Growth optimization of Saccharomyces cerevisiae and Rhizopus oligosporus during fermentation to produce tempeh with high ?-glucan content
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Abstract. Rizal S, Murhadi, Kustyawati ME, Hasanudin U. 2020. Growth optimization of Saccharomyces cerevisiae and Rhizopus oligosporus during fermentation to produce tempeh with high ?-glucan content. Biodiversitas 21: 2667-2673. Saccharomyces cerevisiae grows and produces ?-glucan during fermentation in tempeh production. The content of ?-glucan in tempeh is influenced by the growth of S. cerevisiae throughout fermentation. The purpose of this study was to determine the effects of different types and concentrations of carbon sources on yeast growth, fungi growth, and ?-glucan content in tempeh inoculated using Rhizopus oligosporus and S. cerevisiae. This study used a Factorial Randomized Complete Block Design (RCBD) with two factors and three replications. The first factor was the types of carbon sources, tapioca and wheat flour; the second factor was the concentrations of carbon source, 0.0%, 2.5%, 5.0%, 7.5% and 10.0% (w/w). Tempeh produced was investigated for yeast number, fungi number, ?-glucan content, and pH value. The obtained data were tested using Tukey's Honestly Significance Difference (HSD) test. The results showed that the addition of various types and concentrations of carbon source significantly influenced the increase in yeast number, fungi number, ?-glucan content, and pH in tempeh. The growth of yeast, fungi, and ?-glucan content increased along with the increment of carbon source concentration. The amounts of yeast, fungi, and ?-glucans in tempeh added with tapioca were higher compared to tempeh with wheat flour. The addition of 10% tapioca produced the highest amount of yeast with 9.505 Log CFU/g and the highest ?-glucan content with 0.707% (w/w).
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References
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Varelas, V., P. Tataridis, M. Liouni, dan E. T. Nerantzis.2016.Application ofdifferent methods for the extraction of yeastß-glucan.. e-Journal of Scien ceand Technology (e-JST).2(1) : 75-81
Wang, H.L., Ruttle, D.I. dan Hesseltine, W.2012. Protein quality of wheat and soybeans after Rhizopus oligosporus fermentation. The Journal of Nutrition 20(1): 109-114.
Widyastuti, N., T. Baruji., R. Giarni., H. Isnawan., P.Wahyudi., dan Donawati. 2011. Analysis of Beta-glucan Content Soluble in Water and Alkali from Oyster Mushroom (Pleurotus ostreatus) and Shiitake (Lentinus edodes) Body. Jurnal Sains dan Teknologi. 13 (3): 182-191.
Astuti, S. 2008. Soybean Isoflavone and Its Potentially as Scavenger Free Radicals. Jurnal Teknologi Industri dan Hasil Pertanian. 13 (2): 126-136.
Azizah, N., A.N. Al-Baarri & S. Mulyani. 2012. Effect of Fermentation Time on Alcohol Content, pH, and Gas Production on the Bioethanol Fermentation Process of Whey with Pineapple Skin Substitution. Jurnal Aplikasi Teknologi Pangan. 1 (2): 72-77.
Halimatuddahliana. 2004. Pembuatan Bioetanol Dari Berbagai Proses. Universitas Sumatera Utara. Digital Library.
Hetland, G., E. Johnson, D.M. Eide, B. Grinde, A.B.C. Samuelsen, and H. G. Wiker. 2013. Antimicrobial effects of ß-glucan and pectin and of thec Agaricus blazei Based Mushroom Extract, AndoSan T. Examples of Mouse Models for Pneumococcal, Fecal Bacterial, and Mycobacterial Infections. Microbial Pathogens and Strategies for Combating Them. Science, Technology and Education (A. Méndez-Vilas, Ed.). Formatex. 889-898.
Kobayasi S, Okazaki N, Koseki T. 1992. Purification and characterization of an antibiotic substance produced from Rhizopus oligosporus IFO 8631. Biosci Biotechnol Biochem. 56:94-98.
Kusmiati., F. Rachmawati, S. Siregar, S. Nuswantara, dan A. Malik. 2006. Production of beta-1,3 glucan from Agrobacterium and its wound healing activity on white rat. MAKARA, SAINS. 10(1): 24-29
Kusmiati., S. R. Tamat., E. Jusuf., R. Istiningsih. 2007. ?eta-Glucan Production from Two Strains of Agrobacterium sp in Medium Containing of Molases and Uracil Combine. Jurnal Biodiversitas.8(1) 123-129.
Kustyawati, M.E. 2009. Study on the Role of Yeast in Tempe Production. Journal of. Agritech 29 (2) 64-70.
Kustyawati, M.E., M. Sari, dan T. Haryati. 2013. Effect of Fermentation Using Saccharomyces cerevisiae on the Biochemical Properties Tapioca. Jurnal Agritech 33 (3) : 281-287.
Kustyawati, M.E., O. Nawansih, dan S. Nurdjannah. 2016. Profile of Aroma Compounds and Acceptability of Modified Tempeh. International Food Research Journal 24 (2) : 734-740.
Lee, J.N. 2001. Purification of Soluble ß-Glucan with Immuno-Enhancing activity from The Cell Wall of Yeast. Bioschi. Biotechnol. Biochemical 65: 837-841.
Melliawati, R., Rohmatussolihat dan F. Octavina. 2006. Selection of potential microorganism for sago starch fermentation. Biodiverisitas. Vol. 7, No. 2, hal. 101-104.
Muchtadi, D. 2010. Kedelai Komponen untuk Kesehatan. Alfabeta. Bandung
Pengkumsri, N., B.S. Sivamaruthi, S. Sirilun, S. Peerajan, P. Kesika, K. Chaiyasut, C.t Chaiyasut. 2017. Extraction of B-Glucan From Saccharomyces cerevisiae: Comparison of Different Extraction Methods and In Vivo Assessment of Immunomodulatory Effect in Mice. Journal of Food Sci. Technol, Campinas, 37 (1): 124-130. ISSN 0101-2061.
Pratiwi, L.D. 2018. Study of Microorganism Growth Kinetics and ?-glucan Content During Tempe Fermentation with the addition of Saccharomyces cerevisiae. Thesis. University of Lampung. Bandar Lampung.
Rizal, S., M.E. Kustyawati, Murhadi, U. Hasanudin dan Marniza. 2018. Pengaruh konsentrasi Saccharomyces cerevisiae pada kandungan abu, protein, lemak dan beta-Glucan Tempe. Proceeding of National Seminar in Sebelas Maret University. 2 (1): 96-103.
Samson, R.A., V. Kooij, dan E. deBoer. 1987. Microbiological Quality of Commercial Tempeh in The Netherlands. Journal of Food Protection. 50: 92 94.
Setiarto, R.H.B., N. Widhyastuti dan I. Saskiawan. 2016. Effect of Lactic Acid Bacteria, Fungi and Yeast Fermentation on Nutritional Quality of Sorghum Flour. Agritech, Vol. 36, No. 4, Hal. 440-449
Soka S, A. Suwanto, D. Sajuthi, dan I. Rusmana. 2014. Impact of Tempeh Supplementation on Gut Microbiota Composition in Sprague-Dawley Rats. Research Journal of Microbiology 9 (4) : 189-198.
Shokri, H., F. Asadi, andA. R. Khosravi. 2008. Isolation of ß-glukan from The Cell Wall of Saccharomyces cerevisiae. Natural Product Research.22 (5) :414-421. DOI : 10.1080/14786410701591622
Suprihatin. 2010. Teknologi Fermentasi. UNESA Pres. Surabaya.
Varelas, V., P. Tataridis, M. Liouni, dan E. T. Nerantzis.2016.Application ofdifferent methods for the extraction of yeastß-glucan.. e-Journal of Scien ceand Technology (e-JST).2(1) : 75-81
Wang, H.L., Ruttle, D.I. dan Hesseltine, W.2012. Protein quality of wheat and soybeans after Rhizopus oligosporus fermentation. The Journal of Nutrition 20(1): 109-114.
Widyastuti, N., T. Baruji., R. Giarni., H. Isnawan., P.Wahyudi., dan Donawati. 2011. Analysis of Beta-glucan Content Soluble in Water and Alkali from Oyster Mushroom (Pleurotus ostreatus) and Shiitake (Lentinus edodes) Body. Jurnal Sains dan Teknologi. 13 (3): 182-191.
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