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This research focused on using spent coffee grounds as a source of caffeine by ultrasound-assisted extraction technique. Two types of ultrasound techniques (ultrasonic bath and ultrasonic probe) were studied to extract caffeine. The effect of the sonication type sonication power, extraction time, and extraction temperature on the extraction efficiency was investigated. The results demonstrated that extraction by an ultrasonic probe is superior to ultrasonic bath extraction. The highest caffeine recovery was obtained at 55 °C by using an ultrasound bath where caffeine concentration was 795.74 mg/L after 60 min. The bioactivity of extracted caffeine was also studied and compared with the bioactive of standard caffeine against candida albicance yeast. The results showed that the minimum inhibition concentration for natural caffeine was 100 mg/L which is half of the minimum inhibition concentration of standard caffeine.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
126--133
Opis fizyczny
Bibliogr. 31 poz., rys., tab.
Twórcy
autor
- Department of Chemical Engineering, College of Engineering, University of Baghdad, Iraq
autor
- Department of Chemical Engineering, College of Engineering, University of Baghdad, Iraq
Bibliografia
- 1. Blinová L.,Bartošová A.,Sirotiak M. 2017. Biodiesel Production from Spent Coffee Grounds. Research Papers Faculty of Materials Science and Technology Slovak University of Technology, 25, 113–121.
- 2. Campos-Vega R., Loarca-Piña G., Vergara-Castañeda H.A., Dave Oomah B. 2015. Spent coffee grounds: A review on current research and future prospects. Trends in Food Science and Technology, 45, 24–36.
- 3. Ali M.M., Eisa M., Taha M.I., Zakaria B.A., Elbashir A.A. 2012. Determination of caffeine in some Sudanese beverages by High Performance Liquid Chromatography. Pakistan Journal of Nutrition, 11, 336–342. of Secondary Metabolite, 4, 78–78.
- 4. Soni M. 2019. Extraction and analysis of Caffeine from various brands of tea leaves marketed in India. ~ 119 ~ Journal of Pharmacognosy and Phytochemistry, 8, 119–120.
- 5. Grassia M., Salvatori G., Roberti M., Planeta D., Cinquanta L. 2019. Polyphenols, methylxanthines, fatty acids and minerals in cocoa beans and cocoa products. Journal of Food Measurement and Characterization, 13, 1721–1728.
- 6. Umeda U., Puyate Y.T., Happiness O. 2020. Extraction of Caffeine from Native Kola-nut ( cola acuminate ) using Swiss Water Process. Research Journal of Pure Science and Technology, 3, 42–50.
- 7. van Dam R.M., Hu F.B., Willett W.C. 2020. Coffee, Caffeine, and Health. New England Journal of Medicine, 383, 369–378.
- 8. Alsamarrai K.F. 2022. Simultaneous Ratio Derivative Spectrophotometric Determination of Paracetamol, Caffeine and Ibuprofen in Their Ternary Form. Baghdad Science Journal, 19, 1276–1285.
- 9. Monteiro J., Alves M.G., Oliveira P.F., Silva B.M. 2019. Pharmacological potential of methylxanthines: Retrospective analysis and future expectations. Critical Reviews in Food Science and Nutrition, 59, 2597–2625.
- 10. Grosso G., Godos J., Galvano F., Giovannucci E.L. 2017. Coffee, Caffeine, and Health Outcomes: An Umbrella Review. Annual Review of Nutrition, 37, 131–156.
- 11. Aaseth J., Dusek P., Roos P.M. 2018. Prevention of progression in Parkinson’s disease. BioMetals, 31, 737–747
- 12. Wolde T., 2014. Effects of caffeine on health and nutrition: A Review. Food Science and Quality Management, 30, 59–65.
- 13. Platritis P., Andreou E., Papandreou D. 2013. Caffeine effect on exercise performance and disease issues: An updated mini review. Nutrition and Food Science, 43, 243–253.
- 14. Bijelic R., Milicevic S., Balaban J. 2017. Risk Factors for Osteoporosis in Postmenopausal Women. Medical archives (Sarajevo, Bosnia and Herzegovina), 71, 25–28.
- 15. Erickson-Levendoski E., Sivasankar M. 2011. Investigating the effects of caffeine on phonation. Journal of Voice, 25, e215–e219.
- 16. O’callaghan F., Muurlink O., Reid N. 2018. Effects of caffeine on sleep quality and daytime functioning. Risk Management and Healthcare Policy, 11, 263–271.
- 17. Ali luma Q. 2019. Histological and Physiological Studies on the Long-term Effect of Different Concentrations of Energy Drink (Tiger) on the Renal and Hepatic Systems of Young Mice. Baghdad Science Journal, 16, 816–823.
- 18. Han B., Chen J., Yu Y.Q., Cao Y.B., Jiang Y.Y. 2016. Antifungal activity of Rubus chingii extract combined with fluconazole against fluconazole-resistant Candida albicans. Microbiology and Immunology, 60, 82–92.
- 19. Raut J.S., Chauhan N.M., Shinde R.B., Karuppayil S.M. 2013. Journal of Medicinal Plants Research Inhibition of planktonic and biofilm growth of Candida albicans reveals novel antifungal activity of caffeine, 7, 777–782.
- 20. Torres-Valenzuela L.S., Ballesteros-Gómez A., Sanin A., Rubio S. 2019. Valorization of spent coffee grounds by supramolecular solvent extraction. Separation and Purification Technology, 228, 115759.
- 21. Andrade K.S., Gonalvez R.T., Maraschin M., Ribeiro-Do-Valle R.M., Martínez J., Ferreira S.R. S. 2012. Supercritical fluid extraction from spent coffee grounds and coffee husks: Antioxidant activity and effect of operational variables on extract composition. Talanta, 88, 544–552.
- 22. Pavlović M.D., Buntić A.V., Šiler-Marinković S.S., Dimitrijević-Branković S.I. 2013. Ethanol influenced fast microwave-assisted extraction for natural antioxidants obtaining from spent filter coffee. Separation and Purification Technology, 118, 503–510.
- 23. Zhang Z., Poojary M.M., Choudhary A., Rai D.K., Lund M.N., Tiwari B.K. 2021. Ultrasound processing of coffee silver skin, brewer’s spent grain and potato peel wastes for phenolic compounds and amino acids: a comparative study. Journal of Food Science and Technology, 58, 2273–2282.
- 24. Lopes G.R., Passos C.P., Rodrigues C., Teixeira J.A., Coimbra M.A. 2020. Impact of microwave-assisted extraction on roasted coffee carbohydrates, caffeine, chlorogenic acids and coloured compounds. Food Research International, 129, 108864.
- 25. Ferreira A.M., Gomes H.M.D., Coutinho J.A.P., Freire M.G. 2021. Valorization of spent coffee by caffeine extraction using aqueous solutions of cholinium-based ionic liquids. Sustainability (Switzerland), 13.
- 26. Hasan A., Kurji B.M. 2018. Extraction of Oil from Eucalyptus Camadulensis Using Water Distillation Extraction of Oil from Eucalyptus Camadulensis Using Water Distillation Method. Iraqi Journal of Chemical and Petroleum Engineering, 14, 7–12.
- 27. Mohammed S.A.M., Hameed M.S. 2016. Extraction of 4-Nitrophenol from Aqueous Solutions using Bulk ionic Liquid Membranes. International Journal of Current Engineering and Technology, 6, 542–550.
- 28. Chemat F., Rombaut N., Sicaire A.G., Meullemiestre A., Fabiano-Tixier A.S., Abert-Vian M. 2017. Ultrasound assisted extraction of food and natural products. Mechanisms, techniques, combinations, protocols and applications. A review. Ultrasonics Sonochemistry, 34, 540–560.
- 29. Al-Yaqoobi A.M., Al-Rikabey M.N., Algharrawi K.H.R. 2021. Treatment of dairy wastewater by electrocoagulation and ultrasonic-assisted electrocoagulation methods. Environmental Engineering and Management Journal, 20, 949–957.
- 30. Santos H.M., Lodeiro C., Capelo-Martínez J.L. 2009. The Power of Ultrasound. Ultrasound in Chemistry: Analytical Applications, 1–16.
- 31. Mathur I., Shruthi S., Gandrakota K., Nisha K.J. 2021. Comparative evaluation of antifungal activity of green coffee and green tea extract against candida albicans: An in vitro study. World Journal of Dentistry, 12, 265–270.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-93420247-5238-4227-babd-e539b29978ec