Beata Gutarowska

Elaboration and application of mathematical model for estimation of mould contamination of some building materials based on ergosterol content determination

Abstract The study presents a mathematical function describing a correlation between the amount of ergosterol and the number of colony-forming units (CFU) of mould contaminating selected building materials such as: a block of cellular concrete, gypsum—carton board and gypsum—carton board covered with emulsion paint. The dependence obtained for a particular material as well as an average dependence for all the investigated materials has been described by means of an exponential equation. It has been found out that there is high, statistically significant correlation between ergosterol content and CFU number of mould in all of the building materials. The correlation coefficients have ranged from r=0.790 to 0.933. The elaborated equation describing the above dependence can be applied to estimate mould contamination by means of culture methods within the range 103–108 CFU/m2 of the surface. In addition, the estimated level of ergosterol in these materials has been shown to be the criterion by which to evaluate the degree of filamentous fungal contamination. It has been assessed that an ergosterol content exceeding the level of 3.96 mg/m 2 indicates the active development of mould. This criterion has been applied to evaluate several building materials i.e.: concrete, gypsum board, emulsion coatings, brick, plaster, wallpaper, glass wool, mineral wool and wood. No statistically significant differences have been observed between CFU number of mould calculated from a model equation on the basis of the ergosterol content and CFU number of mould experimentally determined by traditional methods. The results presented in this paper show that the elaborated equation of correlation between the ergosterol content and CFU number of mould can be applied to estimate mould contamination of different building materials, based on the determination of ergosterol.

Metabolomic and high-throughput sequencing analysis—modern approach for the assessment of biodeterioration of materials from historic buildings

Preservation of cultural heritage is of paramount importance worldwide. Microbial colonization of construction materials, such as wood, brick, mortar, and stone in historic buildings can lead to severe deterioration. The aim of the present study was to give modern insight into the phylogenetic diversity and activated metabolic pathways of microbial communities colonized historic objects located in the former Auschwitz II–Birkenau concentration and extermination camp in Oświecim, Poland. For this purpose we combined molecular, microscopic and chemical methods. Selected specimens were examined using Field Emission Scanning Electron Microscopy (FESEM), metabolomic analysis and high-throughput Illumina sequencing. FESEM imaging revealed the presence of complex microbial communities comprising diatoms, fungi and bacteria, mainly cyanobacteria and actinobacteria, on sample surfaces. Microbial diversity of brick specimens appeared higher than that of the wood and was dominated by algae and cyanobacteria, while wood was mainly colonized by fungi. DNA sequences documented the presence of 15 bacterial phyla representing 99 genera including Halomonas, Halorhodospira, Salinisphaera, Salinibacterium, Rubrobacter, Streptomyces, Arthrobacter and nine fungal classes represented by 113 genera including Cladosporium, Acremonium, Alternaria, Engyodontium, Penicillium, Rhizopus, and Aureobasidium. Most of the identified sequences were characteristic of organisms implicated in deterioration of wood and brick. Metabolomic data indicated the activation of numerous metabolic pathways, including those regulating the production of primary and secondary metabolites, for example, metabolites associated with the production of antibiotics, organic acids and deterioration of organic compounds. The study demonstrated that a combination of electron microscopy imaging with metabolomic and genomic techniques allows to link the phylogenetic information and metabolic profiles of microbial communities and to shed new light on biodeterioration processes.

The ability of filamentous fungi to produce acids on indoor building materials.

Sixty two filamentous fungi isolated from paint coatings, wallpaper, carton-gypsum board, and indoor air in buildings were screened for acid activity. It was found that 64.5% of strains produce acids on medium with bromo-cresol purple, where 18% of the strains were distinguished by very high acid activity (acid activity coefficient Q = 1.32–2.83), including the species:Aspergillus niger, Aspergillus versicolor, Penicillium expansum, Penicillium brevicom pactum, Penicillium chrysogenum, Cladosporium cladosporioides, Stachybotrys chartarum, Mucor globosus, Ulocladium chartarum andAlternaria alternata. Research indicated that filamentous fungi considerably decrease the pH of the medium when that medium containing building material. The greatest acid production and pH decrease of the medium was observed during the growth of filamentous fungi in a medium with mortar, while the production of acids was less in a medium with cartongypsum board, gypsum, and wallpaper. Filamentous fungi produced succinic, oxalic, malic and fumaric acids in the medium with indoor building materials. It was stated that the type of building material affects the spectrum and quantity of organic acids produced by filamentous fungi.

Effects of gamma radiation on the mechanical properties of and susceptibility to biodegradation of natural fibers

The effect of gamma radiation on the mechanical properties and surface structure of woven fabrics made of cotton, flax, and silk fibers was investigated. It was found that small radiation doses (up to 15 kGy), sufficient for effective disinfection of textiles, caused only insignificant changes in the fiber parameters tested. However, it was found that doses increased to 100 kGy bring about a considerable weakening of the tested fabrics——their tensile strength decreases by 26–33%. Microbiological examination has shown that preradiation of cotton and linen fabric samples with a dose of 100 kGy does not affect the susceptibility of these fabrics to fungal biodegradation. A silk fabric irradiated under the same conditions shows clear susceptibility to bacterial biodegradation.

A Study of the Toxicity of Moulds Isolated from Dwellings

An analysis of the toxicity of moulds isolated from 34 dwellings with mould-affected walls was performed. During the analysis 74 moulds strains were isolated, 17.5% of them were toxic. Detailed analysis by high performance liquid chromatography/tandem mass spectrometry of six toxic strains proved their ability to grow on building materials and produce mycotoxins. It was confirmed that the toxins stachybotrylactam, sterigmatocystin and roquefortin were produced on gypsum board and concrete by Stachybotrys chartarum, Aspergillus versicolor and Penicillium chrysogenum, respectively. This is also the first report on the production of aflatoxin B1 and G1 by A. flavus on building materials. Extracts from A. versicolor, A. flavus, P. chrysogenum growing on building materials were found to have cytotoxic potential. It was found that some mycotoxin production may be reduced or may even vanish, when moulds grow on building materials. However, taking into consideration the appreciable amounts of some mycotoxins that were still produced on the building materials investigated, the study indicated a toxic risk in the mould-affected buildings analysed.

Abiotic Determinants of the Historical Buildings Biodeterioration in the Former Auschwitz II – Birkenau Concentration and Extermination Camp

The paper presents the results of a study conducted at the Auschwitz-Birkenau State Museum in Oświęcim on the occurrence of biodeterioration. Visual assessment of the buildings revealed signs of deterioration of the buildings in the form of dampness, bulging and crumbling plaster, and wood fiber splitting. The external surfaces, and especially the concrete strips and ground immediately adjoining the buildings, were colonized by bryophytes, lichens, and algae. These organisms developed most intensively close to the ground on the northern sides of the buildings. Inside the buildings, molds and bacteria were not found to develop actively, while algae and wood-decaying fungi occurred locally. The factors conducive to biological corrosion in the studied buildings were excessive dampness of structural partitions close to the ground and a relative air humidity of above 70%, which was connected to ineffective moisture insulation. The influence of temperature was smaller, as it mostly affected the quantitative composition of the microorganisms and the qualitative composition of the algae. Also the impact of light was not very strong, but it was conducive to algae growth.

Microbial Degradation of Woven Fabrics and Protection Against Biodegradation

At the start of the 21st century annual world consumption of unwoven fabrics (for practical and technical uses) stood at 46 million tonnes, of which synthetics and cotton accounted for 49% and 42% respectively (with an upward trend in subsequent years), wool for 5%, and other fabrics 4% (linen, sisal, silk and others, with a downward trend) (Central Statistical Office Yearbooks – Roczniki GUS, Poland 2008). If 2% of the global value of fibre production is assumed, the problem of microbiological decomposition may affect 920 000 tonnes of fabric annually.

New Filtering Antimicrobial Nonwovens With Various Carriers for Biocides as Respiratory Protective Materials Against Bioaerosol

Abstract This study evaluated the bioactivity of polypropylene melt-blown filtering nonwovens used in respiratory protective devices (RPD) with a biocidal agent (alkylammonium microbiocides) on 2 mineral carriers. Two types of carriers were tested: a bentonite, with an aluminosilicate base, and a perlite, volcanic glass. High biostatic and biocidal effects of modified nonwovens with biocides were tested against Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus) bacteria. Nonwovens modified with a biocide on a bentonite carrier showed an opposite reaction to a biocide on a perlite. The research also showed that 10% concentration of a biocidal agent on a perlite carrier was sufficient to inhibit the growth of bacteria (100% reduction) placed in the structure of a filtering material during normal use of RPD. A comparison of the biological activity of 2 filtering materials, each containing 10% of a perlite and produced in a laboratory and industrial conditions, showed no statistically significant differences.

An airborne actinobacteria Nocardiopsis alba isolated from bioaerosol of a mushroom compost facility

Actinobacteria are widely distributed in many environments and represent the most important trigger to the occupant respiratory health. Health complaints, including hypersensitivity pneumonitis of the workers, were recorded in a mushroom compost facility (MCF). The studies on the airborne bacteria were carried out to find a possible microbiological source of these symptoms. Culture analysis of compost bioaerosols collected in different location of the MCF was performed. An assessment of the indoor microbial exposure revealed bacterial flora of bioaerosol in the mushroom compost facility represented by Bacillus, Geobacillus, Micrococcus, Pseudomonas, Staphylococcus spp., and actinobacterial strain with white aerial mycelium. The thermotolerant actinobacterial strain of the same morphology was repeatedly isolated from many locations in MCF: air, compost sample, and solid surface in production hall. On the base of complex morphological, chemotaxonomic, and phylogenetic characteristics, the isolate has been classified as Nocardiopsis alba. Dominant position of N. alba in microbial environment of the mushroom compost facility may represent an indicator microorganism in compost bioaerosol. The bioavailability of N. alba in mushroom compost facility creates potential risk for the health of workers, and the protection of respiratory tract and/or skin is strongly recommended.

Aspects of tests and assessment of filtering materials used for respiratory protection against bioaerosols. Part II: sweat in the environment, microorganisms in the form of a bioaerosol.

The second part of the article presents the results of a study of antimicrobial activity of filter nonwovens with an addition of biocides, as a function of the presence of sweat in the environment and the method of microbe deposition on a nonwoven in the form of a liquid and a bioaerosol. At the same time, the filtration efficiency of nonwovens against microorganisms in the form of a bioaerosol was tested with the dynamic method. The results showed that the addition of sweat on the surface of a nonwoven resulted in an insignificant decrease of biological activity that still remained high. Moreover, an active nonwoven showed biostatic and biocidal activity only when microbes were deposited on the surface in the form of a solution. The nonwoven did not show any biological activity after deposition of microorganisms with the dynamical method in the form of a bioaerosol.