Sains Malaysiana 53(4)(2024): 851-868

http://doi.org/10.17576/jsm-2024-5304-10

 

A Vortex-Assisted Deep Eutectic Solvent for Parabens Extraction in Cosmetic Samples Coupled with High Performance Liquid Chromatography

(Pelarut Eutektik Dalam Berbantu Vortex untuk Pengekstrakan Paraben dalam Sampel Kosmetik Digandingkan dengan Kromatografi Cecair Berprestasi Tinggi)

 

NURIN FARAWANI BINTI MUHAMAD YUSRI, NOORASHIKIN BINTI MD SALEH*, TANUSHA DEVI A/P ELAN SOLAN & MUHAMMAD ZULHAZIMAN MAT SALLEH

 

Department of Chemical and Process Engineering, Faculty of Engineering and Built Environment, Universiti Kebangsaan Malaysia, 43600 UKM Bangi, Selangor, Malaysia

 

Diserahkan: 8 Januari2023/Diterima: 13 Mac 2024

 

Abstract

Parabens, commonly used preservatives in food, cosmetics, and pharmaceutical items, inhibit harmful germ growth. Deep Eutectic Solvents (DES) are intriguing for analyte extraction due to superior properties formed through hydrogen bond acceptors and donor interactions. However, the studies on the optimal DES-based extraction conditions for paraben-containing cosmetics and the accuracy of 'paraben-free' labels are limited. The most effective DES (DL-Menthol and decanoic acid, 1:2 molar ratio) was applied to cosmetic samples after heating at 80 °C following optimization parameters. FTIR study confirmed hydrogen bonds in DES samples. Both paraben-containing and paraben-free samples showed methyl, ethyl, and propyl paraben peaks from the HPLC analysis. Cosmetic sample paraben concentrations ranged from 0.53 mg/L to 26.08 mg/L (non-spiked). LOD and LOQ were 0.24 mg/L-1.62 mg/L, 0.73 mg/L, and 4.8 mg/L, respectively. Goals were met by establishing a paraben extraction method using DES and investigating paraben quantities in cosmetics.

 

Keywords: Cosmetic; deep eutectic solvent; high performance liquid chromatography; paraben; vortex

 

Abstrak

Paraben, bahan pengawet yang biasa digunakan dalam makanan, kosmetik dan bahan farmaseutikal, merencat pertumbuhan kuman berbahaya. Pelarut Eutektik (DES) menarik minat untuk pengekstrakan analit kerana sifat unggul yang terbentuk melalui interaksi penerima dan penderma ikatan hidrogen. Namun, kajian pengekstrakan menggunakan DES yang optimum untuk kosmetik mengandungi paraben dan ketepatan label 'bebas paraben' masih terhad. DES yang paling berkesan (DL-Menthol dan asid dekanoik, nisbah molar 1:2) digunakan pada sampel kosmetik selepas dipanaskan pada 80 °C mengikut pengoptimuman parameter. Kajian FTIR mengesahkan kewujudan ikatan hidrogen dalam sampel DES. Analisis HPLC menunjukkan puncak metil, etil dan propil paraben sama ada sampel mengandungi paraben atau bebas paraben. Kepekatan paraben dalam sampel kosmetik adalah dalam julat 0.53 mg/L hingga 26.08 mg/L (tidak disuntik dengan paraben). LOD dan LOQ masing-masing adalah 0.24 mg/L-1.62 mg/L, 0.73 mg/L, dan 4.8 mg/L. Matlamat telah tercapai dengan membentuk kaedah pengekstrakan paraben yang berkesan menggunakan DES dan mengkaji kuantiti paraben dalam kosmetik.

 

Kata kunci: Kosmetik; kromatografi cecair berprestasi tinggi; paraben; pelarut eutektik; vortex

 

RUJUKAN

Antakli, S., Kabani, R. & Shawa, D. 2013. Determination of preservative parabens in oral and injection formulations by HPLC. Asian Journal of Chemistry 25(2): 1123-1128.

Ariffin, M.M., Sohaimi, N.M., Yih, B.S. & Saleh, N.M. 2019. Magnetite nanoparticles coated with surfactant Sylgard 309 and its application as an adsorbent for paraben extraction from pharmaceutical and water samples. Analytical Methods 11(32): 4126-4136.

Bazmandegan-Shamili, A., Dadfarnia, S., Shabani, A.M.H., Moghadam, M.R. & Saeidi, M. 2018. Temperature-controlled liquid-liquid microextraction combined with high-performance liquid chromatography for the simultaneous determination of diazinon and fenitrothion in water and fruit juice samples. Journal of Separation Science 41(11): 2411-2418.

Beh, S.Y., Mahfut, I.W.B.D., Juber, N.I.B.M., Asman, S., Yusoff, F. & Saleh, N.M. 2021. Extraction of parabens from cosmetic and environmental water samples coupled with UV-visible spectroscopy. Journal of Applied Spectroscopy 87: 1216-1223.

Dalmaz, A. & Özak, S.S. 2022. DES-based vortex-assisted liquid-liquid microextraction procedure developed for the determination of paraben preservatives in mouthwashes. Microchemical Journal 179: 107445.

Dwamena, A.K. 2019. Recent advances in hydrophobic deep eutectic solvents for extraction. Separations 6(1): 9.

El-Deen, A.K. & Shimizu, K. 2021. Deep eutectic solvents as promising green solvents in dispersive liquid-liquid microextraction based on solidification of floating organic droplet: Recent applications, challenges and future perspectives. Molecules 26(23): 7406.

FDA. 2022. Parabens in Cosmetics | FDA.

Florindo, C., Branco, L.C. & Marrucho, I.M. 2019. Quest for green-solvent design: From hydrophilic to hydrophobic (Deep) eutectic solvents. ChemSusChem 12(8): 1549-1559.

Florindo, C., Branco, L.C. & Marrucho, I.M. 2017. Development of hydrophobic deep eutectic solvents for extraction of pesticides from aqueous environments. Fluid Phase Equilibria 448: 135-142.

Ge, D., Gao, Y., Cao, Y., Dai, E. & Yuan, L. 2020. Preparation of a new polymeric deep eutectic solvent and its application in vortex-assisted liquid-liquid microextraction of parabens in foods, cosmetics and pharmaceutical products. Journal of the Brazilian Chemical Society 31(10): 2120-2128.

Ge, D., Wang, Y., Jiang, Q. & Dai, E. 2019. A deep eutectic solvent as an extraction solvent to separate and preconcentrate parabens in water samples using in situ liquid-liquid microextraction. Journal of the Brazilian Chemical Society 30(6): 1203-1210.

Gosens, I., Delmaar, C.J.E., Ter Burg, W., De Heer, C. & Schuur, A.G. 2013. Aggregate exposure approaches for parabens in personal care products: A case assessment for children between 0 and 3 years old. Journal of Exposure Science & Environmental Epidemiology 24(2): 208-214.

Hikmawanti, N.P.E., Ramadon, D., Jantan, I. & Mun’im, A. 2021. Natural deep eutectic solvents (NADES): Phytochemical extraction performance enhancer for pharmaceutical and nutraceutical product development. Plants 10(10): 2091.

Jala, A., Dutta, R., Josyula, J.V.N., Mutheneni, S.R. & Borkar, R.M. 2023. Environmental phenol exposure associates with urine metabolome alteration in young Northeast Indian females. Chemosphere 317: 137830.

Kolesov, B.A. 2021. Hydrogen bonds: Raman spectroscopic study. International Journal of Molecular Sciences 22(10): 5380.

Li, T., Song, Y., Li, J., Zhang, M., Shi, Y. & Fan, J. 2020. New low viscous hydrophobic deep eutectic solvents in vortex-assisted liquid-liquid microextraction for the determination of phthalate esters from food-contacted plastics. Food Chemistry 309: 125752.

Mishra, R.K., Mentha, S.S., Misra, Y. & Dwivedi, N. 2023. Emerging pollutants of severe environmental concern in water and wastewater: A comprehensive review on current developments and future research. Water-Energy Nexus 6: 74-95.

Özak, S.S. 2020. A vortex-assisted microextraction based on deep eutectic solvents for determination of four parabens from cosmetic baby oils and optimization by Box-Behnken design. Duzce University Journal of Science and Technology 8(3): 1936-1947.

Polaka, S., Gomte, S.S., Pandey, V., Tella, J.D., Tekade, M., Sharma, M.C., Molugulu, N. & Tekade, R.K. 2022. Pharmaceutical excipients: Special focus on adverse interactions. Pharmacokinetics and Toxicokinetic Considerations - Vol II: Advances in Pharmaceutical Product Development and Research, edited by Tekade, R.K. Massachusetts: Academic Press. pp. 513-542.

Razavi, N., Foroutan, F., Sahebian, S. & Khaki, J.V. 2022. Extraction and pre-concentration of parabens in liquid pharmaceutical samples by dispersive liquid-liquid microextraction based on deep eutectic solvent. Biomedical Chromatography 37(2): e5547.

Shah, D. & Mjalli, F.S. 2014. Effect of water on the thermo-physical properties of Reline: An experimental and molecular simulation based approach. Physical Chemistry Chemical Physics 16(43): 23900-23907.

Shamsuri, A. & Kuang, A. 2010. Ionic liquids: Preparations and limitations. MAKARA of Science Series 14(2): 101-106.

Sivrikaya, S. 2019. A novel vortex-assisted liquid phase microextraction method for parabens in cosmetic oil products using deep eutectic solvent. International Journal of Environmental Analytical Chemistry 99(15): 1575-1585.

Smith, E.L., Abbott, A.P. & Ryder, K.S. 2014. Deep eutectic solvents (DESs) and their applications. Chemical Reviews 114(21): 11060-11082.

Temova Rakuša, Ž., Škufca, P., Kristl, A. & Roškar, R. 2021. Retinoid stability and degradation kinetics in commercial cosmetic products. Journal of Cosmetic Dermatology 20(7): 2350-2358.

Yih, B.S., Sohaimi, N.M., Aziz, H.B.Z., Zaini, S.R.B.M., Suda, N.B., Kandasamy, S., Subramaniam, K.V.N., Bajuri, F.N.A.B. & Saleh, N.M. 2019. Development of cloud point extraction for parabens using different surfactants with modifiers. Materials Today: Proceedings 19: 1787-1795.

Yıldız, E. & Çabuk, H. 2018. Miniaturized matrix solid-phase dispersion coupled with supramolecular solvent-based microextraction for the determination of paraben preservatives in cream samples. Journal of Separation Science 41(13): 2750-2758.

 

*Pengarang untuk surat-menyurat; email: noorashikin@ukm.edu.my

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

   

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