Science & Technology Review >

2024 , Vol. 42 >Issue 24: 96 - 105

DOI: https://doi.org/10.3981/j.issn.1000-7857.2023.04.00648

Reviews

Research progress in the application of aggregation-induced emission materials in food safety field

  • JIA Yuan ,
  • MENG Fanzhe ,
  • YANG Juxiang ,
  • LI Beibei
Expand
  • 1. School of Chemical Engineering, Xi'an University, Xi'an 710065, China;
    2. Xi'an Key Laboratory of Food Safety Testing and Risk Assessment, Xi'an University, Xi'an 710065, China

Received date: 2023-04-27

  Revised date: 2023-06-21

  Online published: 2024-09-27

Fold

Abstract

Food safety is directly related to human health and safety, thus the development of food safety testing and related safety materials has become a research hotspot in the field of food safety. Aggregation-induced emission (AIE) material, due to their good optical stability and high sensitivity, plays an important role in the field of food safety. based on the introduction of the properties of AIE material, the relationship between its structure and AIE performance was discussed, the application of AIE in the field of food safety was also reviewed, including its application in the detection of foodborne pathogens, pesticide and veterinary drug residues, heavy metals, food additives, as well as its application in food quality assessment and food packaging materials. It can be predicted that the accurate design of AIE material structure and the effective regulation of luminous properties can further expand the application range of new AIE fluorescent materials in the field of food safety.

Key words: aggregation induced emission; food detection; pesticide residues; foodborne pathogens; food safety

Cite this article

JIA Yuan , MENG Fanzhe , YANG Juxiang , LI Beibei . Research progress in the application of aggregation-induced emission materials in food safety field[J]. Science & Technology Review, 2024 , 42(24) : 96 -105 . DOI: 10.3981/j.issn.1000-7857.2023.04.00648

References

[1] Wang C F, Wang X, Gai P P, et al. Target-responsive AIE-Au nanoconjugate for acetylcholinesterase activity and inhibitor assay with ultralow background noise[J]. Sensors and Actuators B: Chemical, 2019, 284: 118-124.
[2] Yang C P, Li Y Y, Wang J M, et al. Fast and highly selective detection of acetaldehyde in liquor and spirits by forming aggregation-induced emission luminogen[J]. Sensors and Actuators B: Chemical, 2019, 285: 617-624.
[3] Yousefi H, Su H M, Imani S M, et al. Intelligent food packaging: A review of smart sensing technologies for monitoring food quality[J]. ACS Sensors, 2019, 4(4): 808- 821.
[4] Gao M, Tang B Z. Fluorescent sensors based on aggregation-induced emission: Recent advances and perspectives [J]. ACS Sensors, 2017, 2(10): 1382-1399.
[5] Esteki M, Simal-Gandara J, Shahsavari Z, et al. A review on the application of chromatographic methods, coupled to chemometrics, for food authentication[J]. Food Control, 2018, 93: 165-182.
[6] Hatzakis E. Nuclear magnetic resonance (NMR) spectroscopy in food science: A comprehensive review[J]. Comprehensive Reviews in Food Science and Food Safety, 2019, 18(1): 189-220.
[7] Mei J, Hong Y N, Lam J W Y, et al. Aggregation-induced emission: The whole is more brilliant than the parts [J]. Advanced Materials, 2014, 26(31): 5429-5479.
[8] Xie H F, Jiang X H, Zeng F, et al. A novel ratiometric fluorescent probe through aggregation-induced emission and analyte-induced excimer dissociation[J]. Sensors and Actuators B: Chemical, 2014, 203: 504-510.
[9] Mei J, Leung N L C, Kwok R T K, et al. Aggregation-induced emission: Together we shine, united we soar! [J]. Chemical Reviews, 2015, 115(21): 11718-11940.
[10] Liu B, Zhang R Y. Aggregation induced emission: Concluding Remarks[J]. Faraday Discussions, 2017, 196: 461-472.
[11] Dong Y Q, Lam J W, Tang B Z. Mechanochromic luminescence of aggregation-induced emission luminogens [J]. Journal of Physical Chemistry Letters, 2015, 6(17): 3429-3436.
[12] Niu S, Yan H X, Li S, et al. Bright blue photoluminescence emitted from the novel hyperbranched polysiloxane-containing unconventional chromogens[J]. Macromolecular Chemistry and Physics, 2016, 217(10): 1185- 1190.
[13] Gao M, Tang B Z. Fluorescent sensors based on aggregation-induced emission: Recent advances and perspectives[J]. ACS Sensors, 2017, 2(10): 1382-1399.
[14] Wang C, Li Q L, Wang B L, et al. Fluorescent sensors based on AIEgen-functionalised mesoporous silica nanoparticles for the detection of explosives and antibiotics[J]. Inorganic Chemistry Frontiers, 2018, 5(9): 2183- 2188.
[15] Wolfe N D, Dunavan C P, Diamond J. Origins of major human infectious diseases[J]. Nature, 2007, 447(7142): 279-283.
[16] Zhao X H, Lin C W, Wang J, et al. Advances in rapid detection methods for foodborne pathogens[J]. Journal of Microbiology and Biotechnology, 2014, 24(3): 297-312.
[17] Dou L N, Luo L P, Zhang X, et al. Biomimetic cell model for fluorometric and smartphone colorimetric dual-signal readout detection of bacterial toxin[J]. Sensors and Actuators B: Chemical, 2020, 312: 127956.
[18] Wang D, Lee M M S, Xu W H, et al. Theranostics based on AIEgens[J]. Theranostics, 2018, 8(18): 4925-4956.
[19] Delibato E, Volpe G, Romanazzo D, et al. Development and application of an electrochemical plate coupled with immunomagnetic beads (ELIME) array for Salmonella enterica detection in meat samples[J]. Journal of Agricultural and Food Chemistry, 2009, 57(16): 7200-7204.
[20] Masoomi L, Sadeghi O, Banitaba M H, et al. A non-enzymatic nanomagnetic electro-immunosensor for determination of Aflatoxin B1 as a model antigen[J]. Sensors and Actuators B: Chemical, 2013, 177: 1122-1127.
[21] Lv X Y, Xu X Y, Miao T, et al. Aggregation-induced electrochemiluminescence immunosensor based on 9, 10-diphenylanthracene cubic nanoparticles for ultrasensitive detection of aflatoxin B(1) [J]. ACS Applied Bio Materials, 2020, 3(12): 8933-8942.
[22] Bagheri P A, Mousavizadegan M, Hosseini M. Sensitive detection of S. Aureus using aptamer- and vancomycincopper nanoclusters as dual recognition strategy[J]. Food Chemistry, 2021, 361: 130137.
[23] Gregersen T. Rapid method for distinction of gram-negative from gram-positive bacteria[J]. European Journal of Applied Microbiology and Biotechnology, 1978, 5(2): 123-127.
[24] Sayed S M, Xu K F, Jia H R, et al. Naphthalimidebased multifunctional AIEgens: Selective, fast, and wash-free fluorescence tracking and identification of Gram-positive bacteria[J]. Analytica Chimica Acta, 2021, 1146: 41-52.
[25] Fahimi-Kashani N, Hormozi-Nezhad M R. Goldnanoparticle-based colorimetric sensor array for discrimination of organophosphate pesticides[J]. Analytical Chemistry, 2016, 88(16): 8099-8106.
[26] Zhang S, Ma L, Ma K, et al. Label-free aptamer-based biosensor for specific detection of chloramphenicol using AIE probe and graphene oxide[J]. ACS Omega, 2018, 3(10): 12886-12892.
[27] Baynes R E, Dedonder K, Kissell L, et al. Health concerns and management of select veterinary drug residues [J]. Food and Chemical Toxicology, 2016, 88: 112-122.
[28] Fahimi-Kashani N, Hormozi-Nezhad M R. Goldnanoparticle-based colorimetric sensor array for discrimination of organophosphate pesticides[J]. Analytical Chemistry, 2016, 88(16): 8099-8106.
[29] Yu L, Chen H X, Yue J, et al. Metal-organic framework enhances aggregation-induced fluorescence of chlortetracycline and the application for detection[J]. Analytical Chemistry, 2019, 91(9): 5913-5921.
[30] Zhang Y, Lv M, Gao P F, et al. The synthesis of high bright silver nanoclusters with aggregation-induced emission for detection of tetracycline[J]. Sensors and Actuators B: Chemical, 2021, 326: 129009.
[31] Lin B X, Yu Y, Li R Y, et al. Turn-on sensor for quantification and imaging of acetamiprid residues based on quantum dots functionalized with aptamer[J]. Sensors and Actuators B: Chemical, 2016, 229: 100-109.
[32] Li S H, Ma X H, Pang C H, et al. Novel chloramphenicol sensor based on aggregation-induced electrochemiluminescence and nanozyme amplification[J]. Biosensors & Bioelectronics, 2021, 176: 112944.
[33] Ma J, Xiao Y, Zhang C H, et al. Preparation a novel pyrene-based AIE-active ratiometric turn-on fluorescent probe for highly selective and sensitive detection of Hg2+[J]. Materials Science and Engineering: B, 2020, 259: 114582.
[34] Pathan S, Jalal M, Prasad S, et al. Aggregation-induced enhanced photoluminescence in magnetic graphene oxide quantum dots as a fluorescence probe for As(iii) sensing[J]. Journal of Materials Chemistry A, 2019, 7(14): 8510-8520.
[35] Shyamal M, Maity S, Maity A, et al. Aggregation induced emission based "turn-off" fluorescent chemosensor for selective and swift sensing of mercury (II) ions in water[J]. Sensors and Actuators B: Chemical, 2018, 263: 347-359.
[36] Li Y Y, Xu K, Si Y, et al. An aggregation-induced emission (AIE) fluorescent chemosensor for the detection of Al(III) in aqueous solution[J]. Dyes and Pigments, 2019, 171: 107682.
[37] Thaler S, Haritoglou C, Choragiewicz T J, et al. In vivo toxicity study of rhodamine 6G in the rat retina[J]. Investigative Ophthalmology & Visual Science, 2008, 49(5): 2120-2126.
[38] Li Y Y, He W Y, Peng Q C, et al. Aggregation-induced emission luminogen based molecularly imprinted ratiometric fluorescence sensor for the detection of Rhodamine 6G in food samples[J]. Food Chemistry, 2019, 287: 55-60.
[39] Wang D W, Wang Z Q, Wang X B, et al. Functionalized copper nanoclusters-based fluorescent probe with aggregation-induced emission property for selective detection of sulfide ions in food additives[J]. Journal of Agricultural and Food Chemistry, 2020, 68(40): 11301-11308.
[40] Yue X, Pan Q L, Zhou J, et al. A simplified fluorescent lateral flow assay for melamine based on aggregation induced emission of gold nanoclusters[J]. Food Chemistry, 2022, 385: 132670.
[41] Fletcher B, Mullane K, Platts P, et al. Advances in meat spoilage detection: A short focus on rapid methods and technologies[J]. CyTA - Journal of Food, 2018, 16(1): 1037-1044.
[42] Odeyemi O A, Alegbeleye O O, Strateva M, et al. Understanding spoilage microbial community and spoilage mechanisms in foods of animal origin[J]. Comprehensive Reviews in Food Science and Food Safety, 2020, 19(2): 311-331.
[43] Zhang Q, Yang L, Han Y, et al. A pH-sensitive ESIPT molecule with aggregation-induced emission and tunable solid-state fluorescence multicolor for anti-counterfeiting and food freshness detection[J]. Chemical Engineering Journal, 2022, 428: 130986.
[44] Arshad F, Sk M P. Aggregation-induced red shift in N, S-doped chiral carbon dot emissions for moisture sensing[J]. New Journal of Chemistry, 2019, 43(33): 13240- 13248.
[45] Xu L F, Ni L, Zeng F, et al. Tetranitrile-anthracene as a probe for fluorescence detection of viscosity in fluid drinks via aggregation-induced emission[J]. The Analyst, 2020, 145(3): 844-850.
[46] Duan Y A, Liu Y, Han H L, et al. A dual-channel indicator of fish spoilage based on a D-π-a luminogen serving as a smart label for intelligent food packaging[J]. Spectrochimica Acta Part A, Molecular and Biomolecular Spectroscopy, 2022, 266: 120433.
[47] Zhu J, Liu Z Q, Chen H, et al. Designing and developing biodegradable intelligent package used for monitoring spoilage seafood using aggregation-induced emission indicator[J]. LWT-Food Science and Technology, 2021, 151: 112135.
[48] Gao M, Li S W, Lin Y H, et al. Fluorescent light-up detection of amine vapors based on aggregation-induced emission[J]. ACS Sensors, 2016, 1(2): 179-184.
Options
Outlines

/

Contact

  • Add:No. 86 Xueyuan South Road, Haidian District, Beijing  Postal Code:100081
  • Tel: +86-10-62138113 Fax: +86-10-62138113
  • E-mail:kjdbbjb@cast.org.cn

    • Visited

      Total visitors:
      Visitors of today:
      Now online:
    Copyright © Science & Technology Review, All Rights Reserved.