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Nanobiotechnology and its Application in Agriculture and Food Production

  • Priyanka Priyanka
  • Dileep Kumar
  • Anurag Yadav
  • Kusum Yadav
Chapter
  • 35 Downloads
Part of the Nanotechnology in the Life Sciences book series (NALIS)

Abstract

Nanobiotechnology involves the use of nanotechnology integrated with biology. It is an emergent field of research that holds vivid applications in agriculture sector and food industry. In agriculture, nanofertilizers are helping to enhance plant growth by providing smart nourishment. Nanopesticides (control pests), nanoinsecticides (against insects), nanofungicides, and nanoherbicides (control weeds in the field) are the output of advanced nanobiotechnological research. Nanoparticles are also used in seed science to enhance seed germination. The technological breakthough in nanotechnology was achieved after the development of nanosensors. Nanobiosensors are available for detecting phytopathogens and pesticide residues. In food sectors, nanoparticles are utilized in food processing and packaging. Besides this, nanoadditives, nutraceutical delivery agents, and nanoencapsulation devices find multiple applications in several fields. Nanoparticles have been effectively used in the food packaging to enhance storage period and decrease pathogenic growth on stored food. Nanobiosensors are utilized to detect the contamination of foodborne pathogens, toxic substance, and pesticide detection in food. Despite a lot of advantages of nanobiotechnology, the environmental toxicity of nanoparticles is a matter of concern that requires risk assessment of nanoparticles on human health and environmental effects.

Keywords

Food packaging Food processing Nanoparticles Nanosensor Nanotechnology 

References

  1. Abd-Elsalam KA, Alghuthaymi MA (2015) Nanobiofungicides: are they the next-generation of fungicides? J Nanotech Mater Sci 2:38–40Google Scholar
  2. Abdel-Aziz HMM, Hasaneen MNA, Omer AM (2016) Nano chitosan-NPK fertilizer enhances the growth and productivity of wheat plants grown in sandy soil. Span J Agric Res 14:e0902.  https://doi.org/10.5424/sjar/2016141-8205CrossRefGoogle Scholar
  3. Abduz Zahir A, Bagavan A, Kamaraj C, Elango G, Abdul Rahuman A (2012) Efficacy of plant-mediated synthesized silver nanoparticles against Sitophilus oryzae. J Biopest 5:95–102Google Scholar
  4. Adhikari T, Kundu S, Rao AS (2013) Impact of SiO2 and Mo nanoparticles on seed germination of rice (Oryza sativa L.). Int J Agric Food Sci Technol 4:809–816Google Scholar
  5. Ali MA, Rehman I, Iqbal A, Din S, Rao AQ, Latif A, Samiullah TR, Azam S, Husnain T (2014) Nanotechnology, a new frontier in agriculture. Adv Life Sci 1:129–138Google Scholar
  6. Alsaeedi A, El-Ramady H, Alshaal T, El-Garawani M, Elhawat N, Al-Otaibi A (2018) Exogenous nanosilica improves germination and growth of cucumber by maintaining K+/na+ ratio under elevated na+ stress. Plant Physiol Biochem 125:164–171PubMedCrossRefGoogle Scholar
  7. Amenta V, Aschberger K, Arena M, Bouwmeester H, Moniz FB, Brandhoff P, Gottardo S, Marvin HJP, Mech A, Pesudo LQ, Rauscher H, Schoonjans R, Vettori MV, Weigel S, Peters RJ (2015) Regulatory aspects of nanotechnology in the Agri/feed/food sector in EU and non-EU countries. Regul Toxicol Pharmacol 73:463–476PubMedCrossRefGoogle Scholar
  8. Ariffin SAB, Adam T, Hashim U, Faridah S, Zamri I, Uda MNA (2014) Plant diseases detection using nanowire as biosensor transducer. Adv Mater Res 832:113–117CrossRefGoogle Scholar
  9. Ardekani MRS, Abdin MZ, Nasrullah N, Samim M (2014) Calcium phosphate nanoparticles a novel non-viral gene delivery system for genetic transformation of tobacco. International journal of pharmacy and pharmaceutical. Science 6:605–609Google Scholar
  10. Avella M, De Vlieger JJ, Errico ME, Fischer S, Vacca P, Volpe MG (2005) Biodegradable starch/clay nanocomposite films for food packaging applications. Food Chem 93:467–474CrossRefGoogle Scholar
  11. Bai YX, Li YF, Yang Y, Yi LX (2006) Covalent immobilization of triacylglycerol lipase onto functionalized nanoscale SiO2 spheres. Process Biochem 41:770–777CrossRefGoogle Scholar
  12. Barik TK, Sahu B, Swain V (2008) Nanosilica – from medicine to pest control. Parasitol Res 103(2):253–258PubMedPubMedCentralCrossRefGoogle Scholar
  13. Bhattacharyya A, Duraisamy P, Govindarajan M, Buhroo AA, Prasad R (2016) Nano-biofungicides: Emerging trend in insect pest control. In: Advances and Applications through Fungal Nanobiotechnology (ed. Prasad R), Springer International Publishing Switzerland 307–319Google Scholar
  14. Bottoms M, Emerson SH (2013) Chemistry, fertilizer, and the environment. California Foundation for Agriculture in the Classroom pp 1–98Google Scholar
  15. Buteler M, Sofie SW, Weaver DK, Driscoll D, Muretta J, Stadler T (2015) Development of nanoalumina dust as insecticide against Sitophilus oryzae and Rhyzopertha dominica. Int J Pest Manag 61:80–89CrossRefGoogle Scholar
  16. Canham LT (2007) Nanoscale semiconducting silicon as nutritional food additive. Nanotech 18:1–6CrossRefGoogle Scholar
  17. Cao Y (2018) The toxicity of nanoparticles to human endothelial cells. Adv Exp Med Biol 1048:59–69PubMedCrossRefGoogle Scholar
  18. Casalinuovo IA, Pierro DD, Coletta M, Francesco PD (2006) Application of electronic noses for disease diagnosis and food spoilage detection. Sensors 6:1428–1439CrossRefGoogle Scholar
  19. Chang Y, Lin Y, Xiao G, Chiu T, Hu C (2016) A highly selective and sensitive nanosensor for the detection of glyphosate. Talanta 161:94–98PubMedCrossRefGoogle Scholar
  20. Chartuprayoon N, Rheem Y, Ng JCK, Nam J, Chen W, Myung NV (2013) Polypyrrole nanoribbon based chemiresistive immunosensors for viral plant pathogen detection. Anal Methods 5:3497–3502CrossRefGoogle Scholar
  21. Chaudhry Q, Watkins R, Castle L (2010) Nanotechnologies in the food. In: Chaudhry Q, Castle L, Watkins R (eds) New opportunities, new questions, new concerns. Royal Society of Chemistry, UK, pp 1–17Google Scholar
  22. Chin-Chan M, Navarro-Yepes J, Quintanilla-Vega B (2015) Environmental pollutants as risk factors for neurodegenerative disorders: Alzheimer and Parkinson diseases. Front Cell Neurosci 9:1–22CrossRefGoogle Scholar
  23. Chen SH, Wu VC, Chuang YC (2008) Using oligonucleotide-functionalized au nanoparticles to rapidly detect foodborne pathogens on a piezoelectric biosensor. J Microbiol Methods 73:7–17PubMedCrossRefGoogle Scholar
  24. Chellaram C, Murugaboopathi G, John AA, Sivakumar R, Ganesan S, Krithika S, Priya G (2014) Significance of nanotechnology in food industry. APCBEE Procedia 8:109–113CrossRefGoogle Scholar
  25. Coccini T, Grandi S, Lonati D, Locatelli C, Simone UD (2015) Comparative cellular toxicity of titanium dioxide nanoparticles 3 on human astrocyte and neuronal cells after acute and 4 prolonged exposure. Neurotoxicology 48:77–89PubMedCrossRefGoogle Scholar
  26. Concina I, Falasconi M, Gobbi E, Bianchi F, Musci M, Mattarozzi M, Pardo M, Mangia A, Careri M, Sberveglieri G (2009) Early detection of microbial contamination in processed tomatoes by electronic nose. Food Cont 20:873–880CrossRefGoogle Scholar
  27. Dasgupta N, Ranjan S, Mundekkad D, Ramalingam C, Shanker R, Kumar A (2015) Nanotechnology in agro-food: from field to plate. Food Res Int 69:381–400CrossRefGoogle Scholar
  28. Davari MR, Kazazi SB, Pivehzhani OA (2017) Nanomaterials: implications on agroecosystem. In: Prasad R, Kumar M, Kumar V (eds) Nanotechnology: an agricultural paradigm. Springer Nature, Singapore, pp 59–71CrossRefGoogle Scholar
  29. Debnath N, Das S, Seth D, Chandra R, Bhattacharya SC, Goswami A (2011) Entomotoxic effect of silica nanoparticles against Sitophilus oryzae (L.). J Pest Sci 84:99–105CrossRefGoogle Scholar
  30. Dehkourdi EH, Mosavi M (2013) Effect of anatase nanoparticles (TiO2) on parsley seed germination (Petroselinum crispum) in vitro. Biol Trace Elem Res 155:283–286PubMedCrossRefGoogle Scholar
  31. Dias MV, Soares NDFF, Borges SV, Sousa MMD, Nunes CA, Oliveira IRND, Medeiros EAA (2013) Use of allyl isothiocyanate and carbon nanotubes in an antimicrobial film to package shredded, cooked chicken meat. Food Chem 141:3160–3166PubMedCrossRefPubMedCentralGoogle Scholar
  32. Donsì F, Annunziata M, Sessa M, Ferrari G (2011) Nanoencapsulation of essential oils to enhance their antimicrobial activity in foods. LWT – Food Sci Tech 44:1908–1914CrossRefGoogle Scholar
  33. Duke MC, Lim A, Luz SC, Nielsen L (2008) Lactic acid enrichment with inorganic nanofiltration and molecular sieving membranes by pervaporation. Food Bioprod Proc 86:290–295CrossRefGoogle Scholar
  34. Durga Devi G, Murugan K, Panneer Selvam C (2014) Green synthesis of silver nanoparticles using Euphorbia hirta (Euphorbiaceae) leaf extract against crop pest of cotton bollworm, Helicoverpa armigera (Lepidoptera: Noctuidae). J Biopest 7:54–66Google Scholar
  35. El-bendary HM, El-Helaly AA (2013) First record nanotechnology in agricultural: silica nano- particles a potential new insecticide for pest control. App Sci Report 4:241–246Google Scholar
  36. Elrahman SHA, Mostafa MAM (2015) Applications of nanotechnology in agriculture: an overview. Egyptian J Soil Sci 55:197–214CrossRefGoogle Scholar
  37. Emamifar A, Kadivar M, Shahedi M, Soleimanian-Zad S (2010) Evaluation of nanocomposite packaging containing ag and ZnO on shelf life of fresh orange juice. Innovative Food Sci Emerg Technol 11:742–748CrossRefGoogle Scholar
  38. Espitia PJP, Soares NDFF, Coimbra JSDR, Andrade NJD, Cruz RS, Medeiros EAA (2012) Zinc oxide nanoparticles: synthesis, antimicrobial activity and food packaging applications. Food Bioprocess Technol 5:1447–1464CrossRefGoogle Scholar
  39. EFSA Scientific Committee (2011) Guidance on the risk assessment of the application of nanoscience and nanotechnologies in the food and feed chain. EFSA J 9:1–36Google Scholar
  40. Fang Y, Umasankar Y, Ramasamy RP (2014) Electrochemical detection of p-ethylguaiacol, a fungi infected fruit volatile using metal oxide nanoparticles. Analyst 139:3804–3810PubMedCrossRefPubMedCentralGoogle Scholar
  41. Fasihnia SH, Peighambardoust SH, Peighambardoust SJ (2017) Nanocomposite films containing organoclay nanoparticles as an antimicrobial (active) packaging for potential food application. J Food Process Preserv e13488:1–10Google Scholar
  42. Feizi H, Moghaddam PR, Shahtahmassebi N, Fotovat A (2012) Impact of bulk and nanosized titanium dioxide (TiO2) on wheat seed germination and seedling growth. Biol Trace Elem Res 146:101–106PubMedCrossRefPubMedCentralGoogle Scholar
  43. Fletcher J, Bender C, Budowle B, Cobb WT, Gold SE, Ishimaru CA, Luster D, Melcher U, Murch R, Scherm H, Seem RC, Sherwood JL, Sobral BW, Tolin SA (2006) Plant pathogen forensics: capabilities, needs, and recommendations. Microbiol Mol Biol Rev 70:450–471PubMedPubMedCentralCrossRefGoogle Scholar
  44. Fu J, Park B, Siragusa G, Jones L, Tripp R, Zhao Y, Cho Y (2008) An au/Si hetero-nanorod-based biosensor for Salmonella detection. Nanotech 19:1–7Google Scholar
  45. Gaikwad KK, Singh S, Lee YS (2018) High adsorption of ethylene by alkali-treated halloysite nanotubes for food-packaging applications. Environ Chem Letters 16:1055–1062CrossRefGoogle Scholar
  46. Garcia M, Aleixandre M, Gutiérrez J, Horrillo MC (2006) Electronic nose for wine discrimination. Sensors Actuat 113:911–916CrossRefGoogle Scholar
  47. Gopinath K, Gowri S, Karthika V, Arumugam A (2014) Green synthesis of gold nanoparticles from fruit extract of Terminalia arjuna, for the enhanced seed germination activity of Gloriosa superba. J Nanostr Chem 4:115–126CrossRefGoogle Scholar
  48. Ghorbanzade T, Jafari SM, Akhavan S, Hadavi R (2017) Nano-encapsulation of fish oil in nano-liposomes and its application in fortification of yogurt. Food Chem 216:146–152PubMedCrossRefPubMedCentralGoogle Scholar
  49. Ghormade V, Deshpande MV, Paknikar KM (2011) Perspective for nano-biotechnology enabled protection and nutrition of plants. Biotech Adv 29:792–803CrossRefGoogle Scholar
  50. Ghosh A, Dey K, Mani A, Dey AN, Bauri FK (2017) Implication of nanocomposite edible coating for shelf life extension of Indian olive (Elaeocarpus floribundus Blume). Curr J App Sci Tech 22:1–8CrossRefGoogle Scholar
  51. Gokmen V, Mogol BA, Lumaga RB, Fogliano V, Kaplun Z, Shimoni E (2011) Development of functional bread containing nanoencapsulated omega-3 fatty acids. J Food Eng 105:585–591CrossRefGoogle Scholar
  52. Gonzalez A, Igarzabal CIA (2013) Soy protein-poly(lactic acid) bilayer films as biodegradable material for active food packaging. Food Hydrocoll 33:289–296CrossRefGoogle Scholar
  53. Grillo R, Pereira AE, Nishisaka CS, de Lima R, Oehlke K, Greiner R, Fraceto LF (2014) Chitosan/tripolyphosphate nanoparticles loaded with paraquat herbicide: an environmentally safer alternative for weed control. J Hazard Materials 278:163–171CrossRefGoogle Scholar
  54. Hafeez A, Razzaq A, Mahmood T, Jhanzab HM (2015) Potential of copper nanoparticles to increase growth and yield of wheat. J Nanosc Advanced Tech 1:6–11Google Scholar
  55. He L, Liu Y, Mustapha A, Lin M (2011) Antifungal activity of zinc oxide nanoparticles against Botrytis cinerea and Penicillium expansum. Microbiol Res 166:207–215PubMedCrossRefGoogle Scholar
  56. Hoet PHM, Brüske-Hohlfeld I, Salata OV (2004) Nanoparticles–known and unknown health risks. J Nanobiotechnol 2:1–15CrossRefGoogle Scholar
  57. Hosseini M, Khabbaz H, Dadmehr M, Ganjali MR, Mohamadneja J (2015) Aptamer-based colorimetric and chemiluminescence detection of aflatoxin B1 in foods samples. Acta Chim Slov 62:721–728PubMedCrossRefGoogle Scholar
  58. Howard J (2013) Occupational exposure to carbon nanotubes and nanofibers. https://www.cdc.gov/niosh/docs/2013-145/pdfs/. Accessed 20 June 2018
  59. Hsieh KL (2010) Lycopene and resveratrol dietary supplement. US Patent WO/2010/132021, 18 Nov 2010Google Scholar
  60. Hussain AA, Al-Rawajfeh AE (2009) Recent patents of nanofiltration applications in oil processing, desalination, wastewater and food industries. Recent Patents Chemical Eng 2:51–66CrossRefGoogle Scholar
  61. Hussain M, Raja NI, Mashwani ZUR, Iqbal M, Sabir S, Yasmeen F (2017) In vitro seed germination and biochemical profiling of Artemisia absinthium exposed to various metallic nanoparticles. 3Biotech 7:101–108Google Scholar
  62. Ing LY, Zin NM, Sarwar A, Katas H (2012) Antifungal activity of chitosan nanoparticles and correlation with their physical properties. Int J Biomat 632698.  https://doi.org/10.1155/2012/632698CrossRefGoogle Scholar
  63. Ismail M, Prasad R, Ibrahim AIM, Ahmed ISA (2017) Modern prospects of nanotechnology in plant pathology. In: Nanotechnology (eds. Prasad R, Kumar M, Kumar V), Springer Nature Singapore Pte Ltd. 305–317Google Scholar
  64. Jamdagni P, Rana JS, Khatri P, Nehra K (2018) Comparative account of antifungal activity of green and chemically synthesized zinc oxide nanoparticles in combination with agricultural fungicides. Int J Nano Dimen 9:198–208Google Scholar
  65. Jampílek J, králová K (2015) Application of nanotechnology in agriculture and food industry, its prospects and risks. Ecol Chem Eng S22:321–361Google Scholar
  66. Jeon JS, Lee HS (2009) Nano-particles containing calcium and method for preparing the same. US Patent WO/2009/011520, 22 Jan 2009Google Scholar
  67. Jo Y, Kim BH, Jung G (2009) Antifungal activity of silver ions and nanoparticles on phytopathogenic fungi. Plant Dis 93:1037–1043PubMedCrossRefGoogle Scholar
  68. Kanhed P, Birla S, Gaikwad S, Gade A, Seabra AB, Rubilar O, Duran N, Rai M (2014) In vitro antifungal efficacy of copper nanoparticles against selected crop pathogenic. Fungi Mater Lett 115:13–17CrossRefGoogle Scholar
  69. Kashyap PL, Rai P, Sharma S, Chakdar H, Kumar S, Pandiyan K, Srivastava AK (2016) Nanotechnology for the detection and diagnosis of plant pathogens. In: Ranjan S et al (eds) Nanoscience in food and agriculture 2, sustainable agriculture reviews 21. Springer, Basel pp 253–276Google Scholar
  70. Khan I, Tango CN, Sumaira M, Deog-Hwan O (2017) Evaluation of nisin-loaded chitosan-monomethyl fumaric acid nanoparticles as a direct food additive. Carbohydrate Poly 184:100–107CrossRefGoogle Scholar
  71. Khalifa NS, Hasaneen MN (2018) The effect of chitosan–PMAA–NPK nanofertilizer on Pisum sativum plants. 3Biotech 8:193–205Google Scholar
  72. Khodakovskaya M, Dervishi E, Mahmood M, Xu Y, Li Z, Watanabe F, Biris AS (2009) Carbon nanotubes are able to penetrate plant seed coat and dramatically affect seed germination and plant growth. ACS Nano 3:3221–3227CrossRefGoogle Scholar
  73. Khooshe-Bast SN, Ghaffari-moghaddam M, Mirshekar A (2016) Insecticidal effects of zinc oxide nanoparticles and Beauveria bassiana TS11 on Trialeurodes vaporariorum (Westwood, 1856) (Hemiptera: Aleyrodidae). Acta Agri Slovenica 107:299–309CrossRefGoogle Scholar
  74. Kim T, Oh J (2016) Dual nutraceutical nanohybrids of folic acid and calcium containing layered double hydroxides. J Solid State Chem 233:125–132CrossRefGoogle Scholar
  75. Kim KJ, Sung WS, Suh BK, Moon SK, Choi JS, Kim JG, Lee DG (2009) Antifungal activity and mode of action of silver nano-particles on Candida albicans. Biometals 22:235–242PubMedCrossRefGoogle Scholar
  76. Kim SW, Jung JH, Lamsal K, Kim YS, Min JS, Lee YS (2012) Antifungal effects of silver nanoparticles (AgNPs) against various plant pathogenic fungi. Mycobiology 40:53–58PubMedPubMedCentralCrossRefGoogle Scholar
  77. Kirdar SS (2015) ISITES conference. Valencia, pp 1517–1527Google Scholar
  78. Ko KS, Koh DC, Kong IC (2017) Evaluation of the effects of nanoparticle mixtures on Brassica seed germination and bacterial bioluminescence activity based on the theory of probability. Nano 7:344–354Google Scholar
  79. Kothari P, Setia H (2017) Silver nanoparticle filled HPMC and xanthan films for food packaging and safety. Indian J Sci Tech 10:1–6CrossRefGoogle Scholar
  80. Kumar GD, Natarajan N, Nakkeeran S (2016) Antifungal activity of nanofungicide Trifloxystrobin 25% + Tebuconazole 50% against Macrophomina phaseolina. African J Microbiol Res 10:100–105CrossRefGoogle Scholar
  81. Lin HY, Huang CH, Lu SH, Kuo IT, Chau LK (2014) Direct detection of orchid viruses using nanorod-based fiber optic particle plasmon resonance immunosensor. Biosens Bioelectron 51:371–378PubMedCrossRefPubMedCentralGoogle Scholar
  82. Lamsal K, Kim SW, Jung JH, Kim YS, Kim KS, Lee YS (2011) Inhibition effects of silver nanoparticles against powdery mildews on cucumber and pumpkin. Mycobiol 39:26–32CrossRefGoogle Scholar
  83. Latva-Nirva, E, Dahms G, Jung A, Fiebrig B (2009) Ultrafine titanium dioxide nanoparticles and dispersions thereof. US Patent WO 2009/141499 Al, 26 Nov 2009Google Scholar
  84. Le Israeli-Lev G, Livney YD (2014) Self-assembly of hydrophobin and its coassembly with hydrophobic nutraceuticals in aqueous solutions: towards application as delivery systems. Food Hydrocoll 35:28–35CrossRefGoogle Scholar
  85. Lee DG, Ponvel KM, Kim M, Hwang S, Ahn IK, Lee CH (2009) Immobilization of lipase on hydrophobic nano-sized magnetite particles. J Mol Catal B Enzym 57:62–66CrossRefGoogle Scholar
  86. Lopez A, Gavara R, Lagaron J (2006) Bioactive packaging: turning foods into healthier foods through biomaterials. Trends Food Sci Technol 17:567–575CrossRefGoogle Scholar
  87. Li FS, Wu WT (2009) Lipase-immobilized electrospun PAN nanofibrous membranes for soybean oil hydrolysis. Biochem Eng J 45:48–53CrossRefGoogle Scholar
  88. Liu R, Lal R (2014) Synthetic apatite nanoparticles as a phosphorus fertilizer for soybean (Glycine max). Sci Reports 4:5686–5691CrossRefGoogle Scholar
  89. Long Q, Li H, Zhang Y, Yao S (2015) Upconversion nanoparticle-based fluorescence resonance energy transfer assay for organophosphorus pesticides. Biosens Bioelectron 68:168–174PubMedCrossRefGoogle Scholar
  90. Longano D, Ditaranto N, Cioffi N, Niso FD, Sibillano T, Ancona A, Conte A, Del Nobile MA, Sabbatini L, Torsi L (2012) Analytical characterization of laser-generated copper nanoparticles for antibacterial composite food packaging. Anal Bioanal Chem 403:1179–1186PubMedCrossRefGoogle Scholar
  91. Mahmoodzadeh H, Nabavi M, Kashefi H (2013) Effect of nanoscale titanium dioxide particles on the germination and growth of canola (Brassica napus). J Ornam Hort Plants 3:25–32Google Scholar
  92. Malaikozhundan B, Vaseeharan B, Vijayakumar S, Thangaraj MP (2017) Bacillus thuringiensis coated zinc oxide nanoparticle and its biopesticidal effects on the pulse beetle, Callosobruchus maculatus. J Photochem Photobiol B Biol 174:306–314CrossRefGoogle Scholar
  93. Manikandan A, Subramanian KS (2016) Evaluation of zeolite based nitrogen nano-fertilizers on maize growth, yield and quality on inceptisols and alfisols. Int J Plant Soil Sci 9:1–9CrossRefGoogle Scholar
  94. Manimaran M (2015) A review on nanotechnology and its implications in agriculture and food industry. Asian J Plant Sci Res 5:13–15Google Scholar
  95. Martin-Ortigosa S, Peterson DJ, Valenstein JS, Lin VSY, Trewyn BG, Lyznik LA, Wang K (2014) Mesoporous silica nanoparticle-mediated intracellular Cre protein delivery for maize genome editing via loxP site excision. Plant Physiol 164:537–547PubMedCrossRefGoogle Scholar
  96. McKeague MK, Giamberardino A, DeRosa MC (2011) Advances in aptamer based biosensors for food safety. In: Somerset V (ed) Environmental biosensors. InTech, Croatia, pp 17–42Google Scholar
  97. Mehrazar E, Rahaie M, Rahaie S (2015) Application of nanoparticles for pesticides, herbicides, fertilisers and animals feed management. Int J Nanoparticles 8:1–19CrossRefGoogle Scholar
  98. Migliore L, Uboldi C, Di Bucchianico S, Coppede F (2015) Nanomaterials and neurodegeneration. Environ Mol Mutagen 56:149–170PubMedCrossRefGoogle Scholar
  99. Mishra S, Singh BR, Singh A, Keswani C, Naqvi AH, Singh HB (2014) Biofabricated silver nanoparticles act as a strong fungicide against Bipolaris sorokiniana causing spot blotch disease in wheat. PLoS One 9:e97881.  https://doi.org/10.1371/journal.pone.0097881CrossRefPubMedPubMedCentralGoogle Scholar
  100. Moghadam A, Vattani H, Baghaei N, Keshavarz N (2012) Effect of different levels of fertilizer nano-iron chelates on growth and yield characteristics of two varieties of spinach (Spinacia oleracea L.): Varamin 88 and Viroflay. Res J App Sci Eng Tech 4:4813–4818Google Scholar
  101. Momin JK, Jayakumar C, Prajapati JB (2013) Potential of nanotechnology in functional foods. Emirates J Food Agricult 25:10–19CrossRefGoogle Scholar
  102. Moura MRD, Mattoso LHC, Zucolotto V (2012) Development of cellulose-based bactericidal nanocomposites containing silver nanoparticles and their use as active food packaging. J Food Eng 109:520–524CrossRefGoogle Scholar
  103. Mozafari MR, Flanagan J, Matia-Merino L, Awati A, Omri A, Suntres ZE, Singh H (2006) Recent trends in the lipid-based nanoencapsulation of antioxidants and their role in foods. J Sci Food Agri 86:2038–2045CrossRefGoogle Scholar
  104. Mukhopadhyay SS (2014) Nanotechnology in agriculture: prospects and constraints. Nanotech Sci App 7:63–71CrossRefGoogle Scholar
  105. Naderi MR, Danesh-Shahraki A (2013) Nanofertilizers and their roles in sustainable agriculture. Intl J Agri Crop Sci 5:2229–2232Google Scholar
  106. Nesi A, Gordi M, Davidovi S, Radovanovic Z, Nedeljkovi J, Smirnova I, Gurikov P (2018) Pectin-based nanocomposite aerogels for potential insulated food packaging application. Carbohydrate Poly 195:128–135CrossRefGoogle Scholar
  107. Nguyen M, Reynolds N, Vigneswaran S (2003) By-product recovery from cottage cheese production by nanofiltration. J Clean Prod 11:803–807CrossRefGoogle Scholar
  108. Niemeyer CM, Doz P (2001) Nanoparticles, proteins, and nucleic acids: biotechnology meets materials science. Angewandte Chemie Int Ed 40:4128–4158CrossRefGoogle Scholar
  109. Oliveira Marques PRB, Lermo A, Campoy S, Yamanaka H, Barbe J, Alegret S, Pividori MI (2009) Double-tagging polymerase chain reaction with a thiolated primer and electrochemical genosensing based on gold nanocomposite sensor for food safety. Anal Chem 81:1332–1339CrossRefGoogle Scholar
  110. Oskam G (2006) Metal oxide nanoparticles: synthesis, characterization and application. J SolGel Sci Technol 37:161–164CrossRefGoogle Scholar
  111. Otles S, Yalcin B (2010) Nano-biosensors as new tool for detection of food quality and safety. LogForum 6:67–70Google Scholar
  112. Ouda SM (2014) Antifungal activity of silver and copper nanoparticles on two plant pathogens, Alternaria alternata and Botrytis cinerea. Res J Microbiol 9:34–42CrossRefGoogle Scholar
  113. Pal S, Alocilja EC (2009) Electrically active polyaniline coated magnetic (EAPM) nanoparticle as novel transducer in biosensor for detection of Bacillus anthracis spores in food samples. Biosens Bioelectron 24:1437–1444PubMedCrossRefGoogle Scholar
  114. Panacek A, Kolar M, Vecerova R, Prucek R, Soukupova J, Krystof V, Hamal P, Zboril R, Kvıtek L (2009) Antifungal activity of silver nanoparticles against Candida spp. Biomaterials 30:6333–6340PubMedCrossRefGoogle Scholar
  115. Paniel N, Radoi A, Marty J (2010) Development of an electrochemical biosensor for the detection of aflatoxin M1 in milk. Sensors 10:9439–9448PubMedCrossRefGoogle Scholar
  116. Parveen A, Rao S (2014) Effect of nanosilver on seed germination and seedling growth in Pennisetum glaucum. J Clust Sci 26:693–701CrossRefGoogle Scholar
  117. Pereira AES, Grillo R, Mello NFS, Rosa AH, Fraceto LF (2014) Application of poly(epsilon-caprolactone) nanoparticles containing atrazine herbicide as an alternative technique to control weeds and reduce damage to the environment. J Hazard Mat 268:207–215CrossRefGoogle Scholar
  118. Perlatti B, Bergo PLD, da Silva MFDGF, Fernandes JB, Forim MR (2013) Polymeric nanoparticle-based insecticides: a controlled release purpose for agrochemicals. In: Trdan S (ed) Insecticides - development of safer and more effective technologies, InTech, Croatia, pp 523–550Google Scholar
  119. Pham DC, Nguyen TH, Ngoc UTH, Le NTT, Tran TV, Nguyen DH (2018) Preparation, characterization and antifungal properties of chitosan-silver nanoparticles synergize fungicide against Pyricularia oryzae. J Nanosc Nanotech 18:1–7CrossRefGoogle Scholar
  120. Popov KI, Filippov AN, Khurshudyan SA (2010) Food nanotechnologies. Russian J Gen Chem 80:630–642CrossRefGoogle Scholar
  121. Pradhan N, Singh S, Ojha N, Shrivastava A, Barla A, Rai V, Bose S (2015) Facets of nanotechnology as seen in food processing, packaging, and preservation industry. Biomed Res Int 365672.  https://doi.org/10.1155/2015/365672CrossRefGoogle Scholar
  122. Prasad R, Kumar V, Prasad KS (2014) Nanotechnology in sustainable agriculture: present concerns and future aspects. Afr J Biotechnol 13(6):705–713Google Scholar
  123. Prasad R, Bhattacharyya A, Nguyen QD (2017a) Nanotechnology in sustainable agriculture: Recent developments, challenges, and perspectives. Front Microbiol 8:1014. doi:  https://doi.org/10.3389/fmicb.2017.01014
  124. Prasad R, Kumar V, Kumar M (2017b) Nanotechnology: Food and Environmental Paradigm. Springer Nature Singapore Pte Ltd. (ISBN 978-981-10-4678-0)Google Scholar
  125. Priyadarshi R, Negi YS (2016) Effect of varying filler concentration on zinc oxide nanoparticle embedded chitosan films as potential food packaging material. J Polym Environ 25:1087–1098CrossRefGoogle Scholar
  126. Puoci F, Lemma F, Spizzirri UG, Cirillo G, Curcio M, Picci N (2008) Polymer in agriculture: a review. Am J Agri Biol Sci 3:299–314CrossRefGoogle Scholar
  127. Putheti S (2015) Application of nanotechnology in food, nutraceuticals and pharmaceuticals. e-J Sci Tech 2:17–23Google Scholar
  128. Rad F, Mohsenifar A, Tabatabaei M, Safarnejad MR, Shahryari F, Safarpour H, Foroutan A, Mardi M, Davoudi D, Fotokian M (2012) Detection of Candidatus Phytoplasma aurantifolia with a quantum dots FRET-based biosensor. J Plant Pathol 94:525–534Google Scholar
  129. Raei M, Rajabzadeh G, Zibaei S, Jafari SM, Sani AA (2015) Nano-encapsulation of isolated lactoferrin from camel milk by calcium alginate and evaluation of its release. Int J Biol Macromol 79:669–673PubMedCrossRefGoogle Scholar
  130. Ragaei M, Sabry AH (2014) Nanotechnology for insect pest control. Int J Sci Environ Tech 3:528–545Google Scholar
  131. Rao PJ, Khanum H (2016) A green chemistry approach for nanoencapsulation of bioactive compound curcumin. LWT - Food Sci Tech 65:695–702CrossRefGoogle Scholar
  132. Ravichandran R (2010) Nanotechnology applications in food and food processing: innovative green approaches, opportunities and uncertainties for global market. Int J Green Nanotech 1:P72–P96CrossRefGoogle Scholar
  133. Rouhani M, Samih MA, Kalantari S (2012) Insecticide effect of silver and zinc nanoparticles against Aphis nerii Boyer de Fonscolombe (Hemiptera: Aphididae). Chilean J Agri Res 72:590–594CrossRefGoogle Scholar
  134. Rui M, Ma C, Hao Y, Guo J, Rui Y, Tang X, Zhao X, Fan X, Zhang Z, Hou T, Zhu S (2016) Iron oxide nanoparticles as a potential iron fertilizer for peanut (Arachis hypogaea). Front Plant Sci 7:815–824PubMedPubMedCentralCrossRefGoogle Scholar
  135. Saharan V, Sharma G, Yadav M, Choudhary MK, Sharma SS, Pal A, Raliya R, Biswas P (2015) Synthesis and in vitro antifungal efficacy of cu–chitosan nanoparticles against pathogenic fungi of tomato. Int J Biol Macromol 75:346–353PubMedCrossRefGoogle Scholar
  136. Sahayaraj K, Madasamy M, Radhika SA (2016) Insecticidal activity of bio-silver and gold nanoparticles against Pericallia ricini fab. (Lepidaptera: Archidae). J Biopest 9:63–72Google Scholar
  137. Sahoo D, Mandal A, Mitra T, Chakraborty K, Bardhan M, Dasgupta AK (2018) Nanosensing of pesticides by zinc oxide quantum dot: an optical and electrochemical approach for the detection of pesticides in water. J Agric Food Chem 66:414–423PubMedCrossRefGoogle Scholar
  138. Sarwar MS, Niazi MBK, Jahan Z, Ahmad T, Hussain A (2017) Preparation and characterization of PVA/nanocellulose/ag nanocomposite films for antimicrobial food packaging. Carbohydrate Poly 184:453–464CrossRefGoogle Scholar
  139. Savithramma N, Ankanna S, Bhumi G (2012) Effect of nanoparticles on seed germination and seedling growth of Boswellia ovalifoliolata – an endemic and endangered medicinal tree. Taxon Nano Vision 2:61–68Google Scholar
  140. Savolainen K, Pylkkänen L, Norppa H, Falck G, Lindberg H, Tuomi T, Vippola M, Alenius H, Hämeri K, Koivisto J, Brouwer D, Mark D, Bard D, Berges M, Jankowska E, Posniak M, Farmer P, Singh R, Krombach F, Bihari P, Kasper G, Seipenbusch M (2010) Nanotechnologies, engineered nanomaterials and occupational health and safety – a review. Saf Sci 48:957–963CrossRefGoogle Scholar
  141. Scampicchio M, Ballabio D, Arecchi A, Cosio SM, Mannino S (2008) Amperometric electronic tongue for food analysis. Microchim Acta 163:11–21CrossRefGoogle Scholar
  142. Scrinis G, Lyons K (2007) THE emerging nano-corporate paradigm: nanotechnology and the transformation of nature, food and Agri-food systems. Int J Socio Food Agri 15:22–44Google Scholar
  143. Singh NB, Amist N, Yadav K, Singh D, Pandey JK, Singh SC (2013) Zinc oxide nanoparticles as fertilizer for the germination, growth and metabolism of vegetable crops. J Nanoeng Nanomanufacturing 3:353–364CrossRefGoogle Scholar
  144. Singh T, Shukla S, Kumar P, Wahla V, Bajpai VK, Rather IA (2017) Application of nanotechnology in food science: perception and overview. Front Microbiol 8:1–7Google Scholar
  145. Shahrekizad M, Ahangara AG, Mirb N (2015) EDTA-coated Fe3O4 nanoparticles: a novel biocompatible fertilizer for improving agronomic traits of sunflower (Helianthus annuus). J Nanostruct 5:117–127Google Scholar
  146. Shaker AM, Zaki AH, Abdel-Rahim EF, Khedr MH (2016) Novel CuO nanoparticles for pest management and pesticides photodegradation. Adv Environ Biol 10:274–283Google Scholar
  147. Sharma R, Pathak Y (2010) Acyl ascorbate in enzymatic synthesis: industrial uses as a food nanoadditive. Nanotech 1:79–82Google Scholar
  148. Sharon M, Choudhary AK, Kumar R (2010) Nanotechnology in agricultural diseases and food safety. J Phytology 2:83–92Google Scholar
  149. Shelby T, Sulthana S, McAfee J, Banerjee T, Santra S (2017) Foodborne pathogen screening using magneto-fluorescent nanosensor: rapid detection of E. coli O157: H7. J Vis Exp 127:e55821.  https://doi.org/10.3791/55821CrossRefGoogle Scholar
  150. Siddiqui MH, Al-Whaibi MH (2014) Role of nano-SiO2 in germination of tomato (Lycopersicum esculentum seeds mill.). Saudi J Bio Sci 21:13–17CrossRefGoogle Scholar
  151. Silva AT, Nguyen A, Ye C, Verchot J, Moon JH (2010) Conjugated polymer nanoparticles for effective siRNA delivery to tobacco BY-2 protoplasts. BMC Plant Biol 10:291–304PubMedPubMedCentralCrossRefGoogle Scholar
  152. Silva HD, Cerqueira MA, Vicente AA (2012) Nanoemulsions for food applications: development and characterization. Food Bioprocess Technol 5:854–867CrossRefGoogle Scholar
  153. Silvestre C, Duraccio D, Cimmino S (2011) Food packaging based on polymer nanomaterials. Prog Poly Sci 36:1766–1782CrossRefGoogle Scholar
  154. Siva GV, Benita LFJ (2016) Iron oxide nanoparticles promotes agronomic traits of ginger (Zingiber officinale Rosc.). Int J Adv Res Biol Sci 3:230–237CrossRefGoogle Scholar
  155. Song K, Lee S, Ban C (2012) Aptamers and their biological applications. Sens 12:612–631CrossRefGoogle Scholar
  156. Song L, Hongna L, Yan D, Lin L, Nongyue H (2013) Development of a magnetic nanoparticles microarray for simultaneous and simple detection of foodborne pathogens. J Biomed Nanotech 9:1254–1260CrossRefGoogle Scholar
  157. Sousa GFM, Gomes DG, Campos EVR, Oliveira JL, Fraceto LF, Stolf-Moreira R, Oliveira HC (2018) Post-emergence herbicidal activity of nanoatrazine against susceptible weeds. Front Environ Sci 6:1–6CrossRefGoogle Scholar
  158. Srivastava G, Das CK, Das A, Singh SK, Roy M, Kim H, Sethy N, Kumar A, Sharma RK, Singh SK, Philip D, Das M (2014) Seed treatment with iron pyrite (FeS2) nanoparticles increases the production of spinach. RSC Adv 4:58495–58504CrossRefGoogle Scholar
  159. Subramanian KS, Tarafdar JC (2011) Prospects of nanotechnology in Indian farming. Indian J Agri Sci 81:887–893Google Scholar
  160. Sun X, Liu B, Xia K (2011) A sensitive and regenerable biosensor for organophosphate pesticide based on self-assembled multilayer film with CdTe as fluorescence probe. Luminescence 26:616–621PubMedCrossRefPubMedCentralGoogle Scholar
  161. Tahira MA, Bajwa SZ, Mansoor S, Briddon RW, Khan WS, Scheffler BE, Amin I (2018) Evaluation of carbon nanotube based copper nanoparticle composite for the efficient detection of agroviruses. J Hazard Mater 346:27–35CrossRefGoogle Scholar
  162. Tarafdar JC (2015) Nanoparticle production, characterization and its application to horticultural crops. In: Aishwath OP, Singh B, Dubey PN, Mishra BK (eds) Winter School on “utilization of degraded land and soil through horticultural crops for agricultural productivity and environmental quality”. NRCSS, Ajmer, Rajasthan, pp 222–229Google Scholar
  163. Thangavel G (2014) Nanotechnology in food industry – a review. Int J Chem Tech 6:4096–4101Google Scholar
  164. Torney FO, Trewyn BG, Lin VSY, Wang K (2007) Mesoporous silica nanoparticles deliver DNA and chemicals into plants. Nature Nanotech 2:295–300CrossRefGoogle Scholar
  165. Tripathi S, Mehrotra GK, Dutta PK (2008) Chitosan based antimicrobial films for food packaging applications. E-Polymers 93:1–7Google Scholar
  166. Upadhyaya H, Roy H, Shome S, Tewari S, Bhattacharya MK, Panda SK (2017) Physiological impact of zinc nanoparticle on germination of rice (Oryza sativa L) seed. J Plant Sci Phytopathol 1:62–70CrossRefGoogle Scholar
  167. Vani C, Brindhaa U (2013) Silica nanoparticles as nanocides against Corcyra cephalonica (S.), the stored grain pest. Int J Pharm Biol Sci 4:1108–1118Google Scholar
  168. Verdian A (2017) Apta-nanosensors for detection and quantitative determination of acetamiprid – a pesticide residue in food and environment. Talanta 176:456–464PubMedCrossRefPubMedCentralGoogle Scholar
  169. Vimala V, Clarke SK, Urvinder Kaur S (2016) Pesticides detection using acetylcholinesterase nanobiosensor. Biosens J 5:1–4Google Scholar
  170. Wang M, Li Z (2008) Nano-composite ZrO2/au film electrode for voltammetric detection of parathion. Sensors Actuators B Chem 133:607–612CrossRefGoogle Scholar
  171. Wang SL, Nguyen AD (2018) Effects of Zn/B nanofertilizer on biophysical characteristics and growth of coffee seedlings in a greenhouse. Res Chem Intermed 44:4889–4901CrossRefGoogle Scholar
  172. Wang Z, Wei F, Liu SY, Xu Q, Huang J-Y, Dong XY, Hua JH, Yang Q, Zhao YD, Chen H (2010) Electrocatalytic oxidation of phytohormone salicylic acid at copper nanoparticles-modified gold electrode and its detection in oilseed rape infected with fungal pathogen Sclerotinia sclerotiorum. Talanta 80:1277–1280PubMedCrossRefPubMedCentralGoogle Scholar
  173. Wani AH, Shah MA (2012) A unique and profound effect of MgO and ZnO nanoparticles on some plant pathogenic fungi. J App Pharm Sci 02:40–44Google Scholar
  174. Warczok J, Ferrando M, Lopez F, Guell C (2004) Concentration of apple and pear juices by nanofiltration at low pressures. J Food Eng 63:63–70CrossRefGoogle Scholar
  175. Win-Shwe T, Fujimaki H (2011) Nanoparticles and neurotoxicity. Int J Mol Sci 12:6267–6280PubMedPubMedCentralCrossRefGoogle Scholar
  176. Wu J, Ding T, Sun J (2013) Neurotoxic potential of iron oxide nanoparticles in the rat brain striatum and hippocampus. Neurotoxicology 34:243–253PubMedCrossRefPubMedCentralGoogle Scholar
  177. Xie Y, Li Y, Niu L, Wang H, Qian H, Yao W (2012) A novel surface-enhanced Raman scattering sensor to detect prohibited colorants in food by graphene/silver nanocomposite. Talanta 100:32–37PubMedCrossRefPubMedCentralGoogle Scholar
  178. Xu X, Liu X, Li Y, Ying Y (2013) A simple and rapid optical biosensor for detection of aflatoxin B1 based on competitive dispersion of gold nanorods. Biosens Bioelectron 47:361–367PubMedCrossRefPubMedCentralGoogle Scholar
  179. Yan X, Song Y, Zhu C, Li H, Du D, Su X, Lin Y (2018) MnO2 nanosheet-carbon dots sensing platform for sensitive detection of organophosphorus pesticides. Anal Chem 90:2618–2624PubMedCrossRefPubMedCentralGoogle Scholar
  180. Yang M, Kostov Y, Rasooly A (2008) Carbon nanotubes based optical immunodetection of staphylococcal enterotoxin B (SEB) in food. Int J Food Microbiol 127:78–83PubMedCrossRefGoogle Scholar
  181. Yang S, Wu T, Zhao X, Li X, Tan W (2014) The optical property of core-shell nanosensors and detection of atrazine based on localized surface plasmon resonance (LSPR) sensing. Sensors 14:13273–13284PubMedCrossRefGoogle Scholar
  182. Yao KS, Li SJ, Tzeng KC, Cheng TC, Chang CY, Chiu CY, Liao CY, Hsu JJ, Lin ZP (2009) Fluorescence silica nanoprobe as a biomarker for rapid detection of plant pathogens. Adv Materials Res 79-82:513–516CrossRefGoogle Scholar
  183. Yassen A, Abdallah E, Gaballah M, Zaghloul S (2017) Role of silicon dioxide nano fertilizer in mitigating salt stress on growth, yield and chemical composition of cucumber (Cucumis sativus L.). Int J Agri Res 12:130–135CrossRefGoogle Scholar
  184. Yildirim S, Röcker B, Pettersen MK, Nilsen-Nygaard J, Ayhan Z, Rutkaite R, Radusin T, Suminska P, Marcos B, Coma V (2017) Active packaging applications for food. Comp Rev Food Sci Food Safety 17:165–199CrossRefGoogle Scholar
  185. Zacco E, Pividori MI, Alegret S (2006) Electrochemical magnetoimmunosensing strategy for the detection of pesticides residues. Anal Chem 78:1780–1788PubMedCrossRefGoogle Scholar
  186. Zhao W, Ge P, Xu J, Chen H (2009) Selective detection of hypertoxic organophosphates pesticides via PDMS composite based acetylcholinesterase-inhibition biosensor. Environ Sci Technol 43:6724–6729PubMedCrossRefGoogle Scholar
  187. Ziaee M, Ganji Z (2016) Insecticidal efficacy of silica nanoparticles against Rhyzopertha dominica F. And Tribolium confusum Jacquelin du Val. J Plant Prot Res 56:250–255CrossRefGoogle Scholar

Copyright information

© Springer Nature Switzerland AG 2020

Authors and Affiliations

  • Priyanka Priyanka
    • 1
  • Dileep Kumar
    • 1
  • Anurag Yadav
    • 2
  • Kusum Yadav
    • 1
  1. 1.Department of BiochemistryUniversity of LucknowLucknowIndia
  2. 2.College of Basic Sciences and HumanitiesSardarkrushinagar Agricultural University DantiwadaBanaskanthaIndia

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