养殖密度对毛蚶幼虫生长及存活的影响

为探讨毛蚶(Scapharca subcrenata)幼虫养殖的最佳密度,本研究设定了5个不同的放养密度(2、5、8、14、20 ind/m L),养殖实验从D型幼虫阶段一直持续到幼虫完成附着变态。实验结果表明,随着放养密度的增加,水体氨氮浓度、亚硝酸盐浓度显著升高(P0.05);幼虫密度为20 ind/m L时,分别达到最大值0.089 mg/L和0.008 mg/L。溶解氧浓度则随幼虫密度的增大呈现下降的趋势,幼虫密度达到14、20 ind/m L时,显著低于其他密度组(P0.05)。幼虫的生长速率随放养密度的增加显著下降,5~8 ind/m L为幼虫最佳生长密度。幼虫的存活率也随着放养密度的增加显著下降(P0.05),当幼虫的放养密度为20 ind/m L时,存活率仅为35%。放养密度为8 ind/m L时,幼虫的附着密度最大,且在附着基下层的附着密度显著高于中层和上层(P0.05)。同时,随着放养密度的增加,幼虫附着变态的时间被延长,附着变态规格也显著减小(P0.05)。因此,综合考虑各种要素,规模化苗种生产中幼虫的培育密度控制在5~8 ind/m L较为适宜。     

温度与盐度对方斑东风螺胚胎发育及幼虫生长的影响

在水温14～33℃（盐度34）、盐度18-40（水温25．5-26℃）范围内各设12个梯度，采用突变法进行温、盐度对方斑东风螺[Babylonia areolata（Link）]卵囊孵化及幼虫生长实验。结果显示：（1）方斑东风螺胚胎发育适宜水温为23～31℃，最适水温为25-30℃；适宜盐度为28-38，最适盐度为30～38。在适宜水温和盐度范围内，孵化速度随水温和盐度升高而加快，但以水温的影响效应最明显；温度或盐度超过其适宜范围时，孵化率明显下降或幼虫畸形率明显增大。（2）幼虫适宜水温及最适水温与胚胎发育的基本一致；适宜盐度和最适盐度存在向高盐度延伸的现象，其适宜和最适盐度下限分别为30和32。温盐度超过适宜范围时，死亡率明显增大，生长受到抑制。     

不同环境条件对方斑东风螺幼螺生长、存活的影响

本文报道了壳高4.13 mm的方斑东风螺幼螺,在不同密度、换水量、投饵率条件下的生长、存活情况.结果表明,在0.6～4.0万个/m2的密度范围内,在小水泥池(0.9 m×0.6 m×0.6 m),日换水量100～400%条件下,密度0.6万个/m2试验组生长最快,28 d平均体重增长24.4 mg/d,体重日均增长率5.9%,存活率最高,28 d平均存活率95.9%,且换水量达到100%以后,换水量的增大,对幼螺的生长和存活率的提高无明显促进作用.认为合适的条件是:密度0.6万粒/m2或略大于0.6万粒/m2,日换水量100～200%,日投饵率6～7%.     

KC1对中间球海胆幼虫变态的诱导效果

中间球海胆（Strongylocentrotus intermedius)八腕后期幼虫，在KC1添加浓度100mmol/L海水中，分别处理5，10，15min后，均变态为正常稚海胆，中间试验及生产应用结果表明，经KC1处理，幼虫的附着时间缩短了36h，附着率则分别增加了40．4％，27．75％。     

波部东风螺人工育苗技术初探

波部东风螺（Bahylonia formosae habei）,隶属于软体动物门,腹足纲,蛾螺科东风螺属,本地俗称黄螺,主要分布于我国的热带、亚热带浅海区域,是国内近年来新兴的一个养殖品种。南于螺肉味鲜美,风味独特,营养高,广为人们喜爱。近几年来各地区滥采严重,东风螺资源不断衰减,市场供不应求。     

培育密度及饵料种类对四角蛤蜊幼虫生长、存活及变态的影响

在水温22.8～24.6℃,盐度24～25,pH 7.82～8.36的条件下,研究了培育密度及饵料种类对四角蛤蜊幼虫生长、存活及变态的影响.试验结果表明,不同的培育密度(5、10、15、20、30个/ml)下,幼虫的生长速度、存活率随着密度的增大而降低;30个/ml试验组幼虫不能发育至匍匐幼虫;5、10、15、20个/ml试验组幼虫的变态率随着密度的增大而降低,各阶段的发育时间随着密度的增大而增加.不同的饵料种类及投喂方式,即单独投喂金藻(J)、小球藻(Q)与混合投喂[JQ11(J:Q=1:1)、JQ12(J:Q=1:2)、JQ21(J:Q=2:1)]对幼虫的生长速度、存活率、变态率及幼虫各阶段发育时间的影响也不同,单独投喂效果较差,混合投喂效果相对较好.在四角蛤蜊苗种生产过程中,培育密度10个/ml较为合理,且混合投喂比单独投喂效果更好.     

方斑东风螺幼虫纤毛虫病的防治方法

近年来，方斑东风螺（Babylonia areolata Link）人工育苗技术取得了突破，南方沿海方斑东风螺养殖规模不断扩大，每年需要大量的苗种以满足养殖生产的需求。在方斑东风螺规模化人工育苗中，由于幼虫摄饵量大，人工培养单胞藻远远满足不了生产的需求，代用饵料的广泛应用，致使育苗水质恶化，纤毛虫大量繁殖，方斑东风螺幼虫的外壳和面盘寄生大量纤毛虫，影响幼虫的活动和摄食，     

光照强度对九孔鲍幼虫及幼鲍生长存活的影响

在自然光周期下，分别在高温长光照和低温短光照的两个节季节，采用控制光照强度的方法进行对九孔鲍幼虫及幼鲍50d左右培育的小型试验。结果表明，光照强度对附着基上摄食微藻的幼虫及幼鲍生长和存活等有重要的影响。对幼虫及幼鲍最适宜的光照强度，在高温长光照下为700－1200lx，在低温短光照下为1300－2000lx。选用适宜的光照强度在高温长光照和低温短光照下先后进行了3次经量育苗试验，获得了与小型试验相同的结果。     

盐度对九孔鲍摄食_生长及存活的影响

九孔鲍摄食人工饲料的盐度范围为２０￣３８,其中较适宜的盐度范围为２５￣３５,在此盐度范围内,小规格鲍（平均壳长１．３０ｃｍ,平均体重０．３７ｇ）的壳长日增长为９１．５￣１０２．３μｍ,日增重为８．６０￣１２．５５ｍｇ;大规格鲍（平均壳长２．７ｃｍ,平均体重２．３ｇ）的壳长日增长为５６．３０￣８１．８０μｍ,日增重为１２．６８￣２２．４８ｍｇ,其最适生长的盐度为３０￣３５,存活率为９７％￣１００％。     

饥饿及恢复生长对方斑东风螺抗氧化体系的影响

在(25.8±1.7)℃条件下,测定了方斑东风螺(Babylonia areolata)不同饥饿期(7d、15d、25d、40d)后再投喂(30d)过程中足肌、肝胰脏的抗氧化体系相关指标变化。结果显示,分别饥饿25d和40d时幼螺两组织丙二醛(MDA)含量较对照组均显著升高;饥饿25d前,超氧化物歧化酶(SOD)、过氧化氢酶(CAT)、谷胱甘肽过氧化物酶(GPx)活力较对照组逐渐增强,当禁食达40d时却显著减弱;谷胱甘肽硫转移酶(GST)活力饥饿状态下先略上升后下降,肝胰脏、足肌中分别于饥饿25d和40d时显著降低;谷胱甘肽还原酶(GR)活力及谷胱甘肽(GSH)含量随禁食延长均呈下降趋势。恢复生长后,除饥饿40d组GR活力及肝胰脏MDA水平较对照呈差异显著外,该组其余指标及其他各处理组相应指标均恢复至或接近对照组水平。结果表明,饥饿胁迫下螺体抗氧化体系虽被激活,但仍处于一定的氧化应激状态,提示幼螺养成中禁食时间不宜超过25d,且SOD、CAT与GPx活性可作为螺体饥饿胁迫状态的指示参数。     

Effects of stocking density and algal concentration on the survival,growth and metamorphosis of Bobu Ivory shell,Babylonia formosae habei (Neogastropoda: Buccinidae) larvae

Independent and combined effects of stocking density and algal concentration on the survival, growth and metamorphosis of the Bobu Ivory shell Babylonia formosae habei larvae were assessed using a 5 × 5 factorial design with densities of 0.25, 0.5, 0.75, 1.00 and 1.50 larvae mL⁻¹ and algal concentrations of 5, 10, 15, 20 and 25 × 10⁴ cells mL⁻¹ in the laboratory. Larval growth, survival and metamorphosis were significantly affected by both the independent effects of stocking density and algal concentration and by their interaction. The highest per cent survival (72.5%) and metamorphosis (49.5%), fastest growth (41.57 μm day⁻¹) and shortest time to initial metamorphosis (10 days) all occurred at the lowest stocking density and the highest algal concentration. Both crowding and food limitation had independently negative impacts on the survival, growth and metamorphosis of larvae, and these negative impacts were further strengthened by the interaction of a higher stocking density and a lower algal concentration. Moreover, the results suggest that stocking density and algal concentration obviously played different roles in determining larval survival and growth. To maximize survival and growth, B. formosae habei larvae should be reared at a lower stoking density of 0.25 larvae mL⁻¹ and fed a higher algal concentration of 25 × 10⁴ cells mL⁻¹ in large-scale hatchery seed culture.     

Effects of food availability on feeding and growth of cultivated juvenile Babylonia formosae habei (Altena & Gittenberger 1981)

Juveniles of the scavenging gastropod Babylonia formosae habei ( Altena & Gittenberger 1981 ) were kept at different ration levels in the laboratory for 30 days. Feeding behaviour and growth performance of the juveniles in relation to food availability were studied. Babylonia formosae habei juveniles were exposed to one of the four ration levels with food provided once either every 1, 2, 5 or 10 days. Higher food consumption, longer time spent on feeding and higher percentage of feeding individuals were obtained in individuals maintained at lower ration levels. Similar growth performances were observed in individuals fed once every day or every two days. A sustained production of shell was obtained in the juveniles maintained at low ration levels. At the end of the experiment, lower protein and lipid content as well as lower energy content were measured in the somatic tissue of juveniles maintained at lower ration levels. During the 30‐day experiment, food availability is not a crucial factor on survival of juvenile B. formosae habei due to its physiological and behavioural adaptations developed in association with starvation.     

Feeding rate responses of Babylonia formosae habei (Prosobranchia: Buccinidae) larvae on cultured algae

Babylonia formosae habei is a commercially important marine gastropod species. Food particles ingested by the planktotrophic larvae of B. formosae habei can be critical in maximizing the larval growth and survival of this species. In this study, feeding rate responses of B. formosae habei larvae on cultured algae were observed using a Coulter multisizer. Variations were recorded based on the changes of different factors of influence, including varied larval stoking density, varied types of algae, varied algae concentrations and selective feeding on mixed algae cells of different types. Results of this study reveal some facts on the feeding of B. formosae habei larvae: larval stoking density has negative effect on their feeding rates; larva has a higher feeding rate on big‐sized algae than small‐sized algae; larva has a higher feeding rate on diatom than green algae and flagellate; feeding rate of larvae increased when fed mixed algae cells. Optimal algal concentration of the cultured algae Chlorella sp., Chaetoceros muelleri, Isochrysis zhanjiangensis and Dunaliella tertiolecta was suggested at 20 × 10⁴, 5 × 10⁴, 20 × 10⁴ and 10 × 10⁴ cells mL^?1 respectively. Results of the preset study can be important in understanding feeding ecology of B. formosae habei larvae, and applicable for the aquaculture of this species.     

Effects of starvation on survival,growth and development of Exopalaemon carinicauda larvae

This study aimed at evaluating the effects of two starvation modes (fasting‐feeding mode and feeding‐fasting mode) on survival, growth and development of mysis larvae of Exopalaemon carinicauda. It showed that food restriction significantly affected the survival, growth and development in both starvation modes. With the extension of initial starvation period, a significantly reduced survival rate during metamorphosis was observed. In the fasting‐feeding mode, the duration of metamorphosis was extended and the body lengths of the individuals, which experienced successful metamorphosis to the post‐larval stage 1, were much shorter. In the feeding‐fasting mode, the extension of initial feeding period led to dramatically increased survival rate and body lengths, while there was no significant difference in duration of metamorphosis of those groups that reached to post‐larval stage. The 50% point‐of‐no‐return and the 50% point‐of‐reserve‐saturation were 3.85 days and 4.81 days respectively. The results of this study indicate that E. carinicauda mysis have the ability to withstand or recover from relatively extended starvation, but to ensure the success of commercial seedling, timely and adequate feeding is necessary. The information obtained from this study could provide a basis to optimize the feeding schedule of artificial seedling of E. carinicauda.     

Effects of starvation on larval growth,survival and metamorphosis of Ivory shell Babylonia formosae habei Altena et al., 1981 (Neogastropoda: Buccinidae)

The impact of starvation on larvae of Ivory shell Babylonia formosae habei was studied in a laboratory experiment. Newly hatched veligers showed considerable tolerance to starvation due to their endogenous yolk material, and time to the point-of-no-return (PNR; the threshold point during starvation after which larvae can longer metamorphose even if food is provided) was calculated to be 104.5 h. However, starvation still affected larval growth, survival, and metamorphosis. Mean shell length of larvae increased 49.77 μm day⁻¹ for nonstarved, but only 11.13 μm day⁻¹ for larvae starved for 108 h. After larvae began feeding, their growth rates rapidly recovered to the level of the nonstarved following short periods of starvation (less than 48 h), but were inhibited and unable to ever reach the level of the nonstarved when being starved beyond 48 h. Percent metamorphosis was 53.75% for the nonstarved, but all larvae died before 10 days for those starved for 108 h. Starvation not only affected larval time to reach metamorphosis, but also caused the delay in the time to metamorphosis. For the nonstarved, larvae took only 11.5 days to reach spontaneous metamorphosis, but they took 20 days to reach spontaneous metamorphosis when starved for 96 h, and this duration of delayed metamorphosis reached 8.5 days. Furthermore, the importance of yolk material for maintaining larval survival of B. formosae habei during starvation periods is also discussed.     

饥饿对白甲鱼(Onychostoma sima)仔鱼摄食、生长的影响

在实验室条件下,采用观察、测量记录外部形态特征等方法研究了饥饿胁迫下白甲鱼(Onychostoma sima)仔鱼的摄食、生长、形态和存活的变化。结果显示:在水温(20±1.5)℃时,饥饿组和投喂组白甲鱼仔鱼在孵化后第4天开始摄食,初次摄食率为48%,第6天初次摄食比率达到100%。饥饿组仔鱼抵达饥饿不可逆点(PNR)的时间为13.5 d,50%累计死亡率出现时间基本上与PNR出现时间相同(13.5 d),表明第13.5天为白甲鱼早期发育中较为敏感的阶段。试验期间,饥饿仔鱼体重、体长、眼间距和体高分别在第6、7、11和12天后均显著低于对照组(P<0.05)。试验结束(16 d)时饥饿组仔鱼体重、体长和眼径的瞬时增长率均显著低于摄食组(P<0.05),而头长、体高和眼间距差异不显著(P>0.05)。结果表明饥饿对仔鱼生长发育起延迟作用,混合营养期延迟投喂,仔鱼生长发育水平明显低于正常投喂仔鱼。     

Effects of diet, stocking density and environmental factors on growth, survival and metamorphosis of clam, Paphia malabarica (Chemnitz) larvae

A series of experiments were conducted to evaluate the effects of diet, stocking density and environmental factors on the growth, survival and metamorphosis of short neck clam Paphia malabarica larvae. These experiments examined the following factors: diet [ Isochrysis galbana , Nannochloropsis salina and a mixture of I. galbana and N. salina (1:1 w/w)], stocking density (1, 3, 5 and 7 larvae mL⁻¹), light intensity (unshaded, partially shaded and fully shaded) and water filtration (unfiltered and sand filtered). Results indicated that N. salina could replace 50% of I. galbana as a food source for the clam larvae with an increase in growth, survival (47.2%), metamorphosis (33.5%) and early settlement. Larval growth decreased significantly with increasing stocking density. A density of 1–3 larvae mL⁻¹ appeared to be optimal for normal growth of clam larvae. Neither diet nor stocking density used in the study had a significant effect on larval survival. Under partially shaded (light intensity=1000–5000 lx) and fully shaded (light intensity <1000 lx) conditions, larval growth was significantly faster than under direct sunlight (unshaded). Larvae grew significantly faster in the unfiltered water than in the filtered water.     

限食对合浦珠母贝幼虫生长、成活及变态的影响

自2009年4月27日至2009年5月25日,在不同投饵条件下研究了限食对合浦珠母贝（Pinctada fucata）幼虫生长、成活和变态的影响。结果显示,试验初期对照组幼虫的壳长、壳高日增长率逐渐升高,自第20天开始迅速下降;试验一组（隔天投喂）和二组（隔2d投喂）幼虫的壳长、壳高日增长率缓慢升高,且与对照组同期幼虫的日增长率差异显著,这表明饵料是否充足直接影响马氏珠母贝幼虫的生长。试验期间,对照组幼虫的成活率逐渐降低,畸形率无显著性变化,而试验一组和二组幼虫的成活率显著低于对照组,试验二组幼虫的畸形率高于同期对照组和试验一组幼虫的畸形率,表明在食物匮乏的情况下,幼虫的发育受到影响。对照组幼虫在第20天时开始变态,随后变态率逐渐升高,试验一组幼虫在第30天时开始变态,而试验二组幼虫在试验期间一直没有变态,表明该组幼虫的营养状况不足以支持其变态附着。     

延迟投饵对瓦氏黄颡鱼仔鱼存活、摄食和生长的影响

以瓦氏黄颡鱼仔鱼为研究对象,将其分为15个处理组,每组200尾（各设3个平行组）,分别在孵化后3、4、5、6、7．8、9、10、11、12、13、14、15和16d开始投喂大型涵,第15组为饥饿组,从不投饵。水温24．5～25．5℃,实验周期为30d。结果表明：（1）孵化后3d的瓦氏黄颡鱼仔鱼初次摄食,15日龄不能建立外源性营养的仔鱼进入PNR期,卵黄囊已耗尽。混合营养期持续4．12h。（2）瓦氏黄颡鱼仔鱼在不同饥饿阶段初次摄食率的变化为：开始较低,此后迅速上升,在4～10日龄达到高峰,最高初次摄食率为100％,此后逐步下降。（3）延迟5天投饵对瓦氏黄颡鱼仔鱼的存活率影响不显著,延迟6d投饵瓦氏黄颡鱼仔鱼的存活率随延迟投饵天数的增加而降低。延迟6d投饵,瓦氏黄颡鱼仔鱼的体长增长率随延迟投饵天数的增加而降低。     

Growth and survival of winter flounder (Pseudopleuronectes americanus) larvae reared on different photoperiod regimes from hatch to metamorphosis

The aim of this study was to determine the effect of photoperiod on growth and survival of winter flounder, Pseudopleuronectes americanus, from hatch until metamorphosis. Sixteen 100 L upwelling tanks were stocked with larvae at an initial stocking density of 20 larvae/L. Larvae in eight tanks were provided with continuous light (24 hr light/0 hr dark), while those in the remaining eight tanks were grown under a photoperiod of 14 hr light/10 hr dark. Tanks were sampled for larval standard lengh from 6 to 28 days post‐hatch, and the number of live larvae, live metamorphosed and dead metamorphosed fish were recorded at the termination of the experiment (starting 46 dph). Results indicated that larvae provided with continuous light were larger than those sampled from 14 hr light/10 hr dark treatment. No effect of photoperiod on the number of non‐metamorphosed fish recovered at the end of the experiment was detected. On the contrary, over three times as many fish survived and reached metamorphosis under continuous light. An ANCOVA model showed a significant interaction between light and age. Both regressions were significant and provided the following growth equations: SL_{24 hr light/0 hr dark} = 0.101 × age + 2.55 (r² = 0.96) and SL_{14 hr light/10 hr dark} = 0.094 × age +2.45 (r² = 0.97). Using 6.36 ± 0.059 mm SL as the mean size at metamorphosis, larvae experiencing continuous and 14 hr light/10 hr dark photoperiods would reach metamorphosis in 38 and 42 days respectively.