sampling - Mold Bacteria Consulting Services

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

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).
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.

A Mold Training Course With A Difference

Jackson Kung'u

The MBL mold training course was first offered on July 5, 2005. Readers of our newsletter suggested that we provide some training based on the topics we used to discuss in our newsletters. That is how this course was born. Since then we have offered the course at least once every month!

Mold training course manual and CD The mold training course started as a half-day course covering topics such as:

How to recognize indoor mould. This section of the course was initially designed for beginners but even experienced professionals have found it useful. Sometimes, one can’t tell for sure whether they are dealing with mold or not.
How to develop effective sampling strategies. Whether to sample for mold or not (like many other issues involving mold) is controversial. However, there are instances where sampling can’t be avoided. Collection of the right kind of samples and at the right place can make results interpretation easier.
How to interpret laboratory results. With no standards on permissible exposure levels, opinions on lab results can significantly differ. An understanding of the key limitations of lab results and the principles applied on results interpretation is essential.

A number of participants suggested that we increase the course content to make it a one-day course. We added more material to the original sections and also added a section on mold control.

The mold training course is currently offered by MBL in association with leaders in the industry. It is has been approved by a number of reputable organization for continuous education. These organizations include:

American Board of Industrial Hygiene (ABIH)
Canadian Registration Board of Occupational Hygienists (CRBOH)
The Institute of Inspection, Cleaning and Restoration Certification (IICRC)
The National Association of Certified Home Inspectors (NACHI) and
The Registered Insurance Brokers of Ontario (RIBO).

For more details about the course click http://www.moldbacteria.com/training.html

Book today using the booking calendar below.

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Taking Air Samples For Mold Testing: Settle Plate Method

Jackson Kung'u

A number of methods can be used to test air for mold or other microbial contamination. One of the oldest methods of testing air for microbial contamination is the settle plates method. Though the method is semi-quantitative, it is still considered a useful method. In industries such as food, pharmaceutical and cosmetics the method is used to assess the likely number of microorganisms depositing onto the product or surface in a given time. The method involves opening and exposing petri dishes containing agar medium suitable for growth of microorganisms of interest. If one is interested in testing for mold, agar plates containing malt extract agar (MEA) supplemented with some antibiotics to suppress bacterial growth would be used. The agar plates are left open at table-top level at selected points in the room for half-hour to 4 hours. This allows mold spores and fragments to settle onto agar media by gravity. Mold test kits (involving growth media) are settle plates.

Settle Plates Results

The number of microorganisms deposited onto the agar surface of the plate over the period of exposure is determined by incubation of the agar plates at 25ºC for 5- 7 days and counting colonies that develop. The results can be expressed as number of colony forming units (CFUs) per unit time. The counted colonies can then be further characterised to genera or species. Higher numbers of CFUs and/or presence of potential pathogenic or toxigenic molds such Aspergillus fumigatus and Stachybotyrs chartarum are indicators of a problem.

Disadvantages of Settle Plates

Settle plate method is an extremely useful method for assessing air contamination by microorganisms. It is easy to conduct and very cost effective. However, only viable microorganisms would be detected by this method and hence it may give a false impression that the air is “clean” if most of the airborne microorgainisms are dead. False negatives may also be obtained from buildings with:

very restricted mold growths.
very still air in undisturbed rooms.
species of poorly culturable molds (e.g., Stachybotrys chartarum).
molds consisting of species with poor airborne dissemination (e.g., Aureobasidium on windowsills, Cladosporium on painted cold air vents, Fusarium and many other wet-spored fungi).

Salmonella food poisoning and symptoms

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Legionella pneumophila – Guidelines for Laboratory Interpretation

Legionella pneumophila is a Gram negative, aerobic bacteria that is characterized as an opportunistic pathogen. It is the cause of Legionnaires’ Disease, a severe form of pneumonia and, it is the cause of Pontiac fever, a non-pneumonic form of L. pneumophila infection. Legionella spp.’s mode of transmission is through aerosols or aspiration of contaminated water. The Public Health […]