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Legionella: Health Effects, Occurrence and Sampling

Health effects of Legionella

In 1976, in Philadelphia, USA, over 200 attendees of the US-American Legion, developed pneumonia. The disease was later called “Legionnaires’ disease”. The causative agent, a Gram-negative bacterium, was named Legionella pneumophila. Legionella pneumophila causes 85-90% of all cases of Legionella infections (legionellosis). There are over 40 species of Legionella.

Legionella pneumophila can cause very severe infection of the respiratory system. However, Legionnaires’ disease epidemics are rare but the disease is fatal if untreated. The disease may develop within 2 to 13 days (average 5-6 days).

Another form of legionellosis is Pontiac fever, named after an outbreak in 1968 in Pontiac, USA. This form of disease, caused by a number of Legionella species, is milder than Legionnaires’ disease. Pontiac fever develops within 48 to 72 hours and the illness may clear in 2-5 days. No fatal cases have been reported in relation to Pontiac fever. This disease mainly appears as epidemics. Pontiac fever is believed to be a reaction to inhaled Legionella antigens rather than an infection.

Disease transmission

There is no evidence for transmission of legionellosis from person to person or by ingestion. Legionella infection occurs when people inhale the bacterium via fine water droplets as aerosols from the environment. Indoor transmission of legionellosis has been reported via contaminated hot water supplies in hospitals, hotels and other public buildings, respiratory therapy equipment, jacuzzis, spas and air-humidifiers.

Occurrence

Legionella bacteria are part of the natural aquatic bacterial population of lakes and rivers. They are present in all types of fresh water, including tap water. Legionella multiply in water, using other microorganisms like bacteria, algae and protozoa. Their concentration in fresh water is influenced mainly by the temperature. They are isolated more frequently and in higher concentrations from warm water (30 to 50 °C.). However, Legionella also survive at much lower temperatures indoors as well as outdoors. At temperatures above 60 °C Legionella can’t survive.

Sampling Of Legionella

Sampling of Legionella in indoor air or water on a routine basis is not recommended. However, sampling is recommended to:

  • determine the source of outbreaks of legionellosis
  • check the effectiveness of maintenance practices and control measures for hot water supplies and humidified ventilation systems
  • guarantee the safe use of hot water supplies and humidified ventilation systems.

When investigating the water services within a building for Legionella, the condition of pipes, the joining methods used, the presence of lagging, sources of heat, and the standard of protection afforded tanks should be noted, as well as disconnected fittings, ‘dead-ends’, and cross-connections with other services.Water Sampling
Water samples should be collected in sterile autoclavable plastic containers. The samples should be taken from:

  • the incoming supply;
  • tanks;
  • an outlet close to, but downstream of, each tank;
  • the distant point of each service;
  • the water entering and leaving any fitting under particular suspicion.

Surface Sampling
Using swabs, surface samples should be taken from shower heads, pipes and taps. Also, sludge, slime or sediments within building water services or humidifiers can also be collected, particularly where accumulation occurs.

Sample Handling and Storage
Samples should be stored at room temperature (20 ± 5 °C.) in the dark and should be processed within 2 days. That means the samples should be sent to the laboratory within 24 hours. It is also important to confirm with the lab that they have the necessary media before sampling is done.

Air sampling
The presence of Legionella in indoor air can be investigated using Reuter Centrifugal Sampler (RCS) or the Andersen sampler. Regardless of the sampler used, the recommended sampling agar at present is BCYE-agar.

References

  1. Flannigan, B., R.A. Samson, and J.D. Miller (Editors). Microorganisms in home and indoor work environments: diversity, health impacts, investigation and control. 2001. London, UK: Taylor & Francis (ISBN: 0-415-26800-1).
  2. Wanner, H-U, AP Verhoeff, A Colombi, B Flannigan, S Gravesen, A Mouilleseux, A Nevalainen, J Papadakis, and K Seidel. 1993. Biological Particles in Indoor Environments. Indoor Air Quality and Its Impact On Man. Brussels: Commission of the European Communities. Report No. 12.

For more information on indoor bacteria, please visit http://www.moldbacteria.com/ or call 905-290-101.

Mould Growth In Buildings

Mould growth only occurs in moisture-damaged and damp building materials. The main causes of mould growth in buildings, therefore, may include poor maintenance and lifestyles of occupants, defective construction and use of building materials susceptible to mould attack. It is estimated that up to 40% and 30% of buildings in the USA and Canada respectively have mould problems.

Health Effects Associated With Mould Growth And Dampness

Several studies suggest that people living and working in damp or mouldy buildings have a higher risk of respiratory health problems such as asthma and bronchitis. Other symptoms associated with mould growth and dampness include blocked nose, itching eyes, and skin irritation. In agricultural environments, where the concentration of spores is several magnitudes higher than in indoor air, inhalation of spores has been associated with cancer, premature birth and farmers lung disease.

Penicillium Species As Indoor Air Contaminants

In 1928, Alexander Fleming’s bacterial cultures were contaminated by airborne spores of a green mould. Fleming noticed that bacteria were not growing close to the green mould. He concluded that the mould was producing a compound that was killing or inhibiting the growth of bacteria. That is how Penicillins, the oldest and probably the best known of all the antibiotics were accidentally discovered. The green mould was later identified as Penicillium notatum. Penicillium notatum (now called Penicillium chrysogenum) is one of the most common indoor fungal contaminants.Spores of Penicillium chrysogenum

Penicillium is found worldwide. The spores of this mould are found everywhere in the air and soil. In indoor environment, this mould proliferates in damp conditions. Penicillium is commonly called the blue or green mould because (depending on the species) it produces enormous quantities of greenish, bluish or yellowish spores which give it the characteristic colour. The blue in the blue-cheese, for example, is the colour of the spores of the Penicillium species used in ripening the cheese. About 200 species have been described.

Penicillium species as contaminants of indoor air

In indoor environments, Penicillium is extremely common on damp building materials, walls and wallpaper, floor, carpet mattress and upholstered furniture dust. The spores of this mould are produced in dry chains and are exposed to the air hence their ease to become airborne. Spore sizes range from 3 to 5 micrometres. Because of their small size, they take long to settle and can be inhaled deep into the lungs. The spores are found indoors throughout the year. For air samples analysed by direct microscopy, it is hard to distinguish between spores of Penicillium from those of Aspergillus. Therefore these spores are often reported as Aspergillus/Penicillium. The most common Penicillium species in indoor environment is Penicillium chrysogenum. It produces a number of toxins of moderate toxicity. It is also allergenic and can infect immuno-compromised patients.
Picture of Penicillium chrysogenum on wood

Penicillium species as a health hazard

Many species of Penicillium are common contaminants on various organic materials and are recognized potential mycotoxin producers. The most well known toxin producing species in foods include P. citreonigrum, P. citrinum, P. crustosum, P. islandicum and P. verrucosum. Therefore, when it comes to food contamination, correct identification of Penicillium is important. Although, human pathogenic species are rare, opportunistic infections have been reported in individuals with weakened immune system such as the HIV/AIDS patients. The species commonly associated with opportunistic infections is P. marneffei.

Penicillium species as food spoilage organisms

Penicillium species are common causes of spoilage of fruits, cheese, cold meats, old sandwiches, cereals and cereal products and a host of other agricultural and animal products. For example, Penicillium italicum and Penicillium digitatum are common causes of rot of citrus fruits, while Penicillium expansum is known to spoil apples. As mentioned above, most Penicillium species produce toxins. It is a good practice to discard foods with any visible mould growth. It is important to know some species of Penicillium are beneficial to humans. For example, cheeses such as Roquefort, Camembert and others are ripened with species of Penicillium.Penicillium on food

References

  1. Introduction to food and airborne fungi. Seventh Edition. Samson, Robert A., Hoekstra, Ellen S., Frisvad, Jens C (Editors). Centraalbureau voor Schimmelcultures, 2004.
  2. Microorganisms in home and indoor work environments: Diversity, Health Impacts, Investigation and control. Flanning Brian, Samson, Robert A., and Miller, David J (Ed.), Tayler and Francis, 2001.

For more information on Penicillium species,please visit http://www.moldbacteria.com/learnmore/moldlist.html or call 905-290-101.

Chaetomium species as indoor contaminants

Chaetomium species

Chaetomium globosumChaetomium species are found worldwide in soil, dung, or decaying plants. Most species are prolific producers of the enzyme cellulase that breaks down cellulose. Destruction of paper and other materials containing cellulose (including foods, feeds, paper, textile, bird feathers, seeds and military equipment) by species of this mould is well documented. Due to their strong ability to destroy material, Chaetomium species are often used in testing materials for resistance to mould growth.

Chaetomium is perhaps the third most common indoor fungal contaminant of mouldy damp buildings. It may be found on wet drywall, wall-paper, carpets, window frames, baseboards and plywood. The most widespread and common species is Chaetomium globosum. This species causes many problems of biodeterioration of paper and other cellulose containing material. It is considered a “weed” of mushroom beds, where it inhibits the growth of cultivated mushrooms.

Chaetomium as a contaminant of indoor air

Generally the concentration of airborne Chaetomium spores is very low. This is because the spores (= ascospores) are produced within flask-shaped bodies (= perithecia) and not exposed to air like those of moulds such as Penicillium and Aspergillus. When the spores mature, they are released inside the perithecium and then squeezed out in a column like toothpaste through an opening at the top of the perithecium. The coiled hairs trap the spores such that they are not easily dispersed into the air by wind.Chaetomium globosum spores

The other reason why the concentration of airborne Chaetomium spores is usually low is because the spores are relatively large and hence have relatively high settling rates and therefore do not remain airborne for long. As a result, airborne spore concentration of Chaetomium is usually low even in contaminated buildings. Due to low air concentration, exposure to airborne Chaetomium is insignificant except in situations where the mould has dried out and disturbed.

What does the presence of Chaetomium in a building tell us?
Chaetomium is one of those moulds that require chronic moisture conditions for it to grow. It’s presence is therefore an indication of existing or previous serious moisture problem. A few spores in pre-remediation air samples is an indication of a mould problem in the building. Because of the low airborne concentration, rarely is Chaetomium detected in outdoor samples. Hence any spores detected indoors are highly likely to have a source indoors and not outdoors. One can also sample house dust to determine whether Chaetomium is present or not.

Health Effects

Although Chaetomium species are rarely associated with human infections, there are reports of infections involving individuals with weak immune system. Chaetomium globosum is known to produce 2 toxins in moisture damaged buildings, chaetoglobosins A and C. These toxins have the potential to cause illness to building occupants.

For more information on Chaetomium species,please visit http://www.moldbacteria.com/learnmore/moldlist.html or call 905-290-101.

References

  1. Fogle, Matthew R (2007). Growth and mycotoxin production by Chaetomium globosum. PhD Dissertation, Texas Tech University Health Sciences Center.
  2. Udagawa S, Muroi T, Kurata H, Sekita S, Yoshihira K, Natori S: Chaetomium udagawe: a new producer of sterigmatocystin. Trans Mycol Soc Jap 1979, 20, 475-480.
  3. Domsch KH, Gams W, Anderson T-H: Compendium of Soil Fungi. Academic Press, London 1993.
  4. Arx JA von, Guarro J, Figueras MJ: The Ascomycete Genus Chaetomium. J. Cramer, Berlin 1986.
  5. Barron MA, Sutton DA , Veve R, Guarro J, Rinaldi M, Thompson E, Cagnoni PJ, Moultney K, and Madinger NE, Invasive Mycotic Infections Caused by Chaetomium perlucidum, a New Agent of Cerebral Phaeohyphomycosis. Journal of Clincal Microbiolgy, Nov. 2003, p. 5302–5307 Vol. 41, No. 11
  6. Piecková E: In vitro toxicity of indoor Chaetomium Kunze ex Fr. Ann Agric Environ Med 2003, 10, 9–14.

House Mold

House mold is not only unsightly but also a potential health hazard. People with allergies, asthma or other respiratory problems can have serious reactions to house mold spores. Also, molds produce digestive enzymes that help them utilize building materials as food. Therefore, apart from being a health hazard, house mold will also compromise the integrity of the materials it is growing on (see the picture on the right) such as wood, wallpaper, ceiling tiles, carpet, and baseboard.

White house mold growing from a basement ceiling
Photo courtesy of One Day Mold Removal

There are a number of factors that encourage house mold growth. By controlling these factors, we can subsequently control mold growth. The factors include: indoor humidity and moisture content of materials, temperature, air circulation, light, and the chemical composition of building materials. For an existing house we cannot change the chemical composition of building materials. Light and temperature would also not be practically possible to control in that we need light and warm temperatures in our houses. However, we can effectively control house mold by maintaining the levels of relative humidity indoors below 60% and also ensuring proper ventilation. Air circulation helps control moisture levels through evaporation.

What do you do if you see or suspect house mold growth?

If you see or suspect house mold growth do not panic. You may submit mold samples to a qualified mold laboratory to determine whether the mold present is hazardous or only a cosmetic concern. The MOLD TAPE SLIDE™ is a straightforward, inexpensive and effective method to sample visible mold found on any surface. From it you get information and guidance on what to do next. It is an easy way to determine if the mold is toxic and if it will require a professional to conduct more intensive investigation and remediation. Click MOLD TAPE SLIDE™ for details.

Peel off seal from slide to expose adhesive (see the words “Peel Here”)
Place sticky side of slide onto the surface with visible mold growth and press gently.

Place slide back into plastic snap-case.

 

If you can’t see mold growth but can smell “musty” or “earthy” odours you can also perform a preliminary air test (call 905-290-9101 for details) before calling in a professional.

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Legionella pneumophila – Guidelines for Laboratory Interpretation

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