1. IntroductionIntensive pond aquac

1. Introduction

Intensive pond aquaculture systems efficiently produce dense bio-
masses of cultivable fish. An intrinsic feature of such systems could be

rapid accumulation of feed residues, organic matter and toxic inorganic

nitrogen species. Fish in pond assimilate only 15-30% of nitrogen added

in the feed (Acosta-Nassar et al., 1994; Gross et al., 2000; Davenport

et al., 2003), rests is lost as ammonia and organic N in feces and residues

(Avnimelech and Ritvo, 2003). Intensive pond aquaculture system

faces low feed use in high water flow system, water quality deteriora-
tion and water discharge with serious environmental consequences (Avnimelech, 2007). To overcome such constraints biofloc technology

(BFT) is known to prevent accumulation of toxic inorganic nitrogen

metabolites by inducing and manipulating carbon/nitrogen ratio (C/N

ratio) and uptake of ammonium by the microbial community even in

zero water exchange system (Avnimelech et al., 1994; McIntosh,

2000). Where, nutrients from excretion and remnant feed are recycled

into microbial community forming bioflocs containing bacteria, phyto-
plankton, protozoa and zooplankton kind of high valued food by fish

or shrimp (McIntosh, 2000; Velasco et al., 1998; Avnimelech, 2007).

This technology reduces the potential spread of pathogenic bacteria

and feed conversion ratio (Burford et al., 2003; Crab et al., 2010;

Xu and Pan, 2013). Currently, biofloc technology has been receiving

attention for closed-water carp, shrimp and tilapia cultivation (Hari

et al., 2006; Zhao et al., 2013; Anand et al., 2014; Liu et al., 2014). Relatively high C/N ratio feed (10 to 20) are recommended for bioflocs

(Hargreaves, 2006; Asaduzzaman et al., 2008; Ballester et al., 2010).

The C/N ratio of most artificial feeds used in semi-intensive pond aqua-
culture is around 10, but bacteria require about 20 units of carbon per

unit of nitrogen assimilated (Avnimelech, 1999). Therefore, adding

carbohydrates can be a practical way to increase the C/N ratio for

bioflocs promotion (De Schryver et al., 2008; Anand et al., 2013). It

has been suggested that higher feed C/N ratio could increase bioflocs

volume without compromising nutritional quality (Azim and Little,

2008; Asaduzzaman et al., 2010; Crab et al., 2012). The optimum feed

C/N ratio in carp aquaculture system can be maintained by adding

locally available inexpensive carbon sources and/or reduction of protein

content in feeds (Avnimelech, 1999; Hargreaves, 2006). Generally, carp

aquaculture includes bottom feeder mirror, typical filter feeding species

subsist on plankton such as silver (Hypophthalmichthys molitrix), big-
head (Aristichthys nobilis) and other carp. Thus, bioflocs technology

combined with polyculture might enhance production performance

of carp, water quality, natural food availability (Rahman et al., 2008;

Fukushima et al., 1999; Ke et al., 2007; Yan et al., 2009). However,

there is only little documentation on practicability of biofloc technology

to bottom and filter feeders carp in minimum water exchange pond

polyculture system. Thus, the main objective of the present study was

to examine the effects of feed C/N ratio on water quality and production

performance of bottom and filter feeder carp in minimum water ex-
change outdoor ponds.