诺氟沙星在大菱鲆体内药代动力学及残留消除规律

利用高效液相色谱法分别测定了单次和多次混饲口灌大菱鲆诺氟沙星(NFLX)后鱼体主要组织中的NFLX含量。通过MCP-KP药动学程序对NFLX在大菱鲆体内的药代动力学及残留消除规律进行了分析研究。结果表明,以30mg/kg的剂量单次混饲口灌大菱鲆,NFLX在大菱鲆体内的达峰时间(Tmax)为2h,血、鳃、肾脏、肝脏、肌肉的达峰浓度(Cmax)分别为:8.365、7.519、1.871、6.485和4.060μg/g;NFLX在组织中的消除半衰期(T1/2)由小到大依次为:肝脏8.18h<肌肉12.39h<鳃丝15.29h<血液23.22h<肾脏23.25h。连续5d以30mg/kg的剂量混饲口灌大菱鲆,消除半衰期(T1/2)由小到大依次为:肌肉74.88h<血液98.16h<肝脏186.43h<鳃192.12h<肾脏200.45h。以上研究表明,诺氟沙星在大菱鲆体内的吸收较为迅速,有利于疾病的预防和治疗用药。在组织中以肾脏中的残留最为显著。使用诺氟沙星进行大菱鲆疾病的预防和治疗时,至少停药30d后方可上市销售。     

Cytotoxic activity against prelabelled RTG-2 cells in the turbot, Scophthalmus maximus (L.)

Leucocytes derived from head kidney, blood and spleen of turbot, Scophthalmus maximus (L.), exhibited cytotoxic activities against an established cell line (RTG-2) derived from rainbow trout, Oncorhynchus mykiss (Walbaum). The optimal effector:target ratio, temperature and incubation period for the activity was determined. Cytotoxicity was not caused by released factors, as effector:target contact was needed. Visualization of the cultures under the transmission electron microscope corroborated the contact between leucocytes and target cells and suggested the implication of monocyte-like cells in this cell-mediated cytotoxicity.     

Induction of triploidy in the turbot (Scophthalmus maximus): II. Effects of cold shock timing and induction of triploidy in a large volume of eggs

Triploidy was induced in the turbot (Scophthalmus maximus, L.) by applying cold shocks shortly after fertilization. The combined effects of the timing of cold shock commencement after fertilization, cold shock duration and cold shock temperature were investigated. Ploidy was assessed by counting the number of nucleoli per nucleus (NOR) in larvae and also by measuring erythrocyte size in juveniles. A clear peak in triploidy induction was obtained when shocks were started between 6 and 7 min after fertilization at a pre-shock temperature of 13–14°C. With this timing, shocks of 20-min duration at 0°C gave >90% triploidy, with survival about 80% of the untreated controls. In order to ensure both high triploidy rates and high survival, it was necessary to carefully maintain the water temperature just below 0°C. Experiments with small and large volumes of eggs were performed in order to determine how changes in the relative volumes of eggs and chilled water could affect survival and triploidy induction. The best combination to induce triploidy in the turbot was as follows: shock commencement 6.5 min after fertilization, shock duration 25 min, and shock temperature between 0 and −1°C. With this combination, 100% triploidy could consistently be induced with survival 60% of the untreated control. This was successfully applied to a large volume of eggs (300 ml; 1 ml 800 eggs) in order to mass-produce triploid turbot. Triploids had lower survival rate than diploids at hatching but similar thereafter, with the ability to complete the different stages of larval rearing, indicating the viability to produce triploid turbot under farming conditions.     

A method for the quantification and optimization of hydrodynamics in culture tanks

A method was developed to quantify hydrodynamic mixing parameters, and to optimize the physical environmental conditions, in culture tanks. Improved mixing will result in better tank water quality, more efficient use of available volume by the culture animals (leading to optimal stocking densities and better feed management) and possibly reduced water pumping requirements. Experiments were conducted to determine the influence of a range of flow rates, residence times, water depths and stocking densities on hydrodynamics in juvenile turbot (Scophthalmus maximus (L.)) tanks. Decreases in water depth resulted in significant improvements in mixing and the efficiency with which the water was used, as indicated by reductions in dead volumes. A depth of less than 9.4 cm at a flow rate of 2 l min^–1 was expected to minimize dead volumes in the tank. This indicated that mixing was better in shallower tanks. Within the range 0–13 l min^–1, increased flow rate improved mixing at a constant depth of 9 cm (and water volume of 18.54 l) though increased flow rates greater than about 2.5 l min^–1 produced only small improvements in mixing. Within the range 0–50 fish per tank (equivalent to a mean stocking density of 0–1.84 kg m^–2), stocking density did not significantly influence mixing in tanks with a depth of 9 cm and flow rate of 2 l min^–1. Such depth reductions, for demersal species, may be a useful means to either decrease water use without reducing residence time, or alternatively to increase the flushing rate without increasing water use, at a given stocking density. The large changes in the efficiency with which the tanks were used, which were achieved with ease, indicates that attention to water mixing can give positive benefits to a wide range of land-based farm operators. Care must be taken when adjusting tank hydrodynamics, that water quality is maintained and that biological parameters such as stress levels, sunlight effects and feed management are optimal.     

大菱鲆"温室大棚+深井海水"工厂化养殖模式

大菱鲆Turbot(Scophthalmus maximus）的引进一方面为我国北方沿海工厂化养鱼增加了一个新的品种，另一方面又创立了“温室大棚＋深井海水”工厂化养殖的新模式，大大丰富了工厂化养鱼的内容，有效的推动了我国海水养殖“第四次浪潮”的形成与发展。本文综述了大菱鲆温室大棚式工厂化养殖模式的养殖技术，以促进大菱鲆养殖业的健康、持续、稳定发展。     

大菱鲆选育家系雌、雄群体的生长发育差异

采用全长/体长、体高/体长、全长/体高和体质量为评价指标,分别对9~33月龄大菱鲆雌、雄群体在生长发育过程中体型的动态变化及生长性能差异进行了比较。大菱鲆雌、雄群体形态比较结果显示,雌、雄群体的全长/体长、体高/体长、全长/体高在不同发育阶段呈现特有的变化,但在雌、雄群体间,除33月龄的体高/体长和全长/体高差异达到显著水平外,3项指标在不同阶段没有差异或差异不显著,即可以认为,对于统计初始体质量相同或相近的大菱鲆雌、雄群体,全长/体长、体高/体长和全长/体高3个形态比例指标是随发育时间序列同步变化。基于Logistic模型对大菱鲆雌、雄群体生长性能的比较结果显示,雌性群体的拐点月龄、拐点体质量和最大月增重均大于雄性群体;对于雌性和雄性群体的瞬时增长率,除在9~13月龄雌性群体稍低于雄性群体外,13~33月龄的雌性群体均高于雄性群体,且随着生长发育和体质量差异的增大,雌、雄瞬时增长率的差异也呈增大趋势;雄性群体进入快速生长期的始速点和进入缓慢生长期的终速点均比雌性群体提前,雄性群体的快速生长期时间区间长度小于雌性群体,其对应的体质量区间长度也小于雌性群体,雌性群体在快速生长期的月增重显著高于雄性群体。研究表明,大菱鲆雌、雄群体在生长发育过程中存在着显著的生长差异,而形态差异不显著。     

不同加工工艺的饲料对大菱鲆幼鱼生长及养殖水环境的影响

比较了两种加工工艺对饲料(D1、D2)颗粒物理性状的影响,并用其投喂初始体重为16 g的大菱鲆幼鱼64 d,比较其对大菱鲆幼鱼生长、饲料利用和养殖水环境的影响。结果显示,D2组饲料平均颗粒直径、平均百粒重和水中稳定性显著高于D1组(P0.05),但其吸水性、堆积密度和沉降速度显著低于D1组(P0.05)。D2组大菱鲆幼鱼的增重率、特异生长率、摄食率及蛋白质效率显著高于D1组(P0.05)。大菱鲆对D2组饲料中干物质和粗蛋白的表观消化率显著高于D1组(P0.05),但对粗脂肪和总磷的表观消化率无显著影响(P0.05)。投喂18 h后,养殖水体中N、P含量均有了显著升高,D2组每升水中每千克鱼产生的亚硝酸氮含量显著高于D1组(P0.05),但硝酸氮和总氮增加量显著低于D1组(P0.05);D2组活性磷酸盐及总磷酸盐增加量显著低于D1组(P0.05)。研究结果表明,不同的加工工艺显著影响了颗粒饲料的物理性状和饲料利用,并对养殖水环境造成了影响。     

Effects of size grading on growth and survival of juvenile turbot at two temperatures

Juvenile turbot were size graded into three size groups (mean initial size): Small (3.4 g), medium (7.0 g) and large (10.5 g), and additional fish were held in ungraded (6.6 g) groups. Subgroups (n = 396) of fish were tagged and individual growth rates and social interactions within different size categories were studied in fish reared at 13 and 19 °C. Size grading of juvenile turbot did not improve growth. Specific growth rates (SGR) were mainly size-related, and no differences in SGR or mortality between the experimental groups at both tem-peratures were found. A higher level of social interactions was indicated amongst medium-sized fish than amongst those in the smallest and largest categories. Excess feeding may have been important factors in reducing aggression, so that the growth of the smallest individuals was not suppressed by the larger individuals in the present study. Grading seems to be an unnecessary operation to improve the growth and survival of juvenile turbot (5- 150 g). However, as it was mainly the smallest individuals in each group that died, grading of very small turbot (2-5 g) can be recommended.     

大菱鲆(Scophthalmus maximus)鱼苗视网膜组织结构与视觉特性

采用石蜡连续切片技术研究了初孵至50日龄大菱鲆(Scophthalmus maximus)鱼苗的视网膜结构及视觉特性.测定了鱼苗发育过程中视网膜横切面上视锥细胞(CC)、外核层细胞核(ONN)和神经节细胞(GC)的数量变化,以及鱼苗经明暗适应后视网膜色素指数的变化.结果显示,2日龄仔鱼视网膜上出现色素层和视锥细胞层,为仔鱼开口摄食提供了视觉基础.5日龄仔鱼的视网膜没有运动反应.鱼苗从16日龄发育到30日龄,明暗适应后视网膜色素指数的差值显著升高(P＜0.01),表明视网膜出现了显著的运动反应.16-39日龄,鱼苗视网膜上CC、GC数量显著减少(P＜0.01),ONN数量显著增多(P＜0.01),39-50日龄,视网膜上CC、GC和ONN数量没有出现显著差异(P＞0.05).大菱鲆鱼苗变态前视网膜视敏度高,光敏性低,变态后视敏度降低,光敏性增强,视网膜逐步适应感受弱光的刺激,这与大菱鲆鱼苗变态后从浮游到底栖的生活习性相适应.变态后的大菱鲆光感受系统不发达.     

应用高通量测序技术分析大菱鲆幼鱼肠道及其养殖环境的微生物群落结构

采用基于Illumina测序平台的高通量测序技术,对大菱鲆(Scophthalmus maximus)幼鱼肠道及其养殖水体、生物饵料中细菌种类及丰度进行研究。测序结果显示,养殖水体、生物饵料和大菱鲆幼鱼肠道等19个样品共获得有效序列547621条,可聚类于3771个可分类操作单元(OTUs),归属于养殖水体、生物饵料、健康幼鱼和发病幼鱼的操作分类单元(OTU)个数分别为3038、1090、87和777,其中,健康幼鱼与生物饵料、健康幼鱼与养殖水体特有的OTU个数分别为57和0,发病幼鱼与生物饵料、发病幼鱼与养殖水体特有的OTU个数分别为481和31。表明幼鱼肠道微生物多样性与生物饵料密切相关。根据细菌注释结果,拟杆菌门(Bacteroidetes)、厚壁菌门(Firmicutes)和变形菌门(Proteobacteria)在大菱鲆幼鱼肠道中占优势地位,其中,健康幼鱼肠道微生物共聚类为8个门,发病幼鱼的肠道微生物可聚类为19个门。与健康幼鱼相比,发病幼鱼肠道门水平上的3种主要优势菌群落结构出现失衡。此外,对各样品中丰度最高的100位OTU分析显示,幼鱼肠道优势菌种类与生物饵料中的优势菌种类密切相关,而每个发病幼鱼肠道优势菌种类具有一定的独立性。本研究旨在为大菱鲆健康养殖和微生态调控提供实验依据。