This study aims to evaluate the effect of C: N ratio level of shrimp feed on inorganic nitrogen
regeneration of shrimp feed using molasses as a source of organic carbon. This research was
conducted for two weeks, namely March 8 to March 20, 2021 in the laboratory.
Materials and tools used in this study include: plastic containers with a lid and a volume of 2
liters of water, aerated stones, aeration sources, sea water and molasses, shrimp feed, water
quality measurement equipment such as thermometers, pH meters, oxygen meters,
spectrophotometers and medium for bacterial growth. For the implementation of the
experiment, each experimental container used shrimp feed with a nitrogen content of 5.89%
weighing 0.1398 grams. The amount of feed used in each experimental container was
equivalent to 5 mg L-1 ammonia or 4.117 mg L-1 nitrogen. The treatments evaluated in this
experiment were: (1) Treatment without using molasses (MR0), (2) Treatment using molasses
with a ratio of C: N = 7.5 (MR7.5), (3) Treatment using molasses with a ratio of C: N = 15.0
(MR15.0), (4) Treatment using molasses with a ratio of C: N = 17.5 (MR17.5), (5) Treatment
using molasses with a ratio of C: N = 20.0 (MR20.0) and (6) The treatment used molasses with
a ratio of C: N = 22.5 (MR22.5).The experiment used a Completely Randomized Design (CRD)
with three replications and the data were analyzed using variance and regression analysis.
Furthermore, comparing the average value of each treatment used Duncan's Test. The results
of measurement of ammonia, nitrite and nitrate concentrations can describe the regeneration of
inorganic nitrogen in shrimp feed in this study. There were a number of results found in this
study, including: (1) there was a significant reduction in the regeneration of inorganic nitrogen
by increasing the level of C: N ratio in shrimp feed, (2) dissolved oxygen in water decreased
due to its response to level ratio C: N for shrimp feed, (3) the number of bacteria increases with
increasing levels of the ratio C: N, (4) there is an increase in the number of heterotrophic
bacteria by increasing the level of C: N ratio of shrimp feed
Key words: Molasses, ratio level, regeneration of inorganic nitrogen, shrimp feed

DAFTAR PUSTAKA

Avnimelech, Y., Diab, S., Kochva, M.,

Mokady, S., 1992a. Control and

utilization of inorganic nitrogen in

intensive fish culture ponds. Aquaculture

and Fisheries Management 23, 421 - 430.

Avnimelech, Y., Lacher, M., Raveh, A., Zur,

O., 1981. A method for the evaluation of

conditions in a fish pond sediment.

Aquaculture 23, 361-365.

Avnimelech, Y., Mokady, S., 1988. Protein

biosynthesis in circulated fishponds. In:

Pullin, R.S.V., Bhukaswan, T.,

Tonguthai, K., Maclean, J.L. (Eds.), The

second International Symposium on

tilapia in aquaculture, pp. 301 - 309.

Avnimelech, Y., Mokady, S., Schroeder,

G.L., 1989. Circulated ponds as efficient

bioreactors for single cell protein

production. The Israel Journal of

Aquaculture-Badmidgeh 41, 58 - 66.

Avnimelech, Y., Mozes., N., Weber, B.,

. Effects of aeration and mixing on

nitrogen and organic matter

transformations in simulated fish ponds.

Aquacultural Engineering 11, 157-169.

Azam, F., Fenchel, T., Field, J.G., Meyer-

Reil, L.A., Thingstad, F., 2003. The

ecological role of microbes in the sea.

Marine Ecology Progress Series 10, 257

- 263.

Billen, G., 2004. Heterotrophic utilization

and regeneration of nitrogen. In: Hobbie,

J.E., P.J.L, W. (Eds.), Heterotrophic in

the sea. Plenum, pp. 313 - 355.

Bovendeur, J., Zwaga, A.B., Lobee, B.G.J.,

Blom, J.H., 2010. Fixed-biofilm reactors

in aquacultural water recycle systems:

effect of organic matter elimination on

nitrification kinetics. Water Res. 24, 207

- 213.

Boyd, C.E., Massaut, L., 1990. Risks

associated with the use of chemicals in

pond aquaculture. Aquacultural

Engineering 20, 113 - 132

Burford, M.A., Thompson, P.J., McIntosh,

P., Bauman, R.H., Pearson, D.C., 2018.

Nutrient and microbial dynamics in highintensity,

zero-exchange shrimp ponds in

Belize. Aquaculture 219, 393 - 411.

Chuntapa, B., Powtongsook, S., Menasveta,

P., 2018. Water quality control using

Spirulina plantensis in shrimp culture

tanks. Aquaculture 220, 355 - 366.

Figueroa, L.A., Silverstein, J., 2012. The

effect of particulate organic matter on

biofilm. Water Environ. Res. 64, 728 -

Fuhrman, J.A., Horrigan, S.G., Capone,

D.G., 2008. Use 13N as tracer for

bacterial and algal uptake of ammonium

from seawater. Marine Ecology Progress

Series 45, 271 -278.

Goldman, J.C., Caron, D.A., Dennet, M.R.,

Regulation of gross growth

efficiency and ammonium regeneration

in bacteria by substrate C:N ratio.

Limnology Oceanography 32, 1239 -

Grace, G.R., Piedrahita, R.H., 1994. Carbon

dioxide control. In: Timmons M., L.T.M.

(Ed.), Aquaculture water reuse systems:

Engineering design and management.

Developments in aquaculture and

fisheries science,27. Elsevier,

Amsterdam-Lausanne-New York-

Oxford-Singapore-Tokyo, pp. 209 - 234.

Grace, G.R., Piedrahita, R.H., 2004. Carbon

dioxide control. In: Timmons M., L.T.M.

(Ed.), Aquaculture water reuse systems:

Engineering design and management.

Developments in aquaculture and

fisheries science,27. Elsevier,

Amsterdam-Lausanne-New York-

Oxford-Singapore-Tokyo, pp. 209 - 234

Hargreaves, J.A., 1998. Nitrogen

biogeochemistry of aquaculture ponds.

Aquaculture 166, 181-212.

Helder, W., DeVeries R.T.P., 2003.

Estuarine nitrite maxima and nitrifying

bacteria (Ems-Dollard Estuary).

Netherlands Journal of Sea Research 17,

- 18.

Hoch, M.P., Fogel, M.L., Kirchman, D.L.,

Isotope fractionation during

ammonium uptake by marine microbial

assemblages. Geomicrobiology 12, 113 –

Hopkins, J.S., Hamilton, R.D., Sandifer,

P.A., Browdy, C.L., Stokes, A.D., 2013.

Effect of water exchange rates on

production, water quality, effluent

characteristics, and nitrogen budgets of

intensive shrimp ponds. J. World

Aquacult. Soc 24, 304

Keil, R.G., Kirchman, D.L., 20111.

Contribution of dissolved free amino

acids and ammonium to the nitrogen

requirements of heterotrophic

bacteriaplankton. Marine Ecology

Progress Series 73, 1 - 10.

Kirchman, D.L., Keil, R.G., Wheeler, P.A.,

Carbon limitation of ammonium

uptake by heterotrophic bacteria in the

Subartctic Pacific. Limnology

Oceanography 35, 1258-1266.

Kirchman, D.L., Keil, R.G., Wheeler, P.A.,

Carbon limitation of ammonium

uptake by heterotrophic bacteria in the

Subartctic Pacific. Limnology

Oceanography 35, 1258-1266.

Kochva, M., Diab, S., Avnimelech, Y.,

Modelling of nitrogen

transformation in intensively aerated fish

ponds. Aquaculture 120, 95 - 104.

Kochva, M., Diab, S., Avnimelech, Y.,

Modelling of nitrogen

transformation in intensively aerated fish

ponds. Aquaculture 120, 95 - 104.

Middelboe, M., Borch, N.H., Kirchman,

D.L., 20155. Bacterial utilization of

dissolved free amino acids, dissolved

combined amino acids and ammonium in

the Delaware Bay estuary: effects of

carbon and nitrogen limitation. Marine

Ecology Progress Series 128, 109 – 120

Montoya, R.A., Lawrence, A.L., Grant,

W.E., Velasco, M., 2002. Simulation of