空气温度在意大利南部军团菌水污染和军团菌病发病率中的作用(2018-2023)。

IF 1.5 Q3 HEALTH CARE SCIENCES & SERVICES Annali di igiene : medicina preventiva e di comunita Pub Date : 2023-11-01 Epub Date: 2023-09-20 DOI:10.7416/ai.2023.2578
M T Montagna, S Brigida, F Fasano, C M Leone, M D'Ambrosio, V Spagnuolo, M Lopuzzo, F Apollonio, F Triggiano, M E Caringella, O De Giglio
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引用次数: 0

摘要

背景:军团病是由吸入或吸入被军团菌污染的小水滴引起的,军团菌通常存在于天然和人造水系以及潮湿的土壤中。在过去的5年里,欧盟/欧洲环境局的这种疾病的通知率几乎翻了一番,从2015年的1.4例增加到2019年的2.2例/10万人口。一些研究表明,水网中微生物的大量存在和军团菌病病例的增加可能与一些环境因素的变化有关,如空气温度,这些因素可能会影响水温。研究设计:由于气候变化对自然环境的重大影响,气候变化目前是世界范围内的一个突出话题。它是众多水传播疾病增加的原因。本研究的目的是将2018年1月至2023年4月阿普利亚地区记录的气温与公共和私人设施供水网络中军团菌的存在以及同期军团菌病的发病率联系起来。方法:在2018年1月至2023年4月期间,从涉及军团菌病病例的设施收集水样,并分析军团菌。在同一时期,向地区流行病学观察站(OER Apulia)通报的所有病例都包括在本研究中。使用Shapiro-Wilk检验来确定军团菌载量是否正态分布,使用Wilcoxon秩和检验来比较军团菌检测阴性和阳性样本的空气温度(平均值和范围),以及使用多变量分析(泊松回归)来比较军团杆菌载量与水样温度,平均空气温度和采样当天的温度范围。配对样本的Wilcoxon检验用于比较温暖和寒冷月份的军团菌病病例。结果:总共对13044份水样进行了军团菌分析,报告了460例军团菌病。军团菌检出率为20.1%。阴性样本和阳性样本之间的空气温度差异具有统计学意义(p值<0.0001):在水样军团菌检测呈阳性的日子里,观察到的温度范围高于水样检测呈阴性的日子(p值=0.004)。泊松回归显示军团菌载量、水温,以及平均空气温度。军团菌病病例在温暖月份的发病率高于寒冷月份(p值=0.03)。结论:我们的研究强调了阿普利亚水系中军团菌的负荷显著增加,以及温暖的温度与军团菌病发病率之间的关联。我们认为,需要在不同的背景和地区进行进一步的调查,以确定军团菌病的流行病学特征,并解释其在不同地理区域的极端变异性,以及这些数据如何受到不同风险因素的影响。
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The role of air temperature in Legionella water contamination and legionellosis incidence rates in southern Italy (2018-2023).

Background: Legionnaires' disease is caused by inhalation or aspiration of small water droplets contaminated with Legionella, commonly found in natural and man-made water systems and in moist soil. Over the past 5 years, notification rates of this disease have almost doubled in the European Union (EU) / European Environmental Agency (EEA), from 1.4 in 2015 to 2.2 cases per 100,000 population in 2019. Some studies show that the greater presence of the microorganism in the water network and the increase in cases of legionellosis could be related to the variations in some environmental factors, such as air temperature, which may influence the water temperature.

Study design: Climate change is currently a prominent topic worldwide because of its significant impact on the natural environment. It is responsible for the increase in numerous waterborne pathologies. The purpose of this study was to correlate the air temperature recorded in Apulia region from January 2018 to April 2023 with the presence of Legionella in the water networks of public and private facilities and the incidence rates of legionellosis during the same period.

Methods: During the period from January 2018 to April 2023, water samples were collected from facilities involved in legionellosis cases and analyzed for Legionella. During the same period, all the cases notified to the regional epidemiological observatory (OER-Apulia) were included in this study. Statistical analyses were conducted using the Shapiro-Wilk test to determine whether the Legionella load was distributed normally, the Wilcoxon rank sum test to compare the air temperatures (average and range) of the negative and positive samples for Legionella detection, and the multivariate analysis (Poisson regression) to compare the Legionella load with the water sample temperature, average air temperature, and temperature range on the day of sampling. The Wilcoxon test for paired samples was used to compare legionellosis cases between the warmer and colder months.

Results: Overall, 13,044 water samples were analyzed for Legionella and 460 cases of legionellosis were notified. Legionella was isolated in 20.1% of the samples examined. The difference in the air temperature between negative samples and positive samples was statistically significant (p-value < 0.0001): on days when water samples tested positive for Legionella a higher temperature range was observed than on days when water samples tested negative (p-value = 0.004). Poisson regression showed a direct correlation between Legionella load, water temperature, and average air temperature. The incidence of legionellosis cases in warmer months was higher than in colder months (p-value = 0.03).

Conclusions: Our study highlights a significant increase in the load of Legionella in the Apulian water network, and an association between warmer temperatures and legionellosis incidence. In our opinion, further investigations are needed in different contexts and territories to characterize the epidemiology of legionellosis, and to explain its extreme variability in different geographical areas and how these data may be influenced by different risk factors.

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来源期刊
Annali di igiene : medicina preventiva e di comunita
Annali di igiene : medicina preventiva e di comunita HEALTH CARE SCIENCES & SERVICES-
CiteScore
3.40
自引率
0.00%
发文量
69
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