Hyaluronic acid (C14H21NO11)n is one of the drugs components, a natural polysaccharide compound that makes up connective tissue and is soluble in water. HA can be applied in cosmetic, biomedical, and food industries. The purpose of this study was to determine the feasibility of a hyaluronic acid manufacturing project through repeated batch fermentation using Streptococcus zooepidemicus and then evaluating from an engineering and economic perspective. Engineering analysis was analyzed based on the available tools and raw materials in online web. The economic analysis was done using several economic parameters, such as the length of time required for an investment to return the total initial expenditure (PBP), the condition of a production project in the form of a production function in years (CNPV), project benefits and so on. The results showed that the production of Hyaluronic Acid nanoparticles was very prospective. Technical analysis to produce 86.4 g/liter of HA nanoparticles per day shows the total cost of the equipment purchased to be 7,264.51 USD. PBP analysis shows that investment will be profitable after more than three years. This project can compete with PBP capital market standards because of the short investment returns. To ensure the feasibility of a project, the project is estimated from ideal conditions to the worst case in production, including labor, sales, raw materials, utilities, and external conditions. The analysis concluded that the present project for the production of Hyaluronic acid nanoparticles is prospective in small scale industry and profitable (by positive values in all economic parameters).

Bank Indonesia. (2021) Kurs transaksi bank Indonesia. [Online]. Available: https://www.bi.go.id/id/statistik/informasi-kurs/transaksi-bi/default.aspx

Bitter, T. (1962). A modified uronic acid carbazole reaction. Analytical Biochemistry, 4, 330-334.

Blank LM, McLaughlin RL, Nielsen LK. (2005). Stable production of hyaluronic acid in Streptococcus zooepidemicus chemostats operated at high dilution rate. Biotechnol Bioeng, 90:685-693.

Maharani, B.S., Yustia, I., Elia, S.H., Girsang, G.C.S., Nandiyanto, A.B.D., and Kurniawan, T. (2021). Review: Synthesis of hyaluronic acid as food supplement and drugs. Journal of Educational, Nutrition, and Culinary Media, 10(1).

Chen, S. J., Chen, J. L., Huang, W. C., and Chen, H. L. (2009). Fermentation process development for hyaluronic acid production by Streptococcus zooepidemicus ATCC 39920. Korean Journal of Chemical Engineering, 26(2), 428-432.

Cooney MJ, Goh LT, Lee PL, and MR. (1999). Structured model-based analysis and control of the hyaluronic acid fermentation by Streptococcus zooepidemicus: Physiological implications of glucose and complex nitrogen limited growth. Biotechnol Prog, 15:898-910.

Don MM and Shoparwe NF. (2010) Kinetics of hyaluronic acid production by Streptococcus zooepidemicus considering the effect of glucose. Biochem Eng J, 49:95-103.

Fong Chong B and Nielsen LK. (2003a). Aerobic cultivation of streptococcus zooepidemicus and the role of NADH oxidase. Biochem Eng J 16:153–162

Fong Chong B and Nielsen LK. (2003b). Amplifying the cellular reduction potential of Streptococcus zooepidemicus. J Biotechnol 100:33–41

Garrett, D. E. (2012). Chemical engineering economics. Springer Science & Business Media.

Huang, W. C., Chen, S. J., and Chen, T. L. (2008). Production of hyaluronic acid by repeated batch fermentation. Biochemical Engineering Journal, 40(3), 460-464.

Im JH, Song JM, Kang JH, and Kang DJ.(2009). Optimization of medium components for high molecular weight hyaluronic acid production by Streptococcus sp. ID9102 via a statistical approach. Journal Industrial Microbiol Biotechnol, 36:1337-1344

Johns MR, Goh LT, and Oeggerli A .(1994). Effect of pH, agitation and aeration on hyaluronic-acid production by StreptococcusZooepidemicus. Biotechnol Letters, 16:507–512

Kim JH, Yoo SJ, Oh DK, and Kweon YG. (1996) Selection of a Streptococcus equi mutant and optimization of culture conditions for the production of high molecular weight hyaluronic acid. Enzyme Microbial Technol 19:440–445

Liu, L., Du, G., Chen, J., Wang, M., and Sun, J. (2008). Enhanced hyaluronic acid production by a two-stage culture strategy based on the modeling of batch and fed-batch cultivation of Streptococcus zooepidemicus. Bioresource Technology, 99(17), 8532-8536.

Mausolf A, Jungmann J, Robenek H, and Prehm P. (1990.) Shedding of hyaluronate synthase from streptococci. Biochemical Journal, 267:191–196

Nandiyanto, A. B. D. (2018). Cost analysis and economic evaluation for the fabrication of activated carbon and silica particles from rice straw waste. Journal of Engineering Science and Technology, 13(6), 1523-1539.

van de Rijn I, and Kessler RE. (1980). Growth characteristics of group A streptococci in a new chemically defined medium. Infect Immun 27:444–448

Vázquez JA, Montemayor MI, Fraguas J, and Murado MA. (2010). Hyaluronic acid production by Streptococcus zooepidemicus in marine by-products media from mussel processing wastewaters and tuna peptone viscera. Microbial Cell Fact, 9:46