[1] G. T. Sigurdson, P. Tang, and M. M. Giusti, “Natural colorants: Food colorants from natural sources,” Annual Review of Food Science and Technology, 2017, 8: 261-280.

[2] N. Bereli, D. Cimen, and A. Denizli, “Optical sensor-based molecular imprinted poly (hydroxyethyl methacrylate-N-methacryloyl-(L)-histidine methyl ester) thin films for determination of tartrazine in fruit juice,” IEEE Sensors Journal, 2021, 21(12): 13215-13222.

[3] K. Rovina, S. Siddiquee, and S. M. Shaarani, “Toxicology, extraction and analytical methods for determination of amaranth in food and beverage products,” Trends in Food Science and Technology, 2017, 65: 68-79.

[4] G. G. Bessegato, M. F. Brugnera, and M. V. B. Zanoni, “Electroanalytical sensing of dyes and colorants,” Current Opinion in Electrochemistry, 2019, 16: 134-142.

[5] P. Mpountoukas, A. Pantazaki, E. Kostareli, P. Christodoulou, D. Kareli, S. Poliliou, et al., “Cytogenetic evaluation and DNA interaction studies of the food colorants amaranth, erythrosine and tartrazine,” Food and Chemical Toxicology, 2010, 48(10): 2934-2944.

[6] Y. Perdomo, V. Arancibia, O. Garcia-Beltran, and E. Nagles, “Adsorptive stripping voltammetric determination of amaranth and tartrazine in drinks and gelatins using a screen-printed carbon electrode,” Sensors, 2017, 17(11): 2665.

[7] K. A. Amin and A. H. Abd Elsttar, “Effect of food azo dyes tartrazine and carmoisine on biochemical parameters related to renal, hepatic function and oxidative stress biomarkers in young male rats,” Food and Chemical Toxicology, 2010, 48(10): 2994-2999.

[8] S. Tajik, Y. Orooji, F. Karimi, Z. Ghazanfari, H. Beitollahi, M. Shokouhimehr, et al., “High performance of screen-printed graphite electrode modified with Ni-Mo-MOF for voltammetric determination of amaranth,” Journal of Food Measurement and Characterization, 2021, 15(5): 4617-4622.

[9] M. Wang, Y. Sun, X. Yang, and J. Zhao, “Sensitive determination of Amaranth in drinks by highly dispersed CNT in graphene oxide ‘‘water’’ with the aid of small amounts of ionic liquid,” Food Chemistry, 2015, 179: 318-324.

[10] G. Karanikolopoulos, A. Gerakis, K. Papadopoulou, and I. Mastrantoni, “Determination of synthetic food colorants in fish products by an HPLC-DAD method,” Food Chemistry, 2015, 177: 197-203.

[11] H. Wu, J. B. Guo, L. M. Du, H. Tian, C. X. Hao, Z. F. Wang, et al., “A rapid shaking-based ionic liquid dispersive liquid phase microextraction for the simultaneous determination of six synthetic food colourants in soft drinks, sugar- and gelatin-based confectionery by high-performance liquid chromatography,” Food Chemistry, 2013, 141(1): 182-186.

[12] X. H. Chen, Y. G. Zhao, H. Y. Shen, L. X. Zhou, S. D. Pan, and M. C. Jin, “Fast determination of seven synthetic pigments from wine and soft drinks using magnetic dispersive solid-phase extraction followed by liquid chromatography-tandem mass spectrometry,” Journal of Chromatography A, 2014, 1346: 123-128.

[13] Y. D. Gao, L. Wang, Y. L. Zhang, L. N. Zou, G. P. Li, and B. X. Ye, “Electrochemical behavior of amaranth and its sensitive determination based on Pd-doped polyelectrolyte functionalized graphene modified electrode,” Talanta, 2017, 168: 146-151.

[14] F. I. Andrade, M. I. F. Guedes, I. G. P. Vieira, F. N. P. Mendes, P. A. S. Rodrigues, C. S.C. Maia, et al., “Determination of synthetic food dyes in commercial soft drinks by TLC and ion-pair HPLC,” Food Chemistry, 2014, 157: 193-198.

[15] B. Zhang, D. L. Du, M. Meng, S. A. Eremin, V. B. Rybakov, J. H. Zhao, et al., “Determination of amaranth in beverage by indirect competitive enzyme-linked immunosorbent assay (ELISA) based on anti-Amaranth monoclonal antibody,” Food Analytical Methods, 2014, 7(7): 1498-1505.

[16] C. I. L. Justino, A. C. Freitas, R. Pereira, A. C. Duarte, and T. A. P. Rocha Santos, “Recent developments in recognition elements for chemical sensors and biosensors,” Trends in Analytical Chemistry, 2015, 68: 2-17.

[17] B. A. Prabowo, A. Purwidyantri, and K. C. Liu, “Surface plasmon resonance optical sensor: a review on light source technology,” Biosensors, 2018, 8(3): 80.

[18] D. Cimen, N. Bereli, H. Yavuz, and A. Denizli, “Chapter 8: sensors for the detection of food,” in Nanosensors for Environment, Food and Agriculture Vol. 1. Vineet Kumar, Praveen Guleria Shivendu Ranjan, Nndita Dasgupta, and Eric Lichtfouse, Ed. Switzerland AG: Springer Nature, 2021, pp.169-182.

[19] J. F. Masson, “Portable and field-deployed surface plasmon resonance and plasmonic sensors,” Analyst, 2020, 145(11): 3776-3800.

[20] A. K. Srivastava, A. Dev, and S. Karmakar, “Nanosensors and nanobiosensors in food and agriculture,” Environmental Chemistry Letters, 2018, 16(1): 161-182.

[21] D. Cimen and A. Denizli, “Development of rapid, sensitive, and effective plasmonic nanosensor for the detection of vitamins in infact formula and milk samples,” Photonic Sensors, 2020, 10(4): 316-332.

[22] S. Faalnouri, D. Cimen, N. Bereli, and A. Denizli, “Surface plasmon resonance nanosensors for detecting amoxicillin in milk samples with amoxicillin imprinted poly(hydroxyethyl methacrylate-N-methacryloyl-(L)-glutamic acid),” ChemistrySelect, 2020, 5(15): 4761-4769.

[23] D. Cimen, N. Bereli, and A. Denizli, “Patulin imprinted nanoparticles decorated surface plasmon resonance chips for patulin detection,” Photonic Sensors, 2022, 12(2): 117-129.

[24] L. Chen, X. Wang, W. Lu, X. Wu, and J. Li, “Molecular imprinting: Perspectives and applications,” Chemical Society Reviews, 2016, 45(8): 2137-2211.

[25] A. Rico-Yuste and S. Carrasco, “Molecularly imprinted polymer-based hybrid materials for the development of optical sensors,” Polymers, 2019, 11(7): 1173.

[26] N. Bereli, D. Cimen, S. Hüseynli, and A. Denizli, “Detection of amoxicillin residues in egg extract with a molecularly imprinted polymer on gold microchip using surface plasmon resonance and quartz crystal microbalance methods,” Journal Food Science, 2020, 85(12): 4153-4160.

[27] S. Cikrik, D. Cimen, N. Bereli, and A. Denizli, “Preparation of surface plasmon resonance-based nanosensor for curcumin detection,” Turkish Journal of Chemistry, 2022, 46(1): 14-26.

[28] C. Huang, H. Wang, S. Ma, C. Bo, J. Ou, and B. Gong, “Recent application of molecular imprinting technique in food safety,” Journal of Chromatography A, 2021, 1657: 462579.

[29] E. M. Elgendy and N. A. Al-Zahrani, “Comparative study of natural and synthetic food additive dye amaranth through photochemical reactions,” International Journal of Scientific Research, 2015, 4: 827-832.

[30] E. Bormashenko, “Contact angles of rotating sessile droplets,” Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2013, 432: 38-41.

[31] O. Payton, A. R. Champneys, M. E. Homer, L. Picco, and M. J. Miles, “Feedback-induced instability in tapping mode atomic force microscopy: theory and experiment,” Proceedings of the Royal Society A, 2011, 467(2130): 1801-1822.

[32] M. R. Lockett and L. M. Smith, “Fabrication and characterization of DNA arrays prepared on carbon-on-metal substrates,” Analytical Chemistry, 2009, 81(15): 6429-6437.

[33] F. I. De Andrade, M. I. F. Guedes, i. G. P. Vieira, F. N. P. Mendes, P. A. S. Rodrigues, C. S. C. Maia, et al., “Determination of synthetic food dyes in commercial soft drinks by TLC and ion-pair HPLC,” Food Chemistry, 2014, 157: 193-198.

[34] F. Martin, J. M. Oberson, M. Meschiari, and C. Munari, “Determination of 18 water-soluble artificial dyes by LC-MS in selected matrices,” Food Chemistry, 2016, 197: 1249-1255.

[35] Y. Wu, G. Li, Y. Tian, J. Feng, J. Xiao, J. Liu, et al., “Electropolymerization of molecularly imprinted polypyrrole film on multiwalled carbon nanotube surface for highly selective and stable determination of carcinogenic amaranth,” Journal of Electroanalytical Chemistry, 2021, 895: 115494.

[36] Q. He, J. Liu, X. Liu, G. Li, P. Deng, and J. Liang, “Manganese dioxide nanorods/electrochemically reduced graphene oxide nanocomposites modified electrodes for cost-effective and ultrasensitive detection of Amaranth,” Colloids and Surfaces B: Biointerfaces, 2018, 172: 565-572.

[37] Q. Zhang, W. Cheng, D. Wu, Y. Yang, X. Feng, C. Gao, et al., “An electrochemical method for determination of amaranth in drinks using functionalized graphene oxide/chitosan/ionic liquid nanocomposite supported nanoporous gold,” Food Chemistry, 2022, 367: 130727.

[38] S. Tajik, H. Beitollahi, H. W. Jang, and M. Shokouhimehr, “A simple and sensitive approach for the electrochemical determination of amaranth by a Pd/GO nanomaterial-modified screen-printed electrode,” RSC Advances, 2021, 11(1): 278-287.

[39] L. Li, H. Zheng, L. Guo, L. Qu, and L. Yu, “A sensitive and selective molecularly imprinted electrochemical sensor based on Pd-Cu bimetallic alloy functionalized graphene for detection of amaranth in soft drink,” Talanta, 2019, 197: 68-76.

[40] Y. Li, S. Luo, L. Sun, D. Kong, J. Sheng, K. Wang, et al., “A green, simple, and rapid detection for amaranth in candy samples based on the fluorescence quenching of nitrogen-doped graphene quantum dots,” Food Analytical Methods, 2019, 12(7): 1658-1665.

[41] N. Nunez-Dallos, M. A. Macias, O. Garcia-Beltran, J. A. Calderón, E. Nagles, and J. Hurtado, “Voltammetric determination of amaranth and tartrazine with a new double-stranded copper (I) helicate-single-walled carbon nanotube modified screen printed electrode,” Journal of Electroanalytical Chemistry, 2018, 822: 95-104.

[42] C. Akkapinyo, K. Subannajui, Y. Poo-Arporn, and R. P. Poo-Arporn, “Disposable electrochemical sensor for food colorants detection by reduced graphene oxide and methionine film modified screen printed carbon electrode,” Molecules, 2021, 26(8): 2312.

[43] W. Huang, M. Zhang, and W. Hu, “N-methyl-2-pyrrolidone-exfoliated graphene nanosheets as sensitive determination platform for amaranth at the nanomolar level,” Ionics, 2017, 23: 241-246.