饵料对河蟹zao状幼体变态发育的影响

报道饵料对河蟹Zao状幼体(Z1-Z3)变态的影响。结果表明：梅尼小环藻是Z1的适口饵料,适量投喂浓度为80万个／m1至l00万个／m1;投喂衣藻或小环藻与衣藻的等浓度混合饵料都不能使Z1顺利变态为Z2。20个／m1褶皱臂尾轮虫密度是适于Z2的饵料密度,轮虫密度低于5个／m1或高于40个／m1都对Z2的变态有不良影响。另外,投喂60万个／m1小环藻加20个／m1轮虫混合饵料对Z2变态发育更为有利;而用20万个／m1衣藻加20个／m1轮虫投喂Z2,却使Z2的变态率明显降低。30个／m1轮虫密度是适于Z3的饵料密度,轮虫密度低于20个／m1或高于40个／m1都会对Z2变态产生不良影响。     

三种淡水藻类对萼花臂尾轮虫培养效果的比较

在28℃下,采用群体累积培养法,探讨了不同浓度的蛋白核小球藻（Chlorella pyrenodeosa）、水华鱼腥藻（Anabaena flas-aquae）和沙角衣藻（Chlamyclomoras sajao）,以及在等生物量条件下,以上3种藻类两两配比饵料（3：1、1：1和1：3）对萼花臂尾轮虫（Brachionus calyciflorus）的培养效果。结果表明,不同浓度的蛋白核小球藻、水华鱼腥藻和沙角衣藻对萼花臂尾轮虫增殖效果的影响分别表现为差异极显著（P〈0．01）、显著（P〈0．05）和不显著（P〉0．05）;蛋白核小球藻与水华鱼腥藻组成的混合饵料对萼花臂尾轮虫的增殖效果均优于其中的单一种类（P〈0．05）;沙角衣藻无论是单独投喂,还是与其它藻类混合投喂,轮虫的培养效果均不理想。因此,该种类不宜用作轮虫饵料开发。该研究还表明,蛋白核小球藻是培养萼花臂尾轮虫的最适单一种类,它与水华鱼腥藻组成的混合饵料培养萼花臂尾轮虫效果更好。     

食物种类对萼花臂尾轮虫种群增长率的影响

在短期慢性观测过程中,食物类型可能是造成萼花臂尾轮虫(Brachionuscalyciflorus)种群繁殖率变化的一种原因。共观测了分别单独投喂10种不同绿藻对轮虫种群增长率的影响。为验证藻青菌是藻类饵料(如绿藻Scenedesmus)有价值的佐剂这一假说,还用蓝细菌单独投喂或与斜生栅藻(Scenedesmusobliquus)混合投喂轮虫进行实验观测。结果发现食物种类对萼花臂尾轮虫种群增长率影响显著。斜生栅藻组获得最大种群增长(1.6/d),而Desmodesmus组增长率最低(0.3/d)。以占斜生栅藻组最大增长的百分率来表示,其它几种绿藻组种群增长由高到低依次为:Desmodesmussubspicatus88%,小球藻(Chlorellavulgaris)83%,单壳缝藻(Monoraphidiumminutum)77%,D.quadricauda74%,S.falcatus71%,S.acuminatus69%,S.pectinatus64%,莱茵衣藻(Chlamydomonasreinhardtii)57%,D.abundans19%。轮虫增长率的差异不能用藻类饵料的大小差异来解释。蓝细菌(Microcystisaeruginosa)和(Synechococcuselongates)不论是单独投喂还是与优良藻类饵料(斜生栅藻)混合投喂都对萼花臂尾轮虫种群增长有抑制作用。这种副作用似乎与微囊藻素无关。该结果不支持无毒蓝细菌可作为与其他绿藻饵料配合使用的优良佐剂这一假说。本研究所观察到的生长变化显示了饵料种类对萼花臂尾轮虫种群增长的影响,也预示了对毒性实验结果的影响     

食物种类和浓度对壶状臂尾轮虫实验种群动态的影响

使用浓度为0.3mg/mL的椭圆小球藻、尖细栅藻和两者以1:1(湿重比)组成的混合藻在26±1℃下对壶状臂尾轮虫进行单个体培养研究。结果表明,虽然三类食物对轮虫的胚胎发育时间和平均寿命无显著影响,但投喂小球藻时轮虫的生殖前期明显比投喂栅藻或混合藻时短,投喂小球藻时轮虫的生殖期明显比投喂栅藻时长;轮虫的生殖后期历时以栅藻组最长,混合藻组次之,小球藻组最短,三者间具显著差异。轮虫的繁殖率、产卵量和种群内禀增长率均以小球藻组最高,混合藻组次之,栅藻组最低。由此可见,小球藻是该种轮虫培养的最适饵料。以浓度为0.375、0.75、1.5、3.0和5.0×106cells/mL的椭圆小球藻为食物在23±1℃下对壶状臂尾轮虫进行单个体培养研究发现,0.75×106cells/mL是其生存和繁殖的最低浓度阈值;食物浓度对轮虫的胚胎发育时间和生殖后期历时无显著影响;食物浓度为1.5×106cells/mL和3.0×106cells/mL时,轮虫各主要发育阶段的历时和产卵量间也无显著差异;食物浓度高于3.0×106cells/mL或低于1.5×106cells/mL对轮虫的生殖前期无显著影响,但使轮虫的平均寿命和产卵量显著减小;食物浓度高于3.0×106cells/mL时,轮虫的生殖期显著缩短。轮虫种群的繁殖率、净生殖率和内禀增长率皆以3.0×106cells／mL组最高,1.5×106cells／mL组次之,0.75×106 cells／mL和5.0×106cells／mL组较低。因此,轮虫种群增长的适宜食物浓度范围为1.5-3.0×106cells／mL,最适食物浓度是3.0×106cells／mL。       

褶皱臂尾轮虫生产性培养的对比试验

褶皱臂尾轮虫(Brachionus plicatilis)是鱼类的仔、稚、幼鱼和虾类幼体最好的活饵料,同时可以净化水质,提高鱼虾育苗成活率和成长度。本文对其生产性大量培养的条件进行了对比试验。1不同饵料种类的对比试验以五个3.5m3/个的水池接种2个/毫升轮虫,分别以扁藻Platymonas sp.、小球藻Chlorella sp.(均来自南海所藻种室)、骨条藻Skeletonema sp.(来自沙头角海区)20—30万个细胞/毫升投喂,随着藻类不断被摄食,不断给予补充,使培养水始终保持20—30万个细胞/毫升的浓度,另外2个池子只投喂人工饲料(面粉或米糠),每日3—4克/m3水体,各池均不断充…     

几种培养方法对萼花臂尾轮虫(Brachionus calyciflorus)种群密度及其环境因子影响的比较研究

分别利用泥鳅 -藻 -轮虫和罗非鱼 -藻 -轮虫共生隔离培养的方法 ,研究萼花臂尾轮虫 ( Brachionuscalyciflorus)的种群密度和主要环境因子的变化。研究结果表明 :加入泥鳅的培养缸中 ,有 1 1 d轮虫数量超过 1 0 0 ind/ml,其中有 5d超过 2 0 0ind/ml,最高密度达 2 50 ind/ml;在罗非鱼的培养缸中 ,在整个实验过程中 ,种群密度超过 1 0 0 ind/ml以上的时间有 6d(第5～ 1 0天 ) ;单纯利用藻类培养轮虫时 ,种群密度较低 ,且维持时间较短 ,最高种群密度不足 1 0 0 ind/ml,利用藻类 -轮虫 -鱼类共存同一生态系统中 ,并使鱼类和轮虫隔离进行生态培养时 ,能提高轮虫种群密度 ,延长种群高峰期     

不同饵料对魁蚶稚贝生长和存活的影响

在温度23.5～24.0 ℃和盐度29.5～30.0条件下,研究了球等鞭金藻、小球藻、牟氏角毛藻和新月菱形藻4种单细胞藻类单独及组合投喂24 d后对魁蚶稚贝生长与存活的影响.结果表明: 不同饵料投喂条件下,稚贝存活率均在95%以上,不同处理组间差异不显著.单一饵料投喂组中,球等鞭金藻组的稚贝生长最快,小球藻组的稚贝生长最慢.组合投喂组中,球等鞭金藻与其他3种单胞藻混合(1∶1)投喂组稚贝壳长及特定生长率均优于其他组,其中与小球藻混合投喂的效果最好,稚贝壳长和壳高的特定生长率分别为5.6%·d^-1和6.4 %·d^-1.研究结果可为魁蚶人工苗种培育技术的优化提供参考依据.
     

酵母及与藻类搭配对萼花臂尾轮虫饵料效果的研究

研究了２种酵母单独投喂萼花臂尾轮虫的最适密度、饵料效果及与藻类搭配的投喂效果．结果表明,在５种密度下,面包酵母和啤酒酵母的最适密度分别为１０和５×１０６个·ｍｌ－１．用面包酵母和啤酒酵母培养轮虫所得到的种群密度和瞬时增长率分别是用蛋白核小球藻培养的４０．２％、２６．０％和８５．５％、７６．６％．用面包酵母和蛋白核小球藻适当比例搭配投喂轮虫,其效果接近或超过单一用小球藻在最适密度下的培养效果．     

不同饵料和饥饿对魁蚶幼虫生长和存活的影响

在水温23.2-24.0℃,盐度29.5-30.0条件下,研究了5种单胞藻饵料和饥饿对魁蚶浮游幼虫生长与存活的影响.投喂不同饵料试验中,球等鞭金藻与4种单胞藻混合投喂试验组幼虫的特定生长率、眼点幼虫比例和壳长均显著高于单一投喂试验组,其中球等鞭金藻与小球藻混合投喂的效果最好;投喂单一饵料试验中,球等鞭金藻组幼虫的生长、眼点幼虫比例与存活率显著高于其它试验组.在饥饿试验中,不同饥饿天数条件下幼虫的存活率差异不显著;生长方面,饥饿1-2d较短时间与一直投喂对照组的幼虫相比较,特定生长率、眼点幼虫比例、壳长的差异不显著,但随着饥饿时间延长,幼虫的生长变慢且眼点幼虫比例下降,一直饥饿情况下幼虫的生长基本停滞.研究结果可以为魁蚶人工苗种繁育技术的改进提供参考依据.     

两种微藻对凡纳滨对虾幼体成活率的影响

试验旨在研究钝顶螺旋藻(Sprinulian platensis)和Picochlorum sp.两种微藻培育凡纳滨对虾(Litopenaeus vannamei)幼体效果, 为开发凡纳滨对虾开口饵料提供参考依据。实验对照组D0 投喂商品螺旋藻粉, 实验组D1、D2 分别投喂钝顶螺旋藻和Picochlorum sp., 每组3 个重复,每个重复2 万尾凡纳滨对虾幼体, 在300 L 育苗桶中饲养七天。 结果表明, D0 和D1 组间凡纳滨对虾存活率无显著差异(P＞0.05), 但两组极显著高于D2 组(P＜0.01)。在凡纳滨对虾育苗过程中, 水体总氨氮浓度小于50 umol·L^-1、亚硝酸盐氮浓度小于2 umol·L^-1。钝顶螺旋藻可以保证较高的幼体变态存活率, 可以作为凡纳滨对虾开口饵料新资源开发利用。     

Growth and physiological changes during metamorphosis of Senegal sole reared in the laboratory

The metamorphosis of Solea senegalensis was studied in larvae reared at 20° C and fed four different feeding regimes. A, Artemia (4 nauplii ml⁻¹); B, Artemia (2 nauplii ml⁻¹); C, mixed diet (2 nauplii ml⁻¹ and 3 mg ml⁻¹ microencapsulated diet); and D, microencapsulated diet (3·7 mg ml⁻¹). Rotifers were also supplied in all cases during the first days of feeding. These feeding regimes supported different growth rates during the pre-metamorphosis period (regime A, G=0·376 day⁻¹; regime B, G=0·253 day⁻¹; regime C, G=0·254 day⁻¹; regime D, G=0·162 day⁻¹). Larvae started metamorphosis 9 days after hatching (DAH) when fed the regime A, 13 DAH with regime B, 11 DAH with regime C and 15 DAH with regime D. A minimum 5·6–5·9 mm L_T was required under all feeding regimes to initiate the metamorphosis. Eye translocation was completed when the larvae reached 8·6–8·7 mm L_T (regimes A, B and C), but only 7·3 mm L_T with regime D. 4·4–6·2 days were required to complete eye migration under the regimes A, B and C, and 18·3 days under the regime D. This transformation is concomitant with changes in body reserves, and with the pattern of some digestive enzymes.     

蒙古裸腹溞与褶皱臂尾轮虫的种间关系

在实验室内将蒙古裸腹溞按0．06、0．10、0．30、0．60个·ml^-1的密度与褶皱臂尾轮虫(密度为0．3个·ml。)进行}昆合培养,同时按上述密度分别单种培养了蒙古裸腹溞和褶皱臂尾轮虫作为对照．结果表明,蒙古裸腹溞与褶皱臂尾轮虫之间存在种间竞争,当二者共存时,褶皱臂尾轮虫对蒙古裸腹溞种群产生压制作用,使蒙古裸腹溞在混合培养体系中以很低的密度存在,而褶皱臂尾轮虫种群受蒙古裸腹溞影响不大．通过进一步的饥饿实验发现90％的褶皱臂尾轮虫经过144h饥饿后仍然存活,而经过120h饥饿后的蒙古裸腹溞100％死亡,褶皱臂尾轮虫耐饥饿能力较强是其在与蒙古裸腹溞竞争中获胜的原因之一。     

Development of larval diets for milkfish (Chanos chanos)

This study aimed to develop nutritionally balanced and cost-effective processed diets for milkfish larvae ( Chanos chanos Forsskal). Two larval diets (feed A and feed B) were formulated and prepared to contain 45&percnt| protein and 10&percnt| lipid. Several larval diet preparations were tried such as microbound/ unpelleted (freeze-dried), microbound/pelleted (oven-dried) and microbound/flaked (drum-dried) and assessed in terms of feed particle size and buoyancy, water stability and feed acceptability. The preparation that gave the best particle size and buoyancy as well as good water stability was prepared as the microbound diet (using K -carrageenan as a binder) and flaked using a drum drier. A series of feeding experiments were conducted to determine the growth and survival of milkfish larvae reared on various feeding schemes using these processed larval diets which were fed either solely or in combination with live feed. Larvae in control treatments were reared on live foods such as Brachionus plicatilis and Artemia nauplii. Larvae were observed to ingest the diets, indicating that the feeds had suitable physical characteristics and were attractive to the larvae. The overall results of the feeding trials showed that the artificial diets could be fed to milkfish larvae in combination with Brachionus rotifers starting on day 2 or day 8, and could be fed alone starting from day 15. These promising results would reduce the dependence of milkfish larvae on live feed and would have significant economic benefits in the form of simplified milkfish hatchery procedures.     

Larval survival and growth of Arbacia punctulata (Echinodermata: Echinoidea) fed with five micro-algae at two salinities

Fertilized eggs from an spontaneously spawn of thirty sexually mature sea urchins (Arbacia punctulata) were incubated to complete embryonic development. The echinopluteus larvae (3 ind/ml) were distributed into 50 plastic containers (25 containers at 30 psu and 25 containers at 40 psu) and fed on Tetraselmis chuii, Nannochloropsis oculata, Isochrysis galbana, Chaetoceros gracilis and C. calcitrans under a natural photoperiod. The water of the containers was partially renewed (75%) everyday. Larval anatomic development aspects, daily survival and growth were determined. The growth was determined through postoral arms and body length measurement, and body diameter of twelve larvae during metamorphosis. During the planktonic larval phase, only the I. galbana diet produced similar results for both salinities. The relative growth of larvae was isometric (I) for larvae fed on I. galbana at two salinities and positive allometric for those fed on C. gracilis and C. calcitrans at both salinities. In this study A. punctulata started metamorphosis at day 14 and was completed 30 days after fecundation. Significant differences were detected in post-settlement body growth between the two salinities (F = 23.58, p < 0.05): growth was better for larvae at 30 psu (final body diameter was 3.14 +/- 0.44 mm). The final rate of planktonic larvae was highest with I. galbana (58.33%). For juveniles the rate was 6.48% for those fed on C. gracilis (40 psu in both larvae and juveniles). We recommend the use of this diet and 40 psu for survival or 30 psu for growth.     

Effect of varying levels of dietary essential fatty acid during early ontogeny of the sea scallop Placopecten magellanicus

This study investigated the biological effects of various dietary essential fatty acids levels to sea scallop larvae, Placopecten magellanicus. Scallop larvae were fed three diets from D-veliger to settlement. Diet A consisted of Isochrysis sp. and Pavlova lutheri, diet B was a mix of Isochrysis sp. and Chaetoceros muelleri and diet C consisted of the same two species, but C. muelleri was grown under silicate deprivation to alter the fatty acid composition. Pediveligers (28 days old) were sampled prior to settlement for fatty acid analysis, growth measurement and survival assessment. Survival and settlement success were measured at the end of the experiment (day 40). Our results show that feeding regime greatly influenced larval size, settlement and fatty acid composition. Diet A was severely deficient in arachidonic acid (20:4n-6, AA), leading to the poorest larval growth, survival and lipid content. Nevertheless, larvae fed diet A selectively accumulate AA by a factor three compared to the dietary amount. Shell size of 28-day-old larvae was positively correlated with AA content and negatively correlated with eicosapentaenoic acid (20:5n-3, EPA)-AA ratio, thus suggesting that these two variables are of major interest for the optimisation of larval growth in sea scallops. Finally, larvae fed diet C displayed 20% higher shell size at day 28 than larvae fed diet A and B, likely in relation to the dietary amount of saturated fatty acid (SFA). However, the moderate survival and settlement success of these groups of larvae might be associated with a relative deficiency in docosahexaenoic acid (22:6n-3, DHA). This study underlines that the overall balance between polyunsaturated fatty acid (PUFA) needs to be considered to adequately fed sea scallop larvae.     

食物条件对日本幼体存活与变态的影响

This paper studied the effects of different kind and density of baits and different starvation duration on Charybdis japonica larvae. The results showed that the preferable baits of zoaea-1 were Chaetoceros sp. and Isochrysis galbana,and their proper feeding density were 20×10⁴ cell·ml^-1.The preferable bait of the larvae after zoaea-1 was Artemia salina nauplius, and its proper feeding density for zoaea-2 and zoaea-3 was 2～3 ind·ml^-1.The point of no-return for zoaea-1 of Charybdis japonica was about 66 hours. 18 hours starvation did not affect the growth of the larvae, but their livability would be decreased, and their metamorphism would be suspended along with the starvation duration.     

Larvae and postlarvae production of the green-white sea urchin Lytechinus variegatus (Echinodermata: Echinoidea) in culture conditions

We evaluated the biological feasibility of massive larvae and postlarvae production of the Caribbean green-white urchin Lytechinus variegatus. Experiments were designed to choose the initial larval density and microalgae diets under culture, to study metamorphosis, postlarval and juvenile growth. Massive production of competent larvae 650 microm long at 12-13 days is possible using larval densities of 0.25 to 1 larva/ml. The microalgae Rhodomonas sp. was suitable for the optimization of larval growth and survival. Metamorphosis of 100% of the larvae can be induced with films of bentic diatoms (Navicula sp. and Amphora sp.), after 96 h; however, diatoms are not adequate for postlarval development and a food supply of Ulva lactuta is necessary for proper growth. For juveniles, a diet of macroalgae (U. lactuta) and/or commercial marine shrimp culture pellet food is enough for growth, but the best results were obtained with shrimp or U. lactuta used alone (85-86%, against 46% with the mixed diet). We recommend future experiments on nutritional requirements to optimize growth of these and subsequent stages.     

食物条件对日本蟳幼体存活与变态的影响

This paper studied the effects of different kind and density of baits and different starvation duration on Charybdis japonica larvae. The results showed that the preferable baits of zoaea-1 were Chaetoceros sp. and Isochysisgalbana, and their proper feeding density were 20 × 10^4 cell· ml^-1. The preferable bait of the larvae after zoaea-1 was Artemia salina nauplius, and its proper feeding density for zoaea-2 and zoaea-3 was 2 - 3 ind· ml^-1. The point of no-return for zoaea-1 of Charybdisjapoptica was about 66 hours. 18 hours starvation did not affect the growth of the larvae, but their livability would be decreased, and their metamorphism would be suspended along with the starvation duration.     

Laboratory culture of the Nudibranch Tritonia diomedea bergh (Tritoniidae: Opisthobranchia) and some aspects of its behavioral development

Tritonia diomedea Bergh was reared from oviposition, through metamorphosis to reproductive maturity in the laboratory. The larvae of T. diomedea are planktotrophic and undergo considerable shell growth (from 144.6–329 μ average maximum shell length). Metamorphosis does not require induction, but there may be a preference to metamorphose in the presence of the probable adult prey, a small Virgularia sp. Larvae in cultures fed no food, Dunaliella tertiolecta Butcher Isochrysis galbana Parke, or Monochrysis lutheri Droop did not achieve metamorphic competence at near ambient sea-water temperatures (11.9±1.3 and 13.0±0.8°C). Larvae from cultures fed Monochrysis at room temperature (20.8±1.5°C) or fed a 1 : 1 mixture of Isochrysis and Monochrysis at near ambient sea-water temperatures did metamorphose. Even so, only those larvae fed the 1 : 1 mixture survived more than a few days following metamorphosis. Adult behavioral patterns developed gradually, feeding being first observed at 5 days, swimming in response to NaCl crystals at about 60 days, copulation at about 272 days, and oviposition at about 277 days after metamorphosis. Growth rates were determined for field collected Tritonia diomedea; smaller animals gained and lost weight relatively faster than larger animals.     

Effect of nematode Panagrellus redivivus density on growth, survival, feed consumption and carcass composition of bighead carp Aristichthys nobilis (Richardson) larvae

The study aimed to determine the optimum density of free‐living nematodes in feeding bighead carp, Aristichthys nobilis, larvae. In the first experiment, carp stocked at 25 larvae L^?1 were fed varying levels of nematodes (50, 75, 100, 125 and 150 per ml) twice a day for 21 days from the start of exogenous feeding. Final body weight was significantly higher (P < 0.05) in larvae fed 125 and 150 nematodes per ml than in those fed 50 and 75 per ml, but survival was low (61.8 and 63.6%, respectively). Survival rate was highest in larvae fed 100 nematodes ml^?1 (81.3%). Carcass analysis showed that larvae fed 125 and 150 nematodes ml^?1 had significantly lower body protein and higher body lipid than those fed other nematode densities. Carcass ash was similar for larvae fed 50–100 nematodes ml^?1 but it decreased significantly at the higher nematode densities. Carp larvae in a subsequent experiment were given 50, 75 and 100 nematodes ml^?1 per feeding. Newly hatched Artemia was the control feed. Nematode consumption and growth of the larvae were determined. Larvae were sampled at intervals of 2–4 days and the nematodes in the gut were counted and measured. At each nematode density, the number of nematodes present in the gut of the larvae increased significantly with time. At each sampling day, the number of nematodes in the gut did not differ significantly among treatments (P > 0.05) although it tended to increase with nematode density at day 2 and day 4 but decrease at day 7 onward. The carp larvae consumed significantly shorter nematodes on day 2 and day 4 than on the succeeding sampling days regardless of nematode density. However, the length of nematodes in the gut of the larvae did not differ significantly among the nematode densities. The final body weight of larvae increased with increasing nematode density. The body weight of larvae fed 100 nematodes ml^?1 did not differ significantly from that of larvae given Artemia nauplii. Results show that bighead carp larvae should be fed 100 free‐living nematodes per ml at each feeding time.