Effect of the particle size on the ammonia removal rate and the bacterial community composition of bioflocs

The total ammonia nitrogen (TAN) removal efficiency and bacterial community composition of bioflocs with <50-μm particle size, > 50-μm particle size and un-sieved bioflocs were investigated in the current study. The initial ratio of dissolved organic carbon to TAN (DOC/TAN) in the three groups were about 14:1. No significant difference was found in the removal rate of TAN, average concentrations of TAN and nitrite nitrogen among the three groups (P > 0.05). The C/N (w/w) ratio of the > 50-μm bioflocs was significantly higher than those of the other groups. No significant differences were found in the crude protein content in the bioflocs among the three groups. The development of the bacterial community compositions of the bioflocs was analyzed by Illumina MiSeq sequencing analyses. Most OTUs were shared among the three groups at all the sampled time points. With the increase in the relative abundance of phylum Firmicutes, that of phylum Proteobacteria, Chorolexi, and Bacteroidetes decreased in all the three groups. The phylum Firmicutes and genus Bacillus were predominant in all the sampled time points. At the end of the experiment, genus Bacillus accounted for 81% in the < 50-μm group, 82% in the > 50-μm group, and 75% in the un-sieved group.     

The use of clarifiers to remove and control the total suspended solids in large-scale ponds for production of Litopenaeus vannamei in a biofloc system

High concentrations of total suspended solids (TSS) need to be controlled, as they can affect shrimp production due to the excess of particles in the water column. Water renewal and clarification are alternatives used to reduce TSS. In order to determine the better method of TSS control, we carried out a study using water renewals and clarification on a commercial scale with nine ponds (600 m² each) in an intensive biofloc system. A total of 87 shrimp m⁻² were stocked in each unit divided into three treatments: R (water renewal), C1 (one clarifier) and C2 (two clarifiers in series). Each treatment had three replicates, and the experiment lasted 105 days. There were no significant differences (p > 0.05) in the parameters of water quality and zootechnical performance. Significant differences (p < 0.05) were observed in the performance of clarifiers (time of operation, TSS removal rate and total solids removed) and in the efficiency of water use and effluent generation. All treatments maintained controlled TSS levels, although C2 showed a better removal efficiency than C1, with percentages rates of 71.2 and 47.9%, respectively. This difference resulted in a 160-hour reduction in the total operating time in C2. Compared to the R treatment, the percentages of water saved in C1 and C2 were 50.7 and 51.3% higher, respectively, and the percentages of effluent generated in C1 and C2 were 97 and 96% lower, respectively. The use of clarifiers helps to control TSS concentrations in large-scale. In addition, they reduce both the amount of water used for renewals and the effluent discharges into the environment, thereby increasing biosafety in the biofloc system.     

Comparative analysis of nitrogen and phosphorus budgets in a bioflocs aquaculture system and recirculation aquaculture system during over-wintering of tilapia (GIFT,Oreochromis niloticus)

Nitrogen (N) and phosphorus (P) budgets in a bioflocs technology (BFT) aquaculture system and a recirculation aquaculture system (RAS) during over-wintering of tilapia (GIFT Oreochromis niloticus)for 64 d were compared in the current study. Fish feed was the major input of N in both systems, specifically, 94±0 % and 82±4 % for the RAS and BFT aquaculture system, respectively. The rate of N recovery in the BFT aquaculture systems was estimated to be 48±5 % of input N, which was significantly different from that of the RAS (37±4 %). There was no significant difference between the RASs and BFT aquaculture systems in terms of P recovery rate. The regular backwashing of the drum filter and biological filter in RAS accounted for 41 ± 2 % of input N and 39 ± 2 % of input P. Approximately 54 % of unassimilated nitrogen N was removed by nitrification in the BFT aquaculture systems. The results from the present study suggest that nitrification may be the dominant pathway for ammonia removal in a BFT aquaculture system rather than by heterotrophic bacterial assimilation.     

生物絮团对水质的调控作用及仿刺参(Apostichopus japonicus)幼参生长的影响

采用模拟实验与现场实验相结合的方法,通过添加3种微生态制剂及碳水化合物作为碳源,研究了其在生物絮团形成与水质调节中的作用,并分析了其对水中无机氮含量、悬浮物、细菌总数及幼参生长的影响,为阐明生物絮团在刺参工厂化苗种培育中的生态环境调控作用提供依据。结果表明,亚硝态氮易于在培育池水体中累积,可高达0.25 mg/L;添加芽孢杆菌后,水中总悬浮物含量和细菌总数均为最高值,且未检测到弧菌和大肠菌群;第20天,仅添加蔗糖组幼参增重与特定生长率均明显高于其他复合碳源组和对照组(P0.05),分别为44.34 g和2.19%/d;而添加蔗糖和芽孢杆菌组增重与特定生长率均明显高于其他处理组和对照组(P0.05),分别为66.60 g和3.01%/d;复合碳源组幼参增重与特定生长率随着玉米淀粉含量增加而逐渐降低,但与对照差异均不显著(P0.05)。结果显示,以蔗糖为碳源,添加芽孢杆菌形成的生物絮团不仅可以改善水体水质和微生态结构,还可以明显促进幼参的生长。     

Effect of different biofloc levels on microbial activity,water quality and performance of Litopenaeus vannamei in a tank system operated with no water exchange

In zero-exchange superintensive culture systems, flocculated particles (bioflocs) accumulate in the water column. Consequently, some control over the concentration of these particles must be performed. The objective of this study is to evaluate the effects of three concentrations of bioflocs on microbial activity, selected water quality indicators and performance of Litopenaeus vannamei in a tank system operated with no water exchange. A 44-day study was conducted with juvenile (6.8 g) shrimp stocked in twelve 850 L tanks at a stocking density of 459 shrimp m⁻³. Biofloc levels were expressed as three presets of total suspended solids (TSS) concentrations, as follows: 200 mg L⁻¹ (T200), 400–600 mg L⁻¹ (T400–600), and 800–1000 mg L⁻¹ (T800–1000). TSS levels were controlled by attaching a 40 L settling tank to each culture tank. Reduction of TSS to concentrations close to 200 mg L⁻¹ decreased the time of bacterial cell residence and significantly reduced the nitrification rates in the water (P < 0.05). The tanks in the T200 treatment had a greater variability of ammonia and nitrite (P < 0.05), which led to the need to increase the C:N ratio of the organic substrate to control ammonia through its assimilation into heterotrophic bacterial biomass. But the higher production of heterotrophic bacteria in T200 (P < 0.05) increased the dissolved oxygen demand. Nitrification rates were higher (P < 0.05) in tanks with TSS concentrations above 400 mg L⁻¹, and ammonia and nitrite were significantly lower than in the T200 tanks. We suggest that ammonia and nitrite in the T400–600 and T800–1000 tanks were controlled primarily by nitrifying bacteria, which provided higher stability of these parameters and of dissolved oxygen. Regarding shrimp performance, the reduction of TSS to levels close to 200 mg L⁻¹ was associated with better nutritional quality of bioflocs. Nevertheless, differences in biofloc levels and nutritional quality were not sufficient to affect the weight gain by shrimp. The rate of shrimp survival and the final shrimp biomass were lower (P < 0.05) when the TSS concentrations were higher than 800 mg L⁻¹. Analysis of the shrimps’ gills showed a higher degree of occlusion in the T800–1000 treatment (P < 0.05), which suggests that the shrimp have an intolerance to environments with a solids concentration above 800 mg L⁻¹. Our results show that intermediate levels of bioflocs (TSS between 400 and 600 mg L⁻¹) appear to be more suitable to superintensive culture of L. vannamei since they create factors propitious for maintaining the system’s productivity and stability