Children's residential exposure to selected allergens and microbial indicators: endotoxins and (1→3)-ß-D-glucans.

OBJECTIVES: The study was aimed at assessment of exposure to endotoxins, (1→3)-ß-D-glucans and mite, cockroach, cat, dog allergens present in settled dust in premises of children as agents which may be significantly correlated with the occurrence of allergic symptoms and diseases in children. MATERIALS AND METHODS: The study covered 50 homes of one-or two-year-old children in Poland. Samples of settled dust were taken from the floor and the child's bed. The levels of (1→3)-ß-D-glucans (floor), endotoxins (floor) and allergens of mite, cat, dog and cockroach (floor and bed) were analyzed. RESULTS: Average geometric concentrations (geometric standard deviation) of endotoxins, (1→3)-ß-D-glucans, Der p1, Fel d1, Can f1 and Bla g1 in children homes were on the floor 42 166.0 EU/g (3.2), 20 478.4 ng/g (2.38), 93.9 ng/g (6.58), 119.8 ng/g (13.0), 288.9 ng/g (3.4), 0.72 U/g (4.4) and in their beds (only allergens) 597.8 ng/g (14.2), 54.1 ng/g (4.4), 158.6 ng/g (3.1) 0.6 U/g (2.9), respectively. When the floor was covered with the carpet, higher concentrations of endotoxins, (1→3)-ß-D-glucans and allergens (each type) were found in the settled dust (p < 0.05). The trend was opposite in case of allergens (except dog) analyzed from bed dust and significantly higher concentrations were found in the rooms with smooth floor (p < 0.05). CONCLUSIONS: Among the analyzed factors only the type of floor significantly modified both the level of biological indicators and allergens. The results of this study could be the base for verifying a hypothesis that carpeting may have a protective role against high levels of cockroach, dog and cat allergens.

Factors influencing biosafety level and LAI among the staff of medical laboratories.

BACKGROUND: The aim of the study was to assess the biological risks of medical laboratory employees with particular focus on laboratory acquired infection (LAI), activities having the greatest risk, accidents with biological material, post exposure procedure, preventive measures and workers' knowledge about biological exposure. MATERIALS AND METHODS: The study involved 9 laboratories. A questionnaire survey was attended by 123 employees and 9 heads of these units with the use of two questionnaires for laboratory workers and the managers. RESULTS: 32.5% of the respondents (40 persons) had an accident at least once. Needlestick or a broken glass injury covered 18.7% respondents (23 persons), while splashing the skin, mucous membranes or conjunctivae related to 22.8% (28 persons). Among the employees who had an accident, only 45% of the respondents (18 persons) reported this to the manager. Microbes dominant in the biological material were known only to 57 respondents (46.3%), less than half could correctly give an example of a disease (57 persons, 46.3%). More than half of the respondents admitted that they do not know all of the possible routes of infection while working in the laboratory (68 persons, 55.3%). CONCLUSIONS: In the study population, a high incidence of accidents was observed, usually during blood sampling and transfer of biological material. Condition of the workers' equipment with personal protective measures and laboratory facilities in devices to reduce the risk of infection and procedures for handling the potentially infectious material should be considered as insufficient. Lack of basic knowledge of the employees about biohazards at workplaces was shown.

[Biological contamination in office buildings related to ventilation/air conditioning system]. / Czynniki biologiczne wplywajace na jakosc powietrza w pomieszczeniach biurowych.

BACKGROUND: Indoor air is contaminated with microorganisms coming from both the atmospheric air and sources present in premises. The aim of this study was to analyze the concentrations of biological agents in office buildings, dependending on ventilation/air conditioning system and season. MATERIALS AND METHODS: The study covered office buildings (different in the system of ventila-tion/air conditioning). Air samples for assessing the levels of inhalable dust, endotoxins and (1-->3)-beta-D-glucans, were taken at the selected stationary points of each building during summer and winter. The air was sampled for 6 h, using portable sets consisting of the GilAir 5 pump and the head filled with a filter of fiber glass. The samples for the presence of airborne bacteria and fungi were collected twice during the day using the impaction method. RESULTS: Average concentrations of inhalable dust, bacteria, fungi, endotoxins and (1-->3)-beta-D-glucans in office premises were 0.09 mg/m3, 6.00 x 10(2) cfu/m3, 4.59 x 10(1) cfu/m3, 0.42 ng/m3 and 3.91 ng/m3, respectively. Higher concentrations of the investigated agents were found in summer. In premises with air conditioning concentrations of airborne fungi, (1-->3)-beta-D-glucans and inhalable dust were significantly lower in winter. In summer the trend was reverse except for (1-->3)-beta-D-glucans. CONCLUSIONS: Concentrations of biological agents were affected by the season and the presence of air conditioning. Concentrations of inhalable dust, bacteria, fungi, endotoxins and (1-->3)-beta-D-glucans, observed inside the office buildings, were significantly higher in summer than in winter. The presence of the air conditioning system modified in various ways the levels of biological agents. Its influence was greater on the concentration of fungi and (1-->3)-beta-D-glucans than on that of bacteria and endotoxins.

Fungal aerosol in the process of poultry breeding--quantitative and qualitative analysis.

BACKGROUND: The aim of this study was to assess fungal air contamination in the processes associated with poultry breeding depending on the season. The evaluation was based on the determined concentrations of fungi and qualitative identification of isolated microorganisms. MATERIALS AND METHODS: The study covered 2 hatcheries and 3 hen buildings. The air was sampled in spring, summer and autumn directly onto a filter using air aspirator. For the quantitative analysis of fungi, the medium MEA with chloramphenicol and streptomycin was used. The qualitative identification of fungi was carried out based on macro- and microscopic analysis. RESULTS: The concentrations of total airborne mesophilic fungi in breeding facilities ranged from 1.22 x 10(3) to 5.87 x 10(5) cfu/m3 with the arithmetic mean value 1.60 x 10(5) cfu/m5. In 45% of the taken samples, these levels exceeded the reference value recommended in Poland for occupational environment exposure. The fungi concentration in the air of poultry houses was significantly modified by season (p = 0.04). A higher concentration of fungi occurred in autumn (p = 0.05). The dominant fungal microflora in the air was composed of molds (88%), with the most prevalent genus Acremonium. Yeasts constituted another 10% of bioaerosol and were mainly represented by genus Candida. The fungal aerosol contained two species qualified to the 2 group of risk--Aspergillus fumigatus and Candida tropicalis. CONCLUSIONS: Facilities of poultry farms are contaminated with high concentrations of fungal aerosols, especially in a colder season, often exceeding the recommended limits. Among the fungi, there are also present pathogenic microorganisms that may pose a risk to farm workers' health.

The variability of bacterial aerosol in poultry houses depending on selected factors.

OBJECTIVES: This study is aimed at evaluation of bacterial air contamination in intensive poultry breeding. The evaluation was based on the determined levels of bacterial concentrations and qualitative identification of isolated microorganisms. MATERIALS AND METHODS: The study covered 5 poultry houses: two hatcheries and three hen houses with the litter bed system. The air was sampled in three measurement series in the central part of the investigated workplace at the height of about 1.5 m over the ground, using portable measuring sets consisting of a GilAir 5 (Sensidyne, USA) pump and a measuring head filled with a glass microfibre filter (Whatman, UK). For the quantitative and qualitative analysis of microorganisms were used appropriate microbiological media. RESULTS: The total concentrations of airborne mesophilic bacteria inside the poultry breeding houses ranged from 4.74 × 10(4) cfu/m(3) to 1.89 × 10(8) cfu/m(3). For Gram-negative bacteria, the range comprised the values from 4.33 × 10(2) cfu/m(3) to 4.29 × 10(6) cfu/m(3). The concentrations of the cocci of Enterococcus genus ranged from 1.53 × 10(4) cfu/m(3) to 1.09 × 10(7) cfu/m(3), whereas those of other Gram-positive bacteria from 3.78 × 10(4) cfu/m(3) to 6.65 × 10(7) cfu/m(3). The lowest concentrations of each group of the examined microorganisms were noted in the second measurement series when the air exchange in the breeding houses was over twice higher than in first and third measurement series because the mechanical ventilation was supported by natural ventilation (opened gates in the buildings). The lowest concentrations of total bacteria were obtained in those buildings where one-day old chickens were kept. Gram-positive bacteria of the genera: Staphylococcus, Enterococcus, Corynebacterium, Brevibacterium, Micrococcus, Cellulomonas, Bacillus, Aerococcus, and Gram-negative bacteria of the genera: Pseudomonas, Moraxella, Escherichia, Enterobacter, Klebsiella, Pasteurella, Pantoea were isolated. It was shown that for most of the investigated livestock premises the total bacteria concentrations exceeded the reference value of 1.0 × 10(5) cfu/m(3). Furthermore, pathogenic microorganisms which are a potential threat to human health (Escherichia coli, Enterobacter cloacae, Klebsiella pneumoniae ssp. ozaenae, Enterococcus faecalis, Enterococcus faecium) were found among the identified bacteria. CONCLUSIONS: The results indicate that the hygienic conditions of the working environment connected with litter bed system production of poultry are affected by changes of the efficiency of ventilation and create a direct health risk to employees. They should use personal protective measures to protect their respiratory tract, especially when the gates in the hen houses are closed.

[Exposure to bioaerosols among CAFO workers (swine feeding)]. / Ocena narazenia na bioaerozole pracowników zatrudnionych przy intensywnej hodowli trzody chlewnej.

BACKGROUND: In this paper the exposure assessment to airborne biohazards (organic dust, microorganisms, endotoxins and ((1 --> 3)-beta-D-glucans) as well as to ammonia and hydrogen sulfide among CAFO (swine farms) workers is presented. MATERIALS AND METHODS: Occupational exposure assessment was carried out on 30 swine farms. Personal dosimetry was carried out among 90 swine farm workers to assess the exposure to organic dust, endotoxins and glucans. Concentrations of ammonia and hydrogen sulfide were measured using Draeger pipes. Endotoxins were assayed with the LAL test in a kinetic, chromogenic version and ((1 --> 3)-beta-D-glucans with the Glucatell test in a kinetic version. RESULTS: Concentrations of inhalable dust ranged from 0.16 to 37.2 mg/m3, with AM = 3.65 mg/m3, whereas AM for respirable fraction was 0.39 mg/m3 with the range from zero to 4.28 mg/m3. Mean concentration of culturable bacteria was 4.79 x 10 (5) jtk/m3, and fungi concentration was ten times lower - 1.55 x 10(4) jtk/m3. Exposure to endotoxins with high degree of differentiation ranged from 95 to 147 885 EU/m3 in inhalable and from 5.5 to 18 708 EU/m3 in respirable fractions. Glucan concentrations ranged from 6 to > 5200 ng/m3 in unhalable and from 1 to 800 ng/m3 in respirable fraction. Ammonia concentrations in the workplace air ranged from 1.78 mg/m3 (2.50 ppm) to 30.1 mg/m3 (42.4 ppm). Hydrogen sulfide did not exceed the level of 4.1 mg/m3. CONCLUSION: Work conditions found in CAFOs may induce adverse effects on workers' respiratory system and should be considered as an important harmful agent. The protection of workers respiratory airways should be recommended.