Truc-Quynh Nguyen , Malin Bomberg , Maija Nuppunen-Puputti , Vilma Ratia-Hanby , Elina Sohlberg , Pauliina Rajala
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The protocol was first validated using microbial pure cultures and materials before being integrated into a biofouling assessment pipeline of SS in a laboratory-scale brackish water circuit, incorporating electrochemical, surface, and molecular biology characterization analyses. The double-labeling HCR-FISH improved bioimaging of surface biofilm morphology and microbial distribution, surpassing monochrome staining methods. This method was compatible and complemented other microscopy techniques and molecular biological analyses, providing additional insights into the biofilms and deposits on the alloy surfaces. The implemented assessment pipeline for biofouling determination frequently detected the ennoblement phenomenon in the evolution of marine biofilm on SS surfaces. However, within the experimental timeframe, microbial activities in the brackish seawater circuit did not flourish significantly, resulting in minimal impact on the steel material. Additionally, surface type and roughness may correlate with microbial adhesion, biofilm growth, and the deformation of passivation layers in SS. Despite abundant sessile bacteria, particularly opportunistic microorganisms, on the steel surfaces, no direct correlations with biodeterioration phenomena or influences of surface roughness of an alloy and the presence of biofilm were conclusively established.</p></div>","PeriodicalId":11725,"journal":{"name":"Environmental Technology & Innovation","volume":"36 ","pages":"Article 103782"},"PeriodicalIF":6.7000,"publicationDate":"2024-08-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.sciencedirect.com/science/article/pii/S235218642400258X/pdfft?md5=fe7ea45d2373be02a979c886e11d33cb&pid=1-s2.0-S235218642400258X-main.pdf","citationCount":"0","resultStr":"{\"title\":\"Integrating double-labeling HCR-FISH into a multidisciplinary pipeline for biofouling assessment on austenitic stainless steel in brackish seawater circuit\",\"authors\":\"Truc-Quynh Nguyen , Malin Bomberg , Maija Nuppunen-Puputti , Vilma Ratia-Hanby , Elina Sohlberg , Pauliina Rajala\",\"doi\":\"10.1016/j.eti.2024.103782\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div><p>This study modified and integrated a bioimaging method of hybridization chain reaction fluorescence <em>in situ</em> hybridization (HCR-FISH) into a pipeline for assessing biofouling on stainless steel (SS). 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引用次数: 0
摘要
本研究将杂交链反应荧光杂交(HCR-FISH)的生物成像方法修改并整合到评估不锈钢(SS)生物污损的管道中。经过修改的双标记 HCR-FISH 方案直接应用于 EN 1.4404 级不锈钢的两种表面类型,分别以细菌 16 S rRNA 基因和亚硫酸盐还原酶(B)基因为靶标,检测局部细菌和硫酸盐还原菌(SRB)。首先利用微生物纯培养物和材料对该方案进行了验证,然后将其整合到实验室规模咸水回路中的 SS 生物污损评估管道中,并进行了电化学、表面和分子生物学特征分析。双标记 HCR-FISH 改善了表面生物膜形态和微生物分布的生物成像,超越了单色染色方法。这种方法与其他显微镜技术和分子生物学分析兼容并互补,为了解合金表面的生物膜和沉积物提供了更多信息。在 SS 表面海洋生物膜的演变过程中,用于生物污损测定的评估流水线经常检测到附着现象。不过,在实验时间范围内,微咸水回路中的微生物活动并没有显著增加,因此对钢材的影响微乎其微。此外,表面类型和粗糙度可能与 SS 的微生物附着、生物膜生长和钝化层变形有关。尽管钢材表面有大量的无柄细菌,尤其是机会微生物,但与生物劣化现象或合金表面粗糙度的影响以及生物膜的存在之间并没有确定的直接关系。
Integrating double-labeling HCR-FISH into a multidisciplinary pipeline for biofouling assessment on austenitic stainless steel in brackish seawater circuit
This study modified and integrated a bioimaging method of hybridization chain reaction fluorescence in situ hybridization (HCR-FISH) into a pipeline for assessing biofouling on stainless steel (SS). A modified protocol of double-labeling HCR-FISH was directly applied to two surface types of SS grade EN 1.4404 to detect localized bacteria and sulfate-reducing bacteria (SRB) by targeting bacterial 16 S rRNA genes and dissimilatory sulfite reductase (dsrB) genes, respectively. The protocol was first validated using microbial pure cultures and materials before being integrated into a biofouling assessment pipeline of SS in a laboratory-scale brackish water circuit, incorporating electrochemical, surface, and molecular biology characterization analyses. The double-labeling HCR-FISH improved bioimaging of surface biofilm morphology and microbial distribution, surpassing monochrome staining methods. This method was compatible and complemented other microscopy techniques and molecular biological analyses, providing additional insights into the biofilms and deposits on the alloy surfaces. The implemented assessment pipeline for biofouling determination frequently detected the ennoblement phenomenon in the evolution of marine biofilm on SS surfaces. However, within the experimental timeframe, microbial activities in the brackish seawater circuit did not flourish significantly, resulting in minimal impact on the steel material. Additionally, surface type and roughness may correlate with microbial adhesion, biofilm growth, and the deformation of passivation layers in SS. Despite abundant sessile bacteria, particularly opportunistic microorganisms, on the steel surfaces, no direct correlations with biodeterioration phenomena or influences of surface roughness of an alloy and the presence of biofilm were conclusively established.
期刊介绍:
Environmental Technology & Innovation adopts a challenge-oriented approach to solutions by integrating natural sciences to promote a sustainable future. The journal aims to foster the creation and development of innovative products, technologies, and ideas that enhance the environment, with impacts across soil, air, water, and food in rural and urban areas.
As a platform for disseminating scientific evidence for environmental protection and sustainable development, the journal emphasizes fundamental science, methodologies, tools, techniques, and policy considerations. It emphasizes the importance of science and technology in environmental benefits, including smarter, cleaner technologies for environmental protection, more efficient resource processing methods, and the evidence supporting their effectiveness.