Chicken Eggshell as an Innovative Bioflocculant in Harvesting Biofloc for Aquaculture Wastewater Treatment

Implementation of biofloc technology(BFT)system in aquaculture industry shows high productivity,low feed conversion ratio,and an optimum culture environment.This study was divided into two phases.The first phase involved maintaining the water quality using the optimum carbon-to-nitrogen ratio by manipulating pH in culture water.The second phase examined the performance of harvesting biofloc(remaining phytoplankton and suspended solids in the system)using chicken eggshell powder(CESP).This study showed that pH 7 to 8 were the best biofloc performance with high removal percentage of ammonia(>99%)with a remaining ammonia concentration of 0.016 mg L^(−1)and 0.018 mg L^(−1),respectively.The second phase of this study was performed to determine the optimal formulation and conditions of using CESP as a bio-flocculant in harvesting excess biofloc.The use of eggshell showed a higher harvesting efficiency of more than 80%under the following treatment conditions:0.25 g L^(−1)of eggshell dosage;with rapid and slow mixing rates of 150 and 30 rpm,respectively;30 min of settling time;settling velocity of 0.39 mm s^(−1)and pH of 6 to 7.Therefore,the results indicated that biofloc would be the best green technology approach for sustainable aquaculture wastewater and the CESP is an organic matrix that environmental-friendly bio-coagulant for biofloc harvesting.

Effects of Bioflocs on Artemia Growth and Water Quality

1 Introduction Bioflocs is a heterogeneous mixture of the microorganisms,particles,organic polymers and dead cells,etc.(Hargreaves,2006).Among which,heterotrophic bacteria convert efficiently the ammonia nitrogen into the bacterial protein,which provides the supplementary feed for culture animals and reduces the nitrogen level in the culture system(De Schryver et al,2008).In the closed aquaculture system,the growth of

Sexual Reversal with 17α-Methyltestosterone in Oreochromis sp.:Comparison between Recirculation Aquaculture System(RAS)and Biofloc Technology(BFT)

Precocity in tilapia implies the use of several methods of obtaining monosex seed;the most common tends to use masculinizing hormone 17α-methyltestosterone(17αMT),with variable results.Thus the objective of this study was to compare the efficiency of the sexual reversion process using 17αMT,in a recirculation system and in biofloc.In a totally randomized design,three tanks for recirculation(T-RAS)and three tanks for biofloc(T-BIO)with a capacity of 200 L effective volume were taken and filled with 1,056 larvae of Oreochromis sp.,without reversing and with an initial weight of 0.02 g and an initial total length of 1.4 mm.The study was carried out during 65 d,the fish were fed(10%biomass,adjusted every 15 d)by a commercial diet at 45%of crude protein that included 17αMT(60 mg/kg).Water quality,microbiology,zootechnical and gonadal analysis were monitored.Consequently the water quality results showed that just dissolved oxygen(DO),temperature(T-°C)and alkalinity did not show significant differences.Additionally,in the productive parameters there were significant differences in the final length,the gain in length and in K which were better in T-BIO.The microbiological ones did not present significant differences between the treatments.Lastly,the percentage of reversion was significantly better in T-RAS.Then,this study suggests that settleable solids concentrations above 35 cm decrease the efficiency of the sexual reversion for this species.

Effects of Different Carbon Sources on the Water of Aristichthys nobilis Richardson Aquaculture by Biofloc

In order to explore the effects of different carbon sources on the water of Aristichthys nobilis Richardson culture by biofloc as well as regular,glucose,sucrose,dextrin,brown sugar and molasses 5 soluble carbon source were added into the water of Aristichthys nobilis Richardson culture containing a certain amount of ammonia nitrogen,nitrite nitrogen to research their effects on pH value,dissolved oxygen,ammonia-nitrogen,nitrite nitrogen value.The results showed that sucrose had the best effect in converting ammonia nitrogen and nitrite nitrogen;glucose and dextrin had significant effect in converting ammonia nitrogen.However,compared with sucrose,glucose and dextrin had bad effect in converting nitrite nitrogen molasses had bad effect in converting ammonia nitrogen and nitrite nitrogen,and had little effect on pH value and dissolved oxygen;glucose,sucrose and dextrin had significant effect in decreasing pH value and dissolved oxygen;brown sugar had good effect in converting nitrite nitrogen,whereas it had little effect in converting ammonia nitrogen.Therefore,sucrose was the best carbon source,and if the cost factor was taken into account,glucose also had a high cost performance.

Applied Biofloc Technology for Target Species in the Mekong Delta in Vietnam： A Review

BFT （Biofloc Technology） has been currently applied in Cantho University to a number of targeted species from fresh-to marine and saline water species in the Mekong Delta, e.g. striped catfish （Pangasianodon hypophthalmus）, white leg shrimp （Litopenaeus vannamei）, tiger shrimp （Penaeus monodon） and Artemia Vinhchau strain （Artemia franciscana） for both in the lab-scales or production scales. The best growth and survival rate of striped catfish was obtained in 6%o. For white leg shrimp, the results indicated： （1） C （Carbon） source e.g. rice-flour or molasses supplementary based on the feed provided to promote survival, growth and shrimp biomass harvested; （2） it was fed less than 20% as usual but showed similar to those in the control; （3） combination of rice-flour and molasses at a ratio of 70：30 by weight of C and N （Nitrogen） in a ration of 15：1 enhanced shrimp survival and growth; （4） in intensive culture, shrimp could be against the infection of disease and end up with higher survival, growth in earthen ponds. For tiger shrimp, a set up for larvae till post larvae at different ratios of C and N and C：N of 30 PLI5 displayed with better survival rate （49.73 ± 7.07%） and production （74,596 ± 10.608 PL/m3）. Artemiafranciscana was set up at C：N = 10：1 and salinities from 35, 60, 80 and 100 ppt. After two weeks, there were no significant difference among treatment and the control （without biofloc） in term of survival and growth. Moreover, total embryos per female was not significant different with the control and even the number of embryos as cysts tended to be higher. BFT displayed its advantages when applied on culture system of different targeted species and there is no doubt that it could help to sustain aquaculture and save environment in the Mekong Delta in near future.

Effect of carbon and nitrogen ratio control on Artemia growth, water quality, biofloc microbial diversity under high salinity and zero-water exchange culture condition

Biofloc technology has been applied successfully in the intensive aquaculture of several fish and shrimp species. The growth of heterotrophic microorganisms can be stimulated through adding extra carbon, which reduces the nitrogen level in the water and provides microbial protein to the animals. However, most of the studies and practical applications have been conducted in freshwater and marine environment. This paper focused on brine shrimp Artemia that lives in high salinity environment together with other halophilic or halotolerant microorganisms. The effect of carbon supplementation on Artemia growth, water quality, and microbial diversity of biofl ocs was studied in the closed culture condition without any water exchange. The salinity of the culture medium was 100. A 24-d culture trial was conducted through supplementing sucrose at carbon/nitrogen (C/N) ratio of 5, 15, and 30 (Su5, Su15, and Su30), respectively. The culture without adding sucrose was used as a control. Artemia was fed formulated feed at a feeding ration of 60% recommended feeding level. The results showed that sucrose supplementation at higher C/N ratio (15 and 30) signifi cantly improved the Artemia survival, growth and water quality ( P <0.05). Addition of sucrose at C/N ratio of 15 and 30 significantly increased biofloc volume (BFV)( P <0.05). The Illumina MiSeq sequencing analysis showed that supplementing carbon at C/N ratio of 15 had a better total bacterial diversity and richness, and shaped the microbial composition at genera level. This study should provide information for studying the mechanism of biofloc technology and its application in high salinity culture conditions.

Fish culture in biofloc technology(BFT):Insights on stocking density carbon sources,C/N ratio,fish nutrition and health

The growth of aquaculture demands intense consumption of formulated foods,scarce natural resources such as water and land.The increase in aquaculture production needs to be sustainable in several aspects of the activity,including the use of more sustainable farming systems that provide reduced water demand,less space dependence for increased production,and availability of complementary natural food.In this perspective,the biofloc system(BFT),presents itself as a more friendly cultivation technology as a way to mitigate some impacts of aquaculture production.Much research has been carried out,addressing different aspects important to the production of fish in BFT.In this review,we address how stocking density,carbon sources and carbon nitrogen ration(C/N)affect animal performance and the nutritional value of bioflocs;the use of microbial aggregates as“in situ”and“ex situ”food and the benefits in feed conversion,and their influence on the immune system and disease resistance.

Effect of seeding biofloc on the nitrification establishment in moving bed biofilm reactor(MBBR)

In recirculating aquaculture systems,nitrification is usually accelerated by inoculating nitrifier or mature biocarriers.In this study,the performance of the establishment of nitrification in the MBBR according to three different strategies:conventional method(Control group A),inoculation with biofloc recovered from a tilapia biofloc culture system(Group B),and addition with extra nitrite(Group C)in the Moving bed biofilm reactor(MBBR)was compared.Among them,the biofloc-inoculated group considerably accelerated the nitrification process in the MBBR(38 d),which is roughly 18 d faster than the control group(A)(56 d)and 21 d faster than group C(59 d).Less ammonia(8 mg/L NH_(4)^(+)-N,10 mg/L in other groups)and external nitrite(2 mg/L NO_(2)􀀀^(-)N)in the influent caused effluent ammonia to drop more slowly(5 d slower than the control group,8 d slower than the B group),which is detrimental to the nitrification process’development.Notably,the influent’s hydraulic retention time(HRT)was reduced from 12 h to 6 h following the successful establishment of nitrification.During the adaptation to reduced HRT,the MBBR inoculated with biofloc experienced short-term changes in the water quality index of the effluent water,whereas the other groups did not.The biofilm seeded with biofloc had the highest mean gray value ratio(1.42)of live/dead cell fluorescence,which grew better and could cover the entire groove under multiple microscope observations.However,the other groups did not demonstrate a similar trend.In summary,the research found that seeding biofloc use as nitrification bioaugmentation into the MBBR of the recirculating aquaculture system(RAS)to greatly speed up the nitrification process.

保存温度对生物絮团硝化性能和形态结构的影响

为探究生物絮团适宜的保存温度,通过单因素实验设计,将絮团在常温(25°C)、冷藏(4°C)和冷冻(–20°C)条件下分别密封保存了7、14、21和28 d。结果显示,随着保存时间的延长,絮团的硝化性能在3种温度保存条件下较初始硝化性能均有不同程度的下降。在4°C保存28天的絮团中,氨氧化速率为(0.16±0.10) mg/(L·h),显著高于25°C条件下的(0.08±0.09) mg/(L·h)和-20°C条件下的(0.01±0.09) mg/(L·h),其中,-20°C保存条件下的絮团在第7天几乎丧失氨氧化活性,较初始氨氧化速率下降了99.52%。在第28天,4°C下保存的絮团亚硝态氮氧化速率为(0.19±0.03) mg/(L·h),显著高于25°C保存条件下的(0.10±0.05) mg/(L·h)和-20°C保存条件下的(0.14±0.02) mg/(L·h)。显微观察的结果显示,25°C保存条件下絮团结构松散,絮团的体积平均粒径由初始的(245.92±21.51)μm减小到第28天的(148.50±9.90)μm;在-20°C保存条件下,絮团的体积平均粒径由(245.92±21.51)μm增大到(310.82±29.67)μm;4°C保存条件下,絮团的形态结构和粒径均未受到显著变化。研究表明,4°C的保存条件可作为生物絮团的保存温度。本研究为生物絮团适宜的保存温度和保存时间提供了参考依据,有利于生物絮团在实际生产中的保存和再使用。

接种两株有益菌的生物絮团净水性能及饲料化潜力

为强化新的絮团形成菌伪杜擀氏菌YN12(Pseudoduganella eburnea YN12,YN)利用养殖尾水生成生物絮团效果,并将絮团制成饲料,探讨在胡子鲶(Claris fuscus)饲养上的可行性。在生物絮团系统中,接种活性污泥(Activated sludge,AS)、伪杜擀氏菌YN12和枯草芽孢杆菌(Bacillus subtilis,BS)并配制成7组(AS、YN、BS、AS+YN、AS+BS、YN+BS和AS+YN+BS),分析絮团形态结构差异,评估出对模拟养殖尾水氮去除效果及微生物群落结构优势的最佳组合,最终收集最佳组合絮团烘干研磨成粉末添加到商业饲料制粒,分成对照组和絮团组两组,探讨对胡子鲶的生长性能、饲料利用率、肌肉营养成分及肝脏的消化酶和免疫酶活性的影响。结果表明:YN+BS组水质净化效果稳定,总氮去除效果(89.6%)良好,氨氮、亚硝酸盐和硝酸盐积累低,具有良好的絮团生成量(9.0 ml/L)及占据优势(47.5%)的反硝化菌群(包括Hydrogenophaga、Flavobacterium、Pseudoxanthomonas、Burkholderiaceae、Comamonas、Acinetobacter等)。该组絮团粉以5%比例与商业饲料混合、研磨加工制粒后用于胡子鲶养殖,发现胡子鲶生长性能[包括存活率:(100±0.00)%>(95±0.00)%;增重:(2.81±0.35)g>(2.52±0.52)g;体长增加(1.68±0.36)cm>(1.51±0.34)cm]和饲料系数55±0.03>46±0.12均优于纯商业饲料的对照组,然而在淀粉酶等消化酶、免疫酶包括过氧化氢酶、总超氧化物歧化物、谷胱氨酸过氧化物酶等及肌肉营养成分包括谷氨酸、天冬氨酸、丙氨酸和甘氨酸等鲜味氨基酸上均低于对照组。YN+BS组絮团饲料在生长性能占据优势,然而在消化能力、免疫活性及肌肉营养成分上并未表现出明显优势,需要进一步调整水平絮团添加水平以优化胡子鲶饲养效果。

凡纳滨对虾生物絮团养殖系统中泡沫体积与生物絮团及环境的关系

为探究生物絮团(BFT)系统中泡沫体积与生物絮团及环境因子的关系,以求通过泡沫体积判断生物絮团的运行情况。实验采用3组凡纳滨对虾生物絮团养殖系统进行100 d的实验研究,测定泡沫体积、水体表面张力及水环境因子等参数,选用Pearson相关系数进行相关性分析,研究泡沫体积变化与生物絮团、环境因子之间的关系。结果显示,泡沫体积与总氨氮(TAN)呈现较强的正相关性,相关系数为0.571。泡沫体积受生物絮团状况影响,与絮团体积(FV)呈负相关性,相关系数为−0.266。泡沫体积由增转降的日期与生物絮团开始形成的日期高度拟合,二者相差在5 d内。随着生物絮团的形成,泡沫体积逐渐降低。当生物絮团成熟稳定时,泡沫体积会维持在0.0110 m^(3)/t以下(1 t水体生成0.0110 m^(3)泡沫)。研究表明,可以通过泡沫体积的变化判断生物絮团的运行情况。本研究可提高生物絮团的可控性,对凡纳滨对虾生物絮团养殖技术的推广具有重要的指导意义。

短期存贮温度对生物絮团反硝化性能的影响

为探究存贮温度对生物絮团反硝化性能的影响,试验收集凡纳滨对虾( Litopenaeus vannamei )养殖池中的生物絮团,分别密封保存于室温25 ℃(T25组)、低温4 ℃(T4组)、 冷冻-20 ℃(T-20组)和超低温冷冻-80 ℃(T-80组)条件下,为期28 d。初始收集到的生物絮团对硝酸盐氮的去除速率为0.71±0.03 mg /(L·h)。保存前7 d,仅T-80组的生物絮团去除速率出现衰减。保存时长超过14 d以后,仅T4组的生物絮团反硝化性能未衰减。保存至第28天,T4组生物絮团对硝酸盐氮的去除速率为0.72±0.01 mg/(L·h),显著高于T25组0.52±0.02 mg/(L·h)、T-20组0.57±0.03 mg/(L·h)和T-80组0.52±0.02 mg/(L·h)。显微结构观察表明,生物絮团保存 7 d与初始相比,T4组和T25组未出现明显变化,死亡细胞比例增加缓慢;保存至第28天,T4组生物絮团轻微变质,死亡细胞比例低,其他组别均出现生物絮团严重变质、死亡细胞比例较高的情况。综上,4 ℃是生物絮团反硝化性能短期保存的适宜温度。

LED光照对生物絮团模式下凡纳滨对虾肌肉营养成分的影响

LED光源具有节能环保、光电转化效率高等优点,可满足工厂化养殖对绿色高效、智能化发展的需求。为探究LED养殖灯对生物絮团模式下凡纳滨对虾(Litopenaeus vannamei)肌肉品质的影响,以凡纳滨对虾幼体(平均体长5.23±0.61 cm,平均体质量1.52±0.47 g)为材料,设置2个处理组:LED光照组(L组)和自然光照组(N组),进行为期8周的养殖试验。L组光照参数为蓝绿光混合(绿光545 nm、蓝光450 nm),光照周期15 L∶9 D,光照度2000 lx;N组光照参数为自然光谱,光照周期为12L∶12D,光照度400~1000 lx。结果显示,两组对虾肌肉常规营养成分(水分、粗蛋白、粗脂肪、灰分)均无显著性差异(P>0.05)。两组对虾肌肉中均检测到18种氨基酸,L组对虾肌肉苏氨酸(Thr)、酪氨酸(Tyr)、精氨酸(Arg)、甘氨酸(Gly)、∑EAA/∑NEAA显著高于N组(P<0.05),而必需氨基酸(EAA)、半必需氨基酸(HEAA)、呈味氨基酸(DAA)均无显著性差异(P>0.05)。两组对虾肌肉中均检测到37种脂肪酸,L组对虾肌肉中月桂酸(C12:0)、DHA、EPA+DHA含量显著高于N组(P<0.05),C21:0、C20:3n-3、C22:5n-6含量显著低于N组(P<0.05)。研究表明,在生物絮团养殖模式下,补充特定参数的LED养殖灯能够改善凡纳滨对虾肌肉营养品质。

两种斑节对虾养殖模式水质净化效果与细菌群落结构的比较分析

为了提高对虾养殖系统水质净化能力,改善对虾养殖水环境,利用红糖+枯草芽孢杆菌和聚氨酯填料+硝化细菌分别构建生物絮团和内循环斑节对虾(Penaeus monodon)养殖系统,比较两个系统在对虾标苗和养殖阶段的水质净化效果和细菌群落结构,从微生物学层面探究其水质净化机理。将体长(0.5±0.1)cm的5日龄仔虾养殖在1 m^(3)水体的帆布池中,标苗期密度为5 000 ind.·m^(-3),养殖期降为400 ind.·m^(-3)。标苗结束时,各帆布池底铺约3 cm厚的砂子。生物絮团系统中加活化后的枯草芽孢杆菌,每天一次性加50%日投饲量的红糖,每隔7 d加0.5 L活化后的芽孢杆菌,每隔14 d换水20%。内循环系统中悬挂已挂膜的聚氨酯填料包,其上表面浸没在水中,内部放一个气石。每个系统设2组平行,各阶段养殖周期分别为20 d和40 d。实验结束时,采集生物絮团系统水样、底砂和内循环系统生物膜、水样及底砂的细菌样品,提取DNA,利用Illumina Mi Seq平台对DNA样品进行高通量测序。结果显示,生物絮团系统氨氮和亚硝酸盐氮浓度波动变化较大,显著高于内循环系统(P<0.05);加芽孢杆菌和换水后,氨氮和亚硝酸盐氮浓度有所下降。生物絮团系统硝酸盐氮浓度显著低于内循环系统(P<0.05);化学需氧量显著高于后者(P<0.05)。两个系统总磷浓度无显著差异(P>0.05)。细菌群落结构分析表明,在44个菌门中,有25个为所有样品所共有,5个样品优势菌门均为变形菌门(Proteobacteria)和拟杆菌门(Bacteroidota),其在生物絮团系统水样、底砂和内循环系统生物膜、水样及底砂中的相对丰度之和依次为58.51%、55.44%、61.48%、73.42%及65.69%。生物絮团和内循环系统中分别存在芽孢杆菌属(Bacillus)、栖砂杆菌属(Arenibacter)、珞珈苍黄色杆菌属(Luteolibacter)等和硝化螺旋菌属(Nitrospira)、硝化刺菌属(Nitrospina)、假交替单胞菌属(Pseudoalteromonas)等具有有机物降解、水质净化及对虾益生作用的菌属。由此可知,生物絮团系统对氨氮和亚硝酸盐氮的净化能力不如内循环系统;生物絮团和内循环系统门和属水平上细菌群落组成及其相对丰度均存在差异。

Comparing salinities of 0, 10 and 20 in biofloc genetically improved farmed tilapia (Oreochromis niloticus) production systems

A 150 days(150-d)experiment was carried out to investigate the production efficiency,inorganic nitrogen syndrome and bacteria community of indoor biofloc technology(BFT)systems used to rear genetically improved farmed tilapia(Oreochromis niloticus)under 0(S-0),10(S-10),and 20 salinities(S20).The start-up period for BFT was 50,60 and 80 d for S-0,S-10 and S-20 groups,respectively.At steady state,the total ammonium nitrogen(NH4þ-N)and nitrite nitrogen(NO2-N)were lower than 3.0 mg/L and 0.34 mg/L,respectively and no nitrate-nitrogen(NO3-N)accumulation was observed.The fish survival rate was above 95%for all the groups.The final fish biomass of the S-10 group(35.83±1.08 kg/m^(3))was not significantly different from the S-0(34.79±1.33 kg/m^(3))group but was significantly higher than S-20(32.6±1.04 kg/m3).The feed conversion ratio for the tilapia in S-20 was 1.46,which was higher than the ratio in S-0(1.40)and S-10(1.39)tilapia.There was no significant difference in the crude protein content of the back muscle from tilapia of the three experimental groups.No significant difference in blood parameters,except for aspartate aminotransferase and alkaline phosphatase was observed between the three groups.Evaluation of microorganisms in the three BFT systems revealed that Proteobacteria,Bacteroidetes,and Fusobacteria were the top three at the phylum level in all groups.However,a significant difference was observed at the genus level in the bacteria of the three BFTs at different salinity(P<0.05).©2017 Published by Elsevier B.V.on behalf of Shanghai Ocean University.This is an open access article。

Dynamics of nitrogenous compounds and their control in biofloc technology (BFT) systemsA review

Controlling toxic nitrogenous substances in biofloc technology(BFT)systems is critical for the success of this novel technology.To effectively control nitrogen accumulation in BFT systems,it is important to first understand the dynamics and the removal pathways of this element and its related compounds from aquaculture water.This review focuses on synthesizing the information of nitrogen dynamics in BFT systems to provide researchers and practitioners with a guide to the fate of nitrogen and its control methods.This paper discusses the different types of nitrogenous compounds in BFT water,the transformation processes of ammonia to nitrites and nitrates,the relationship between the two forms of ammonia(NH3 and NH4+)in water and the equilibrium between them.This paper also discusses nitrification as a major nitrogen removal pathway and the factors that influence the nitrification process.Notably,the control of nitrogen in BFT systems by manipulating the carbon to nitrogen ratio(C/N)using external carbohydrates is described in this paper.This paper suggests that further studies should focus on investigating the various factors that influence nitrogen dynamics in BFT systems and the means of controlling contaminants other than nitrogen.

不同低聚糖对生物絮团形成及其菌群结构的影响

本研究旨在探究不同低聚糖对生物絮团形成及生物絮团菌群结构特征的影响。以葡萄糖(GLU)为对照,采用低聚木糖(XOS)、低聚果糖(FOS)、甘露寡糖(MOS)、大豆低聚糖(SBOS)、低聚麦芽糖(MTOS)作为碳源构建生物絮团,氯化铵为氮源,碳氮比(C/N)为15。结果显示,SBOS组与其他各组相比,显著提高水中悬浮颗粒物含量及生物絮团体积,其他低聚糖组与对照组相比差异不显著。氨氮逐渐下降然后趋于稳定,SBOS组与对照组和其他实验组相比,显著降低了氨氮水平,其中除FOS组外,其他实验组降低氨氮能力均高于对照组。亚硝态氮降解作用均没有显著差异。硝态氮呈现先降低后升高的趋势,除XOS组外均可降低硝态氮的积累,其中SBOS组与MTOS组显著降低硝态氮的积累。XOS组与对照组相比,显著降低生物絮团菌群的丰度与微生物多样性指数。从门水平上分析,变形菌门在各实验组中均丰度最大,各低聚糖组与对照组相比,对拟杆菌门、变形菌门均有不同程度提高,其中FOS组显著提高变形菌门与拟杆菌门的丰度。从属水平上分析,实验组与对照组相比均降低蛭弧菌比例,其中FOS组与对照组及其他实验组相比,显著提高unclassified_f_Rhodobacteraceae的丰度,显著降低norank_f_Microscillaceae与norank_f_Enterobacteriaceae丰度。研究表明,低聚糖作为碳源构建生物絮团,可改善水质,优化菌群结构,提高有益菌数量,降低有害菌数量。本研究为低聚糖作为碳源应用于生物絮团提供理论依据。

大豆低聚糖替代葡萄糖对生物絮团系统菌群结构的影响

为了筛选出对生物絮团系统水质及菌群结构有积极作用的适宜浓度,本研究通过使用不同浓度的大豆低聚糖(SBOS)替代葡萄糖(GLU)作为生物絮团的碳源,对照组碳源为葡萄糖,实验组分别设置2.5%、5.0%、7.5%和10.0%SBOS (SBOS-2.5、SBOS-5.0、SBOS-7.5、SBOS-10.0组)替代葡萄糖为碳源。氯化铵为氮源,C/N为15,并添加枯草芽孢杆菌促进生物絮团系统形成。结果显示,各实验组与对照组均有效降低水中氨氮、亚硝态氮、硝态氮、总氮的浓度,各组之间均无显著差异。基于16S rRNA高通量测序,在门水平下,14 d时各实验组及对照组的优势菌门为变形菌门。28 d时,变形菌门与拟杆菌门的比例相近。属水平下,14 d时,SBOS-2.5组与SBOS-10.0组均显著提高芽孢杆菌属的丰度,显著降低气单胞菌科的丰度。28 d时,SBOS-2.5组与对照组和SBOS-10.0组相比显著提高黄杆菌属的丰度,各实验组与对照组相比显著降低金黄杆菌属的丰度。将菌群组成与环境因子关联分析,发现部分菌群对氮的硝化与反硝化有重要作用。研究表明,2.5%和10.0%的SBOS替代葡萄糖作为生物絮团的碳源均可有效提高有益菌丰度,降低有害菌丰度,有利于维持水体中细菌群落的稳定性。综合实验结果与生产应用成本,SBOS替代葡萄糖的推荐比例为2.5%。本研究为SBOS作为碳源应用于生物絮团系统提供基础,并为后续研究提供参考。

上海地区凡纳滨对虾工厂化养殖的发展瓶颈及建议

工厂化循环水养殖具有节约水土资源、养殖密度高、生产控制能力强、自动化程度高以及生态绿色环保等优点,是现阶段我国养殖产业主推的绿色养殖模式之一。文章对凡纳滨对虾工厂化养殖模式的内涵、国内外发展历程和水平等进行了概述,通过调研分析上海实施工厂化养虾的典型案例,发现目前上海地区工厂化养虾存在前期投资较大、运营成本较高、技术支撑体系不够完备、技术和管理类复合型人才缺乏、市场不稳定等瓶颈问题,并提出了加大政府扶持力度、加强基础应用研究、开展技术培训指导、重视品牌战略建设等切实可行的对策和建议,可为上海工厂化养虾的进一步发展和推广提供参考。

Performance of feeding Artemia with bioflocs derived from two types of fish solid waste

The production of bioflocs with the solid waste from recirculating aquaculture systems(RAS)and feeding Artemia results in additional nutrient retention and lowers waste discharged from RAS.The solid waste from the drumfilters of two RAS,which stocked European eel(Anguilla anguilla)and Nile tilapia(Oreochromis niloticus),was used as substrate to produce bioflocs in suspended growth reactors,referred to as E-flocs and T-flocs,respectively.Mono-diets consisting of 100%E-flocs and 100%T-flocs were added to culture Artemia,referred as E-Artemia and T-Artemia,respectively,in a laboratory scale test.The efficiency of this feeding regime was investigated.A significant difference was observed in terms of crude protein content(35.59±0.2%)for E-flocs,(29.29±0.95)%for T-flocs,(70.01±0.92)%for E-Artemia and(65.63±0.89)%for T-Artemia.134 out of the total operational taxonomic units(OTUs)were present in E-flocs and T-flocs from the analysis of high-throughput sequencing data.Most of the shared OTUs belonged to cyanobacteria.C18:1n7 of T-flocs was higher than that of E-flocs(P<0.05).C18:2n6 of E-flocs was significantly higher than that of T-flocs(P<0.05).No significant difference was observed in the other fatty acid compositions(P>0.05).The survival rate of E-Artemia was(22±0.02)%,significantly higher than that of T-Artemia(16%±0.02%)(P<0.05).No significant difference was observed between the average body weight of E-Artemia(2.38±0.40 mg)and E-Artemia(2.91±0.21)(P>0.05).The EPA of Artemia fed with E-flocs was(3.00±0.46)%,significantly higher than that of T-Artemia(1.57±0.19%)(P<0.05).This study offers a method for reusing the aquaculture waste,which will be helpful to achieve a zero-pollution discharge for aquaculture systems.