbial biosensor for direct determination of organophosphate pesticides using recombinant microorganism with surface expressed organophosphorus hydrolase. Biosens Bioelectron 16:433–437
Muñoz-Quezada MT, Lucero BA, Barr DB, Steenland K, Levy K, Ryan PB, …Vega C (2013) Neurodevelopmental effects in children associated with exposure to organophosphate pesticides: a systematic review Neurotoxicology 39 158 168. https://doi.org/10.1016/j.neuro.2013.09.003
Nagabooshanam S, Roy S, Mathur A, Mukherjee I, Krishnamurthy S, Bharadwaj LM (2019) Electrochemical micro analytical device interfaced with portable potentiostat for rapid detection of chlorpyrifos using acetylcholinesterase conjugated metal organic framework using Internet of things. Sci Rep 9:1–9
Narenderan S, Meyyanathan S, Karri VVSR, Babu B, Chintamaneni P (2019) Multivariate response surface methodology assisted modified QuEChERS extraction method for the evaluation of organophosphate pesticides in fruits and vegetables cultivated in Nilgiris. South India Food Chemistry 300:125188
NIPHM (2020) Pesticide classification on use, chemical nature, formulation, toxicity and mode of action etc. Access date: 20-11-2021 https://niphm.gov.in/Recruitments/ASO-PMD.pdf
OPHL (2020) OP-CB kit. https://www.daganghalal.com/Product/op-cb_kit_29175
Peng L, Dong S, Wei W, Yuan X, Huang T (2017) Synthesis of reticulated hollow spheres structure NiCo2S4 and its application in organophosphate pesticides biosensor. Biosens Bioelectron 92:563–569
Pichetsurnthorn P, Vattipalli K, Prasad S (2012) Nanoporous impedemetric biosensor for detection of trace atrazine from water samples. Biosens Bioelectron 32:155–162
Pico Y, El-Sheikh MA, Alfarhan AH, Barcelo D (2018) Target vs non-target analysis to determine pesticide residues in fruits from Saudi Arabia and influence in potential risk associated with exposure. Food Chem Toxicol 111:53–63. https://doi.org/10.1016/j.fct.2017.10.060
Queensland Uo (2020) Pesticide mixtures a bigger problem than previously thought. Access date: 20-11-2021 https://www.eurekalert.org/pub_releases/2020-07/uoq-pma071420.php
Rahimi R, Abdollahi M (2007) A review on the mechanisms involved in hyperglycemia induced by organophosphorus pesticides. Pestic Biochem Physiol 88:115–121
Rainina E, Efremenco E, Varfolomeyev S, Simonian A, Wild J (1996) The development of a new biosensor based on recombinant E. coli for the direct detection of organophosphorus neurotoxins. Biosens Bioelectron 11:991–1000
Ramasubramanian T, Paramasivam M (2016) Development and validation of a multiresidue method for the simultaneous determination of organophosphorus insecticides and their toxic metabolites in sugarcane juice and refined sugar by gas chromatography with flame photometric detection. J Sep Sci 39:2164–2171
RENEKABIO (2020) Pesticide detection test cards cat: 003RT-03 | 20 tests/kit. Access date: 20-11-2021 https://www.renekabio.com/products/food-safety-tests/pesticide-detection-test-cards/
Renganathan V, Balaji R, Chen S-M, Kokulnathan T (2020) Coherent design of palladium nanostructures adorned on the boron nitride heterojunctions for the unparalleled electrochemical determination of fatal organophosphorus pesticides. Sens Actuators, B Chem 307:127586
Sabarwal A, Kumar K, Singh RP (2018) Hazardous effects of chemical pesticides on human health–cancer and other associated disorders. Environ Toxicol Pharmacol 63:103–114
Sahub C, Tuntulani T, Nhujak T, Tomapatanaget B (2018) Effective biosensor based on graphene quantum dots via enzymatic reaction for directly photoluminescence detection of organophosphate pesticide. Sens Actuators, B Chem 258:88–97. https://doi.org/10.1016/j.snb.2017.11.072
Shrivastav AM, Usha SP, Gupta BD (2016) Fiber optic profenofos sensor based on surface plasmon resonance technique and molecular imprinting. Biosens Bioelectron 79:150–157
Singh M, Kashyap H, Singh PK, Mahata S, Rai VK, Rai A (2019) AuNPs/Neutral red-biofunctionalized graphene nanocomposite for nonenzymatic electrochemical detection of organophosphate via NO2 reduction. Sens Actuators, B Chem 290:195–202
Song D, Li Y, Lu X, Sun M, Liu H, Yu G, Gao F (2017) Palladium-copper nanowires-based biosensor for the ultrasensitive detection of organophosphate pesticides. Anal Chim Acta 982:168–175
Sruthi S, Shyleshchandran M, Mathew SP, Ramasamy E (2017) Contamination from organochlorine pesticides (OCPs) in agricultural soils of Kuttanad agroecosystem in India and related potential health risk. Environ Sci Pollut Res 24:969–978
Swetha (2020) Pesticide usage in India – Issues and Solutions Access date: 20-11-2021 https://www.iasexpress.net/pesticide-usage-in-india/
Sylvie Azandjeme C, Bouchard M, Fayomi B, Djrolo F, Houinato D, Delisle H (2013) Growing burden of diabetes in sub-saharan Africa: contribution of pesticides? Curr Diabetes Rev 9:437–449
Thangarasu R, Victor VD, Alagumuthu M (2019) MnO2/PANI/rGO-A modified carbon electrode based electrochemical sensor to detect organophosphate pesticide in real food samples. Anal Bioanal Electrochem 11(4):427–447
Vinoth Kumar J, Karthik R, Chen S-M, Natarajan K, Karuppiah C, Yang C-C, Muthuraj V (2018) 3D flower-like gadolinium molybdate catalyst for efficient detection and degradation of organophosphate pesticide (fenitrothion). ACS Appl Mater Interfaces 10:15652–15664
Viswanathan S, Radecka H, Radecki J (2009) Electrochemical biosensor for pesticides based on acetylcholinesterase immobilized on polyaniline deposited on vertically assembled carbon nanotubes wrapped with ssDNA. Biosens Bioelectron 24:2772–2777
Wang Y, Zhang S, Du D, Shao Y, Li Z, Wang J, Engelhard MH, Li J, Lin Y (2011) Self assembly of acetylcholinesterase on a gold nanoparticles–graphene nanosheet hybrid for organophosphate pesticide detection using polyelectrolyte as a linker. J Mater Chem 21:5319–5325
Wang A, Cockburn M, Ly TT, Bronstein JM, Ritz B (2014) The association between ambient exposure to organophosphates and Parkinson’s disease risk. Occup Environ Med 71:275–281. https://doi.org/10.1136/oemed-2013-101394
Wang J, Zhang J, Wang J, Fang G, Liu J, Wang S (2020) Fluorescent peptide probes for organophosphorus pesticides detection. J Hazard Mater 389:122074
Wei M, Wang J (2015) A novel acetylcholinesterase biosensor based on ionic liquids-AuNPs-porous carbon composite matrix for detection of organophosphate pesticides. Sens Actuators, B Chem 211:290–296
Xu X, Guo Y, Wang X, Li W, Qi P, Wang Z, … Wang Q (2018) Sensitive detection of pesticides by a highly luminescent metal-organic framework Sens Actuators, B Chem 260 339 345. https://doi.org/10.1016/j.snb.2018.01.075
Xue G, Yue Z, Bing Z, Yiwei T, Xiuying L, Jianrong L (2016) Highly-sensitive organophosphorus pesticide biosensors based on CdTe quantum dots and bi-enzyme immobilized eggshell membranes. Analyst 141:1105–1111
Yan X, Li H, Han X, Su X (2015) A ratiometric fluorescent quantum dots based biosensor for organophosphorus pesticides detection by inner-filter effect. Biosens Bioelectron 74:277–283
Yang G, White IM, Fan X (2008) An opto-fluidic ring resonator biosensor for the detection of organophosphorus pesticides. Sens Actuators, B Chem 133:105–112
Yang G, Xu X, Shen M, Wang W, Xu L, Chen G, Fu F (2009) Determination of organophosphorus pesticides by capillary electrophoresis-inductively coupled plasma mass spectrometry with collective sample-introduction technique. Electrophoresis 30:1718–1723
Yang Y, Asiri AM, Du D, Lin Y (2014) Acetylcholinesterase biosensor based on a gold nanoparticle–polypyrrole–reduced graphene oxide nanocomposite modified electrode for the amperometric detection of organophosphorus pesticides. Analyst 139:3055–3060
Zhang P, Sun T, Rong S, Zeng D, Yu H, Zhang Z, Chang D, Pan H (2019) A sensitive amperometric AChE-biosensor for organophosphate pesticides detection based on conjugated polymer and Ag-rGO-NH2 nanocomposite. Bioelectrochemistry 127:163–170
Zhou Q, Yang L, Wang G, Yang Y (2013) Acetylcholinesterase biosensor based on SnO2 nanoparticles–carboxylic graphene–nafion modified electrode for detection of pesticides. Biosens Bioelectron 49:25–31
Zhou L, Zhang X, Ma L, Gao J, Jiang Y (2017) Acetylcholinesterase/chitosan-transition metal carbides nanocomposites-based biosensor for the organophosphate pesticides detection. Biochem Eng J 128:243–249
Acknowledgements
The authors acknowledge the funding from the Electronics System Development and Application Division (ESDA)[grant ID: 26(4)/2019-ESDA, dated 23/01/2020]. The authors are also thankful to the Ministry of Electronics and Information Technology (MeitY), Government of India, for their continuous support.
Funding
Funding agency 1: National Agricultural Science Fund (NASF), grant number: NASF/MECH-8015/2019–20 dated: 29th February, 2020; funding agency 2: Ministry of Electronics and Information technology, grant number: 26(4)/2019-ESDA, dated 23/01/2020.
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Subhankar Mukherjee: Conceptualization and writing—review and editing. Koustuv Ghosh: Writing—original draft preparation and writing—review and editing. Soumyadeb Bhattacharyya: Writing—original draft preparation and writing—review and editing. Bijay Kumar Behera: Conceptualization and supervision. Om Krishan Singh: Funding acquisition and supervision. Souvik Pal: Conceptualization and supervision.
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Mukherjee, S., Ghosh, K., Bhattacharyya, S. et al. A Review on Recent Trends in Advancement of Bio-Sensory Techniques Toward Pesticide Detection. Food Anal. Methods 15, 3416–3434 (2022). https://doi.org/10.1007/s12161-022-02382-4
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DOI: https://doi.org/10.1007/s12161-022-02382-4