光合细菌对养殖水质及凡纳滨对虾抗病力的影响

在凡纳滨对虾养殖环境中人工引入不同浓度的光合细菌,监测氨氮、亚硝酸氮、化学需氧量的变化,15d后测定凡纳滨对虾的AKP、POD、PO、SOD、抗菌、溶菌活力,以及不同光合细菌浓度下凡纳滨对虾的成活率与体重增长率,研究光合细菌对水质和凡纳滨对虾抗病力的影响。结果表明,引入光合细菌可显著降低水体化学需氧量、氨氮含量,并抑制亚硝酸盐氮的产生,提高凡纳滨对虾的抗病力。当光合细菌投放浓度为3×103/mL时,水体中化学需氧量、氨态氮、亚硝酸盐氮含量的均值分别比对照组降低31.59%、43.42%、52.20%,差异显著(P<0.05);对虾的AKP、POD、PO、SOD、抗菌、溶菌活力分别比照组提高31.92%、72.29%、55.56%、31.61%、39.07%、69.51%,差异显著(P<0.05);成活率,体重增长率分别比对照组提高18.67%、34.03%,差异显著(P<0.05)。     

2种养殖模式下凡纳滨对虾池塘水质理化因子的变化特征

2016年4月23日至7月12日对地膜精养及普通土池模式下凡纳滨对虾池塘水体的主要理化因子进行跟踪监测,研究不同养殖模式对水质变化的影响。结果表明,2种养殖模式下池塘水体的p H和DO均随养殖时间的延长逐渐下降,地膜池与普通土池相比p H无统计学意义(P>0.05),但30 d起地膜池DO含量高于土池(P<0.05);地膜池和土池的COD、氨氮、亚硝酸盐和磷酸盐的含量总体上均呈上升趋势,但土池亚硝酸盐含量在养殖后期(70~90 d)迅速下降。     

牟氏角毛藻对对虾育苗水质及抗逆性的影响

在凡纳滨对虾((Litopenaeus vannamei)育苗水体中引入不同浓度的牟氏角毛藻(Chaetoceros muelleri),检测主要水质因子,测定凡纳滨对虾对主要环境因子抗逆性,研究微藻对水质和凡纳滨对虾抗逆性的影响。结果表明,不同浓度牟氏角毛藻可明显改善对虾育苗水体的水质,提高幼虾的抗逆性(P<0.05)。牟氏角毛藻浓度为0.6×108～1×108/L时,实验组氨氮含量比对照组降低37.29%～46.32%,亚硝酸氮含量降低48.65%～62.70%,化学耗氧量(COD)值降低9.99%～12.19%;实验组育苗成活率达78.7%～84.0%,对照组育苗成活率46.0%;在氨氮、亚硝酸盐氮、硫化氢、甲醛抗逆性实验中,实验组幼虾成活率分别为75%～80%、75%、75%～85%、65%～70%,均显著高于对照组(P<0.05)。     

虾池微藻定向培育及其对养殖环境因子的影响

采用微藻三级扩大培养技术,将在对虾养殖池选育的波吉卵囊藻Oocysits borgei引入凡纳滨对虾Litopenaeusvannamei高位养殖池,并检测养殖环境中微藻群落结构、水质因子、对虾抗病力相关因子、对虾生长情况,研究了以微藻生态调控为主的对虾防病技术。结果表明:养殖前、中、后期,波吉卵囊藻平均生物量占浮游植物总生物量分别为98.02%、78.89%和45.12%,成为虾池中的绝对优势种;作为优势种的持续时间长达77 d。波吉卵囊藻为主的微藻群落控制的水质较稳定,实验池氨氮和亚硝酸盐氮浓度较对照池低。对虾的血细胞数、溶菌(LSZ)活力、抗菌活力、超氧化物歧化酶(SOD)和酚氧化酶(PO)均显著高于对照池(P<0.05);血清蛋白含量差异不显著(P>0.05)。实验池对虾生长速度显著高于对照池(P<0.05)。可见,通过微藻的定向培育方法来优化虾池微藻群落结构,可改善养殖环境。     

凡纳滨对虾与点带石斑鱼的混养模式

对凡纳滨对虾(Litopenaeus vannamei)与点带石斑鱼(Epinephelus malabaricus)进行90 d的混养试验,研究点带石斑鱼混养密度、规格对凡纳滨对虾生长、成活率和产量的影响。结果表明,点带石斑鱼混养密度、规格均对凡纳滨对虾生长、成活率和平均产量的影响有统计学意义(P0.05)。在混养密度相同的条件下,混养小规格点带石斑鱼的凡纳滨对虾成活率比混养大规格点带石斑鱼提高15.1%~23.2%,平均产量比混养大规格点带石斑鱼提高19.0%~40.6%。随着点带石斑鱼混养密度增加,凡纳滨对虾成活率和平均产量呈下降趋势。小规格点带石斑鱼混养密度分别为0.4尾·m-2时,凡纳滨对虾成活率和平均产量最高,分别为66.25%%±7.24%、(1 181.0±101.8)kg,较单一养殖凡纳滨对虾成活率提高5.46%,平均产量提高16.2%;大规格点带石斑鱼混养密度为0.2尾·m-2时,凡纳滨对虾成活率和平均产量最高,分别为(52.04±6.11)%、(959.8±89.1)kg,但较单一养殖凡纳滨对虾成活率下降8.75%,平均产量下降5.88%     

异枝江蓠与凡纳滨对虾室内零换水混养

【目的】通过模拟养殖系统,在零换水条件下研究虾藻混养模式中藻体与对虾的生长。【方法】将异枝江蓠(Gracilaria bailinae)与凡纳滨对虾(Litopenaeus vannamei)混养,设置对虾混养密度(114±5)g/m~2,以及0、114、228、456、926 g/m~2 5个藻体密度梯度,混养时间为20 d,测定藻体和对虾的特定生长率,藻的光合特性参数,NH_4~+-N、NO_2~--N和NO_3~--N浓度。【结果】混养密度对藻体和对虾生长,藻的光合特性参数,NH_4~+-N、NO_2~--N和NO_3~--N浓度有显著影响(P0.05)。异枝江蓠密度为456g/m~2时,藻和对虾的特定生长率最高,分别为(1.63±0.04)%/d、(1.82±0.21)%/d;叶绿素荧光参数Fv/Fm和Y(Ⅱ)最高,分别为(0.61±0.00)μmol·m~(-2)·s~(-1)、(0.64±0.00)μmol·m~(-2)·s~(-1);NH_4~+-N、NO_2~--N和NO_3~--N浓度最低,较单养组分别降低27.7%、46.9%和45.1%。【结论】在零换水条件下,异枝江蓠混养密度为456 g/m~2时,更有利于藻体和凡纳滨对虾的生长,对水体中氮浓度的稳定效果最佳。     

中草药复合益生菌制剂对凡纳滨对虾生长、抗病力及水质的影响

将枯草芽孢杆菌、纳豆芽孢杆菌、地衣芽孢杆菌等比例混合,制成芽孢杆菌制剂;将芽孢杆菌制剂与粪肠球菌、嗜酸乳杆菌等比例混合制成复合益生菌制剂;将分别用3种芽孢杆菌发酵的中草药等比例混合制成中草药芽孢杆菌制剂;将分别用5种益生菌发酵的中草药等比例混合,制成中草药复合益生菌制剂。在饲料中分别添加4种益生菌制剂(活菌为2×10~7 cfu/g),研究4种制剂对凡纳滨对虾(Litopenaeus vannamei)生长、抗病力及水质的影响。结果表明:1)4种益生菌制剂均可提高凡纳滨对虾的成活率、增重率和饲料利用率(P0.05),中草药益生菌制剂组的促生长效果优于益生菌制剂组,以中草药复合益生菌制剂组促生长效果为最佳(P0.05);2)4种益生菌制剂均可维持对虾养殖水体p H值、氨态氮和亚硝酸盐含量的稳定(P0.05),中草药益生菌制剂对水质的改良效果优于益生菌制剂(P0.05);3)用1×10~8 cfu/m L的哈维氏弧菌(Vibro harveyi)菌液浴浸泡凡纳滨对虾10 d,凡纳滨对虾的累计死亡率由大到小依次为中草药复合益生菌制剂组(31.11%)、复合益生菌制剂组(35.56%)、中草药芽孢杆菌制剂组(37.78%)、芽孢杆菌制剂组(44.44%)、对照组(93.33%)。在饲料中添加一定比例的中草药复合益生菌制剂可提高凡纳滨对虾的生长指标、改善养殖水体环境、提高对虾的抗病力。     

抗菌肽对凡纳滨对虾生长和机体免疫的影响

基础饲料(对照组)中添加10g/kg抗菌肽制剂喂养体重0.10±0.01g、体长2.17±0.11cm的凡纳滨对虾(Penaeus vannamei)30d,进行10d的水浴攻毒(鳗弧菌10~8/mL),探讨饲料中添加抗菌肽对凡纳滨虾生长、成活率、免疫保护率,以及肌肉中溶菌酶活性、超氧化物歧化酶活性、总抗氧化能力的影响。结果表明:饲料中添加抗菌肽可显著提高凡纳滨对虾相对增重率、成活率和对致病菌的免疫保护率(P<0.05),但对饲料系数无显著影响(P>0.05);未受外界微生物刺激时,饲料中添加抗菌肽对凡纳滨对虾总抗氧化能力有促进作用(P<0.05),受外界微生物刺激后,饲料中添加抗菌肽喂养凡纳滨对虾可提高对虾超氧化物歧化酶活性(P<0.05)和总抗氧化能力(P<0.01)。因此饲料中添加抗菌肽喂养凡纳滨对虾可提高其机体非特异性免疫。     

大黄对凡纳滨对虾生长和非特异性免疫指标的影响

在凡纳滨对虾饲料中分别添加大黄0、0.5、1.0、5.0、10.0和20.0g/kg,研究大黄对凡纳滨对虾(初始体重为0.34±0.004g)生长及非特异性免疫指标的影响。结果表明,大黄对凡纳滨对虾成活率、增重率、特定生长率、饲料系数、蛋白质效率和蛋白质累积率的影响不显著(P>0.05),对全虾和尾肌肉的灰分、脂肪和粗蛋白含量影响显著,全虾的粗蛋白和粗脂肪含量以1.0g/kg组最高(P<0.05),对凡纳滨对虾血清碱性磷酸酶、酸性磷酸酶、酚氧化酶、超氧化物歧化酶、溶菌酶以及血清总蛋白量等的影响显著,溶菌酶活性以1.0g/kg组最高(P<0.05);细菌感染实验中以1.0g/kg组存活率最高(P<0.05)。以非特异性免疫反应指标及感染实验存活率为指标,凡纳滨对虾饲料中大黄的适宜添加量为1.0g/kg。     

酵母培养物替代鱼粉对凡纳滨对虾生长性能、血清生化指标、免疫力和抗病力的影响

【目的】探讨高蛋白酵母培养物替代鱼粉对凡纳滨对虾(Litopenaeusvannamei)生长性能、血清生化指标、非特异性免疫力和抗病力的影响。【方法】在基础饲料中分别添加质量分数0、2.5%、5.0%和7.5%酵母培养物(记为Y0、Y2.5、Y5.0和Y7.5组),分别替代质量分数0、10%、20%和30%的鱼粉,配制4种等氮等脂饲料,饲喂凡纳滨对虾(初始体质量0.70±0.03 g)56 d后,测定对虾生长性能、血清生化及免疫酶指标;用哈维氏弧菌(Vibrioharveyi)攻毒,测定对虾累计死亡率。【结果】Y2.5和Y5.0组凡纳滨对虾增重率和特定生长率与Y0组的差异无统计学意义(P 0.05),Y5.0组凡纳滨对虾摄食率显著高于Y0和Y2.5组(P 0.05);Y5.0组凡纳滨对虾血清甘油三酯含量显著低于Y0组(P0.05),Y7.5组凡纳滨对虾血清谷丙转氨酶含量显著高于Y0、Y2.5组(P 0.05),血清总胆固醇显著低于Y0、Y2.5组(P 0.05);酵母培养物替代饲料中20%和30%的鱼粉可显著提高对虾攻毒前肝胰腺超氧化物歧化酶、过氧化物酶活性(P 0.05),Y7.5组对虾肝胰腺丙二醛含量在哈维氏弧菌(Vibrio harveyi)攻毒后显著低于Y0组(P 0.05);攻毒7 d后,Y7.5组凡纳滨对虾累积死亡率显著低于Y0组(P0.05)。【结论】酵母培养物替代鱼粉比例小于20%时,不会显著影响凡纳滨对虾生长性能;替代比例为30%时,生长受抑制。当替代量比例为30%时可显著提高凡纳滨对虾非特异性免疫力和抗病力。     

凡纳滨对虾高位池养殖系统的水质理化状况

对凡纳滨对虾高位养殖池水质环境状况进行了研究。结果表明,养殖期间虾池水体透明度前期较高,中后期较低;虾池pH变化在7.89~9.02之间,变化幅度较小。虾池水体悬浮物数量和CODMn随养殖时间延长而持续升高,变化范围分别为18.5~162.3 mg/L和3.52~14.58 mg/L。虾池水体中营养盐各月份波动较大,无机氮的数量变化在0.206~1.621 mg/L之间,含量逐渐升高,磷酸盐数量变化在0.009~0.067 mg/L之间,含量逐渐下降。水环境中N、P比较高,平均为62.7。养殖水体中后期处于严重富营养化状态。     

虾—鱼—贝—藻多池循环水生态养殖模式的研究

建立了一种虾、鱼、贝、藻多池循环水生态养殖及水质生物调控系统 ,该系统包括对虾养殖、鱼类养殖、贝类养殖、大型海藻栽培等 4个功能不同的养殖区 ,1个水处理区及 1个应急排水渠。通过在封闭循环系统内不同池塘中放养生态位互补的经济动植物 ,对虾池水质环境进行生物调控。结果表明 ,循环系统内虾池水层悬浮物数量、COD值、氨态氮含量比对照组单养对虾池明显降低 (t检验 ,P <0 .0 1)。养殖后排放水不处于富营养化状态 (E <1)。投入每千克对虾饲料生产0 .6 6 7kg对虾 ,同时生产 0 .0 37kg罗非鱼、0 .738kg牡蛎、0 .4 37kg江蓠 ,饲料利用率和经济效益显著增加。该养殖模式还具有防病性、环保性、高效性等优点     

Closed recirculating system for shrimp-mollusk polyculture

This paper deals with a new system of aquaculture, i.e., a closed recirculating system for shrimp-mollusk polyculture. The culture system consisted of several shrimp ponds, a mollusk water-purifying pond and a reservoir. During the production cycle, water circulated between the shrimp and mollusk ponds, and the reservoir compensated for water loss from seepage and evaporation. Constricted tagelus, Sinonovacula constricta, was selected as the cultured mollusk, and Pacific white shrimp, Litopenaeus vannamei, as the cultured shrimp. The main managing measures during the production cycle were： setting and using the aerators; introducing the probiotic products timely into the shrimp ponds; adopting a “pen-closing” method for controlling shrimp viral epidemics; setting the flow diversion barriers in the mollusk pond to keep the circulating water flowing through the pond along a sine-like curve and serve as substrate for biofilm; no direct feeding was necessary for the cultured mollusk until the co-cultured shrimp was harvested; natural foods in the water from the shrimp ponds was used for their foods. Two sets of the system were used in the experiment in 2002 and satisfactory results were achieved. The average yield of the shrimp was 11 943.5 kg/hm^2, and that of the mollusk was 16 965 kg/hm^2. After converting the mollusk yield into shrimp yield at their market price ratio, the food coefficient of the entire system averaged at as low as 0.81. The water quality in the ponds was maintained at a desirable level and no viral epidemics were discovered during the production cycle.     

COMPARATIVE STUDIES ON NITROGEN BUDGETS OF CLOSED SHRIMP POLYCULTURE SYSTEMS＂

April to October, 1997 comparative studios on the nitrogen budgets of closed shrimp polyculture systems showed that, in all the studied polyculture systems, nitrogen from feeds and fertilizers were the main input items, which comprised 70.7% - 83.9% of the total input nitrogen, 3.2% - 7.4% of which was provided by nitrogen fixation. It was in monoculture enclosures (Y-4, Y-11 and Y-12) that the percentage reached the maximum value. The output nitrogen in harvested products comprised 10.8% - 24.6% of total input nitrogen, and the highest percentage, 24.6%, was found in shrimp-fish-tagelus polyculture systems. In shrimp monoculture and shrimp-fish polyculture systems, they were 19.1% and 21.9%, respectively. The nitrogen utilization efficiency was different and varied from 12.2% to 20.1%. The highest, 20.1%, was found in shrimp-fish-tagelus polycultttre systems, and the average of 20.0% was found in shrimp-tagelus polyculture systems. The lowest, 12.2%, was found in shrimp monoculture systems.All the nitrogen utilization efficiencies in shrimp-fish systems or shrimp-scallop systems seemed to be higher than that of the monoculture system, but they showed little statistical difference. The main outputs of nitrngen were found in sediment mud, and comprised 48.2% -60.8% of the total input, the lowest percentage was found in shrimp-fish-tagelus polyculture systems, and the highost percentage in shrimp-scallop systems.During the experiment, nitrogen lost through denitrification and ammonia volatilization comprised 1.9% - 6.2%, averaged 2.8%, of the total input, and the loss through seepage comprised 5.9% - 8.9% of the total.The estimated nitrogen attached to the enclosure wall comprised 3.7% - 13.3% of the total, and was highest in shrimp monoculture systems. Compared with the classic shrimp farming industry, the closed shrimp polycul-ture systems may improve the nitrogen utilization efficiency, and hence reduce the environmental impacts on coastal waters. The nitrogen discharging rates for all the studied polyculture systems ranged from 3.0% to 6.0% of total input nitrogen.     

Trophic Interaction in a <Emphasis Type="Italic">Portunus rituberculatus</Emphasis> Polyculture Ecosystem Based on Carbon and Nitrogen Stable Isotope Analysis

Trophic interaction among various biomass groups in a swimming crab Portunus trituberculatus polyculture pond was investigated using carbon and nitrogen stable isotope analysis. The polycultured animal species also included white shrimp Litopenaeus vannamei, short-necked clam Ruditapes philippinarum, and redlip mullet Liza haematochila. The mean δ¹³C value for all the biomass groups in polyculture ecosystem ranged from ?25.61‰ to ?16.60‰, and the mean δ¹⁵N value ranged from 6.80‰ to 13.09‰. Significant difference in the δ¹³C value was found between particulate organic matter (POM) and sediment organic matter (SOM) (P < 0.05), indicating that these two organic matter pools have different material sources. Assuming that a ¹³C-enrichment factor of 1.00‰ and a ¹⁵N-enrichment factor of 2.70‰ existed between consumer and prey, diets of the four cultured animals were estimated using a stable isotope mixing model. The estimated model results indicated that P. trituberculatus mainly feed on Aloidis laevis; L. vannamei mainly feed on shrimp feed; while A. laevis, R. philippinarum and L. haematochelia mainly feed on POM. Shrimp feed was also an important food source of R. philippinarum and L. haematochelia. The diets of P. trituberculatus, L. vannamei, R. philippinarum, and L. haematochila showed complementary effects in this polyculture ecosystem. Our finding indicated that the polyculture of these four organisms with suitable farming density could make an effective use of most of the food sources, which can make a highly efficient polyculture ecosystem.     

小东江茂名段浮游生物及污染状况分析

2007年7月对茂名市小东江的浮游生物及污染状况进行调查和分析,结果共检出浮游植物122种,其中蓝藻门15属34种,占(总种类数,下同)27.9%,硅藻门16属26种,占21.3%,绿藻门29属52种,占42.6%,裸藻门3属6种,占4.9%,金藻门1属1种,占0.8%,黄藻门3属3种,占2.5%;浮游动物78种,其中原生动物门26属36种,占46.2%,轮虫动物门9属16种,占20.5%,节肢动物门枝角类8属14种,占17.9%,桡足类10属11种,占14.1%,水生昆虫1属1种,占1.3%。各调查断面浮游植物的种类数平均为37种,细胞密度在11.3×104~19.5×104/L,Ⅴ断面最高,Ⅰ断面最低,平均为14.4×104/L;浮游动物种类数平均为27种,密度平均为2 895/L。相邻断面间Jaccard种类相似性指数范围为0.13~0.23,各断面环境异质性相差较大,该季节河水流动性小。叶绿素a含量为19.9~45.3μg/L,它与细胞密度呈显著的正相关,与无机氮、无机磷和COD均不存在明显的相关性。各断面的浮游植物多样性指数为3.1~4.5,均匀度为0.62~0.85;浮游动物的多样性指数为2.7~3.9,均匀度我0.59~0.80。对βm-αm指示种种类组成和群落结构分析,Ⅱ、Ⅲ、Ⅳ、Ⅴ断面水质属生态中污类型,而Ⅰ断面属生态寡污类型。以国家地表水质量标准评判,各断面COD含量为Ⅰ类水;无机氮含量除Ⅰ断面外,其他断面均为Ⅲ类水;无机磷含量均优于Ⅱ类水;石油类除Ⅰ、Ⅱ断面为Ⅳ类水外,其他断面均为Ⅴ类水。单因子污染指数分析表明,小东江流域水质为中污染至重污染之间。     

中国江蓠的商品生产及其与对虾混养(英文)

以江湾和对虾混养预防虾病。试验和生产实践表明，江蒿和对虾混养能明显地改善虾池水质，防止对虾细菌性病害，除江南有一定产量外，可使对虾产量比单养增加60％以上。并论述了中国江蓠人工栽培的种类、生长条件和主要生产方式。     

珠海地区凡纳滨对虾淡水养殖池浮游植物群落的演替

对珠海凡纳滨对虾淡水养殖池塘浮游植物及其理化因子进行了调查和分析,结果表明:调查中共检出浮游植物143种,优势种主要有林氏藻、螺旋鱼腥藻、小颤藻、微囊藻和点状平裂藻等,物种多样性指数在0.24~2.77之间,优势度与多样性指数呈显著的负相关,相关系数r=-0.984;而均匀度与多样性指数呈显著的正相关,相关系数r=0.967,养殖后期优势度不高,浮游植物的密度及化学因子的浓度到后期都有所上升,藻类密度的剧烈变化会引起氨氮和硫化氢含量的变化;藻类密度的波动滞后于无机氮的波动,群落演替具有突发性、时间短、速度快等特点。     

凡纳滨对虾常见养殖模式下养殖后期浮游植物及理化因子的变化

对凡纳滨对虾几种常见养殖模式后期的浮游植物及理化因子进行了调查研究,结果表明,浮游植物的群落特征因养殖模式、养殖时间、不同的环境条件等原因变化很大,其群落组成由最少的11种到最多的28种不等;其优势种与次优势种中以蓝藻门、绿藻门、硅藻门为主,甲藻门、裸藻门偶有出现,主要优势种有小环藻、波吉卵囊藻、中肋骨条藻、颤藻、林氏藻、裸甲藻、胶球藻、小席藻、腔球藻等,浮游植物群落的生物多样性由高至低依次为高位池分级精养模式、海水土池粗养模式、低盐度养殖模式、咸淡水半精养模式、工厂化集约养殖模式、高位池集约养殖模式,多样性指数与优势度呈显著的负相关,而与均匀度呈显著的正相关。细胞密度485.9×104~35459.8×104L-1,在高密度精养模式中,浮游植物的密度与无机氮、硫化氢含量的变化在早期呈负相关,在后期则几乎同步增长;在低密度养殖模式中,浮游植物的密度与无机氮、硫化氢含量的变化始终呈负相关。各养殖模式pH值的变化与浮游植物的密度呈正相关。综合分析表明,高密度养殖宜采用高位池分级精养模式,低密度养殖宜采用海水土池粗养模式。