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《海洋科学集刊》2016,(0)
海洋中的部分微藻能够产生藻毒素,导致鱼、贝类等养殖动物染毒或死亡,甚至危及人类健康和海洋生态安全。近20年来,随着对有害藻华(harmful algal bloom,HAB)问题关注程度的不断提高和研究手段的快速发展,对我国近海有毒藻和藻毒素的认识也在不断深入。本文针对几类常见的藻毒素,从贝类中藻毒素污染状况、毒素来源、有毒赤潮发生情况等方面,对我国已开展的相关研究工作进展进行了综述。大量研究表明,麻痹性贝毒毒素(paralytic shellfish toxins,PSTs)和腹泻性贝毒毒素(diarrhetic shellfish toxins,DSTs)是我国近海最为常见的藻毒素,广东沿海、福建沿海、长江口邻近海域、海州湾、北黄海和渤海秦皇岛近岸海域贝类沾染藻毒素的问题比较突出,中毒事件也时有发生。麻痹性贝毒主要来自有毒的亚历山大藻(Alexandrium spp.),大田软海绵酸(okadaic acid,OA)和扇贝毒素(pectenotoxins,PTXs)等腹泻性贝毒毒素则主要来自有毒鳍藻(Dinophysis spp.)。近年来,随着孢囊分离与培养方法的不断完善及藻毒素分析技术的快速发展,在我国近海发现了越来越多的有毒藻和藻毒素。在对文献进行综合分析的基础上,简单探讨了有毒藻与藻毒素对我国沿海海产品食品安全的影响及风险,以及未来研究的发展方向。 相似文献
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渤海裸甲藻和链状亚历山大藻的麻痹性贝毒毒素分析 总被引:1,自引:0,他引:1
目的:分析渤海裸甲藻(Gymnodinium sp.)和链状亚历山大藻(Alexandrium catenella)的麻痹性贝毒毒素,为渤海天津海域的赤潮研究积累基础数据。方法:通过实验室培养裸甲藻和链状亚历山大藻,选取对数生长期、平台生长期的裸甲藻以及平台生长期的链状亚历山大藻,利用高效液相色谱法(HPLC)对这两种微藻进行麻痹性贝毒(PSP)毒素分析。结果:裸甲藻细胞内不含有麻痹性贝毒(PSP);链状亚历山大藻细胞内含有C毒素和GTX1-4毒素,该微藻每个细胞毒素含量约为10.81 fmol/cell。结论:裸甲藻细胞内虽不含有麻痹性贝毒(PSP),但不能排除其含有其它毒素的可能。链状亚历山大藻细胞内含有麻痹性贝毒(PSP),属于有毒微藻,需要对其进行密切监测。 相似文献
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有毒赤潮藻及其毒素的危害与检测 总被引:6,自引:0,他引:6
海洋中可引发赤潮的藻类约有300种,其中有毒赤潮藻为80种左右。现已知道的赤潮藻主要毒素有麻痹性贝毒、腹泻性贝毒、记忆缺失性贝毒、神经性贝毒、西加鱼度和溶血性毒素,前5种毒素的结构已经基本得到证实。有毒赤潮藻的毒素可以在海洋生物体内积累,人类误食含有藻毒素的食品时可能中毒,严重者还可能死亡。海洋有毒赤潮藻及其毒素的检测已经成为当今全球赤潮研究和监测的重要内容之一,可以通过形态学分类方法、分子生物学技术(遗传探针)和免疫学检测技术对有毒赤潮藻进行检测;可以通过生物学、物理化学检测方法和神经受体结合、免疫学检测技术对赤潮藻毒素进行检测。 相似文献
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赤潮毒藻塔玛亚历山大藻研究进展 总被引:1,自引:0,他引:1
塔玛亚历山大藻(Alexandrium tamarense)是一种可产生麻痹性贝毒素(PSP)的海洋甲藻,其适应能力强、生存范围广,在中国北至胶州湾、南至厦门海域[1]和大鹏湾[2]都有发现,并有发生赤潮的记录,是重要的赤潮原因生物之一。其所产生的麻痹性贝毒素在一定条件下可通过食物链在鱼类、贝类等生物体内蓄积,对生物甚至人类产生危害,成为影响水产品食用安全的重要因素。同时,海洋生物毒素的高特异性、高活性特征,成为现代研究海洋药物的开发热点。因此,对塔玛亚历山大藻的研究有着重要的现实意义。作者主要综述塔玛亚历山大藻近年来的研究进展。1塔玛… 相似文献
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通过对2005年4月至9月广东近岸海域贝类81个样品的腹泻性贝毒素进行小白鼠生物法检测,结果表明:(1)DSP毒素含量值≥0.05MU/g的有34个样品,其中翡翠贻贝和牡蛎所占的比例最大;同种贝类的腹泻性贝毒素存在一定的季节差异,秋季含量最高。(2)对其中腹泻性贝毒素含量值较高的8个样品进行胃含物海洋微藻种类的鉴定,结果是波纹巴非蛤、三棱骨螺和结蚶胃含物样品中含有产腹泻性贝毒的利玛原甲藻(Prorocentrum lima)和原甲藻(Prorocentrum sp.)。 相似文献
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中国近海藻毒素及有毒微藻产毒原因种调查研究进展 总被引:2,自引:0,他引:2
麻痹性贝类毒素在我国近海污染问题已十分突出,基本呈现逐年加剧的趋势。20世纪90年代,南海麻痹性贝类毒素污染较重; 21世纪初,北黄海麻痹性贝类毒素污染较重;近几年,渤海和福建近海麻痹性贝类毒素污染较重;可产生麻痹性贝类毒素的微藻有亚历山大藻和裸甲藻等。采用小鼠生物法检测我国近海腹泻性贝类毒素超标率32%左右,采用液相色谱/质谱法检测,仅有3起超标的研究报道;现行小鼠生物法检测腹泻性贝类毒素假阳性问题十分突出,应尽快废除;腹泻性贝类毒素均是脂溶性的,脂溶性海洋生物毒素在我国近海常年可检出,偶有虾夷扇贝毒素和鳍藻毒素超标现象。可产生脂溶性毒素微藻有鳍藻和原甲藻及网状原角藻等。失忆性贝类毒素在我国近海常有检出,但无超标现象;产毒微藻有拟菱形藻等。西加鱼毒素在我国南海污染较重,但毒素标准物质的匮乏,限制了西加鱼毒素的调查研究;至今尚未确定产生西加鱼毒素的微藻。酶联免疫吸附法和液相色谱串联质谱法相结合已成为藻毒素快速准确检测成熟的技术,逐渐代替小鼠生物法和液相色谱法。 相似文献
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采用麻痹性贝类毒素小白鼠生物测定法 ,研究了在可控生态条件下两株海洋细菌S1 0 、P42 对塔玛亚历山大藻生长及其产毒量的影响。结果表明 ,菌株S1 0 在较高浓度下对藻细胞的生长有明显的抑制作用 ,在较低浓度下抑藻生长作用较弱 ,不同浓度的菌株S1 0 均能有效地抑制藻细胞内麻痹性贝类毒素的产生 ,且在较低浓度下效果较好 ;菌株P42 对该藻的作用恰好与S1 0 相反 ,在较低浓度下明显抑制藻细胞的生长 ,不同浓度的菌株P42 也能有效地抑藻产毒 ,且在较高浓度下作用较明显。实验用的藻株毒力约为 ( 0 .95— 1 2 .1 4)× 1 0 - 6MU/cell,属于低毒藻株 ,该藻株在培养第 1 4天达到毒性最高峰 ,峰值为 1 2 .1 4× 1 0 - 6MU/cell,之后逐渐下降。讨论了海洋细菌在赤潮生物防治中的应用前景 相似文献
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麻痹性贝毒能够在贝类体内累积,威胁海产品消费者健康。在以往调查中,多次在毛蚶(Scapharca subcrenata)体内发现高含量的麻痹性贝毒,但对于毛蚶体内麻痹性贝毒的转化过程及其食品安全风险还缺乏认识。通过室内模拟实验,选择太平洋亚历山大藻(Alexandrium pacificum)和链状裸甲藻(Gymnodinium catenatum)作为产毒藻种,研究了两种有毒藻种所产麻痹性贝毒在毛蚶体内的转化过程。结果表明,毛蚶体内主要出现了三种麻痹性贝毒转化过程,一是R1位羟基的还原反应,二是N-磺酰氨甲酰基类毒素R4位磺酸基团的水解反应,三是含羟基苯甲酸(hydroxybenzoate)基团的链状裸甲藻毒素在R4位的水解反应。毛蚶体内麻痹性贝毒的生物转化过程复杂,对毛蚶毒性的影响具有一定的不确定性,未来仍需要进一步深化毛蚶体内毒素累积、代谢、转化过程的研究,同时加强对毛蚶体内毒素含量的全面监测,防范毛蚶可能导致的麻痹性贝毒中毒风险。 相似文献
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塔玛亚历山大藻对墨西哥湾扇贝幼体发育的影响 总被引:13,自引:3,他引:10
塔玛亚历山大藻是一种能产生麻痹性贝毒的有毒甲藻,它所引发的赤潮在世界各地多有发生,对海水养殖业和人们的生命安全造成很大的威胁[3]。有毒赤潮发生时,贝类起一种媒介的作用,可将有毒藻产生的毒素累积在体内,沿食物链转移给高营养级生物和人,使之中毒[4]。已有研究表明有毒藻对贝类本身的生命活动也会产生不利影响。但这些工作多数是围绕着贝类成体展开的,对幼体发育阶段的研究报道甚少。本文以墨西哥湾扇贝(Argopectenirradiansconcentricus)的D形幼虫、眼点幼虫、稚贝和仔贝为对象,研究了塔… 相似文献
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Occurrence and seasonal variations of algal toxins in water, phytoplankton and shellfish from North Stradbroke Island, Queensland, Australia 总被引:4,自引:0,他引:4
Takahashi E Yu Q Eaglesham G Connell DW McBroom J Costanzo S Shaw GR 《Marine environmental research》2007,64(4):429-442
A number of marine microalgae are known to produce toxins that can accumulate in shellfish and when eaten, lead to toxic and potentially fatal reactions in humans. This paper reports on the occurrence and seasonal variations of algal toxins in the waters, phytoplankton and shellfish of Southeast Queensland, Australia. These algal toxins include okadaic acid (OA), domoic acid (DA), gymnodimine (GD), pectenotoxin-2 (PTX-2) and pectenotoxin-2-seco acid (PTX-2-SA), which were detected in the sampled shellfish and phytoplankton, via HPLC-MS/MS. Dissolved OA, PTX-2 and GD were also detected in the samples collected from the water column. This was the first occasion that DA and GD have been reported in shellfish, phytoplankton and the water column in Queensland waters. Phytoplankton tows contained both the toxic Dinophysis and Pseudo-nitzschia algae species, and are suspected of being the most likely producers of the OA, PTX-2s and DA found in shellfish of this area. The number of cells, however, did not correlate with the amount of toxins present in either shellfish or phytoplankton. This indicates that toxin production by algae varies with time and the species present and that number of cells alone cannot be used as an indicator for the presence of toxins. The presence of OA and PTX-2s were more frequently seen in the summer, while DA and GD were detected throughout the year and without any obvious seasonal patterns. 相似文献
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《African Journal of Marine Science》2013,35(1):255-271
The Benguela upwelling system is subjected to blooms of harmful and toxic algae, the incidence and consequences of which are documented here. Red tides are common and usually attributed to members of the Dinophyceae, most of which are non-toxic. The incidence of these blooms varies spatially, with most blooms confined to the area west of Cape Agulhas. Cape Point forms the natural divide for species that dominate blooms of the west coast of South Africa as opposed to those that dominate the South Coast. Blooms occur most commonly from January to May, during the latter half of the upwelling season. Each red tide is associated with synoptic weather patterns, which dictate the onshore and offshore movement of dinoflagellate-dominated frontal blooms. There is also interannual variation, thought to be related to weather pattern changes. The harmful effects of high-biomass, non-toxic blooms include die-offs resulting from anoxia or hypoxia. Other effects of high biomass blooms include those that may cause mechanical or physical damage or those that may alter the foodweb. Recently, a bloom of the very small pelagophyte, Aureococcus anophagefferens, referred to as brown tide, in Saldanha Bay and Langebaan Lagoon resulted in growth arrest in both oysters and mussels. Toxic species cause mass mortalities of fish, shellfish, marine mammals, seabirds and other animals. Human illness is caused by contaminated seafood when toxic phytoplankton are filtered from the water by shellfish that accumulate toxins to levels that are potentially lethal to humans and other consumers. Of these shellfish poisoning syndromes, Paralytic (PSP) and Diarrhetic Shellfish Poisoning (DSP) are common in the Benguela. Confirmed cases of PSP have been attributed to the dinoflagellate Alexandrium Catenella. Although shellfish are usually only marginally affected, in extreme cases of poisoning, mussel mortalities have been observed, and in most instances these have been attributed to blooms of A. Catenella. Sardine Sardinops sagax mortalities in St Helena Bay have also been attributed to the ingestion of this PSP-producing dinoflagellate. Monitoring has revealed the presence of Dinophysis acuminata, D. fortii, D. hastata, D. tripos and D. rotundata, all of which have been reported to cause DSP. The dinoflagellate Gymnodiniun cf. mikimotoi, has been implicated in a type of Neurotoxic Shellfish Poisoning and human skin and respiratory irritations have been attributed to aerosol toxins produced by this species. 相似文献
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虾夷扇贝毒素yessotoxins(YTXs),中国沿海贝类中首次发现的一组贝类生物毒素 总被引:6,自引:0,他引:6
采用高效液相色谱-串联质谱方法对我国近海贝类中腹泻性贝毒成分进行研究,结果发现采自北黄海大连附近海域的海湾扇贝和虾夷扇贝含有25~41μg/kg的虾夷扇贝毒素(yessotoxin,YTX),在虾夷扇贝体内还含有37.2μg/kg的45-OH-YTX,并在5种贝中发现微量的Homo-YTX毒素组分,这是首次报道在我国贝中检出此类毒素。虾夷扇贝毒素YTXs是一类含有2个磺酰基的脂溶性多环聚醚类化合物,对小鼠的腹腔注射急性致死毒性很高,毒理作用机制尚不清楚。本研究的结果说明我国贝类体内生物毒素成分复杂,亟需进行毒素成分结构、来源生物、生态毒理效应、分布规律及安全限定标准的研究。 相似文献
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Toxic algal species of marine and brackish-water plankton, as well as nontoxic microalgae, which are capable of initiating harmful blooms, cause a detriment to human health (seafood poisoning) and often lead to a total crisis of coastal water ecosystems. The Russian coastal waters are inhabited by dozens of toxic and bloom-causing algal species, their toxins are accumulated in the tissues of edible mollusks, and there have been incidents of human poisonings and marine fauna mortality due to these blooms. An analysis of the current situation concerning the problem of toxic algae and harmful blooms of nontoxic species in the seas of Russia provides evidence that it is necessary to create a system of compulsory governmental monitoring of the exploited marine areas to serve as the basis of ecological safety control in the exploitation of the biological resources of the Russian Federation, as well to introduce compulsory sanitary control of diarrheic, paralytic, and amnesic phycotoxins. The compiled summary of algal toxic and potentially toxic species met in the European and Far Eastern seas of Russia is given with notes on their toxicity type and its manifestations. 相似文献
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改性粘土法是一种高效、环保的有害藻华应急处置技术,可通过絮凝作用有效去除水体中藻华生物。但利用改性粘土絮凝产毒藻后,水体中胞内外藻毒素的变化情况目前尚不清楚。文章考察了I型改性粘土(MCI)絮凝典型产毒甲藻——太平洋亚历山大藻(Alexandriumpacificum)后,水体中残留藻细胞内和胞外麻痹性贝类毒素(paralytic shellfish toxins, PSTs)含量、组分的变化情况。实验结果表明, MC I对密度为6.11×10~3 cells/mL的A. pacificum 3小时去除率达62%,水体中残留藻细胞单细胞毒素含量和PSTs组分与对照组无显著差异,但水体中总PSTs含量大大降低,其中由絮凝沉降导致的胞内PSTs被去除量占水体中PSTs总减少量的90%以上。另外,针对MC I对胞外PSTs吸附效果的研究发现,低于0.5 g/L的MC I对胞外PSTs无明显吸附效果,而在利用0.2 g/L MC I絮凝去除大部分亚历山大藻后,水体中胞外PSTs含量无明显变化。由此可以推测该用量下的MC I未造成大量藻细胞破裂向水体中释放毒素。该研究结果将为改性粘土治理有毒甲藻藻华的现场应用提供科学依据。 相似文献
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2004年~2005年在长江口及邻近海域曾发生有毒赤潮13起,约占赤潮总数的15%,引发赤潮的有毒赤潮生物包括链状亚历山大藻(Alexandrium catenella)、红色裸甲藻(Gymnodinium sanguineum)、米氏凯伦藻(Karenia mikimotoi)和环状异甲藻(Heterocapsa circularisquama),其中曾造成严重危害的有米氏凯伦藻和环状异甲藻。通过连续2年的四季本底调查结果表明,该海域存在多种有毒藻类,主要包括产麻痹性贝毒(PSP)的链状亚历山大藻、塔玛亚历山大藻(Alexandrium tamarense),产腹泻性贝毒(DSP)的具尾鳍藻(Dinophysis caudata)、倒卵形鳍藻(Dinophysis fortii);产记忆缺失性贝毒(ASP)的尖刺拟菱形藻(Pseudo-Nitzschia pungens)、多列拟菱形藻(Pseudo-Nitzschia multiseries)和多纹拟菱形藻(Pseudo-Nitzschia multistriata);其它有毒有害藻类包括红色裸甲藻、环状异甲藻、米氏凯伦藻等。有毒藻类种类5、6月份较多,产腹泻性贝毒(DSP)和产记忆缺失性贝毒(ASP)的有毒藻类常年均在该海域出现,这些有毒有害藻类多数密度并不高。与有毒藻类监测同步开展了赤潮毒素检测,长江口贝类赤潮毒素检出时段主要集中在5~6和8~9月份,PSP和DSP检出率分别在5%和12%左右,敏感种类为养殖的紫贻贝,未检出记忆缺失性贝毒。针对目前赤潮的危害中由有毒藻类和赤潮毒素造成的危害较大,建议在长江口贝类养殖海域开展的有毒藻类监测计划,以确保贝类水产品食用安全。 相似文献