International Journal of Environmental Chemistry

A major part of present science and technological development links with nano- technologies as it contributes to each branch of science by its versatile characteristics which make it familiar in both living & non-living world. Food is one of the essential necessities for all the living elements as a source of energy. Without food, no one can survive in this world, hence regular intake of foods with proper nutrition is utmost important for all living elements. When it comes in concern of human life, it is carrying an extra important, each country maintains a strict and strong rules and regulations on food quality & safety. Sensitive and reliable analytical methods for monitoring pathogens, additives, adulterants, and toxicants present in the food stuff have urgent requirement to reduce food waste and improve the overall food qualities. Worldwide several scientific groups work together on improvise healthy and quality foods for healthy lifestyle.

Kerry J, O’grady M, Hogan S. Past, current and potential utilisation of active and intelligent packaging systems for meat and muscle-based products, A review. Meat Sci. 2006; 74: 113–130p.

Turner A, Karube I, Wilson G S. Biosensors: Fundamentals Applications; Oxford University Press: New York, NY, USA, 1987.

Viswanathan S, Radecka H, Radecki J. Electrochemical biosensors for food analysis, Monatsh. Chem. Chem. Mon. 2009; 140: 891.

Mannelli I, Minunni, M, Tombelli S, Mascini, M. Quartz crystal microbalance (QCM) affinity biosensor for genetically modified organisms (GMOs) detection, Biosens. Bioelectron. 2003; 18: 129–140p.

Yang C, Wang, Y, Marty J. -L, Yang X. Aptamer-based colorimetric biosensing of Ochratoxin A using unmodified gold nanoparticles indicator, Biosens. Bioelectron. 2011; 26: 2724–2727p.

Narsaiah K, Jha S.N, Bhardwaj, R, Sharma R, Kumar, R. Optical biosensors for food quality and safety assurance-A review, J. Food Sci. Technol. 2012; 49: 383–406p

Kuswandi B, Restyana, A, Abdullah A, Heng L. Y, Ahmad M. A novel colorimetric food package label for fish spoilage based on polyaniline film., Food Control. 2012; 25: 184–189p

Kuswandi B, Nurfawaidi, A. On-package dual sensors label based on pH indicators for real-time monitoring of beef, Food Control., 2017; 82: 91–100p

Nakatani H. S, dos Santos L. V, Pelegrine C. P, Gomes S, Matsushita M, de Souza N. E, Visentainer J. V., Biosensor based on xanthine oxidase for monitoring hypoxanthine in fish meat, Am. J.

Biochem. Biotechnol., 2005; 1: 85–89p

Agüí, L, Manso J, Yáñez-Sedeño P, Pingarrón J. M. Amperometric biosensor for hypoxanthine based on immobilized xanthine oxidase on nanocrystal gold-carbon paste electrodes., Sens. Actuators B Chem. 2006; 113: 272–280p

Cunningham, S, Keaveny T. A two-stage enzymatic method for determination of uric acid and hypoxanthine/xanthine, Clin. Chim. Acta., 1978; 86: 217–221p

Chang L. –Y. Chuang M. -Y, Zan H. -W, Meng H. –F, Lu C. –J, Yeh P. –H, Chen J. –N. One- Minute Fish Freshness Evaluation by Testing the Volatile Amine Gas with an Ultrasensitive Porous-Electrode-Capped Organic Gas Sensor System, ACS Sens., 2017; 2: 531−539p

Maier, D, Channaiah, L, Martinez-Kawas, A, Lawrence J, Chaves E, Coradi P, Fromme G. Monitoring carbon dioxide concentration for early detection of spoilage in stored grain, Julius- Kühn-Archiv, 2010; 425: 505p

VidalJ. C, Bonel L, Ezquerra A, Hernández S, Bertolín J. R, Cubel C, Castillo J. R. Electrochemical affinity biosensors for detection of mycotoxins: A review, Biosens.Bioelectron., 2013; 49: 146–

p

Pohanka M, Jun D, Kuca K. Mycotoxin assays using biosensor technology: A review, Drug Chem. Toxicol., 2007; 30: 253–261p

Neethirajan, S, Karunakaran C, Jayas D, White N. Detection techniques for stored- product insects in grain, Food Control, 2007; 18: 157–162p

Neethirajan, S, Freund M, Jayas D, Shafai C, Thomson D, White N. Development of carbon dioxide (CO2) sensor for grain quality monitoring, Biosyst. Eng., 2010; 106: 395–404p

Neethirajan S, Jayas D. S. Nanotechnology for the food and bioprocessing industries, Food Bioprocess Technol., 2011; 4: 39–47p

White S. P, Frisbie C. D, Dorfman K. D. Detection and sourcing of gluten in grain with multiple floating-gate transistor biosensors, ACS Sens., 2018; 3: 395–402p

Zain M. E. Impact of mycotoxins on humans and animals, J. Saudi Chem. Soc., 2011; 15: 129–144p

Bonel L, Vidal J. C, Duato P, Castillo J. R. An electrochemical competitive biosensor for ochratoxin a based on a DNA biotinylated aptamer, Biosens. Bioelectron., 2011; 26: 3254–3259p

Kuswandi, B, Maryska C, Abdullah A, Heng L. Y. Real time on-package freshness indicator for guavas packaging, J. Food Meas. Charact., 201; 7: 29–39 p

WHO., Global Burden of Foodborne Diseases; WHO Press: Geneva, Switzerland, 2015

Liu X, Marrakchi M, Xu D, Dong H, Andreescu S. Biosensors based on modularly designed synthetic peptides for recognition, detection and live/dead differentiation of pathogenic bacteria, Biosens. Bioelectron., 2016; 80: 9–16 p

Alhogail S, Suaifan G. A, Zourob M. Rapid colorimetric sensing platform for the detection of Listeria monocytogenes foodborne pathogen Biosens. Bioelectron. 2016 ; 86 : 1061–1066 p

Yousefi H, Ali M. M, Su H. -M, Filipe C. D, Didar T. F. Sentinel wraps: Real- time monitoring of food contamination by printing DNAzyme probes on food packaging, ACS Nano., 2018 ; 12 : 3287–

p

Wang, H, Zhou Y, Jiang X, Sun B, Zhu Y, Wang H, Su Y, He Y. Simultaneous capture, cetection, and inactivation of bacteria as enabled by a surface- enhanced raman scattering multifunctional

chip, Angew. Chem. Int. Ed., 2015; 54 : 5132– 5136 p

DeMoura M. R, Mattoso L. H, Zucolotto V. Development of cellulose-based bactericidal nanocomposites containing silver nanoparticles and their use as active food packaging, J. Food

Eng., 2012 ; 109 : 520–524 p

Zhou, L, Lin Y, Huang Z, Ren J. and Qu X. Carbon nanodots as fluorescence probes for rapid, sensitive, and label-free detection of Hg2+ and biothiols in complex matrices, Chem. Comm., 2012; 48 : 1147–1149 p

Hou, J, Dong G, Tian Z. et al. A sensitive fluorescent sensor for selective determination of dichlorvos based on the recovered fluorescence of carbon dots-Cu(II) system, Food Chemistry, 2016 ; 202 : 81–87 p

Feng Y, Zhong D, Miao H, and Yang X, Carbon dots derived from rose flowers for tetracycline sensing, Talanta, 2015 ; 140 : 128–133 p

Lei C, Zhao X, Jiao S. et al. A turn-on fluorescent sensor for the detection of melamine based on the anti-quenching ability of Hg2+ to carbon nanodots, Analitical Methods, 2016; 8: 4438–4444 p

Shi L, Li Y, Li X. et al. Controllable synthesis of green and blue fluorescent carbon nanodots for pH and Cu2+ sensing in living cells, Biosens. Bioelectron., 2016; 77: 598–602 p

Roshni V. and Ottoor D. Synthesis of carbon nanoparticles using one step green approach and their application as mercuric ion sensor, J. Lumin., 2015; 161: 117–122 p

Zhou M, Zhou Z, Gong A. Zhang Y. and Li Q. Synthesis of highly photoluminescent carbon dots via citric acid and Tris for iron(III) ions sensors and bioimaging, Talanta, 2015 ; 143 : 107–113 p

Sun X. -Y, Wu L.-L, Shen J. -S. et al. Highly selective and sensitive sensing for Al3+ and F− based on green photoluminescent carbon dots, RSC Advances, 2016; 6: 97346–97351p

Xu, J, Zhou Y, Cheng G, Dong M, Liu S. and Huang C. Carbon dots as a luminescence sensor for ultrasensitive detection of phosphate and their bioimaging properties, Luminescence, 2015; 30:411–415 p

Yin, B, Deng J, Peng X. et al. Green synthesis of carbon dots with down- and up- conversion fluorescent properties for sensitive detection of hypochlorite with a dual-readout assay, Analyst, 2013; 138: 6551–6557 p

Zhang Y, Cui P, Zhang F. et al. Fluorescent probes for "off-on" highly sensitive detection of Hg2+ and L-cysteine based on nitrogen-doped carbon dots, Talanta, 2016; 152: 288–300 p