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Sequential ultrasound-microwave assisted extraction as a green method to extract essential oil from Zataria multiflora | ||
Journal of Food and Bioprocess Engineering | ||
دوره 3، شماره 2، اسفند 2020، صفحه 101-109 اصل مقاله (919.89 K) | ||
نوع مقاله: Original research | ||
شناسه دیجیتال (DOI): 10.22059/jfabe.2020.308833.1064 | ||
نویسندگان | ||
Safoora Karimi؛ Shady Sharifzadeh؛ Habib Abbasi* | ||
Department of Chemical Engineering, Jundi-Shapur University of Technology, Dezful, Iran | ||
چکیده | ||
Sequential ultrasound-microwave associated extraction (SUMAE) is a combination of ultrasound waves and microwaves energies in which ultrasonic extraction is used as a pretreatment. It was performed to extract essential oil from Zataria multiflora. The extraction conditions were optimized by response surface methodology (RSM) and Central Composite Design (CCD). The antioxidant and antibacterial activities of the extracted essential oil were investigated. Moreover, the results were compared with microwave associated extraction (MAE) method in terms of process yield, chemical composition, antioxidant activity and environmental impacts. The results show that the optimal conditions were ultrasound power of 150W, microwave power of 800W, and extraction time of 12min. Under these conditions, the yield of the extracted essential oil was 0.812%, which was higher than that obtained by MAE method (0.6%). Regarding environmental impacts, the quantity of carbon dioxide emission was lower in case of SUMAE method (0.25kg) compared to MAE method (0.54kg). This is also true for energy consumptions, which were 0.3125kWh and 0.675kWh for performed SUMAE and MAE, respectively, at the same power level. Furthermore, antioxidant activity of essential oil extracted by SUMAE was higher than that of MAE. Generally, the SUMAE not only did not damage the antioxidant properties, but also improved it and had less environmental damage. Consequently, it can be introduced as a green and safe method for the extraction of essential oils from Zataria multiflora. | ||
کلیدواژهها | ||
Antioxidant activity؛ Environmental impact؛ Microwave associated extraction؛ Optimization | ||
مراجع | ||
Abd Rahim, E. N. A., Ismail, A., Omar, M. N., Rahmat, U. N., & Ahmad, W. A. N. W. (2018). GC-MS analysis of phytochemical compounds in Syzygium polyanthum leaves extracted using ultrasound-assisted method. Pharmacognosy Journal, 10(1), 110-119.
Alissandrakis, E., Daferera, D., Tarantilis, P., Polissiou, M., & Harizanis, P. (2003). Ultrasound-assisted extraction of volatile compounds from citrus flowers and citrus honey. Food Chemistry, 82(4), 575-582.
Asofiei, I., Calinescu, I., Trifan, A., David, I. G., & Gavrila, A. I. (2016). Microwave-assisted batch extraction of polyphenols from sea buckthorn leaves. Chemical Engineering Communications, 203(12), 1547-1553.
Basti, A. A., Gandomi, H., Noori, N., & Khanjari, A. (2016). Shirazi thyme (Zataria multiflora Boiss) Oils. In Essential Oils in Food Preservation, Flavor and Safety (pp. 731-736): Elsevier.
Brand-Williams, W., Cuvelier, M. E., & Berset, C. (1995). Use of a free radical method to evaluate antioxidant activity. LWT - Food Science and Technology, 28(1), 25-30.
Chemat, F., Lucchesi, M., Smadja, J., Favretto, L., Colnaghi, G., & Visinoni, F. (2006). Microwave accelerated steam distillation of essential oil from lavender: A rapid, clean and environmentally friendly approach. Analytica Chimica Acta, 555(1), 157-160.
Chen, Y., Gu, X., Huang, S.-q., Li, J., Wang, X., & Tang, J. (2010). Optimization of ultrasonic/microwave assisted extraction (UMAE) of polysaccharides from Inonotus obliquus and evaluation of its anti-tumor activities. International Journal of Biological Macromolecules, 46(4), 429-435.
Danh, L. T., Triet, N. D. A., Zhao, J., Mammucari, R., & Foster, N. (2012). Antioxidant activity, yield and chemical composition of lavender essential oil extracted by supercritical CO2. The Journal of Supercritical Fluids, 70, 27-34.
Drinić, Z., Pljevljakušić, D., Živković, J., Bigović, D., & Šavikin, K. (2020). Microwave-assisted extraction of O. vulgare L. spp. hirtum essential oil: Comparison with conventional hydro-distillation. Food and Bioproducts Processing, 120, 158-165.
El Asbahani, A., Miladi, K., Badri, W., Sala, M., Addi, E. A., Casabianca, H., . . . Renaud, F. (2015). Essential oils: from extraction to encapsulation. International journal of pharmaceutics, 483(1-2), 220-243.
Farhat, A., Benmoussa, H., Bachoual, R., Nasfi, Z., Elfalleh, W., Romdhane, M., . . . Processing, B. (2017). Efficiency of the optimized microwave assisted extractions on the yield, chemical composition and biological activities of Tunisian Rosmarinus officinalis L. essential oil. Food and Bioproducts Processing, 105, 224-233.
Garcia-Vaquero, M., Ummat, V., Tiwari, B., & Rajauria, G. (2020). Exploring ultrasound, microwave and ultrasound–microwave assisted extraction technologies to increase the extraction of bioactive compounds and antioxidants from brown macroalgae. Marine Drugs, 18(3), 172.
Gavahian, M., Farahnaky, A., Majzoobi, M., Javidnia, K., Saharkhiz, M. J., & Mesbahi, G. (2011). Ohmic‐assisted hydrodistillation of essential oils from Zataria multiflora Boiss (Shirazi thyme). International Journal of Food Science & Technology, 46(12), 2619-2627.
Gfrerer, M., & Lankmayr, E. (2005). Screening, optimization and validation of microwave-assisted extraction for the determination of persistent organochlorine pesticides. Analytica Chimica Acta, 533(2), 203-211.
Gharibzahedi, S. M. T., Smith, B., & Guo, Y. (2019). Ultrasound-microwave assisted extraction of pectin from fig (Ficus carica L.) skin: Optimization, characterization and bioactivity. Carbohydrate polymers, 222, 114992.
Golmakani, M. T., & Rezaei, K. (2008). Microwave‐assisted hydrodistillation of essential oil from Zataria multiflora Boiss. European Journal of Lipid Science and Technology, 110(5), 448-454.
Guandalini, B. B. V., Rodrigues, N. P., & Marczak, L. D. F. (2019). Sequential extraction of phenolics and pectin from mango peel assisted by ultrasound. Food Research International, 119, 455-461.
Guimarães, J. T., Silva, E. K., Ranadheera, C. S., Moraes, J., Raices, R. S., Silva, M. C., . . . Cruz, A. G. (2019). Effect of high-intensity ultrasound on the nutritional profile and volatile compounds of a prebiotic soursop whey beverage. Ultrasonics sonochemistry, 55, 157-164.
Hashemi, S. M. B., Khaneghah, A. M., Koubaa, M., Barba, F. J., Abedi, E., Niakousari, M., & Tavakoli, J. (2018). Extraction of essential oil from Aloysia citriodora Palau leaves using continuous and pulsed ultrasound: Kinetics, antioxidant activity and antimicrobial properties. Process Biochemistry, 65, 197-204.
Hassanein, H. D., El‐Gendy, A. E. N. G., Saleh, I. A., Hendawy, S. F., Elmissiry, M. M., Omer, E. A. (2020). Profiling of essential oil chemical composition of some Lamiaceae species extracted using conventional and microwave‐assisted hydrodistillation extraction methods via chemometrics tools. Flavour and Fragrance Journal, 35(3), 329-340.
J Mason, T., Chemat, F., & Vinatoru, M. (2011). The extraction of natural products using ultrasound or microwaves. Current Organic Chemistry, 15(2), 237-247.
Khajenoori, M., Asl, A. H., Hormozi, F., Eikani, M., & Bidgoli, H. N. (2009). Subcritical water extraction of essential oils from Zataria multiflora Boiss. Journal of Food Process Engineering, 32(6), 804-816.
Khalili, G., Mazloomifar, A., Larijani, K., Tehrani, M. S., & Azar, P. A. (2018). Solvent-free microwave extraction of essential oils from Thymus vulgaris L. and Melissa officinalis L.. Industrial Crops and Products, 119, 214-217.
Kohari, Y., Yamashita, S., Chiou, T.-Y., Shimotori, Y., Ohtsu, N., Nagata, Y., & Murata, M. (2020). Hydrodistillation by solvent-free microwave extraction of fresh Japanese peppermint (Mentha arvensis L.). Journal of Essential Oil Bearing Plants, 23(1), 77-84.
Kratchanova, M., Pavlova, E., & Panchev, I. (2004). The effect of microwave heating of fresh orange peels on the fruit tissue and quality of extracted pectin. Carbohydrate polymers, 56(2), 181-185.
Lianfu, Z., & Zelong, L. (2008). Optimization and comparison of ultrasound/microwave assisted extraction (UMAE) and ultrasonic assisted extraction (UAE) of lycopene from tomatoes. Ultrasonics Sonochemistry, 15(5), 731-737.
Liu, S., Shi, X., Xu, L., & Yi, Y. (2016). Optimization of pectin extraction and antioxidant activities from Jerusalem artichoke. Chinese journal of oceanology and limnology, 34(2), 372-381.
Lu, X., Zheng, Z., Li, H., Cao, R., Zheng, Y., Yu, H., . . . Zheng, B. (2017). Optimization of ultrasonic-microwave assisted extraction of oligosaccharides from lotus (Nelumbo nucifera Gaertn.) seeds. Industrial Crops and Products, 107, 546-557.
Lucchesi, M. E., Chemat, F., & Smadja, J. (2004). Solvent-free microwave extraction of essential oil from aromatic herbs: comparison with conventional hydro-distillation. Journal of Chromatography A, 1043(2), 323-327.
Luque-Garcıa, J., & De Castro, M. D. L. (2003). Ultrasound: a powerful tool for leaching. TrAC Trends in Analytical Chemistry, 22(1), 41-47.
Maran, J. P., & Priya, B. (2015). Ultrasound-assisted extraction of pectin from sisal waste. Carbohydrate Polymers, 115, 732-738.
Marić, M., Grassino, A. N., Zhu, Z., Barba, F. J., Brnčić, M., Brnčić, S. R. (2018). An overview of the traditional and innovative approaches for pectin extraction from plant food wastes and by-products: Ultrasound-, microwaves-, and enzyme-assisted extraction. Trends in Food Science & Technology, 76, 28-37.
Memar, M. Y., Raei, P., Alizadeh, N., Aghdam, M. A., & Kafil, H. S. (2017). Carvacrol and thymol: strong antimicrobial agents against resistant isolates. Reviews in Medical Microbiology, 28(2), 63-68.
Molyneux, P. (2004). The use of the stable free radical diphenylpicrylhydrazyl (DPPH) for estimating antioxidant activity. Songklanakarin Journal of Science and Technology, 26(2), 211-219.
Morales, R. (2002). The history, botany and taxonomy of the genus Thymus. Thyme: the genus Thymus, 1, 1-43.
Morsy, N. F. S. (2015). A short extraction time of high quality hydrodistilled cardamom (Elettaria cardamomum L. Maton) essential oil using ultrasound as a pretreatment. Industrial Crops and Products, 65, 287-292.
Mosayebi, V., & Tabatabaei Yazdi, F. (2018). Optimization of microwave assisted extraction (MAE) of pectin from black mulberry (Morus nigra L.) pomace, Journal of Food and Bioprocess Engineering. 1(1), 57-66.
Pasandide, B., khodaiyan, F., Mousavi, Z., & Hosseini, S. S. (2018). A Box-Behnken experimental design for microwave assisted extraction optimization of pectin from citron peel. Journal of Food and Bioprocess Engineering, 1(2), 149-156.
Rahimi, V., Hekmatimoghaddam, S., Jebali, A., Khalili Sadrabad, E., Akrami Mohajeri, F. (2019). Chemical composition and antifungal activity of essential oil of Zataria multiflora. Journal of Nutrition and Food Security, 4(1), 1-6.
Sajed, H., Sahebkar, A., & Iranshahi, M. (2013). Zataria multiflora Boiss.(Shirazi thyme)—an ancient condiment with modern pharmaceutical uses. Journal of ethnopharmacology, 145(3), 686-698.
Stahl-Biskup, E. (2002). Essential oil chemistry of the genus Thymus–a global view. Thyme: the genus Thymus, 75-124.
Vinatoru, M. (2001). An overview of the ultrasonically assisted extraction of bioactive principles from herbs. Ultrasonics sonochemistry, 8(3), 303-313.
Wang, X., Peng, M.-J., Wang, Z.-H., Yang, Q.-L., & Peng, S. (2020). Ultrasound-microwave assisted extraction of flavonoid compounds from Eucommia ulmoides leaves and an evaluation of their antioxidant and antibacterial activities. Archives of Biological Sciences, (00), 15-15.
Wang, Y., Li, R., Jiang, Z.-T., Tan, J., Tang, S.-H., Li, T.-T., . . . Li, J.-T. (2018). Green and solvent-free simultaneous ultrasonic-microwave assisted extraction of essential oil from white and black peppers. Industrial Crops and Products, 114, 164-172.
Wen, C., Zhang, J., Zhang, H., Dzah, C. S., Zandile, M., Duan, Y., . . . Luo, X. (2018). Advances in ultrasound assisted extraction of bioactive compounds from cash crops–A review. Ultrasonics sonochemistry, 48, 538-549.
Yang, J.-S., Mu, T.-H., & Ma, M.-M. (2019). Optimization of ultrasound-microwave assisted acid extraction of pectin from potato pulp by response surface methodology and its characterization. Food chemistry, 289, 351-359.
Zhao, G., Li, T., Qu, X., Zhang, N., Lu, M., & Wang, J. (2017). Optimization of ultrasound-assisted extraction of indigo and indirubin from Isatis indigotica Fort. and their antioxidant capacities. Food Science and Biotechnology, 26(5), 1313-1323.
Zhao, L., Dong, Y., Chen, G., & Hu, Q. (2010). Extraction, purification, characterization and antitumor activity of polysaccharides from Ganoderma lucidum. Carbohydrate polymers, 80(3), 783-789.
Zheng, X., Fangping, Y., Chenghai, L., & Xiangwen, X. U. (2011). Effect of process parameters of microwave assisted extraction (MAE) on polysaccharides yield from pumpkin. Journal of Northeast Agricultural University (English Edition), 18(2), 79-86.
Živković, J., Šavikin, K., Janković, T., Ćujić, N., Menković, N. (2018). Optimization of ultrasound-assisted extraction of polyphenolic compounds from pomegranate peel using response surface methodology. Separation and Purification Technology, 194, 40-47. | ||
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