为集中的的水性病毒和农业人畜共患病病原体的玻璃纤维过滤器
Summary
玻璃棉过滤器已用于水性病毒集中了世界各地的研究小组。在这里,我们表明兴建玻璃棉过滤器的一个简单的方法,并展示过滤器也有效地集中水性的病毒,细菌和原生动物病原体。
Abstract
关键的第一步是在怀疑受污染的水的病原体水平评估中的浓度。浓度的方法往往是具体 的特定病原体,例如,美国环境保护局方法1, 贾第鞭毛虫和隐 1623,这意味着需要多种方法,抽样方案,如果针对多个病原体组。目前的方法的另一个缺点是可以是复杂和昂贵的设备,例如,集中病毒2 1MDS滤芯过滤器VIRADEL方法。在这篇文章中,我们描述了如何构建集中水源性病原体的玻璃纤维过滤器。经过过滤洗脱,浓缩是服从第二个浓度的步骤,如离心,文化或分子生物学方法的病原体检测和枚举。该过滤器有几个优点。建设是很简单的过滤器,可以建立一个NY大小为满足特定的取样要求。过滤器零件价格便宜,从而有可能严重影响项目预算的情况下收集大量的样品。大样本量(100到千件L)可以集中根据浊度堵塞率。高度便携和过滤器是用最少的设备,如泵和流量计,他们可以在现场实施抽样成品饮用水,地表水,地下水,农业径流。最后,玻璃纤维过滤是有效集中各种病原体的类型,所以只有一个方法是必要的。在这里,我们集中水性人类肠病毒, 隐孢子虫 ,S almonella肠炎,禽流感病毒的报告过滤器的有效性。
Protocol
1。准备玻璃棉使每批过滤器前后,用10%漂白粉溶液消毒工作区。 戴上手套和礼服。至少20分钟,在121°C和15磅高压灭菌消毒桶。放置在无菌桶玻璃棉。 玻璃棉与反渗透水饱和,让浸泡15分钟。 排水反渗透水从桶。 1 M盐酸饱和玻璃棉,让浸泡15分钟。 从桶里漏1 M盐酸。 用反渗透水冲洗玻璃棉。 调匀。 使用pH试纸检查pH值和重复反渗?…
Discussion
玻璃棉过滤器已使用的几个研究小组3,5,6集中精力从各种水源,如成品饮用水,地下水8,9,10地表水,海水,废水12人的肠道病毒,农业径流13。在这里,我们报告的过滤器也有效的禽流感病毒以及细菌和原生动物病原体沙门氏菌 (伤寒沙门)和隐孢子虫 ,分别在集中。 deboosere 等。最近还报道了玻璃羊毛浓度禽流感病毒14。
<p class="j…Declarações
The authors have nothing to disclose.
Acknowledgements
我们感谢叙述视频威廉·T·埃克特。发展的玻璃棉协议的一部分是在威斯康星州的水和卫生审判肠溶风险(WAHTER研究)资助,由美国环保署STAR格兰特R831630。 A.穿过,A. Ramey,和B Meixell阿拉斯加样品收集来自美国地质调查局的财政支持。任何贸易,产品或公司名称的使用仅是描述目的,并不意味着美国政府认可。
Materials
| Name of reagent or item | Company | Catalogue number |
| Hydrochloric acid | Fisher Scientific | A144-500 |
| Sodium hydroxide | Fisher Scientific | BP359-212 |
| Phosphate Buffered Saline Sodium chloride Potassium phosphate-dibasic Potassium phosphate-monobasic |
Fisher Scientific Fisher Scientific Fisher Scientific |
BP358-212 BP363-500 BP362-500 |
| Sodium hypochlorite i.e., household bleach | The Clorox Co. | |
| Sodium thiosulfate, anhydrous | Fisher Scientific | S 475-212 |
| Beef extract, desiccated | Becton, Dickinson and Company | 211520 |
| Glycine | Fisher Scientific | G46-500 |
| Oiled sodocalcic glass wool
Or R-11 unfaced fiberglass insulation |
Isover
Johns Manville |
Bourre 725 QN |
| Polypropylene mesh | Industrial Netting | xN4510 |
| 2″x4″ Sch 80 PVC threaded pipe nipple | Grainger | 6MW35 |
| 2″ Sch 40 PVC cap | Grainger | 5WDW3 |
| Male adapter nylon fitting (1/2″x1/2″) | US Plastic Corp. | 62178 |
| Sample bottles for eluate- 1 liter | Fisher Scientific | 03-313-4F |
| 60 mL syringe | Fisher Scientific | NC9661991 |
| pH strips | Whatman | 2614 991 |
| Prefilter, Polypropylene, 10 inch cartridge, 10 μm | McMaster-Carr | 4411K75 |
| Prefilter housing | Cole-Parmer | S-29820-10 |
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Tags
Glass Wool FiltersConcentrationWaterborne VirusesAgricultural Zoonotic PathogensPathogen LevelsSampling ProgramConcentration MethodsEquipmentVIRADEL Method1MDS Cartridge FilterFilter ElutionCentrifugationPathogen DetectionEnumerationCultural MethodsMolecular MethodsAdvantagesConstructionSampling RequirementsInexpensive Filter PartsLarge Sample VolumesSample TurbidityPortable FiltersField Sampling
Citar este artigo
Millen, H. T., Gonnering, J. C., Berg, R. K., Spencer, S. K., Jokela, W. E., Pearce, J. M., Borchardt, J. S., Borchardt, M. A. Glass Wool Filters for Concentrating Waterborne Viruses and Agricultural Zoonotic Pathogens. J. Vis. Exp. (61), e3930, doi:10.3791/3930 (2012).