Impact of flushing procedures on drinking water biostability and invasion susceptibility in distribution systems.

IF 3.9 2区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Applied and Environmental Microbiology Pub Date : 2025-05-13 DOI:10.1128/aem.00686-25

Fien Waegenaar, Thomas Pluym, Elise Vermeulen, Bart De Gusseme, Nico Boon

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引用次数: 0

Abstract

Ensuring high-quality drinking water remains challenging, as complaints about odors, discoloration, or contamination persist. In Belgium and beyond, traditional flushing is a common curative strategy that involves discharging large water volumes through hydrants while the network remains in use. In some cases, free chlorine (0.5 mg/L) is added, and consumers are advised not to drink the water. However, flushing can alter water biostability, potentially increasing susceptibility to microbial invasion. This study used a pilot-scale drinking water distribution system with three identical 100 m polyvinyl chloride(PVC) loops (DN 80 mm) to assess the impact of flushing with and without chlorination as practiced in chlorinated networks. Loop 1 was flushed with tap water and sodium hypochlorite (NaOCl), followed by two non-chlorinated flushes, loop 2 was unflushed, and loop 3 underwent three flushes. Biostability was assessed using online flow cytometry, and susceptibility to bacterial invasion (Aeromonas media, Pseudomonas putida, and Serratia fonticola) was evaluated in the days following flushing. The water had a 7-day residence time. Results showed that chlorinated flushing promoted microbial regrowth (3.8 × 10⁵ vs 2.0 × 10⁵ and 1.6 × 10⁵ cells/mL for loops 1, 2, and 3, respectively), primarily of resident Sphingopyxis spp. Biofilm cell densities (~4 × 10⁶ cells/cm²) remained stable across conditions. Bacterial indicators declined over time, with P. pudita and S. fonticola surviving longer (>100 hours) than A. media (13 hours). Decay rates were highest in chlorinated loops, likely due to increased microbial competition. For example, the decay constant of S. fonticola at 20°C was -0.082 h^-1, -0.042 h^-1, and -0.027 h^-1 for loops 1, 2, and 3, respectively.

Importance: Traditional flushing is used as a curative strategy to solve unwanted quality issues during distribution, yet its impact on microbial biostability remains poorly understood. This study provides critical insights into how traditional flushing, both with and without chlorination, influences microbial regrowth and susceptibility to invasion. Findings reveal that chlorinated flushing promotes the regrowth of resident drinking water bacteria while accelerating the decay of introduced unwanted bacterial indicators, emphasizing the complex trade-off between microbial control and system stability. Understanding these dynamics is essential for optimizing flushing procedures, minimizing unintended consequences, and improving distribution system resilience.

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冲水程序对供水系统中饮用水生物稳定性和入侵易感性的影响。

确保高质量的饮用水仍然具有挑战性，因为有关气味、变色或污染的投诉持续存在。在比利时和其他地方，传统的冲洗是一种常见的治疗策略，涉及在管网仍在使用的情况下通过消火栓排放大量水。在某些情况下，添加了游离氯（0.5 mg/L），建议消费者不要饮用。然而，冲洗会改变水的生物稳定性，潜在地增加对微生物入侵的敏感性。本研究使用了一个中试规模的饮用水分配系统，该系统具有三个相同的100米聚氯乙烯（PVC）回路（直径80毫米），以评估在氯化管网中进行有氯和无氯冲洗的影响。循环1用自来水和次氯酸钠（NaOCl）冲洗，随后进行两次非氯化冲洗，循环2不冲洗，循环3进行三次冲洗。使用在线流式细胞术评估生物稳定性，并在冲洗后的几天内评估对细菌入侵（媒介气单胞菌、化脓性假单胞菌和fonticola沙雷菌）的敏感性。水的停留时间为7天。结果表明，氯化冲洗可促进微生物再生（循环1、循环2和循环3分别为3.8 × 105和2.0 × 105和1.6 × 105个/mL），主要是常驻鞘膜菌的再生，生物膜细胞密度保持稳定（~4 × 106个/cm2）。细菌指标随着时间的推移而下降，P. pudita和S. fonticola的存活时间（100 ~ 100小时）比A. medium（13小时）长。在氯化循环中，腐烂率最高，可能是由于微生物竞争增加。例如，S. fonticola在20°C时，回路1、回路2和回路3的衰变常数分别为-0.082 h-1、-0.042 h-1和-0.027 h-1。重要性：传统的冲洗被用作一种治疗策略，以解决配送过程中不必要的质量问题，但其对微生物生物稳定性的影响仍然知之甚少。这项研究为传统冲洗（含氯和不含氯）如何影响微生物再生和对入侵的易感性提供了重要的见解。研究结果表明，氯化冲洗促进了居民饮用水细菌的再生，同时加速了引入的有害细菌指标的腐烂，强调了微生物控制与系统稳定性之间的复杂权衡。了解这些动态对于优化冲洗过程、减少意外后果和提高分配系统的弹性至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Applied and Environmental Microbiology 生物-生物工程与应用微生物

CiteScore

7.70

自引率

2.30%

发文量

730

审稿时长

1.9 months

期刊介绍： Applied and Environmental Microbiology (AEM) publishes papers that make significant contributions to (a) applied microbiology, including biotechnology, protein engineering, bioremediation, and food microbiology, (b) microbial ecology, including environmental, organismic, and genomic microbiology, and (c) interdisciplinary microbiology, including invertebrate microbiology, plant microbiology, aquatic microbiology, and geomicrobiology.