The atlas compiled by these editors is a commendable effort and welcome addition to the mycology textbook sector. Up until now, the publication of medical mycology textbooks has been sparse and those that have been published are either too detailed for a resident in training or practicing physician or do not provide sufficient photographs or illustrations of the main features of the mycotic organisms. As a lecturer in mycology for the dermatology residents at my local teaching hospital and program, there are 3 key objectives of my mycology lectures: (1) to provide some type of organizational approach to mycotic organisms, (2) to provide a concise clinical history, and (3) to provide as many photographs and illustrations of mycotic organisms as possible. This atlas provides an exemplary addition to my book collection on medical mycology textbooks and sources for illustrations of mycotic organisms. The electron photomicrographs, photoplates, and line drawings of

Atlas of Clinical Fungi

 Bacteria are ubiquitous in the atmosphere, with concentrations of bacterial cells typically exceeding 1×104 m−3 over land Numerous studies have suggested that the presence of bacteria in the atmosphere may impact cloud development, atmospheric chemistry, and microbial biogeography A sound knowledge of bacterial concentrations and distributions in the atmosphere is needed to evaluate these claims This review focusses on published measurements of total and culturable bacteria concentrations in the atmospheric aerosol We discuss emission mechanisms and the impacts of meteorological conditions and measurement techniques on measured bacteria concentrations Based on the literature reviewed, we suggest representative values and ranges for the mean concentration in the near-surface air of nine natural ecosystems and three human-influenced land types We discuss the gaps in current knowledge of bacterial concentrations in air, including the lack of reliable, long-term measurements of the total microbial concentrations in many regions and the scarcity of emission flux measurements

/pdf/bacteria-in-the-global-atmosphere-part-1-review-and-2japsgbxzp.pdf

Bacteria in the global atmosphere – Part 1: Review and synthesis of literature data for different ecosystems

Damp indoor spaces and health , Damp indoor spaces and health , کتابخانه دیجیتال جندی شاپور اهواز

Damp Indoor Spaces and Health

Bacterial and fungal aerosol in indoor environment in Upper Silesia, Poland

Studies of indoor bioaerosols conducted in Central and Eastern European countries, as a result of the scarcity of funding, mostly do not attain the level presented by similar studies in Northern America and Western Europe. For socio-economic reasons, most of the intense studies on indoor bioaerosols in Central and Eastern European countries were carried out in industrial facilities and have contributed significantly to occupational health science. In contrast, until recently, insufficient of studies have been conducted on bioaerosols of residential and communal premises (dwellings, offices, schools, etc.) and no network for monitoring the microbiological quality of air in such premises exists. In Poland, in the mid-1990s complex bioaerosol investigations were carried out by the Bioaerosol Group at the Institute of Occupational Medicine and Environmental Health in Sosnowiec. The concentrations of airborne bacteria and fungi in dwellings without mold problems were between 88-4297 cfu/m(3) and 0-1997 cfu/m(3), while in moldy homes they were 178-4751 cfu/m(3) and 49-16,968 cfu/m(3), respectively. As many as 167 microbial species were isolated from the air of examined dwellings. Most frequently occurred Gram-positive cocci (Micrococcus/ Kocuria spp., Staphylococcus spp.), endospore-forming bacilli (Bacillus spp.), Gram-negative bacteria (Pseudomonadaceae, Aeromonas spp.), filamentous fungi (Penicillium spp., Aspergillus spp.), and yeasts. Notable studies of indoor bioaerosols have also been performed in the other Central and Eastern European countries: Lithuania, Latvia, Estonia, Russian Federation, Ukraine, Czech Republic, Slovakia, Bulgaria and Hungary, are reviewed in this article. The lack of reference limit values for bioaerosols seriously hinders interpretation of results obtained in various countries. The following residential limit values (RLV) for dwellings and communal premises are proposed for the concentration of airborne bacteria, fungi and bacterial endotoxin: 5 x 10(3) cfu/m(3), 5 x 10(3) cfu/m(3) and 5 ng/m(3) (50 EU), respectively. The proposed values of occupational exposure limit (OEL) for industrial settings contaminated by organic dust are 100 x (3) cfu/m(3), 50 x (3) cfu/m(3) and 200 ng/m(3) (2000 EU), respectively. It is also proposed that the presence in indoor air of microorganisms from risk groups 3 and 4 of European Community Directive 2000/54/EC (e.g., Mycobacterium tuberculosis, Bacillus anthracis, Coxiella burnetii), independently of the concentration, should always be inadmissible and result in preventive actions.

http://www.aaem.pl/pdf-72765-25372?filename=Bacterial and fungal.pdf

Bacterial and fungal aerosols in indoor environment in Central and Eastern European countries.

The purpose of this study was to evaluate the influence of two municipal landfills on the microbiological air quality in offices on landfill sites. The evaluation was based on the concentration levels of airborne bacteria and fungi and the identification of isolated strains. Air samples were collected with a six-stage Andersen impactor. The concentrations of bacterial aerosol ranged from 1.0 × 103 to 7.2 × 104 colony forming units (CFU)/m3 indoors, and from 7.0 × 10 to 4.0 × 104 CFU/m3 outdoors. The corresponding fungal aerosol ranges were from 2.3 × 102 to 7.3 × 103 CFU/m3 indoors and from 2.0 × 102 to 1.2 × 104 CFU/m3 outdoors. The concentration levels were affected by the season of the year. The study showed that both indoor and outdoor air were heavily contaminated with bacteria and fungi. The proximity of the unpaved transport route and the weighing of refuse loads contributed to the increase of bacterial and fungal aerosol concentrations significantly. The air in the offices was characterized not on...

Microbial Air Quality in Offices at Municipal Landfills

Biodeterioration of heritage collections caused by microorganisms is a worldwide problem. To avoid degradation caused by biological contaminants transported into the indoor environment by air, proper bioaerosol protection is required. The aim of this study was to assess the level of microbial contamination of the Auschwitz-Birkenau Museum collection based on qualitative and quantitative analyses of bacteria and fungi isolated from the atmosphere and settled dust of museum storerooms. The obtained results demonstrated that a correctly operated air-conditioning system and limiting the number of visitors in the studied storerooms can significantly inhibit microbial contamination of the air and decrease deposition of bacterial and fungal particulates on exhibit surfaces. The performed analyses confirm that an aerobiological assessment of museum premises is a useful tool in their hygienic evaluation and, if necessary, in decision-making regarding interventions to minimize biological decay of collections.

Microbial contamination of storerooms at the Auschwitz-Birkenau Museum

The aim of this study was to characterize the microbial contamination of the air in farmhouses (defined as residential buildings on farms) on the basis of volumetric (using a six-stage Andersen impactor) measurements of bacterial and fungal aerosols. The microbial air quality (including both the total concentration of bioaerosols and their respirable fractions) in farmhouses was collated with the bacterial and fungal air contamination in urban dwellings. In comparison with the urban dwellings, the air in the farmhouses was characterized by significantly higher concentrations of culturable bacteria and fungi. However, respirable microorganisms in the farmhouses constituted the smaller fraction of all culturable bacteria and fungi. The results indicate that the microbial air quality in the farmhouses was most likely affected by the presence of farm buildings, which acted as additional bioaerosol emission sources. The smaller respirable bioaerosol fraction observed in the farmhouses could be explained by the indirect transfer of bacteria and fungi on workers' clothing and bodies from farm buildings to the habitable environments.

https://onlinelibrary.wiley.com/doi/pdf/10.1002/clen.200800003

Microbial Air Contamination in Farmhouses – Quantitative Aspects

The effects of microwave radiation on viability of fungal and actinomycetal spores growing on agar (medium optimal for growth) as well as on wooden panel and drywall (common building construction/finishing materials) were studied. All materials were incubated at high (97-99%) and low (32-33%) relative humidity to mimic "wet" and "dry" environmental conditions. Two microwave power densities (10 and 60 mW/cm2) and three times of exposure (5, 30, and 60 min) were tested to find the most effective parameters of radiation which could be applied to non-invasive reduction or cleaning of building materials from microbial contaminants. Additionally, a control of the surface temperature during the experiments allowed differentiation between thermal and microwave effect of such radiation. The results showed that the viability of studied microorganisms differed depending on their strains, growth conditions, power density of microwave radiation, time of exposure, and varied according to the applied combination of the two latter elements. The effect of radiation resulting in a decrease of spore viability on "wet" wooden panel and drywall was generally observed at 60 min exposure. Shorter exposure times decreased the viability of fungal spores only, while in actinomycetes colonizing the studied building materials, such radiation caused an opposite (supporting growth) effect.

/pdf/viability-of-fungal-and-actinomycetal-spores-after-microwave-43vi98c2aq.pdf

Danuta O. Lis

Papers

Bacterial and fungal aerosol in indoor environment in Upper Silesia, Poland

Microbial Air Quality in Offices at Municipal Landfills

Microbial contamination of storerooms at the Auschwitz-Birkenau Museum

Microbial Air Contamination in Farmhouses – Quantitative Aspects

Viability of fungal and actinomycetal spores after microwave radiation of building materials.