Dextran production is conducted by fermentation by using Leuconostoc mesenteriodes wich produces dextransucrase enzyme.Sucrose is converted to dextran by dextransucrase. Sucrose is a main carbon source in dextran fermentation. Hence, sugar cane juice mainly contains sucrose is potential material for dextran fermentation. The effect of inoculum concentration added at the beginning of fermentation of di-potassium hydrogen phosphate concentration in the medium were studied. L.mesenteroides B-512F was used. The results showed that there were no effect on optimum growth and dextran production when the inoculum concentration added at 1% and 5%(w/v). The only difference was inoculum at 1% (w/v) delaying the growth and dextran formation in comparison to the addition of 5%(w/v) inoculum. The optimum growth and dextran production were affected by di-potassium hydrogen phosphate concentration in the medium (0,5, 1,0 and 1,5% w/v).The growth was highest at di-potassium hydrogen phosphate concentration 1,5 % w/v. On the otherhand, dextran production was lower compared to the other treatments.

Dekstran/dextran, fermentasi/fermentation, inokulum/inoculum, di-kalium hidrogen fosfat/di-potassium hydrogen phosphate.

Alsop RM. 1983. Industrial production of dextrans. Dalam: Bushell ME (Ed.), Progress Industrial Microbiology Vol. 18 (Microbial Polysaccharides). Elsevier, Amsterdam, Him 1-43.

Barker PE and NJ Ajongwen. 1990. The production of the enzyme dextransucrase using nonaerated fermentation techniques. Biotechnology and Bio engineering 37, 703-707.

Barker CZ, AA Brooks, RZ Greenly and JM Henis. 1992. Encapsulation of biological material in non-ionic polymer beads. US Patent No.05089407.

Dols M, W Chraibi, MR Simeon, ND Lindley and PF Monsan. 1997. Growth and energetics of Leuconostoc mesenteroides NRRL B 1299 during metabolism of various sugars and their consequences for dextransucrase production. Applied and Enviromental Microbiology 63 (6), 2159-2165.

ICUMSA, 1994. Report of Proceeding of the 21th Session International Commision for Uniform Methods of Sugar Analysis.

Keniry JS, Lee JB and VC Mahoney, 1969. Improvements in the dextran assay of cane sugar materials. International Sugar Journal 71,131-135.

Kobayashi M, I Yokoyama and K Matsuda, 1985. Effectors differency modulating the dextransucrase activity of Leuconostoc mesenteroides. Agricultur Biological Chemistry 52 (12):3169-3171.

LandonRS,fflHudson,WKramerandCWebb. 1993. A model of dextransucrase synthesis by Leuconostoc mesenteroides. Trans Ichem E 72 Part C - December, 209-215.

Landon RS and C Webb. 1990. Separating enzyme (dextransucrase) production and product (dextran) synthesis within a traditional fermentation process. Process Biochemistry - February, 19-23.

Michelena G, A Martinez, A Bel and O. Almazan. 1999. Technological optimization of dextransucrase enzyme production. Proc. ISSCT Congress, New Delhi, India, Co-P6,408-414.

Shamala TR and Prasad MS. 1995. Preliminary studies on the production of high and low viscosity dextran by Leuconostoc spp. Process Biochemistry 30(3), 237-241.

Triantarti and JP Dufour. 1998. Dextran formation and effect of Maillard Reaction Product in relation with medium viscosity during fermentation of Leuconostoc mesenteroides ATCC 10830. Master Thesis. University of Otago, Dunedin, New Zealand.

Triantarti dan H Santoso. 2002. Nira tebu sebagai medium fermentasi untuk produksi dekstran. Prosiding Seminar Naional Kimia IV. Institut Teknologi Sepuluh November. Surabaya. Him 193-197.

Yamaoka T, M Kuroda, YTabata and Y Ikada. 1995. Body distribution of dextran derivatives with electric charges after intravenous administration. International Journal of Pharmaceutics (Netherland) 113(16), 149-157.