棕囊藻囊泡的培养与去除研究

对广东省珠海市海域球形棕囊藻Phaeocytstis globosa赤潮进行了现场采样及除藻研究,发现3种除藻剂对球形棕囊藻囊泡作用效果存在较大差异。对球形棕囊藻生活史及特征进行了研究,在实验室条件下培养出直径6mm球形棕囊藻囊泡,其生长周期约为14d。实验结果表明,囊泡的形成是球形棕囊藻应对恶劣环境的表现之一。     

无公害刺参稳产健康养殖新技术

本文针对目前刺参养殖中存在的问题,简单明了叙述刺参无公害健康养殖一系列新技术和新方法,对推动海参养殖业持续、稳定、健康发展,起到积极作用和效果。     

应用荧光抗体技术检测牙鲆体内的河流弧菌

用灭活的河流弧菌(Vibrio fluvialis)抗原,注射免疫实验兔,制得凝集价为1∶5 120的抗血清。用试管凝集法检测了抗血清的特异性,再用免疫吸附法去除交叉反应,从而得到高效价、高特异性的抗河流弧菌血清。用所制备的抗血清在实验室中建立起河流弧菌荧光抗体检测技术(FAT),在荧光显微镜下可清楚地看到被标记的病原菌,整个检测过程只需3h。用河流弧菌感染牙鲆(Paralichthys olivaceus),24 h后,用FAT测定牙鲆的血液、肾脏和肝脏中的河流弧菌,在血液中河流弧菌的检出率最高,其次是肾脏,肝脏的检出率最低。以上结果表明:荧光抗体技术可以快速、灵敏、准确地检测出牙鲆体内的河流弧菌。     

不同环境下镉对小球藻吸收磷速率的影响

在人工配制的污水中进行静态模拟实验,研究了不同光照强度及不同pH值下,镉对小球藻(Chlorella vulgaris)在悬浮和固定状态下对污水中正磷酸盐的吸收速率的影响。结果表明,镉存在的情况下,在实验所设的各光照强度内,悬浮态小球藻对磷的吸收速率为4~10μg/(h.个),固定化小球藻为12~16μg/(h.个);而相同的镉浓度下,在不同的pH范围中,悬浮态小球藻对磷的吸收速率为1.9~9.4μg/(h.个),固定化小球藻为5.7~12μg/(h.个)。在不同光照强度下,镉总体上降低了小球藻对磷的吸收速率,其中使悬浮藻普遍下降40%~60%,而固定处理使藻受镉的影响较少,至多下降10%~20%,但在个别光照强度下镉反而促进了小球藻对磷的吸收速率。不同pH值时,无论悬浮态还是固定态,镉在大多pH下使小球藻的磷吸收速率下降20%~30%,固定处理并没有减少镉的影响,同样在个别pH下镉促进了对磷的吸收。     

大米草中生物活性物质的筛选

大米草(Spartina anglica)是一种资源丰富的盐沼植物，目前已在中国沿海大量分布，综合开发利用大米草具有重要的生态意义和经济效益。利用硅胶柱层析方法分离大米草甲醇提取物，再分别用DPPH法、纸碟法和MTT法对大米草中40多个组分进行了抗氧化、抗细菌和抗肿瘤活性的筛选。结果得到抗氧化活性组分5个、抗菌活性组分2个、抗肿瘤活性组分3个。目前对其活性先导化合物的分离纯化研究正在进行中。     

Long-term Sensor Drift Found in Recovered Argo Profiling Floats

We recovered three Argo profiling floats after 2 to 2.5 years of operation, and recalibrated their temperature, conductivity, and pressure sensors. The results demonstrate that these floats exhibited a significant drift in salinity of −0.0074 to −0.0125, primarily due to the conductivity sensor drift. Combined with the recalibration result for another previously recovered float, the indication is that the negative salinity drift increases nearly in proportion to the operating period of floats. The increasing rate is −0.0041 (±0.0015) year⁻¹, which yields a salinity drift of −0.016 (±0.006) for the expected float lifetime of four years. The present result suggests that reducing the float surfacing time would improve the accuracy of the salinity measurements.     

海洋平台阴极保护监测系统的研制及应用

介绍了自行研制的海洋平台阴极保护监测系统，它由双电极电位测量探头，牺牲阳极输出电流测量探头，信号传输电缆系统和微机数据采集系统组成，并结合近10a其在南海北部近海石油开发区的应用和运行状况，对阴极保护监测系统的性能，作用及意义进行了系统论述，以期为进一步的工作奠定基础。     

基于模糊神经网络(FNN)的赤潮预警预测研究

为研究各种理化因子与赤潮藻类浓度间的非线性对应规律和有效预测赤潮藻类浓度,构建了基于BP 算法的一个四层模糊神经网络模型。将模糊神经网络(FNN)技术引入赤潮预测研究,并与普通 BP 网络、RBF 网络的结果作比较,结果表明,该模型能够较好地反演出各种理化因子与夜光藻密度的非线性对应变化规律,有更好的预测功能。     

Simple determination of dimethylsulfide (DMS) and dimethylsulfoniopropionate (DMSP) using solid-phase microextraction and gas chromatography-mass spectrometry

Solid-phase microextraction (SPME) is a simple, sensitive and less destructive method for the determination of dimethylsulfide (DMS) in seawater. Combined with detection by gas chromatography-mass spectrometry (GC-MS), the method had sufficient sensitivity (minimum detectable concentration of DMS was 0.05 nM), and practical levels of reproducibility (relative standard deviation ≤7%) and linearity (r ² > 0.995) over a wide concentration range (0.5 to 910 nM). The protocol developed was applied to a Sagami Bay water sample to determine concentrations of DMS and DMSP, and in situ DMSP-lyase activity.     

Eddy Shedding from the Kuroshio Bend at Luzon Strait

TOPEX/POSEDIENT-ERS satellite altimeter data along with the mean state from the Parallel Ocean Climate Model result have been used to investigate the variation of Kuroshio intrusion and eddy shedding at Luzon Strait during 1992–2001. The Kuroshio penetrates into the South China Sea and forms a bend. The Kuroshio bend varies with time, periodically shedding anticyclonic eddies. Criteria of eddy shedding are identified: 1) When the shedding event occurs, there are usually two centers of high Sea Surface Height (SSH) together with negative geostrophic vorticity in the Kuroshio Bend (KB) area. 2) Between the two centers of high SSH there usually exists positive geostrophic vorticity. These criteria have been used to determine the eddy shedding times and locations. The most frequent eddy shedding intervals are 70, 80 and 90 days. In both the winter and summer monsoon period, the most frequent locations are 119.5°E and 120°E, which means that the seasonal variation of eddy shedding location is unclear.