Hostname: page-component-cd9895bd7-lnqnp Total loading time: 0 Render date: 2024-12-22T16:06:05.493Z Has data issue: false hasContentIssue false

An unusually long-lasting outbreak of community-acquired Legionnaires' disease, 2005–2008, Italy

Published online by Cambridge University Press:  27 November 2014

M. SCATURRO
Affiliation:
Istituto Superiore di Sanità, Rome, Italy
S. FONTANA
Affiliation:
Istituto Superiore di Sanità, Rome, Italy
S. CRIPPA
Affiliation:
Azienda Sanitaria Locale, Desio, Italy
M. G. CAPORALI
Affiliation:
Istituto Superiore di Sanità, Rome, Italy
T. SEYLER
Affiliation:
Istituto Superiore di Sanità, Rome, Italy
E. VESCHETTI
Affiliation:
Istituto Superiore di Sanità, Rome, Italy
G. VILLA
Affiliation:
Azienda Sanitaria Locale, Desio, Italy
M. C. ROTA
Affiliation:
Istituto Superiore di Sanità, Rome, Italy
M. L. RICCI*
Affiliation:
Istituto Superiore di Sanità, Rome, Italy
*
*Author for correspondence: M. L. Ricci, Istituto Superiore di Sanità, Rome, Italy. (Email: [email protected])
Rights & Permissions [Opens in a new window]

Summary

An unusually long-lasting community-acquired outbreak of Legionnaires’ disease (LD) occurred in the inhabitants of a town in northern Italy from 2005 to 2008. Overall, 43 cases were diagnosed including five deaths. Hundreds of water samples were collected for Legionella isolation but only two clinical samples were obtained. Clinical strains were ST23 as were environmental isolates detected in most Legionella-positive patients' homes and those from a public fountain. Although no Legionella was found in the municipal water mains, a continuous chlorination was applied in 2008. This action resulted in a halving of cases, although incidence remained tenfold higher than the Italian average incidence until the end of 2013, when it dropped to the expected rate. Retrospective analyses of prevalent wind direction suggested that a hidden cooling tower could have been the main cause of this uncommon outbreak, highlighting the importance of implementation of cooling tower registers in supporting LD investigations.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2014 

INTRODUCTION

Since Legionnaires’ disease (LD) was first described at the end of the 1970s, many community-acquired outbreaks have occurred and Legionella pneumophila serogroup 1 (Lp1) has been found to be the most common causative agent [1]. In Europe, the largest community-acquired outbreak of LD occurred in Spain in 2001 with 449 confirmed cases [Reference Garcia-Fulgueiras2]. In Italy, since the 1990s three outbreaks have been identified: the first outbreak involving 34 cases occurred in 1995 in Sestri Ponente [Reference Castellani3], the second occurred in Rome in 2003 with 15 cases [Reference Rota4, Reference Scaturro5], and the latest in Lazise in 2011 with 17 cases [Reference Rota6]. In three of these events, epidemiological and molecular investigations identified a cooling tower as the source of infection, while in the Lazise outbreak the source of most cases was found to be the water distribution system of a campsite. However, globally the occurrence of both sporadic cases and community outbreaks of LD has also been associated with other environmental sources, such as spa pools, water distribution systems of accommodation sites, private homes and ships [Reference Coetzee7Reference Beyrer11].

In this paper, we describe an unusually long-lasting community-acquired outbreak of LD occurring from December 2005 to August 2008 in Cesano Maderno, a small industrial town in northern Italy. Epidemiological, microbiological and environmental investigations conducted and control measures implemented to stop the outbreak are reported.

MATERIALS AND METHODS

Setting

Cesano Maderno is a small town (11·5 km2) with 37 400 inhabitants, located in north-west Italy, at 198 m above sea level in the Po valley. It is characterized by the presence of a number of small- and medium-sized factories and commercial companies.

Following the occurrence of the first LD cases, as soon as the existence of an outbreak was recognized, the local health authority formed a joint multidisciplinary outbreak control team consisting of medical doctors, public health professionals, engineers, environmental technicians and microbiologists working at the local level. Epidemiologists and microbiologists of the Italian National Institute of Health (Istituto Superiore di Sanità) coordinated the investigation in Cesano Maderno town and surrounding area.

Epidemiological investigations

A case of LD was defined as a person residing in, or having visited, Cesano Maderno in the 10 days before the onset of disease, according to the EU case definition for LD [12]. Confirmed nosocomial cases or cases associated with travel outside Cesano Maderno for the entire incubation period were not considered.

Case-finding included mandatory notifications, and requests for information to local health authorities, general practitioners and hospitals present in the area. Surveillance was also enhanced, informing physicians of the on-going outbreak and asking them to test all pneumonia cases due to Legionella. Standardized questionnaires, concerning health status, type of residence, places visited and routes taken within the district, and usual social activities, were recorded by interviewing the cases.

In addition, at the beginning of the outbreak to ascertain whether further undiagnosed LD cases could have occurred during the outbreak, data regarding hospital discharge records of the main referral hospital were also analysed. To this aim, records reporting the ICD-IX code, identifying ‘pulmonary infections without aetiological diagnosis’ or ‘pulmonary infections due to other Gram-negative pathogens’ occurring during the period 2003–2006, were considered and incidence trend in the 3 years prior to the outbreak was compared to that in 2006.

Differences in the hospital discharge records for the considered years were evaluated by applying a χ 2 test using Stata software version 10·0 (Stata Corp LP, USA). A P value <0·05 was regarded as significant.

Environmental investigations

As the patients resided in different zones of Cesano Maderno, the entire town was inspected searching for all potential sources of Legionella infection. The environmental investigations first focused on large buildings, especially factories and supermarkets, and on patients' homes. The municipal drinking water system, consisting of pipes and wells without any disinfection procedure in place, was also inspected. Moreover, information about works performed on the municipal water system (such as building of new wells, replacement of sections of pipes, disinfection practices, etc.) was requested from the local relevant authorities.

Environmental samples were collected from 10 cooling towers (four located in Cesano Maderno and six in neighbouring towns), from tanks of a wood processing manufacturer, from drinking water taps, wells and tanks of the municipal water system and from public drinking water fountain in Cesano Maderno. In addition, all patients’ homes, but one, were sampled as well as 16 control houses, selected for similar heating system, building type and age. Five litres of water were collected from the municipal water network and 1 litre from all the other sampling sites.

The potential sources of infection as well as patients' homes were mapped using the Geographical Information System (Quantum GIS version 1.8.0; www.qgis.org) to detect possible spatial patterns.

Diagnosis of clinical and environmental samples

Legionella urinary antigen was detected by immune-enzymatic test (Biotest, Germany). Isolation of Legionella from two clinical samples (one lung tissue and one respiratory secretion) was performed using both glycine vancomycin polymyxin B cycloheximide (GVPC, Oxoid, UK) and buffered charcoal yeast extract (BCYE-α, Oxoid, UK) agar plates.

All water samples were analysed by culture according to ISO 11 731–1:1998 recommendations [13] while the ISO 11 731–2: 2004 standard [14] was used for the municipal water system comparative study.

Active air sampling was performed using a surface air system (SAS) sampler (International PBI, Italy) with a flow rate of 180 l/min and an aspiration volume of 1 m3 of air per sample. The sampler was placed at the emission point of the investigated cooling towers. Presence of Legionella was evaluated using replicate organism detection and counting agar plates containing GVPC medium.

Typical Legionella colonies from clinical and environmental samples were identified by latex agglutination test (Oxoid, UK) and confirmed by immunofluorescence assay using monoclonal antibodies (Dresden University) directed against the 15 different Legionella serogroups.

Molecular typing

Both clinical and environmental strains of Lp1 isolates were assayed for monoclonal subgroup by immuneofluorescent indirect assay according to the ‘Monoclonal (MAb) Dresden Panel’ [Reference Helbig15]. They were also typed by amplified fragment length polymorphism (AFLP) and sequence-based typing (SBT), using genomic DNA extracted from single Lp1 colonies with 20% Chelex 100 (Sigma, Germany). Briefly, the colonies were suspended in 1-ml sterile distilled H2O in a microfuge tube and centrifuged for 1 min at 12 000 g . Then the supernatant was removed and DNA extracted by adding 200 μl 20% Chelex 100 to the pellet followed by boiling for 10 min. AFLP was performed as described elsewhere [Reference Fry16] and the obtained genomic patterns were compared by visual analysis. SBT was performed according to the ‘sequence-based typing protocol for epidemiological typing of Legionella pneumophila’ version 4.2, analysing raw sequence data using the Legionella Sequence Quality Tool [17]. Thirty environmental strains, selected for having either the same AFLP profile but different MAb subgroup or different AFLP profile than those of the two clinical strains, were analysed by SBT.

Meteorological data

Meteorological data on air temperatures (minimum, maximum and average daily values), relative humidity (RH), atmospheric events (fog, rain, storm, snow), wind velocity (hourly and maximum daily values) and direction were acquired at two nearby stations in Carate Brianza and Milan Linate airport (at 8·1 and 21·3 km, respectively, from Cesano Maderno) from 4 months before to 4 months after the LD outbreak period (August 2005–December 2008). These data were correlated with the geographical and temporal distribution of the LD cases in order to explore potential infection sources and promoting factors in the examined area. In particular, wind direction was placed in relation to the geographical distribution of the patients' homes. For every meteorological parameter, the frequency distribution of median values recorded during the LD incubation period (i.e. 2–10 days before each illness onset) was compared with the frequency distribution of the corresponding data acquired in the other days of the investigated period (reference frequency distribution). A χ 2 two-sample test was applied to investigate whether the two frequency distributions differed from one another and a P value <0·05 was regarded as significant.

RESULTS

Descriptive epidemiology

From December 2005 to August 2008, 43 confirmed LD cases in residents of Cesano Maderno were notified, with two peaks, each of five cases, in July and October 2006, respectively, as shown in Figure 1. Mapping of the cases indicated that they were distributed throyghout the city (Fig. 2). All cases were hospitalized and five patients died. Legionella urinary antigen test was positive for all cases, whereas Legionella cultural isolation was only obtained for two patients. Of the two clinical strains the first was isolated in February 2007 and the second in February 2008. The outbreak mainly involved elderly individuals (median age 71 years, range 32–95 years) and the male/female ratio was 1·8:1. Most (75%) of the cases were affected by underlying chronic diseases, such as diabetes, chronic bronchitis, pulmonary emphysema, renal failure, transplant and cancer. Four patients reported they had never left their homes during the disease incubation period. All the patients' homes, both houses (75%) and flats (25%), received drinking water from the municipal network and hot water was produced by gas (71·4%), electric storage (19%) or by instant water heaters (4·8%). In 4·8% of cases people were not able to provide the information. The questionnaires administered to all the patients did not reveal any common habit, places visited or social activity.

Fig. 1. Legionnaire's disease cases by month of onset in residents in Cesano Maderno, December 2005–August 2008.

Fig. 2. Geographical distribution of the examined sites. ●, Home contaminated by Legionella; ○, home not contaminated by Legionella; × , not-sampled home; , sports centre; , public drinking water fountain; ■, cooling tower contaminated by Legionella; □, cooling tower not contaminated by Legionella; ▲, wood processing factory. Dashed lines indicate the boundaries of the funnel-shaped area.

Compared to previous years, the analysis of discharge records of the main hospital, where most of the cases were admitted, did not show a significant increase of pneumonia cases without aetiological diagnosis or due to other Gram-negative pathogens (P = 0·379). This suggested that a low probability of undiagnosed and under-reported cases occurred during the outbreak of LD.

Microbiological investigations

Culture examination of the two clinical samples allowed the isolation of Lp1.

Over 400 environmental water and air samples were collected and about 140 samples resulted negative for Legionella by culture, some of them also by repeated testing. Overall, in 22 (52%) patients' homes Legionella was detected at a concentration ranging from 102 to 105 c.f.u./l. Of these, 19 (86·4%) were positive for Lp1 at 1·2 × 102 to 7·1 × 105 c.f.u./l, two (9·1%) for Lp serogroups 2–15 at 1·4 × 103 to 3·2 × 105 c.f.u./l, and one (4·5%) for Legionella non-pneumophila at 3 × 103 to 9 × 105 c.f.u./l. In 4/19 houses positive for Lp1, Legionella non-pneumophila was also isolated at 103–105 c.f.u./l. In the remaining 20 houses (48%), although sampling was repeated at least twice, the culture always failed to detect Legionella. It is noteworthy that one patient living in one of the negative houses reported he had never left home during the disease incubation period. Water samples were collected in 16 control houses and 14 gave negative results. Of the remaining two houses one was positive for Lp1 at <2 × 102 to 8 × 102 c.f.u./l and the other for Lp serogroups 2–15 at 1·3 × 103 to 1 × 104 c.f.u./l (Table 1 and Fig. 2).

Table 1. Legionella contamination in the investigated sites in Cesano Maderno

Lp1, Legionella pneumophila serogroup 1; L-np, Legionella non-pneumophila; n.d., not detected.

* Different species and serogroups were often present simultaneously in the analysed samples.

Wood processing factory, supermarket and health centre.

Sampling performed at 48 points of the municipal water distribution system in Cesano Maderno gave positive results only in one public drinking water fountain, where Lp1 was isolated at a concentration of 102 c.f.u./l in November 2006 and 7 × 102 c.f.u./l in May 2007.

Seven out of 10 sampled cooling towers were Lp positive (Fig. 2) and four of them were Lp1 and were located in Cesano Maderno (Table 1); the remaining three cooling towers (outside Cesano Maderno) were Lp non-serogroup 1-positive (Fig. 2). In a wood processing factory, equipped with hot-water tanks but without cooling towers, water from a tap was also positive for Lp1and Lp serogroups 2–15 at <102–105 c.f.u./l. A sports centre was found Lp1 positive at <102–103 c.f.u./l (Table 1). Air samples collected near the cooling towers and the wood processing factory as well as in the main streets of the town, where most of cases resided, were found negative.

MAb typing

MAb typing showed that Lp1 colonies isolated from two clinical samples were Knoxville for one patient and Philadelphia subgroup for the other one. Overall, 92 Lp1 environmental isolates from patients' homes, municipal water system and factories' cooling towers were typed as Philadelphia (45·7%), Knoxville (30·4%), Olda (15·2%), Oxford (4·3%), France/Allentown (2·2%), and Benidorm (2·2%). In four patients' homes, as well as in the public drinking fountain, water samples were contaminated with Lp1 (both Knoxville and Philadelphia subgroups). Lp1 Olda strains were found in three houses and one cooling tower, while Lp1 Oxford strains were found only in two cooling towers. The two Lp1 France/Allentown strains were found in two houses' water systems together with Knoxville subgroup. The only Benidorm subgroup strain was found in the sports centre together with Knoxville subgroup (Table 2).

Table 2. Molecular typing of clinical and environmental Legionella pneumophila serogroup 1 isolates

MAb, Monoclonal antibody; AFLP, amplified fragment length polymorphism, n.d., not determined.

AFLP and SBT analyses

The two Lp1 clinical and 92 environmental strains were typed by the AFLP method and 14 different genomic profiles were identified. The two clinical and 11 environmental strains, nine from patients' houses and two from the public drinking water fountain, showed the same genomic profile. All the other environmental strains, indicated by the same number but different letters (i.e. 3E, 3 F), differed for a maximum of two bands, while the remaining isolates differed for at least three bands (Table 2).

SBT showed that the two clinical strains were ST23, a type frequently observed in community- and travel-associated cases occurring in Italy [Reference Fontana18].

Overall, 30 environmental Legionella strains were typed: 21 from 18 patients' homes (for one patient's home no Lp1 strains were provided by the Regional Reference Laboratory), four from three cooling towers, two from the sports centre, two from the public drinking fountain, and one from a tap of the wood processing factory's tank. All the Lp1 (both Philadelphia and Knoxville subgroups), from patients' homes, from the public drinking water fountain and from the taps of the wood processing factory's tank were ST23. The Lp1 Olda subgroups found in two houses were ST146. Four isolates from three cooling towers were all identified as ST1. Both Lp1 Knoxville and Benidorm found in the sports centre were ST42 (Table 2).

Analysis of meteorological data

Prevailing wind direction in the examined area was North-Northeast (Fig. 3) during all the investigated period with a very low hourly wind velocity (mainly in the range 0·3–2·0 m/s). It was perfectly aligned with the main axis of the funnel-shaped geographical distribution of the patients' homes (Fig. 2). Frequency distribution of the maximum daily wind velocities recorded during the LD incubation period was statistically different (P < 0·05) from the corresponding reference frequency distribution (Fig. 4) due to a significant increase of the percentage of the values in the range 3·0–4·0 m/s, which corresponds to a light breeze according to the Beaufort scale.

Fig. 3. Wind rose plot obtained from hourly data on wind directions (directions from which the wind was blowing) and velocities acquired between 2 and 10 days before every confirmed case of Legionnaire's disease. Hourly wind velocities (m/s): , 0·0–0·3; , 0·4–2·0; , 2·1–4·0; ■, >4·0.

Fig. 4. Frequency distributions of maximum daily wind velocities. , Median of the data acquired between 2 and 10 days before each confirmed case of Legionnaire's disease (values interpolated with a continuous line); ■, data acquired on the other days of the investigated period (values interpolated with a dashed line).

During all the investigated period, the average daily air temperature was in the range 0–30 °C (with a mode of 25 °C) while the maximum daily air temperature was in the range 5–40 °C (with a mode of 30 °C). A statistically significant difference (P < 0·05) in the frequency distribution of the minimum daily air temperature was observed between the LD incubation period of every case and the other days of the investigated period due to a shift of the first towards higher temperatures (20–25 °C). Similarly, the two frequency distributions of air humidity differed substantially between them (P < 0·05) as a consequence of the significant incidence of medium-high humidity values (mainly 65% relative humidity) during the LD incubation period. Overall, these findings are consistent with the ecology of Legionella, whose airborne survival and transmission is affected by various environmental factors, chief among them being warm air temperature and medium-high relative humidity [Reference Hambleton19Reference Tang21].

Unlike the results of a previous report on the influence of rainfall on LD occurrence [Reference Garcia-Vidal22], data acquired in this case study have shown that the LD incubation period was characterized by scant rainfall events. This meteorological condition together with thermal inversion, which usually affects the Po valley, has probably increased the permanence of the supposed aerosol plume in the atmosphere above the area.

Recommendations, implemented control measures and follow-up of the outbreak

During environmental and microbiological investigations, the local health authority and the National Institute of Health released recommendations according to Italian and European Legionella guidelines [23, 24] on how to reduce the risk of Legionella contamination in household water distribution systems.

Implementation of control measures and disinfection practices were requested for the cooling towers found positive for Legionella and in June 2008 a continuous disinfection (0·2 mg/l of residual chlorine) was applied as preventive action throughout the whole municipal water network. In addition, all the general practitioners of the city were alerted to pay more attention to patients reporting symptoms of pneumonia and influenza-like diseases. These recommendations and the chlorination applied to the municipal water network slightly reduced the number of cases in the subsequent years (eight in 2009, seven in 2010, six in 2011, seven in 2012) but the incidence of LD in Cesano Maderno remained tenfold higher than the average incidence in Italy up to 2012. It was only in 2013 that, due to unknown reasons, only three cases were notified, returning the LD average incidence to the expected value.

DISCUSSION

This study describes an unusual community-acquired LD outbreak, characterized by 43 cases including five deaths, distributed throughout a period of 3 years with two major peaks in July and October 2006, followed by a period of high LD incidence lasting up to 2012.

Although an accurate epidemiological, environmental and microbiological investigation was conducted, no common source of infection which could explain such a long-lasting distribution of cases spread throughout the area of Cesano Maderno was identified.

Legionella contamination was found in 52% of the internal water distribution systems of the patients' homes. This high percentage of Legionella contamination never described before, is in contrast with the high presence of instant heaters (71%) known to be less prone to favour colonization of water systems [Reference Simmons25] and is probably explained by the extra attention given to the search for the bacterium with repeated samplings.

Molecular typing strongly suggested a clonal relation between the two clinical isolates and most of the analysed Lp strains (i.e. those found in 18 household water systems, in the public drinking water fountain and in the wood processing factory). MAb typing revealed that clinical isolates were from two different subgroups, Philadelphia and Knoxville both from the MAb 3/1 positive group, while the genomic (AFLP) and allelic (SBT) profiles showed that they were identical and matched many environmental strains described previously. Since phenotypic differences between strains are possible, when a correlation between strains must be defined, genetic identity has a greater discriminatory power especially when it is confirmed by two typing methods.

Although according to molecular typing the houses and the water mains could be considered a probable source of infection, the samples collected in the municipal network of Cesano Maderno repeatedly failed to provide evidence of Legionella presence. In addition, no plumbing work on the water mains of Cesano Maderno, which might suggest an increased risk of LD acquisition [Reference Straus26] had taken place.

Even though house contamination by Legionella is widely demonstrated [Reference Beyrer11, Reference Straus26Reference Thomas28], the occurrence of a so high number of cases linked to house contamination is not common [Reference Krojgaard29, Reference Lim30]. Notwithstanding, it is not possible to exclude that the poor water system maintenance in some of the houses may have acted as source of infection, especially for those patients who, because of health problems, never left their homes during the incubation period.

The modest wind velocity only suggested that an aerosol plume released intermittently by a hidden cooling tower might have contaminated the area. The surprising fit of the prevalent wind direction with the main axis of the funnel-shaped geographical distribution of the homes of the cases, made by a retrospective comparative examination, has suggested that the source of microbiological contamination was presumably localized in the north-east part of Cesano Maderno. The direction of the light breeze, the thermal inversion and the scant rainfall events, resulting from the analysis of the meteorological data, could all be responsible for the cases within 4–5 km of the supposed contamination source. This hypothesis, as well as the outcomes so far examined, is fully compatible with previous studies [Reference Addiss31Reference Nygard33].

However, we were not able to demonstrate this hypothesis because only four cooling towers were found to be contaminated by Lp1 but with different sequence types compared to the two clinical strains. As a matter of fact, one of the weaknesses of this study was that in spite of the high number of cases only two clinical isolates were available, due to the large diagnostic use of the urinary antigen test that in Italy has almost completely replaced all other diagnostic tests.

Another critical aspect was the lack of a cooling tower register, as their notification by owners is not mandatory in Italy. The thorough environmental investigations conducted in Cesano Maderno and in the neighbouring towns allowed identification of the presence of 10 cooling towers, most of them subjected to proper and regular maintenance so that Legionella was found in low concentrations in the collected water samples. However, the possibility of having missed some cooling towers cannot be ruled out. Indeed, these devices may be hidden by thick vegetation or located below the road surface as we experienced during the last two outbreak investigations conducted in Italy [Reference Rota4].

Although since June 2008 a continuous disinfection treatment has been implemented in the municipal water supply, the incidence of LD in Cesano Maderno remained high in the following years. This finding underlines that in all likelihood, this intervention, albeit appropriate, was not able to halt the outbreak because one or more undetected sources were still active.

It was only in 2013 that the frequency of cases suddenly decreased to the expected background level. We might speculate that this effect was caused by the shutdown of the supposed contaminated cooling tower following the closure of several factories or companies affected by the recent worldwide economic crisis.

In conclusion, this investigation highlights, once more, how the identification of a source of a LD outbreak can be difficult and how the presence of a cooling tower register and the availability of as many as possible clinical isolates for comparison with environmental isolates, may facilitate this task.

ACKNOWLEDGMENTS

We are grateful to Ghezzi Marco and Gricini Ennio of Dipartimento di Prevenzione Medica, U.O. Igiene Pubblica of Desio (local health authority of Monza and Brianza) for their valuable support in the environmental investigation as well as to Giacomini Monica for the patients' interviews and epidemiological data collection.

The authors thank Alessandra Galbiati of Servizio Igiene Alimenti e Nutrizione, U.O. of Desio and Antoniazzi Chiara of Agenzia Regionale Prevenzione per l'Ambiente of Lombardy Region, U.O. Metereologia, Milan for providing us with wind data.

We also thank the municipal authority of Cesano Maderno, the staff of Desio's hospital, the local health authorities of Cesano Maderno, and the neighbouring towns and everyone who contributed to investigations, management and control of the described outbreak.

This investigation was funded by a grant of the Ministry of Health (Centro per il controllo delle malattie, CCM, years 2006–2009) as part of public health response to Legionnaires' disease outbreak and by the local health authority of Monza and Brianza.

DECLARATION OF INTEREST

None.

References

REFERENCES

2. Garcia-Fulgueiras, A, et al. Legionnaires' disease outbreak in Murcia, Spain. Emerging Infectious Diseases 2003; 9: 915921.CrossRefGoogle ScholarPubMed
3. Castellani, Pastoris M, et al. Molecular epidemiology of an outbreak of Legionnaires' disease associated with a cooling tower in Genova-Sestri Ponente, Italy. European Journal of Clinical Microbiology and Infectious Diseases 1997; 16: 883892.CrossRefGoogle Scholar
4. Rota, MC, et al. Legionnaires' disease outbreak in Rome, Italy. Epidemiology and Infection 2005; 133: 853859.CrossRefGoogle ScholarPubMed
5. Scaturro, M, et al. Comparison of three molecular methods used for subtyping of Legionella pneumophila strains isolated during an epidemic of Legionellosis in Rome. Journal of Clinical Microbiology 2005; 43: 53485350.Google Scholar
6. Rota, M, et al. Cluster of travel-associated Legionnaires disease in Lazise, Italy, July to August 2011. Eurosurveillance 2011; 16(40).Google Scholar
7. Coetzee, N, et al. An outbreak of Legionnaires' disease associated with a display spa pool in retail premises, Stoke-on-Trent, United Kingdom, July 2012. Eurosurveillance 2012; 17(37).Google Scholar
8. Palmore, TN, et al. A cluster of cases of nosocomial legionnaires disease linked to a contaminated hospital decorative water fountain. Infection Control and Hospital Epidemiology 2009; 30: 764768.Google Scholar
9. Rota, MC, et al. Clusters of travel-associated Legionnaires disease in Italy, Spain and France, July 2002–June 2006. Eurosurveillance 2007; 12(11): E3–4.Google Scholar
10. Luck, PC, et al. Community-acquired Legionnaires' disease caused by Legionella pneumophila serogroup 10 linked to the private home. Journal of Medical Microbiology 2008; 57: 240243.Google Scholar
11. Beyrer, K, et al. Legionnaires' disease outbreak associated with a cruise liner, August 2003: epidemiological and microbiological findings. Epidemiology and Infection 2007; 135: 802810.Google Scholar
12. Commission of the European Communities. Amending Decision No 2119/98/EC of the European Parliament and of the Council and Decision 2000/96/EC as regards communicable diseases listed in those decisions and amending Decision 2002/253/EC as regards the case definitions for communicable diseases [notified under document number C(2003) 2301]. Commission Decision of 17 July 2003. Official Journal of the European Union, 2003.Google Scholar
13. International Organization for Standardization. Water quality – detection and enumeration of Legionella, 1998.Google Scholar
14. International Organization for Standardization. Water quality-detection and enumeration of Legionella. Part 2: direct membrane filtration method for waters with low bacterial counts, 2004.Google Scholar
15. Helbig, JH, et al. Pan-European study on culture-proven Legionnaires' disease: distribution of Legionella pneumophila serogroups and monoclonal subgroups. European Journal of Clinical Microbiology and Infectious Diseases 2002; 21: 710716.Google Scholar
16. Fry, NK, et al. Designation of the European Working Group on Legionella infection (EWGLI) amplified fragment length polymorphism types of Legionella pneumophila serogroup 1 and results of intercentre proficiency testing using a standard protocol. European Journal of Clinical Microbiology and Infectious Diseases 2002; 21: 722728.Google Scholar
17. European Working Group for Legionella Infections, Health Protection Agency, European Centre for Disease Prevention and Control. Legionella pneumophila sequence-based typing (http://www.hpa-bioinformatics.org.uk/legionella/legionella_sbt/php/sbt_homepage.php).Google Scholar
18. Fontana, S, et al. Molecular typing of Legionella pneumophila serogroup 1 clinical strains isolated in Italy. International Journal of Medical Microbiology 2014; 304: 597602.Google Scholar
19. Hambleton, P, et al. Survival of virulent Legionella pneumophila in aerosols. Journal of Hygiene 1983; 90: 451460.Google Scholar
20. Dennis, PJ, Lee, JV. Differences in aerosol survival between pathogenic and non-pathogenic strains of Legionella pneumophila serogroup 1. Journal of Applied Bacteriology 1988; 65: 135141.Google Scholar
21. Tang, JW. The effect of environmental parameters on the survival of airborne infectious agents. Journal of the Royal Society Interface. 2009 6: S737S746.Google Scholar
22. Garcia-Vidal, C, et al. Rainfall is a risk factor for sporadic cases of Legionella pneumophila pneumonia. PLoS ONE 2013; 8: e61036.Google Scholar
23. Linee guida per per la prevenzione e il controllo della legionellosi. Guidelines for prevention and control of legionellosis. Gazzetta Ufficiale della Repubblica Italiana 5.05.2000Google Scholar
24. EWGLI Technical Guidelines for the investigation, control and prevention of travel-associated Legionnaires’ disease. September 2011, version 1.1 (http://www.ecdc.europa.eu/en/publications/Publications/legionnaires-disease-surveillance-2012.pdf).Google Scholar
25. Simmons, G, et al. A Legionnaires' disease outbreak: a water blaster and roof-collected rainwater systems. Water research. 2008; 42: 14491458.CrossRefGoogle ScholarPubMed
26. Straus, WL, et al. Risk factors for domestic acquisition of legionnaires disease. Ohio legionnaires Disease Group. Archives of Internal Medicine 1996; 156: 16851692.Google Scholar
27. Alary, M, Joly, JR. Risk factors for contamination of domestic hot water systems by legionellae. Applied Environmental Microbiology 1991; 57: 23602367.Google Scholar
28. Thomas, V, et al. Amoebae in domestic water systems: resistance to disinfection treatments and implication in Legionella persistence. Journal of Applied Bacteriology 2004; 97: 950963.Google Scholar
29. Krojgaard, LH, et al. Cluster of Legionnaires disease in a newly built block of flats, Denmark, December 2008–January 2009. Eurosurveillance 2011; 16(1).Google Scholar
30. Lim, WS, et al. Community-acquired Legionnaires' disease in Nottingham – too many cases? Epidemiology and Infection 2003; 131: 10971103.Google Scholar
31. Addiss, DG, et al. Community-acquired Legionnaires' disease associated with a cooling tower: evidence for longer-distance transport of Legionella pneumophila. American Journal of Epidemiology 1989; 130: 557568.CrossRefGoogle ScholarPubMed
32. Nguyen, TM, et al. A community-wide outbreak of legionnaires disease linked to industrial cooling towers – how far can contaminated aerosols spread? Journal Infectious Diseases 2006; 193: 102111.Google Scholar
33. Nygard, K, et al. An outbreak of legionnaires disease caused by long-distance spread from an industrial air scrubber in Sarpsborg, Norway. Clinical Infectious Diseases 2008; 46: 6169.Google Scholar
Figure 0

Fig. 1. Legionnaire's disease cases by month of onset in residents in Cesano Maderno, December 2005–August 2008.

Figure 1

Fig. 2. Geographical distribution of the examined sites. ●, Home contaminated by Legionella; ○, home not contaminated by Legionella; × , not-sampled home; , sports centre; , public drinking water fountain; ■, cooling tower contaminated by Legionella; □, cooling tower not contaminated by Legionella; ▲, wood processing factory. Dashed lines indicate the boundaries of the funnel-shaped area.

Figure 2

Table 1. Legionella contamination in the investigated sites in Cesano Maderno

Figure 3

Table 2. Molecular typing of clinical and environmental Legionella pneumophila serogroup 1 isolates

Figure 4

Fig. 3. Wind rose plot obtained from hourly data on wind directions (directions from which the wind was blowing) and velocities acquired between 2 and 10 days before every confirmed case of Legionnaire's disease. Hourly wind velocities (m/s): , 0·0–0·3; , 0·4–2·0; , 2·1–4·0; ■, >4·0.

Figure 5

Fig. 4. Frequency distributions of maximum daily wind velocities. , Median of the data acquired between 2 and 10 days before each confirmed case of Legionnaire's disease (values interpolated with a continuous line); ■, data acquired on the other days of the investigated period (values interpolated with a dashed line).