2017年广西壮族自治区5个城市贝类海产品致病性弧菌污染状况分析

目的 了解广西壮族自治区贝类海产品中副溶血性弧菌、创伤弧菌、溶藻弧菌和霍乱弧菌的污染现状,为食源性疾病防控和微生物风险评估提供参考依据。方法 2017年在广西壮族自治区3个沿海和2个内陆城市采集贝类海产品进行定性检测,其中副溶血性弧菌同时进行定量检测和毒力基因检测。结果 5个城市共采集800份贝类海产品,致病性弧菌总阳性率为76.5%(612/800),副溶血性弧菌、创伤弧菌和霍乱弧菌阳性率分别为73.9%(591/800)、18.4%(147/800)、0.1%(1/800),未检出溶藻弧菌。副溶血性弧菌阳性率与采样地区、样品状态和贝类品种有关,沿海地区阳性率高于内陆地区,但含量却低于内陆地区；活产品阳性率和含量均高于鲜/冰鲜海产品；蛏子、泥蚶、牡蛎和蛤/蚬子阳性率较高,均在75.0%以上,扇贝和贻贝阳性率相对较低,但含量较高；1.0%(6/591)的菌株检出致病性毒力基因。创伤弧菌阳性率与样品来源、采样地区和贝类品种有关,沿海地区高于内陆地区,农村高于城市,蛏子和泥蚶阳性率最高,均在35.0%以上。结论 广西壮族自治区贝类海产品中副溶血性弧菌和创伤弧菌污染较严重,需重点加强贝类海产品食品安全卫生宣教,加强沿海农村地区创伤弧菌监测。     

2008—2010年上海市夏秋季市售海产品中副溶血性弧菌污染监测结果分析

目的 了解上海市夏秋季节市售海产品中副溶血性弧菌的污染水平和特征.方法 2008-2010年5-10月,采用GB/T 4789.7-2008《食品卫生微生物学检验副溶血性孤菌检验》方法,对上海市批发市场、集贸市场、卖场超市和餐饮单位等污染物监测点的市售海产品进行副溶血性弧菌的定性和定量检测.结果 共监测市售海产品941件,副溶血性弧菌总体检出率为13.2％,不同种类、不同监测月份和不同采样地点的海产品,其副溶血性弧菌检出率和样品几何平均浓度总体上差异有统计学意义(P＜0.05).其中,海产虾类副溶血性弧菌检出率(25.0％)和样品几何平均浓度(5.0 MPN/g)显著高于其他类海产品(P＜0.05);8月份海产品副溶血性弧菌检出率(27.4％)和样品几何平均浓度(3.3 MPN/g)显著高于其他监测月份(P＜0.05);集贸市场副溶血性弧菌检出率(28.5％)和批发市场样品几何平均浓度(3.9 MPN/g)显著高于其他采样地点(P＜0.05).结论 上海市市售海产品中副溶血性孤菌的污聚率较高,应进一步开展海产品中副溶血性弧菌的风险监测和评估,并针对副溶血性弧菌污染的高风险环节开展监管.     

烟台海域海产品中食源性致病菌污染状况调查及膳食风险分析

目的了解烟台濒临的黄海和渤海海域海产品中食源性致病菌污染分布特征,掌握致病菌污染的"基线值",为市场监管、消费指导和风险预警提供数据支持。方法按照GB 4789规定的方法,进行6种食源性致病菌检测。借助快速微生物定量风险评估(s QMRA)方法,评价海产品中副溶血性弧菌的感染风险。结果 6类260种海产品中仅有副溶血性弧菌阳性检出,创伤弧菌、金黄色葡萄球菌、沙门菌、单增李斯特菌和大肠杆菌O157:H7均未检出。海产品中副溶血性弧菌总体污染率为19.62%(51/260),贝类、甲壳类污染水平较高,鱼类、海藻类偏低,污染率分别为26.42%(28/106)、20.00%(6/30)、10.00%(3/30)、10.00%(3/30);贝类中牡蛎是副溶血性弧菌高污染的海产品,污染率为31.03%(9/29)。普通人群摄食加热海产品后副溶血性弧菌致病风险概率值为2.97×10-7,年均患病率为6.03×10~(-6)次/人年,7~9月份为高发病时间段。结论烟台海域鲜活海产品主要存在副溶血性弧菌的污染,摄食人群具有潜在的感染风险,尤其温度较高的第三季度。     

淄博市市售生食贝类中副溶血性弧菌污染水平调查

为了解山东省淄博市市售生食贝类中副溶血性弧菌的污染状况和毒力基因的携带情况,分别于2019年8、9、10月从不同区县的零售市场采集牡蛎和毛蚶样品共40份,运用副溶血性弧菌MPN定量法和多重荧光MPN-PCR法对副溶血性弧菌的污染状况和毒力基因的携带情况进行调查。结果显示,副溶血性弧菌(tlh基因)检出率为47.50%(19/40),其中污染量≥110MPN/g的样品占26.00%(5/19);毒力基因(tdh、trh)阳性15份,携带率37.50%(15/40),其中牡蛎携带率为45.00%(9/20),毛蚶携带率为30.00%(6/20)。故得出结论,淄博市市售牡蛎和毛蚶中副溶血性弧菌的污染水平较高,存在一定的食品安全风险。     

福建省带壳牡蛎中副溶血性弧菌的市场调查

为了解零售带壳牡蛎中副溶血性弧菌(VP)的污染情况，2003年4月～2004年3月每月在福建省福州和厦门两地收集带壳牡蛎，样品共252份，分别来自水产品批发市场(11％)、零售市场(50％)和饭店(39％)。采用Vitek鉴定系统和最可能数(MPN)法进行VP的定性和定量分析。结果显示，带壳牡蛎VP几何平均密度为46MPN，100g，46％的试样VP密度低于30MPN/100g的最低检出限，仅厦门2个试样菌量超过104MPIN/100g。两个地区、不同采样点和不同季节之间试样vP平均密度差别均有显性。厦门试样菌量高于福州；批发市场试样菌量最高；春季试样菌量(93MPN/100g)高于其它季节(约为40MPN/100g)。研究结果可以用于估计生食牡蛎人群VP的暴露量。     

上海市零售梭子蟹中副溶血性弧菌的污染状况及风险评估

目的 研究上海市场零售梭子蟹中副溶血性弧菌的污染状况,并对副溶血性弧菌可能引发的公共卫生风险进行初步评估.方法 采用最可能数(MPN)法检测上海和宁波市售梭子蟹中副溶血性弧菌的带菌量,采用膳食回顾性调查方法对上海居民梭子蟹消费量进行调查,采用Risk Ranger软件对梭子蟹中副溶血性孤菌进行丰定量风险评估.结果 上海和宁波市零售梭子蟹中副溶血性弧菌阳性率分别为60.5%和13.3%,阳性试样平均菌量分别为0.75 MPN/g和5.50 MPN/g.膳食调查结果显示,上海居民梭子蟹人均日摄入量为2.95 g/d.风险评估结果显示,风险评分为36分,梭子蟹食用者每人每天的发病概率为8.22×10-9,每年上海地区预期发生42.5例副溶血性弧菌感染病例.通过改变评估模型中某些风险的选择,如采取良好的控制措施,风险可降低至原来的1/10.结论 上海市售梭子蟹副溶血性弧菌污染状况较为严重,可能对人群健康造成较高的风险,未来有必要进一步加强监测.     

大连市不同海产品中副溶血性弧菌污染的健康风险分级研究

目的对大连市不同海产品中副溶血性弧菌(Vibrio parahaemolyticus, VP)污染的健康风险进行分级和评价。方法 2017年1～10月,在大连市10个县市区分层随机采集4类944份常见海产品。依据GB 4789.7—2013《食品安全国家标准食品微生物学检验副溶血性弧菌检验》进行海产品中VP定量检测,使用实时荧光定量聚合酶链式反应(PCR)方法进行VP毒力基因检测;采用食物频率法获得各类海产品的消费量数据;利用专家咨询法获得海产品交叉污染和烹调习惯参数;采用快速微生物定量风险评估(sQMRA)方法,对4类海产品中致病性VP的健康风险进行分级。结果甲壳类导致人体感染致病性VP发病风险和年发病例数最高,分别为3.5×10~(-6)和2 799.3例。鱼类导致人体感染致病性VP发病风险和年发病例数居第二位,分别为1.1×10~(-6)和1 304.4例。海产品导致人群VP发病的主要途径为交叉污染。结论应关注大连市甲壳类中VP对人群的致病风险,重点控制海产品在加工处理过程中VP的交叉污染。     

生食动物性水产品中副溶血性弧菌和创伤弧菌污染状况分析

目的 了解生食动物性水产品中副溶血性弧菌和创伤弧菌污染状况。方法 采用随机抽样方法,在我国13个地区的餐饮店、零售店和批发市场采集生食动物性水产品,共计2 980份,对样品进行副溶血性弧菌和创伤弧菌检测。结果 生食动物性水产品中副溶血性弧菌检出率为14.7%(437/2 980),污染水平＞100 MPN/g的样品比例为2.9%(83/2 909)；创伤弧菌检出率为3.5%(104/2 980)。采样于批发市场的样品中副溶血性弧菌检出率、污染水平＞100 MPN/g的样品比例和创伤弧菌检出率均高于餐饮店和零售店。第三季度副溶血性弧菌检出率、污染水平＞100 MPN/g的样品比例和创伤弧菌检出率最高。造成污染的主要原因包括原产地污染,储存不当及加工过程交叉污染。结论 生食动物性水产品中存在副溶血性弧菌和创伤弧菌的污染,其健康风险应引起关注,本次污染状况分析可为标准制修订提供理论依据。     

2010—2018年江苏省淡水产品中副溶血性弧菌监测结果研究

目的 掌握江苏省淡水产品中副溶血性弧菌污染水平和趋势,为风险评估提供基础定量数据。方法 2010—2018年在江苏省13个市的流通和餐饮环节的不同场所,采集8类淡水产品1 170份,按照GB 4789.7《食品安全国家标准 食品微生物学检验 副溶血性弧菌检验》进行副溶血性弧菌的定性和定量检验,使用@RISK软件对数据进行模拟分析,拟合定量污染数据。结果 1 170份淡水产品中副溶血性弧菌检出率28.0%,污染水平为(-1.01±1.58) lg MPN/g,毒力基因携带率3.7%。内陆地区副溶血性弧菌检出率和污染水平高于沿海地区,差异有统计学意义(P<0.05)。不同年份、不同地区、不同种类、不同月份和季度检出率和污染水平差异有统计学意义(P<0.05),不同采样场所检出率和污染水平差异无统计学意义(P>0.05)。内陆地区和沿海地区副溶血性弧菌污染水平分别为(-0.89±1.59) lg MPN/g和(-1.56±1.54) lg MPN/g;第二季度污染水平最高为(-0.56±1.72) lg MPN/g;饭店/酒店污染水平最高为(-0.68±1.55) lg MPN/g;淡水虾类中副溶血性弧菌污染水平最高为(-0.44±1.68) lg MPN/g。结论 江苏省淡水产品中副溶血性弧菌污染严重,副溶血性弧菌的污染由海产品向淡水产品转移,由沿海地区向内陆地区扩散,且有高于沿海地区的趋势。淡水产品可能是引起副溶血性弧菌感染的危险因素之一,淡水虾类中副溶血性弧菌污染严重,需对淡水产品开展风险评估。     

温暖月份零售带壳牡蛎中副溶血性弧菌的定量研究

为了解温暖月份零售带壳牡蛎中副溶血性弧菌 (VP)的污染情况 ,2 0 0 3年 4～ 8月在福建省福州和厦门两地共收集带壳牡蛎 113份 ,样品分别来自水产品批发市场 (18% ) ,零售市场 (4 6 % )和饭店 (36 % )。采用Vitek鉴定系统和最可能数法进行VP的定量分析。结果显示 ,带壳牡蛎中VP密度的几何均数为 6 0MPN 10 0g ,4 1 6 %的样品VP密度低于 30MPN 10 0g的最低检出限 ,仅厦门2个样品菌量超过 2 4 0 0 0MPN 10 0g。两个地区、不同采样点和不同月份之间样品VP密度的几何均数差别均有统计学意义 (P <0 0 1)。厦门样品污染菌量高于福州 ;批发市场样品菌量最高 ;5月份样品菌量最高 ,为 14 9MPN 10 0g ,而 6～ 8月样品菌量约为 4 0MPN 10 0g。零售环节带壳牡蛎VP的检出率较高。未来应加强对生食海产品中VP污染状况的监测。     

Levels of Vibrio parahaemolyticus and thermostable direct hemolysin gene-positive organisms in retail seafood determined by the most probable number-polymerase chain reaction (MPN-PCR) method

The incidence and levels of Vibrio parahaemolyticus and thermostable direct hemolysin gene (tdh)-positive organisms in retail seafood were determined. The most probable number-polymerase chain reaction (MPN-PCR) method using a PCR procedure targeting the species-specific thermolabile hemolysin gene (tlh) and tdh was used to determine the levels of V. parahaemolyticus and tdh-positive organisms, respectively. In seafood for raw consumption, V. parahaemolyticus was found in four (13.3%) of 30 fish samples, 11 (55.0%) of 20 crustacean samples, and 29 (96.7%) of 30 mollusc samples. Levels of V. parahaemolyticus were below 10(4) MPN/100 g in all fish and crustacean samples tested. However, they were above 10(4) MPN/100 g in 11 (36.7%) of the 30 mollusc samples. In all seafood for raw consumption, the level of tdh-positive organisms was below the limit of detection (< 30 MPN/100 g). In seafood for cooking, V. parahaemolyticus was found in 15 (75.0%) of 20 fish samples, nine (45.0%) of 20 crustacean sample, and 20 (100%) of 20 mollusc samples. Levels of V. parahaemolyticus were above 10(4) MPN/100 g in only three (15.0%) and one (5.0%) of the 20 fish and 20 crustacean samples, respectively. However, they were above 10(4) MPN/100 g in 18 (90.0%) of the 20 mollusc samples. In seven (35.0%) of the 20 mollusc samples, tdh-positive organisms were found and their levels ranged from 3.6x10 to 1.1 x 103 MPN/100 g. From four of seven tdhpositive samples, tdh-positive V. parahaemolyticus was isolated.     

东南沿海地区零售海产品中创伤弧菌的监测

目的了解我国东南沿海地区零售海产品中创伤弧菌的污染状况。方法采用3%氯化钠碱性蛋白胨水增菌,改良纤维二糖-多粘菌素B-多粘菌素E(mCPC)琼脂和纤维二糖-多粘菌素E(CC)琼脂分离海产品试样中的创伤弧菌,可疑菌落的鉴定采用生化试验或PCR法。采用最可能数(MPN)法和PCR法检测牡蛎试样的创伤弧菌污染水平。结果天然污染海产品试样创伤弧菌的检出率为19.8%(20/101)。牡蛎试样中45%(55/122)创伤弧菌密度低于3MPN/g的最低检出限。牡蛎中创伤弧菌的污染水平存在季节性差异。结论未来应加强对我国海产品中创伤弧菌污染状况的监测,尤其是在温暖的季节。     

Vibrio parahaemolyticus: a concern of seafood safety

Vibrio parahaemolyticus is a human pathogen that is widely distributed in the marine environments. This organism is frequently isolated from a variety of raw seafoods, particularly shellfish. Consumption of raw or undercooked seafood contaminated with V. parahaemolyticus may lead to development of acute gastroenteritis characterized by diarrhea, headache, vomiting, nausea, and abdominal cramps. This pathogen is a common cause of foodborne illnesses in many Asian countries, including China, Japan and Taiwan, and is recognized as the leading cause of human gastroenteritis associated with seafood consumption in the United States. This review gives an overview of V. parahaemolyticus food poisoning and provides information on recent development in methods for detecting V. parahaemolyticus and strategies for reducing risk of V. parahaemolyticus infections associated with seafood consumption.     

Vibrio vulnificus and Vibrio parahaemolyticus in U.S. retail shell oysters: a national survey from June 1998 to July 1999.

From June 1998 to July 1999, 370 lots of oysters in the shell were sampled at 275 different establishments (71%, restaurants or oyster bars; 27%, retail seafood markets: and 2%, wholesale seafood markets) in coastal and inland markets throughout the United States. The oysters were harvested from the Gulf (49%). Pacific (14%), Mid-Atlantic (18%), and North Atlantic (11%) Coasts of the United States and from Canada (8%). Densities of Vibrio vulnificus and Vibrio parahaemolyticus were determined using a modification of the most probable number (MPN) techniques described in the Food and Drug Administration's Bacteriological Analytical Manual. DNA probes and enzyme immunoassay were used to identify suspect isolates and to determine the presence of the thermostable direct hemolysin gene associated with pathogenicity of V. parahaemolyticus. Densities of both V. vulnifcus and V. parahaemolyticus in market oysters from all harvest regions followed a seasonal distribution, with highest densities in the summer. Highest densities of both organisms were observed in oysters harvested from the Gulf Coast, where densities often exceeded 10,000 MPN/g. The majority (78%) of lots harvested in the North Atlantic, Pacific, and Canadian Coasts had V. vulnificus densities below the detectable level of 0.2 MPN/g; none exceeded 100 MPN/g. V. parahaemolyticus densities were greater than those of V. vulnificus in lots from these same areas, with some lots exceeding 1,000 MPN/g for V. parahaemolyticus. Some lots from the Mid-Atlantic states exceeded 10,000 MPN/g for both V. vulnificus and V. parahaemolyicus. Overall, there was a significant correlation between V. vulificus and V. parahaemolyticus densities (r = 0.72, n = 202, P < 0.0001), but neither density correlated with salinity. Storage time significantly affected the V. vulnificus (10% decrease per day) and V. parahaemolyticus (7% decrease per day) densities in market oysters. The thermostable direct hemolysin gene associated with V parahaemolyticus virulence was detected in 9 of 3,429 (0.3%) V. parahaemolyticus cultures and in 8 of 198 (4.0%) lots of oysters. These data can be used to estimate the exposure of raw oyster consumers to V. vulnificus and V. parahaemolyticus.     

OCCURRENCE OF VIBRIO PARAHAEMOLYTICUS IN DIFFERENT FINFISH AND SHELLFISH SPECIES

Occurrence of Vibrio parahaemolyticus was examined in 293 samples of finfish and Penaeus monodon from wholesale fish markets in Kolkata, India, by standard culture technique. The bacterium was isolated from 45.83% of shellfish and 16.73% of finfish samples. Among finfishes, about 30% of Chela laubuca and Otolithoides biauritus, and 18–21% of Lates calcarifer, Ompok bimaculatus and Herpadon nehereus samples were contaminated. The bacterium was mostly recovered from intestinal contents (32.25%) as compared to skin (11.95%) and gill tissue (16.43%). Seasonal variation in occurrence of the bacterium was also recorded. The occurrence was slightly more in seafishes (21.74%) as compared to estuarine (16.04%) and freshwater fishes (13.83%), and in demersal fish species (19.35%) posing health risk to the consumers.

PRACTICAL APPLICATIONS / SIGNIFICANCE OF THE STUDY

Although seafoods, especially molluscan shellfishes, are known to carry Vibrio parahaemolyticus and are common sources of human infection, presence of the bacterium in finfishes is less documented. We have examined presence of V. parahaemolyticus in 20 finfish and shellfish species in India. Relative occurrences of the bacterium in finfishes from different habitats (sea, estuarine and freshwater) and in pelagic/benthopelagic or demersal fish species give new insights about distribution of the bacterium in nature. Data on unequal distribution of the pathogen in different fish and shellfish species will be helpful to the food industry, as well as the fish-eating community, ensuring fish food safety.     

Occurrence and density of vibrio parahaemolyticus in live edible crustaceans from markets in China

Vibrio parahaemolyticus is a marine bacterium causing foodborne disease. Occurrence of the bacterium was investigated in six species of edible crustaceans available from markets in mainland China. The bacterium was detected in 22 of 45 whole-body, shell, and feces samples, including mitten crabs, which are supposed to be produced in freshwater ponds. The mean densities ranged from 2.8 log CFU/g in mitten crabs (Eriocheir sinensis) to 5.1 CFU/g in giant tiger prawns (Penaeus monodon). In hemolymph and muscle samples collected axenically, V. parahaemolyticus was detected in all of the prawns at a mean density of 2.6 log most probable number (MPN)/g, in two of five striped stone crabs (Charybdis feriatus) at a mean density of 1.1 log MPN/ml, and two of five mangrove mud crabs (Scylla serrata) at a mean density of 1.3 log MPN/ml. When six mitten crabs were collected from two freshwater ponds in China and were examined, V. parahaemolyticus was not detected. It seemed that cross-contamination occurred among live crustaceans at the markets. The results suggest that proper handling, storage, and cooking of these crustaceans will be necessary to lessen the risk of foodborne illness from V. parahaemolyticus.