鱼蚌混养对池塘水质、藻相结构及三角帆蚌生长的影响

2012年4月26日—2012年12月12日通过在鲢鳙鱼养殖池塘中放养不同密度的三角帆蚌,研究不同三角帆蚌放养比例对鲢鳙鱼养殖池塘中水质、藻相结构及三角帆蚌生长的影响。实验中,鲢鳙放养比例统一为3∶7,总密度为1.5尾/m3。三角帆蚌放养密度则设置4个水平,分别为单养鲢鳙鱼池塘(0只/m3),低密度三角帆蚌混养池塘(0.8只/m3),中密度三角帆蚌混养池塘(1.0只/m3)和高密度三角帆蚌混养池塘(1.2只/m3)。结果显示,混养三角帆蚌池塘的水化指标(TP、PO4-P、NH3-N、NO2-N和NO3-N)均显著低于单养鱼池塘。中密度三角帆蚌混养池塘除NH3-N和化学需氧量(COD)与低密度三角帆蚌混养池塘无显著差异外,其他各项水化指标均显著低于其他3个池塘,并且极显著低于单养鲢鳙鱼池塘。单养鲢鳙鱼池塘藻类平均密度均极显著高于鱼蚌混养池塘,其中在鱼蚌混养池塘中浮游植物密度与三角帆蚌密度成负相关关系。单养鲢鳙鱼池塘的浮游植物生物量均极显著低于中、高密度鱼蚌混养池塘,并且显著低于低密度混养池塘。浮游植物生物量与三角帆蚌密度成正相关关系,鱼蚌池塘中绿藻和裸藻的生物量在养殖过程中上升显著。低、中密度三角帆蚌混养池塘三角帆蚌存活率均显著高于高密度三角帆蚌混养池塘;低密度混养池塘中蚌湿重、壳长及壳宽相对增长率均为最大,显著高于中、高密度三角帆蚌混养池塘。研究表明,养鱼池塘混养三角帆蚌不仅能改善养殖池塘的水质,还能控制藻类数量,促使绿藻和裸藻等大型藻类的生长,提高养殖水体浮游植物的生物量总量,最终还能有效提高三角帆蚌的存活率及生长率。从改善水质,藻相结构,蚌成活率及生长等指标角度考虑,在鲢鳙鱼养殖池塘中,三角帆蚌最佳放养密度为1.0只/m3。     

摄食配合饲料的鱼密度和EM菌对蚌鱼综合养殖系统中浮游植物的影响

通过93 d围隔实验比较了增加摄食配合饲料的鱼(草鱼和银鲫)密度和添加EM菌对三角帆蚌、草鱼、银鲫、鲢和鳙综合养殖系统中浮游植物群落和初级生产力的影响。采用2×2实验设计,设4个处理:LF0(20尾草鱼+10尾银鲫)、LFA(20尾草鱼+10尾银鲫+EM菌)、HF0(40尾草鱼+20尾银鲫)和HFA(40尾草鱼+20尾银鲫+EM菌)。所有处理中三角帆蚌、鲢和鳙密度相同,均为每个围隔内40只蚌、8尾鲢和2尾鳙。实验期间围隔内不换水,每天分2次投喂配合饲料;定期向LFA和HFA围隔内泼洒EM菌。结果显示,围隔内出现浮游植物超过81种,分别隶属7门、32科、73属;实验前期浮游植物优势种为微囊藻和栅藻,后期转为微囊藻、平裂藻和腔球藻;浮游植物生物量平均为3.2×108～8.3×108个/L;摄食配合饲料的鱼密度和EM菌对浮游植物种类组成和多样性无显著影响,但高密度草鱼和银鲫组(HF0和HFA)中浮游植物生物量和群落呼吸强度较高,初级生产力较低;添加EM菌可降低蓝藻在浮游植物生物量中的比例,增加初级生产力。研究表明,在蚌鱼综合养殖中放养摄食配合饲料的鱼密度不宜过高。     

在淡水鱼类混养系统中吊养三角帆蚌对养殖产量和水质的影响

通过78 d围隔养殖实验检验了在草鱼、鲫、鲢、鳙混养系统中吊养三角帆蚌对鱼产量和水质的影响。设2个处理,处理Ⅰ混养草鱼、鲫、鲢和鳙,处理Ⅱ在处理Ⅰ基础上按鱼∶蚌=1∶1的比例配养三角帆蚌。实验期间定期采样分析浮游植物种类组成和生物量、初级生产力(P)、群落呼吸(R)、溶氧(DO)、pH、透明度(SD)、主要离子(CO2-3、HCO-3、Cl-、SO2-4、Ca2+、Mg2+)、总碱度、总硬度、氨态氮、亚硝酸态氮、硝酸态氮、活性磷、总氮(TN)、总磷(TP)、总有机碳(TOC)、高锰酸钾指数(COD M n)和生化耗氧量(BOD5)。结果发现,吊养三角帆蚌显著降低水体中Ca2+浓度,但对其他指标均无显著影响。处理Ⅱ草鱼、鲫、鲢产量略高于处理Ⅰ,而鳙产量略低于后者,表明在草鱼、鲫、鲢、鳙混养系统中按1∶1的比例配养三角帆蚌不会导致草鱼和鲫产量下降,但导致鳙产量降低。处理Ⅱ浮游植物多样性(Shannon-Weaver多样性指数、Margalef丰富度指数、Pielou均匀度指数和种类数)、P、P/R、SD和DO略高于处理Ⅰ,而氨态氮、活性磷、TN、TP、COD M n、BOD5和TOC略低于后者,表明在混养系统中配养三角帆蚌可显著降低养殖水体Ca2+浓度,同时可在一定程度上提高浮游植物多样性、P和DO并降低TN、TP、COD M n、BOD5和TOC。结果表明,在淡水鱼类混养系统中适度配养三角帆蚌可提高养殖的经济效益,同时有助于降低养殖系统内氮、磷和有机废物的积累。     

不同施肥方法对鱼蚌综合养殖池塘浮游植物群落结构的影响

通过155 d围隔实验检验了不同施肥条件下鱼蚌综合养殖水体中的浮游植物群落结构。实验设3个处理:施鸭粪、施化肥、兼施鸭粪和化肥。放养种类为三角帆蚌、草鱼、鲫、鲢和鳙,放养量分别为每围隔20、15、5、5和5个。结果发现,围隔内浮游植物生物量平均值为(2.1~6.0)×108个/L。不同施肥方法对浮游植物种类组成和优势种、叶绿素a(Chl.a)、生物量以及蓝藻在浮游植物生物量中的比例无显著影响。浮游植物群落变化表现出较明显的季节性特点,影响围隔浮游植物群落的理化因子为TN、NH3-N和DO。研究表明,采用不同施肥方法的围隔内浮游植物群落结构未表现出显著差异,难以从浮游植物角度解释兼施鸭粪和化肥的围隔珍珠产量高于施鸭粪或施化肥的围隔的事实,也难以确定珍珠产量与浮游植物群落结构之间存在必然的联系。     

不同鲢密度对千岛湖沿岸池塘浮游植物群落结构的影响

为了进一步检验中营养条件下滤食性鲢（Hypophthalmichthys molitrix）的控藻效应,于2017年5-9月,在浙江省淳安县千岛湖邵家鱼种场选择8口大小、形状等各种条件基本一致的池塘,设置无鱼（CK）0 g/m3、低密度（LD）10 g/m3、中密度（MD）20 g/m3和高密度（HD）30 g/m3共计4个鲢处理组,放养的鲢体重为（61.03±3.70）g、体长为（14.21±0.27）cm,经每月3次浮游植物样品采集和观察,探究不同密度的鲢放养对浮游植物群落结构的影响。结果表明,浮游植物优势种组成在不同处理组池塘间无显著差异。双因素方差分析表明,鲢密度和月份对浮游植物密度和生物量均有显著作用,月份而非鲢密度对其多样性产生显著影响,2个因素对浮游植物生物量有而对其密度和多样性指数无交互作用。3个有鲢处理组池塘藻类总密度和蓝藻密度均有较大幅度下降,它们的蓝藻密度、中高密度组池塘藻类总密度显著低于无鱼组;中、高密度组池塘蓝藻生物量、中密度组池塘藻类总密度均显著低于无鱼组和低密度组。实验结果表明,鲢对浮游植物的抑制作用具有密度效应,随鲢放养密度和水体藻类现存量的变化而变化,鲢中等密度放养能显著遏制浮游植物现存量,密度依赖的鲢滤食量对浮游植物的抑制作用明显大于营养短路和藻类小型化对浮游植物的促进效应。     

罗氏沼虾与三角帆蚌、鲢和鳙混养模式优化

研究了罗氏沼虾、三角帆蚌、鲢和鳙不同混养系统的养殖产量、饲料系数、增长率、总氮(TN)/总磷(TP)利用率和综合养殖效果,以期获得最优养殖模式。采用基于陆基围隔的比较实验方法,设6个实验组,分别为罗氏沼虾单养(G),罗氏沼虾与三角帆蚌二元混养(GH2)、罗氏沼虾、鲢和鳙三元混养(GSB),罗氏沼虾、鲢、鳙和三角帆蚌按照不同密度放养的四元混养(GSBH1、GSBH2和GSBH3),各实验组设置4个重复。结果表明:GSBH2组罗氏沼虾产量最高[(14.71±0.33)kg/32 m2],显著高于G组[(12.44±0.60)kg/32 m2,P0.01];GSBH1组饲料系数最低(1.43±0.04);GSBH1组增重率最高(4.66%±0.12%),G组最低(3.80%±0.23%);TN平均相对利用率在(0.92±0.09)~(1.60±0.23)之间,GSB组最高,G组最低;TP平均相对利用率为(0.23±0.03)~(1.46±0.32),GSBH3组最高,G组最低;综合养殖效果指数在(0.91±0.02)~(1.25±0.05)之间,GSB组最高,GSBH1组次之,G组最低,且三元、四元混养组显著大于G组和GH2组(P0.05)。研究表明,混养组能显著提高罗氏沼虾养殖的经济效益和生态效益。     

罗氏沼虾不同养殖模式对水体浮游生物的影响

通过围隔实验比较罗氏沼虾不同养殖模式对水体浮游生物的影响。实验设置6种养殖模式:罗氏沼虾单养(MP)、罗氏沼虾+浮萍(水面覆盖率5%)(PP)、罗氏沼虾+鲢(PF)、罗氏沼虾+背角无齿蚌+鲢(PMF)、罗氏沼虾+背角无齿蚌+浮萍(PMP)、罗氏沼虾+背角无齿蚌+浮萍+鲢(PMPF)。养殖64 d后,测定不同模式中浮游植物和三大类浮游动物(轮虫、枝角类及桡足类)的种类和数量。结果显示,上述6种模式中浮游植物共同优势种有4种,但优势度指数最大的浮游植物不同,MP组是锥囊藻属,有浮萍的PP和PMP组均为细小平裂藻,混养鲢的PF、PMF和PMPF组均为针杆藻。不同养殖模式无共同的浮游动物优势种。养殖模式对浮游生物密度具有显著影响,PF组浮游植物密度最高,MP组浮游植物密度最低,PF组浮游植物密度比MP、PP和PMP组分别高78%、53%和61%。相反,浮游动物密度MP组最高,PF组最低。混养鲢的PF、PMF和PMPF组浮游动物密度显著低于其他3组。研究表明,罗氏沼虾养殖中混养鲢可增加浮游植物密度而降低浮游动物密度,浮萍和鲢影响池塘优势种。     

不同混养鱼类和投喂方式对鱼蚌综合养殖水体化学特征的影响

选用草鱼(Ctenoparyngodon idellus)、银鲫(Carassius gibelio)、鲢(Hypopthalmichthys molitrix)、鳙(Aristichthysnobilis)作为本研究的混养鱼类,通过围隔实验检验了不同混养鱼类组合(草鱼+鲫+鲢+鳙或鲢+鳙)和配合饲料投喂方式(投喂或不投喂)对三角帆蚌(Hyriopsis cumingii)养殖水体化学特征的影响,实验为期155 d。结果表明,实验设计的混养鱼类组合可显著影响鱼蚌综合养殖水体的Ca2+、总碱度(Alk)、总硬度(HT)和总磷(TP)水平;投喂配合饲料可显著影响Ca2+、Alk、HT、氨氮(TAN)、TP和化学耗氧量(CODMn)。采用混养组合(草鱼+鲫+鲢+鳙)且投喂配合饲料的围隔内溶氧(DO)水平和透明度(SD)较低,Ca2+、HT、TN、TP、TAN和CODMn水平较高;采用混养组合(鲢+鳙)且不投喂的围隔内DO和SD水平较高,而Ca2+、HT、TN、TP、TAN和CODMn水平较低。随养殖时间延长,各组围隔内Ca2+水平下降,TN、TP、TAN和CODMn水平升高。实验期间,DO与SD水平呈正相关;DO和SD与TAN、TN、TP、Ca2+和CODMn水平呈负相关。因此,鱼蚌综合养殖中,控制CODMn和TAN浓度,维持Ca2+稳定及较高的DO水平是水质管理的基本目标。     

河蚌对草鱼混养精养池塘中浮游植物群落结构的影响

试验池塘4口,每口面积0.8hm2,水深1.8m,放养体质量50g的草鱼12000尾,体质量24~100g的鲢鱼500尾,体质量150g的鳙鱼100尾,常规管理,其中2口池塘放养1龄河蚌两万只,2口对照塘不放河蚌,定期采集水样,测定水中浮游植物种类和数(生物)量。结果表明,鱼蚌混养塘中有浮游植物6门48属94种,而对照塘中仅有6门42属91种。混养塘与对照塘水体中均以绿藻门的种类为主,分别占总数的47.8%和41.8%。鱼蚌混养组中以绿藻为优势种群,出现频率较高的优势藻类为:硅藻门的小环藻、针杆藻,绿藻门的小球藻、栅藻、新月藻;而对照组中的优势种不仅有试验组中的优势种类,还包含了蓝藻门的平裂藻、螺旋藻、微囊藻以及硅藻门的直链藻、舟形藻、双壁藻,绿藻门的梭形藻等。鱼蚌混养组与对照组中浮游植物多样性指数分别为1.24~1.41和1.26~1.36,鱼蚌混养组中浮游植物多样性指数均略高于对照组。鱼蚌混养组浮游植物密度为539.23×104个/L~1289.53×104个/L,生物量为6.68~12.47mg/L;对照组浮游植物密度为669.57~1608.50×104个/L,生物量为8.40~18.62mg/L,鱼蚌混养组浮游植物的密度和生物量略低于对照塘,且差异显著(P0.05)。结果表明,鱼蚌混养模式可有效控制塘中浮游植物的繁殖与生长,浮游植物的多样性指数提高,池塘生态系统更加稳定。     

基于16SrDNA比较研究混养三角帆蚌和鲢鳙对池塘养殖水体微生物群落结构的影响

为了研究混养三角帆蚌(Hyriopsis cumingii)和鲢(Hypophthalmichthys molitrix)鳙(Aristichthys nobilis)对池塘养殖水体微生物群落结构的影响,分别在浙江海盐、江西九江、上海浦东开展了罗氏沼虾-三角帆蚌混养、草鱼—三角帆蚌混养、罗氏沼虾-三角帆蚌-鲢鳙鱼混养三组系列实验。利用DGGE技术对养殖水体的16S r DNA进行指纹图谱分析。三组实验共鉴定出57条不同条带,每组实验中混养三角帆蚌或鲢鳙实验组的平均条带数均高于单养水体水样平均条带数。Shannon多样性指数分析结果显示,各养殖水体混养三角帆蚌、鲢鳙后,多样性指数均有所增加。PCA分析和DGGE聚类结果显示,在无鲢鳙的情况下,蚌与主养物种(罗氏沼虾、草鱼)混养实验组的16S r DNA图谱聚为一类,显示出蚌对于微生物群落结构影响的贡献;在同时引入鲢鳙和蚌的情况下,16S r DNA指纹图谱则是按照有无鲢鳙聚为两类,提示在本实验中鲢鳙对于水体微生物的影响要大于蚌。对DGGE图谱其中20条显著条带进行回收、测序和系统发育分析,结果表明,所获序列主要分属于放线菌门(Actinobacteria,25%)、蓝藻门(Cyanobacteria,25%)、α-变形菌亚门(Alphaproteobacteria,15%)、β-变形菌亚门(Betaproteobacteria,15%)、γ-变形菌亚门(Gammaproteobacteria,10%)、ε-变形菌亚门(Epsilonproteobacteria,5%)、裸藻叶绿体(Euglenales,5%)。     

鲢鳙混养对三角帆蚌生长和养殖水质影响的围隔实验

2008年4月23日—9月21日通过围隔实验,研究了不同鲢鳙混养比例对三角帆蚌生长及水化学指标的影响。实验中鲢鳙混养比例设置了6个水平,分别为0/0(对照组),100/0,70/30,50/50,30/70和0/100。实验开始和结束时测量三角帆蚌湿重,壳长和壳宽。每个月上下旬测量围隔水化学指标包括NO3N、NO2N、NH3N、TN、TP、PO4P和COD。实验结果表明,鲢鳙混养比例100/0的围隔蚌壳长相对生长率显著低于混养比例0/0,50/50和0/100的围隔(P<0.05),而不同混养比例下蚌的成活率、蚌壳宽及蚌重增长均无显著差异(P>0.05)。从水质来看,混养比例30/70围隔TP显著低于100/0(P<0.05),COD显著低于100/0及70/30(P<0.05),NH3N显著低于100/0(P<0.05)以及PO4P显著低于70/30(P<0.05)。因此,综合蚌生长及水质指标,混养比例30/70围隔对三角帆蚌养殖最有利。     

Effects of tilapia (Oreochromis niloticus L.) stocking and artificial feeding on water quality and production in rohu–common carp bi‐culture ponds

Previous research showed that stocking 1.5 rohu (Labeo rohita) and 0.5 common carp (Cyprinus carpio) m⁻² yields the highest production in small holder ponds in Bangladesh. The present study looked into the effects of additional stocking of Nile tilapia (Oreochromis nilotica) in fed or non‐fed ponds on water quality and fish production. A low, additional stocking density of 0.2 Nile tilapia m⁻² was tested. All treatments were executed in triplicate in 100 m² ponds and the duration of the experiment was 4.5 months. The results showed that tilapia addition increased nutrient concentrations and reduced total suspended solid concentration and phytoplankton biomass (P<0.05). Tilapia stocking resulted in additional production without affecting the growth and production of rohu and common carp. Supplemental feeding increased the nitrogen and phosphorus concentrations, phytoplankton availability and the growth and production of rohu and common carp (P<0.01). The combination of supplemental feeding and tilapia stocking resulted in a higher net yield than the other treatments (P<0.05). Stocking 1.5 rohu, 0.5 common carp and 0.2 tilapia m⁻² in fed‐ponds is a good culture combination for polyculture farmers in South Asia.     

Effects of integrated combination and quicklime supplementation on growth and pearl yield of freshwater pearl mussel, Hyriopsis cumingii (Lea, 1852)

The effects of integrated combination and quicklime supplementation on growth and pearl yield of a freshwater mussel, Hyriopsis cumingii (Lea, 1852), were examined through a 137-day growout in land-based enclosures. The integrated combinations examined were either mussel, bighead carp and gibel carp or mussel and bighead carp. Each combination was treated either with or without quicklime supplementation. One half of the mussels in each enclosure were grafted with pieces of the mantle epithelium while the other half were not. During the experiment, gibel carp were fed formulated feed while the mussel and bighead carp were fed natural live food. Quicklime was regularly provided in the enclosures as calcium replenishment. The species composition in the integrated system significantly affected growth in shell size and wet weight of the mussels regardless of the graft and pearl yield, while no significant effects of quicklime supplementation were detected. Growth rates in shell size and wet weight of both grafted and non-grafted mussels and pearl yield were slightly higher in the enclosures with mussel, bighead carp and gibel carp than those with mussel and bighead carp, although these differences were not statistically significant. The non-grafted mussel exhibited faster growth in shell size and wet weight than the grafted mussel within the same treatment. Results of the present study indicate that species combination in an integrated system can affect growth and pearl yield of H. cumingii . The species combination of mussel, bighead carp and gibel carp is recommended for commercial H. cumingii farming.     

Fish-management relationships in Israeli commercial fish farming

To analyse the relationships among fish species performance and management procedures, a database was built up with data from 31 fish farms during the period 1976–1987 (1673 observations) and analysed through multivariate statistics (factor analysis). The data include nurseries, grow-out and operational ponds with mono- and polycultures of common carp, Cyprinus carpio, tilapia hybrid, Oreochromis niloticus × O. aureus, silver carp, Hypophthalmichthys molitrix, and mullet, Mugil cephalus. The main conclusions include the following. (1) The highest total yields and best tilapia performances were obtained in polyculture ponds where tilapia was the main species. (2) The best carp performances occurred in grow-out polyculture ponds where carp was the main species. Carp performance was improved in polycultures with mullet and silver carp, irrespective of whether tilapia were present or not. (3) Carp and tilapia yields increased as the nutritional inputs (feed pellets, sorghum pellets, manure), pond size and culture duration increased. The effect of the nutritional input was not linear, but logarithmic. (4) Growth rate of common carp was more affected by total density and stocking size than that of tilapia. Better carp and tilapia growth occurred in grow-out ponds when stocked at large sizes and cultured during short periods, mainly when both species were present. (5) Carp growth varied with the geographical region and size of fish pond, being better in smaller than in larger ponds due to reduced access to natural benthic food in deep ponds.     

缺氧和有毒微囊藻胁迫下三角帆蚌鳃和主要消化器官以及晶杆体的扫描电镜观察

为了阐明缺氧和有毒铜绿做囊藻对三角帆蚌鳃和主要消化器官的毒理效应和组织病理,实验利用扫描电镜研究了暴露于缺氧和有毒铜绿做囊藻下三角帆蚌的鳃、胃、肠以及晶杆体等器官组织病理学变化。结果显示,从第7天开始缺氧和有毒藻类复合胁迫组三角帆蚌的鳃丝及柱状细胞出现大量坏死和脱落,胃肠腔面纤毛脱落、上史细胞破裂坏死,晶杆体在第5天已经完全消失;第7天单独缺氧组和单独有毒藻类组的鳃和消化道出现少量的病变,单独缺氧组晶杆体在第7天完全消失,单独有毒藻类组晶杆体则一直存在。胁迫消失后,3个实验暴露组的晶杆体都未恢复正常对照组水平,因此缺氧和有毒铜绿做囊藻对三角帆蚌鳃和消化系统产生不可恢复性损伤,双重胁迫组影响最为严重,缺氧胁迫组相对有毒铜绿做囊藻胁迫组影响更为显著。本研究为三角帆蚌在缺氧和有毒藻类胁迫下的生理适应机制提供了组织病理学上的参考,并为其作为富营养化水体治理工具种的可行性提供了理论依据。     

Low-density silver carp Hypophthalmichthys molitrix (Valenciennes) polyculture does not prevent cyanobacterial off-flavours in channel catfish Ictalurus punctatus (Rafinesque)

Silver carp Hypophthalmichthys molitrix (Valenciennes) were co‐cultured with channel catfish Ictalurus punctatus (Rafinesque) in 0.4 ha earthen ponds to determine the impacts of carp grazing on pond phytoplankton communities and cyanobacterial off‐flavours in catfish. Carp were stocked at densities of 0, 75, or 250 fish ha^?1 in seven replicate ponds per treatment. The mean chlorophyll a concentrations (a measure of phytoplankton standing crop) steadily increased in all treatments from about 100 μg L^?1 in April to more than 400 μg L^?1 by mid‐October. Silver carp had no affect (P>0.1) on chlorophyll a concentrations across all sampling dates (April though October) or for sampling dates late in the growing season (August–October) when the prevalence of cyanobacterial off‐flavours among catfish populations is usually greatest. Silver carp did not eliminate odour‐producing cyanobacteria from pond phytoplankton communities: on sampling dates in September and October, three to six ponds in all treatments contained populations of the odour‐producing cyanobacteria Oscillatoria perornata, Anabaena spp., or both. Failure of silver carp to eliminate odour‐producing cyanobacteria resulted in a relatively high incidence in all treatments of ponds with off‐flavoured catfish. On sampling dates in September and October, catfish in three to five ponds in each treatment were tainted with either musty (2‐methylisoborneol) or earthy (geosmin) off‐flavours. The presence of silver carp had no obvious effect on off‐flavour intensity: on each sampling date, at least three ponds in each treatment contained catfish described as distinctly to extremely off‐flavored. Apparently, hypertrophic conditions in catfish ponds overwhelm the effect of silver carp grazing at the low carp densities used in this study.