 |
 |
 |
 |
 |
 |
Sains Malaysiana 50(4)(2021): 989-996
http://doi.org/10.17576/jsm-2021-5004-09
Colorimetric Amine
Detection by Vanillin-Hydrazone
Derivatives during Chicken Meat Spoilage
(Pengesanan Amina Colorimetrik
oleh Terbitan Vanilin-Hidrozon semasa Kerosakan Daging Ayam)
BAMBANG PURWONO1*, BETA ACHROMI NUROHMAH1 & SUHARMAN2
1Department of Chemistry,
Faculty of Mathematics and Natural Science, Universitas Gadjah Mada, Jalan Kaliurang Sekip
Utara Bulaksumur 21, Yogyakarta, 55281, Indonesia
2Department of Chemistry, Universitas Sumatera
Utara, Jalan T. Dr. Mansyur No. 9, Padang Bulan,
Medan Baru,
Medan, Sumatera Utara, 201555, Indonesia
Received: 10 June 2020/Accepted: 2 September 2020
ABSTRACT
Two
vanillin-hydrazone compounds as the colorimetric
amine detection during chicken meat spoilage are described. Two hydrazone compounds (1 and 2) have
been synthesized from the condensation reaction of vanillin with phenylhydrazine and 2,4-dinitrophenylhydrazine. Their
properties for colorimetric recognition of amine were determined by the naked
eye and UV-vis spectra. Their properties as amine indicators were investigated
toward primary amine: butylamine (BA); secondary amine: dimethylamine (DMA), diethylamine (DEA); tertiary amine: triethylamine (TEA),
and also ammonia (Amm). The hydrazone 1 in DMSO showed no significant
color changes (colorless) after the addition of amines solution. Hydrazone 2 (5×10-5 M in DMSO) showed color changes from yellow to violet in the
presence of ammonia, DEA and BA, to reddish-violet for DMA, and light brown
after addition of TEA solutions. The colorimetric amine detection by vanillin-hydrazone 2 could
recognize the real amine during chicken meat spoilage from yellow to light
brown after 24 h storage at room temperature.
Keywords:
Colorimetric; food spoilage; hydrazone; indicator
ABSTRAK
Dua sebatian vanilin-hidrazon sebagai pengesanan am kolorimetrik semasa kerosakan daging ayam dijelaskan. Dua sebatian hidrazon (1 dan 2) telah disintesis daripada tindak balas pemeluwapan vanilin dengan fenilhidrazin dan 2,4-dinitrofenilhidrina. Sifat mereka untuk pengecaman amina kolorimetrik ditentukan oleh mata kasar dan spektrum UV-vis. Sifat mereka sebagai petunjuk amina dikaji terhadap amina primer: butilamina (BA); amina sekunder: dimetilamina (DMA), dietilamina (DEA); amina tertier: trietilamina (TEA) dan juga amonia (Amm). Hidrazon 1 dalam DMSO tidak menunjukkan perubahan warna yang ketara (tidak berwarna) setelah penambahan larutan amina. Hidrazon 2 (5 × 10-5 M dalam DMSO) menunjukkan perubahan warna daripada kuning ke ungu dengan adanya amonia, DEA dan BA, menjadi ungu kemerahan untuk DMA dan coklat muda setelah penambahan larutan TEA. Pengesanan amina kolorimetrik oleh vanillin-hidrazon2 dapat mengenali amina sebenar semasa kerosakan daging ayam daripada kuning ke coklat muda setelah penyimpanan 24 jam pada suhu bilik.
Kata kunci: Hidrazon; kerosakan makanan; kolorimetrik; penunjuk
REFERENCES
Arulkumar, A., Karthik, G., Paramasivam, S. & Rabie, M.A. 2017. Histamine levels in Indian fish via enzymatic, TLC and HPLC
methods during storage. Journal of Food
Measurement and Characterization 11(1): 281-289.
Basavaraja, D., Dibyendu,
D., Varsha, T.L., Chettiyan, T.F., Manas, K.P. & Sasidhar, B.S.
2020. Rapid visual detection of amines by pyrylium salts for food spoilage taggant. ACS Applied Bio Materials 3: 772-778.
Bóka, B., Adányi, N., Virág, D., Sabela, M. & Kiss, A. 2012. Spoilage detection with
biogenic amine biosensors, comparison of different enzyme electrodes. Electroanalysis 24(1): 181-186.
Boruah,
B.S., Daimari, N.K. & Biswas, R. 2019.
Functionalized silver nanoparticles as an effective medium towards trace
determination of arsenic (III) in aqueous solution. Results in Physics 12: 2061-2065.
Brightwell, G.
& Clemens, R. 2012. Development and validation of a
real-time PCR assay specific for Clostridium estertheticum and C. estertheticum-like psychrotolerant bacteria. Meat Science 92(4): 697-703.
Chen,
X., Zhou, Y., Peng, X. & Yoon, J. 2010. Fluorescent and colorimetric probes
for detection of thiols. Chemical Society
Review 391(6): 2120-2135.
Duong, H.D. & Rhee,
J.I. 2014. A ratiometric fluorescence sensor
for the detection of ammonia in water. Sensors and Actuators B:
Chemical 190: 768-774.
Erande, Y., Chemate, S., More, A. & Sekar,
N. 2015. PET governed fluorescence “Turn ON” BODIPY probe for selective
detection of picric acid. RSC Advances 5(109): 89482-89487.
Fletcher,
B., Mullane, K., Platts, P., Todd, E., Power, A., Roberts, J., Chapman, J.,
Cozzolino, D. & Chandra, S. 2018. Advances in meat spoilage detection: A
short focus on rapid methods and technologies. CyTA - Journal of Food 16(1): 1037-1044.
Gao,
M., Li, S., Lin, Y., Geng, Y., Ling, X., Wang, L.,
Qin, A. & Tang, B.Z. 2016. Fluorescent light-up
detection of amine vapors based on aggregation-induced emission. ACS Sensors 1(2): 179-184.
Gribble, A.
& Brightwell, G. 2013. Spoilage characteristics of Brochothrix thermosphacta and campestris in chilled vacuum
packaged lamb, and their detection and identification by real time PCR. Meat Science 94(3): 361-368.
Janzen,
M.C., Ponder, J.B., Bailey, D.P., Ingison, C.K. & Suslick, K.S. 2006. Colorimetric
sensor arrays for volatile organic compounds. Analytical Chemistry 78(11): 3591-3600.
Li, Y., Li, J., Lin, H., Shao, J., Cai, Z.S. & Lin, H.
2010. A
novel colorimetric receptor responding AcO‒ anions based on an azo derivative in DMSO and DMSO/water solution. Journal of Luminescence 130(3): 466-472.
Naila, A.,
Flint, S., Fletcher, G., Bremer, P. & Meerdink,
G. 2010. Control of biogenic amines in food-existing and emerging approaches. Journal of Food and Science 75(7): 139-150.
Raudienė, E., Gailius, D., Vinauskienė,
R., Eisinaitė, V., Balčiūnas,
G., Dobilienė, J. & Tamkutė, L.
2018. Rapid evaluation of fresh chicken meat quality by electronic nose. Czech Journal of Food Science 36(5):
420-426.
Reid, R., Burgess, C.M., McCabe, E., Fanning, S., Whyte, P., Kerry, J. & Bolton, D. 2017. Real-time PCR methods for the detection of blown pack spoilage causing
Clostridium species; C. estertheticum, C. gasigenes and C. ruminantium. Meat Science 133: 56-60.
Rodriguez-Lazaro, D., Gonzalez-García, P., Delibato, E., De-Medici, D., García-Gimeno, R., Valero, A. & Hernandez, M. 2014. Next day Salmonella spp. detection method based on real-time PCR for meat, dairy and
vegetable food products. International
Journal of Food Microbiology 13(8): 113-120.
Ruiz-Capillas, C. & Herrero, A.M. 2019. Impact of biogenic
amines on food quality and safety. Foods 8(62): 1-16.
*Corresponding
author; email: purwono.bambang@ugm.ac.id
|
|||
|
