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Article

The Dynamics of Mycobiota Development in Various Types of Wood Dust Depending on the Dust Storage Conditions

by
Marta Pędzik
1,
Anna Przybylska-Balcerek
2,*,
Lidia Szwajkowska-Michałek
2,
Tomasz Szablewski
3,
Tomasz Rogoziński
4,
Maciej Buśko
2 and
Kinga Stuper-Szablewska
2
1
Łukasiewicz Research Network—Wood Technology Institute, Winiarska St. 1, 60-654 Poznan, Poland
2
Department of Chemistry, Faculty of Forestry and Wood Technology, Poznan University of Life Sciences, ul. Wojska Polskiego 75, 60-625 Poznan, Poland
3
Department of Menegment of Food Quality and Safety, Poznan University of Life Sciences, 60-637 Poznan, Poland
4
Department of Furniture Design, Faculty of Forestry and Wood Technology, Poznan University of Life Sciences, Wojska Polskiego St. 38/42, 60-627 Poznan, Poland
*
Author to whom correspondence should be addressed.
Forests 2021, 12(12), 1786; https://doi.org/10.3390/f12121786
Submission received: 29 November 2021 / Revised: 10 December 2021 / Accepted: 13 December 2021 / Published: 16 December 2021
(This article belongs to the Special Issue Advanced Technologies in Improving the Design Life and Durability of Timber)
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Versions Notes

Abstract

:
Solid or processed wood, and wood waste in particular (dust, shavings, etc.) are the source of a number of health hazards for workers in the wood industry. One of the many negative health effects of exposure to fungi is allergic diseases caused by hypersensitivity reactions. The aim of this study was to investigate the effect of wood species and the degree of dust fragmentation, resulting from processing conditions and storage conditions on the level of wood dust contamination with microscopic fungi during 1 year of storage. An additional aspect of the research was the assessment of the influence of the antioxidant wood bioactive compounds on the development of A. alternata microscopic fungi. It was found that the conditions in which wood dust is stored significantly affect the development of microscopic fungi, especially fungi of the genus Alternaria. The results indicate that temperature is the determining factor, not the relative humidity of the air. The degree of dust fragmentation resulting from the sanding paper grit also has a significant impact on the development of microscopic fungi. Finer dust is more susceptible to the development of microscopic fungi. The antioxidant activity of the wood from which the dust was formed was found to have a significant impact on the development of microscopic fungi. An inverse relationship was observed, indicating the strong activity of antimicrobial substances. Gaining comprehensive knowledge of how all factors affect each other is a key step in understanding the risk and implementing measures to prevent and protect the work environment.

1. Introduction

Alternaria alternata (Fr.) Keissl. is a fungus species belonging to the phylum Ascomycota, in the class Dothideomycetes. They are ubiquitous organisms that can develop on various surfaces. The optimal conditions for their development are high humidity and temperature. The development of the thallus and the release of spores lead to colonization of the surface. The consequence of this is the presence of both spores and fragments of hyphae in the air surrounding the affected surfaces. These components of mushroom biomass are part of dust [1,2].
Hypersensitivity is a pathological and qualitatively altered tissue reaction caused by repeated exposure to antigens. It consists of the development of an immune reaction related to the formation of specific antibodies or sensitized lymphocytes. As a result, there may be a very strong response of both the cellular and humoral type, and in extreme cases even the destruction of one’s own cells. One of the many negative health effects of exposure to fungi is allergic diseases caused by hypersensitivity reactions. Fungal spores are among the most abundantly represented biological particles in the atmospheric air. They are much more numerous than the pollen grains of other environmental allergens. Due to their small size, the spores enter the respiratory tract with the inhaled air [3,4]. The diagnosis of allergies and fungal diseases is difficult due to the clinical picture of the disease. In addition, most patients are hypersensitive to several species of these pathogens, which may be due to both independent allergies to more than one allergen, and the presence of cross-allergies [5,6,7]. An important feature of hypersensitivity to allergens in the form of particles of fungal biomass is the variability of the biochemical and allergenic properties of fungi from different populations, even within species, which is related to their unlimited adaptability to environmental conditions [8,9,10,11].
Solid or processed wood, and wood waste in particular (dust, shavings, etc.), are the source of a number of health hazards for workers in the wood industry. The number of workers exposed to wood dust in contemporary Poland was estimated at approximately 310,000 for the years 2000–2003; 79,000 workers were exposed to an LO concentration of 5 mg/m3, 52,000 to a concentration of 0.5–1 mg/m3, 63,000 to a concentration of 1–2 mg/m3, 72,000 to a concentration of 2–5 mg/m3 and approximately 44,000 to a concentration above 5 mg/m3 [12,13,14,15,16,17,18].
Sanding, sawing, milling and drilling wood materials are among the most dust-generating processes in the wood industry. The automation of processing is particularly related to the high emission of dust pollutants. The most disadvantageous is the use of machines with high rotational speed [17,18,19,20,21]. The greater the speed of the tool during machining, the greater the generation of heat in the tool [22]. The thermal properties may vary not only depending on the modification method, but also the material’s density and thickness [23]. There are visible differences between the density of modified and native beech wood. Higher density provides better thermal conductivity, which is especially important when using these raw materials for flooring, but undesirable in industrial processing [16,18,24]. In turn, thermal modification may contribute to the formation of a greater number of fine fractions, depending on the type of processing (e.g., during milling) [13,25,26]. The exposure of workers to dust from deciduous trees (hardwood) or in mixture with conifers (softwood) is correlated with the occurrence of occupational diseases. An additional factor increasing the undesirable effect of dust is the presence of organic particles—mainly microscopic fungi, and to a lesser extent bacteria [27,28]. Taking into account the health effects and the socio-economic conditions presented by the European Commission, the NDS (maximum permissible concentration) was changed from 3 mg/m3 to 2 mg/m3 for the respirable dust fraction. Wood dusts are carcinogenic, mutagenic and dust-generating (according to Directive 2017/2398/EC) [28]. Numerous scientific studies prove the high danger posed by long-term contact with wood dust. Most of this research, however, focuses on fire hazards and the effects of temperatures that can ignite a dust mixture both in the air and on utility surfaces. Another significant risk factor is the temperature increase caused by the work of tools that are in direct contact with chips and dust, which can lead to ignition. Another issue is that long-term exposure to dust and dust in humid conditions degrades wood materials, resulting in discoloration and an unfavorable change in the color of wood and wood-based materials [28,29,30,31].
Another group of studies is devoted to the analysis of the quantity and size of dust particles formed during processing, which are respirable fractions (i.e., the most hazardous to health) [30,31]. The dust of all tree species have been classified as carcinogenic to humans (Group 1) by the International Agency for Research on Cancer (IARC) (IARC, 2012) [30]. Such activities lead to the extension of research in the understanding and comprehensive assessment of the harmfulness of dusts of individual tree species subjected to mechanical treatment. In addition, growing microorganisms pose an additional health risk. Therefore, it becomes important to examine the effect of the variable content of bioactive compounds contained in individual wood species. Comprehensive knowledge and understanding of the risk is a key step in introducing risk prevention and protection measures in the work environment [31,32]. The basis of this research is the risk related to the occurrence of dust and the possibility of the development of microscopic fungi in the dust deposited in workplaces.
The aim of this study was to investigate the effect of wood species and the degree of dust fragmentation resulting from processing conditions and storage conditions on the level of wood dust contamination with microscopic fungi during 1 year of storage. An additional aspect of the research was the assessment of the influence of the antioxidant wood bioactive compounds on the development of A. alternata microscopic fungi.

2. Materials and Methods

2.1. Preparation of Dust

Six hardwood species (black alder, European ash, common walnut, pedunculate oak, hornbeam, European beech) and three softwood species (larch, pine, and spruce) were studied. The wood was kiln-dried to 8% ± 1% moisture content, then specimens with a sanded surface of 150 mm × 80 mm were prepared.
Sanding was performed using a prototype narrow-belt sanding machine designed and made in the laboratory of the Department of Furniture Design (Faculty of Wood Technology, Poznań University of Life Sciences (PULS)). EKA 1000 F (Ekamant, Poznan, Poland) sanding paper in the form of belts with dimensions 1000 mm × 80 mm was used. The grits of the paper were P60 and P180. A sanding belt speed of 14.5 m.s−1 and a sanding pressure of 0.65 N.cm−2 were applied. The dust created during sanding was collected using a multi-purpose vacuum cleaner of the type NT 30/1 Tact (Alfred Kärcher SE & Co. KG, Winnenden, Germany) connected to the working zone. The sanding process has already been described in the literature [33].

2.2. Preparation of the Inoculum of Microscopic Fungi

A yeast extract-sucrose (YES) agar medium was used in this study. Alterneria alternata isolates were incubated on the agar medium for approximately 4 weeks. The contents of the plates were washed with saline to obtain a spore suspension. The concentration of the spore suspensions of the individual isolates was adjusted to approximately 5 × 105 spores/mL using the hematocrit. The suspensions were mixed in equal proportions. The dust material was brought to a constant weight by drying at 40 °C. Then it was sprayed with a spore suspension in the amount of about 10 mL of suspension per 100 g of dust.

2.3. Dust Storage Conditions

The inoculated dust samples were stored for 1 year in controlled temperature and relative humidity chambers. The combinations of air relative humidity and temperature presented in Table 1 were selected for the experiment. The dust storage conditions were selected on the basis of the optimal growth parameters of microscopic fungi of the genus Alternaria: 20 °C and 90% air relative humidity. In order to determine which factor (humidity or temperature) influences the growth of mycobiota, several variants (also unfavorable for the development of microscopic fungi) were examined, as presented in Table 1 [34].

2.4. Ergosterol Analysis

Samples were analyzed for the presence of ergosterol (ERG) according to Stuper-Szablewska et al. (2017) [33]. Briefly, samples of 100 mg were placed into culture tubes, suspended in methanol, treated with 2 M aqueous NaOH and sealed tightly. Samples were irradiated (370 W) for 20 s, after 5 min for additional 20 s and extracted with pentane (3 × 4 mL) within the culture tubes. The combined pentane extracts were evaporated to dryness in a gentle stream of high-purity nitrogen. Prior to analysis, samples were dissolved in 4 mL of methanol, filtered through 13 mm syringe filters with 0.5 μm pore diameter, evaporated to dryness in a stream of nitrogen and dissolved in 1 mL of methanol. Chromatographic separation was performed on a Acquity H class UPLC system equipped with a Waters Acquity PDA detector (Milford, MA, USA). The chromatographic separation was performed on an Acquity UPLC® BEH C18 column (Watersy, Dublin, Ireland) (100 mm × 2.1 mm, particle size 1.7 µm) (Watersy, Dublin, Ireland) and eluted with methanol/acetonitrile/water (85:10:5) at a flow rate of 0.4 mL/min. Ergosterol was detected with a Waters Acquity PDA detector (Waters, Milford, MA, USA) set at 282 nm. The presence of ERG was confirmed by a comparison of retention times and by co-injection of every tenth sample with an ergosterol standard [32,35,36,37]. Determining ERG levels was also the subject of household dust studies in which dust from a dust bag was grown to determine the types of fungi formed there, and seasonal variability of conditions was observed with respect to its concentration level. Household dust, through the mechanisms of settling and re-suspending dust in the air, is an exposure to the inhalation of harmful particles along with microorganisms, as are the particles of wood dust in wood processing plants.

2.5. ABTS •+ Method

For ABTS •+ generation from ABTS salt, 3 mM of K2S2O8 was reacted with 8 mM ABTS salt in distilled, deionized water for 16 h at room temperature in the dark. The ABTS •+ solution was then diluted with a pH 7.4 phosphate buffer solution containing 150 mM NaCl (PBS) to obtain an initial absorbance of 1.5 at 730 nm. A fresh ABTS •+ solution was prepared for each analysis. Reaction kinetics was determined over a 2 h period with readings every 15 min. Reactions were complete in 30 min. Samples and standards (100 µm) were reacted with the ABTS •+ solution (2900 µm) for 30 min. Trolox was used as a standard. Results were expressed in ABTS •+ (µmol TROLOX/kg) d.m. sample [32,35,36,37].

3. Results and Discussion

The conducted research was aimed at verifying the hypothesis that the growing of mycobiota in wood dust is influenced by:
  • The conditions in which the wood dust was produced;
  • Dust decomposition degree resulting from processing parameters;
  • Antioxidant activity of the wood from which the dust was formed.
For this purpose, model tests were carried out on dust from various types of wood produced during machine sanding. The level of contamination by microscopic fungi was investigated using the analysis of ergosterol concentration. It is a sterol characteristic for the mycobiotic cell membrane, and the assessment of its content is used as a marker for quantifying the level of fungal contamination of various materials [35,36,37].
The conducted research and the literature on the subject indicate that the biotic components of wood, especially those of an antioxidant nature, have a significant impact on the growth dynamics of microscopic fungi [35,36,37]. In the conducted research, the antioxidant activity of extracts obtained from dusts was analyzed using the reaction with the radical ABTS. Samples of tested dusts with different particle sizes resulting from sanding using sanding papers with two grits were stored for a year in various conditions of temperature and air relative humidity. Apart from the storage parameters and dust particle size, the variable in the experiment was the level of dust contamination by mycobiota. The control samples were characterized by a natural level of mycobiotic contamination, while the second test variant was samples additionally infected with Alternaria alternata spores isolated from wood.
The results of the dynamics of mycobiota growth depending on the storage conditions and the dust particle size for control and inoculated (additionally infected) samples are presented in Figure 1.
Linear growth of the mycobiota over time was found for all sample variants. Moreover, a significantly higher concentration of ERG (i.e., up to 10 times higher) was found in the dust inoculated with A. alternata compared to the samples naturally contaminated with microscopic fungi (control). Increased air temperature and humidity favored the growth of mycobiota. In the case of dusts with smaller particle size, formed during sanding with P180 sanding paper, it was found that mycobiota developed more intensively, as evidenced by a higher concentration of ERG. While analyzing the influence of storage conditions on the development of microscopic fungi, it was found that the dynamic development of the samples of dust inoculated with A. alternata during the year was influenced by temperature. A significantly higher concentration of ERG was observed in the dust samples stored at 20 °C compared to those stored at 6 °C, and the trend was the same for dust created during sanding with both papers (P60 and P180). In the conditions of 90% air relative humidity and 20 °C temperature, a significant increase in the amount of microscopic fungi (measured by the concentration of ERG) was observed in comparison to the control dust samples—a 10-fold increase was observed for dust created during sanding with sanding paper of grit P180 and a 5-fold increase was observed for dust created with P60 sanding paper. Comparing the results in the control dust and inoculated dust samples stored at 90% and 6 °C, the ERG concentration values were 8 and 10 times lower for the dusts created with papers with grits P180 and P60, respectively. Summing up, the changes in ERG concentration indicated a significant influence of temperature on the development of microscopic fungi, especially A. alternata.
The second experimental factor was the dust particle size, the influence of which on the level of ERG concentration was investigated. In the case of the dust created during sanding with sanding paper with P180 grit, a significantly higher concentration of ERG was found compared to the dust created with the P60 paper, on average twice for all analyzed samples. Thus, it was found that the finer the dust, the more dynamic the growth of microscopic fungi (Figure 2).
The growth of microscopic fungi, and wood pathogens in particular, is one of the stressors. Previous research and literature reports indicate that substances contained in wood cells belonging to the group of low-molecular-weight antioxidants fulfill their role even after cutting a tree and subjecting its wood to technological treatment. In this study, the antioxidant activity of wood dust extracts was analyzed at the same time as ERG analysis was performed. A significant inverse relationship was found between the ERG concentration and the antioxidant activity measured by the reaction with the radical ABTS •+ (Table 2).
Results recorded in the course of the conducted chemical analyses were subjected to statistical analysis with the use of STATISTICA v. 13.3 software. The correlation matrix between ergosterol (ERG) concentration and antioxidant activity, measured by the reaction with the radical ABTS, was determined on the basis of the Pearson linear correlation coefficient at the significance level α = 0.05.
This means that the greater the activity of antioxidants or their compounds, the slower the development of microscopic fungi or its inhibition. Antioxidant compounds also showed antimicrobial activity. So far, this phenomenon has not been described in the literature for wood, or for dust. Some types of wood were characterized by higher activity, which was correlated with lower activity of microscopic fungi and their slower growth. The results indicate that the resistance mechanisms of wood were active even after technological processing.

4. Discussion

The type of research presented in this paper has not been conducted so far in terms of the relationship between antioxidant activity, dynamics of microscopic fungi growth, dust particle size and dust storage conditions. The level of dust contamination with microscopic fungi, expressed as ERG concentration, is a characteristic quantity for the type of wood and correlated with the biomass of microscopic fungi. In the case of antioxidant activity, studies have so far been carried out on other organic raw materials, such as grain or straw. These studies showed significant differences between the types of raw materials [38,39,40], which is inextricably linked with the qualitative and quantitative profile of antioxidant bioactive compounds. This research aimed to determine the dependence of the development of microscopic fungi as a function of antioxidant activity in the raw material (i.e., wood dust), representing an original and innovative approach. The relationship between these parameters is known for raw materials other than wood [41,42,43,44]. There was a significant positive correlation between the concentration of antioxidant compounds and the antioxidant activity measured by the reaction with the radical ABTS [36,37,38]. Along with the growth of microscopic fungi, the defense mechanisms of wood dust are activated in the form of the release of low-molecular-weight antioxidants from cells and their introduction into the metabolism of microscopic fungi [45,46,47,48]. This leads to growth inhibition, which was observed in our studies as a decrease in ERG levels. Similar results were obtained by Szablewski et al. (2021) [41]. At the same time, an increase in the antioxidant activity of the test system was observed. On the other hand, if the activity or amount of antioxidant compounds was too low, microscopic fungi grew significantly.

5. Conclusions

It was found that the conditions (humidity and temperature) in which wood dust was stored significantly affected the development of microscopic fungi, especially fungi of the genus Alternaria. Temperature was the more important determining factor, followed by the air relative humidity. The degree of dust fragmentation resulting from the sanding paper grit also had a significant impact on the development of microscopic fungi. Finer dust was more susceptible to the development of microscopic fungi. The antioxidant activity of the wood from which the dust was formed had a significant impact on the development of microscopic fungi. The effect of the antioxidant activity of wood, especially wood dust, has not previously been studied in terms of limiting the growth of microscopic fungi. The obtained results indicate the activity of low-molecular-weight antioxidants in wood/wood dust even when the tree metabolism is not active. Indeed, an inverse relationship was observed, indicating the strong activity of antimicrobial substances.

Author Contributions

Conceptualization, M.P. and T.R.; Formal analysis, M.P.; Funding acquisition, T.R.; Investigation, M.P.; Methodology, A.P.-B., L.S.-M., T.S. and M.B.; Project administration, K.S.-S.; Resources, M.P.; Software, T.R.; Visualization, K.S.-S.; Writing—original draft, M.P., L.S.-M. and T.S.; Writing—review & editing, A.P.-B., T.R. and K.S.-S. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the funding for statutory R&D activities as the research task No. 506.272.02.00 and 506.227.02.00 of the Faculty of Forestry and Wood Technology, Poznań University of Life Sciences.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Department of Furniture Design, Faculty of Forestry and Wood Technology, Poznan University of Life Sciences, Wojska Polskiego St. 38/42, 60-627 Poznan, Poland; [email protected].

Conflicts of Interest

The authors declare no conflict of interest.

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Forests 12 01786 g001a 550Forests 12 01786 g001b 550Forests 12 01786 g001c 550Forests 12 01786 g001d 550
Figure 1. Dynamics of changes in ERG concentration in the dust of various wood species depending on the storage conditions.
Figure 1. Dynamics of changes in ERG concentration in the dust of various wood species depending on the storage conditions.
Forests 12 01786 g001aForests 12 01786 g001bForests 12 01786 g001cForests 12 01786 g001d
Forests 12 01786 g002 550
Figure 2. Dynamics of microscopic fungi development measured with ERG concentration (mg/kg) for averaged results depending on the dust particle size.
Figure 2. Dynamics of microscopic fungi development measured with ERG concentration (mg/kg) for averaged results depending on the dust particle size.
Forests 12 01786 g002
Table
Table 1. Variants of dust storage conditions.
Table 1. Variants of dust storage conditions.
Variant No.Temperature (°C)Air Relative Humidity (%)
12040
22090
3640
4690
Table
Table 2. Correlation coefficient of ERG/ABTS•+.
Table 2. Correlation coefficient of ERG/ABTS•+.
Storage ConditionsVariant03 Months6 Months9 Months12 Months
P60P180P60P180P60P180P60P180P60P180
40% humidity and 20 °CControl−0.70156−0.74993−0.56722–0.71651–0.61991–0.78133–0.74582–0.74499–0.64323–0.81287
Inoculated–0.70156–0.74993–0.60822–0.58257–0.52366–0.80532–0.67543–0.79601–0.81623–0.95139
90% humidity and 20 °CControl–0.70156–0.74993–0.6493–0.58471–0.55785–0.67855–0.85123–0.64394–0.69996–0.95733
Inoculated–0.70156–0.74993–0.87075–0.91542–0.5267–0.76719–0.81554–0.92154–0.9718–0.94241
40% humidity and 6 °CControl–0.70156–0.74993–0.96615–0.43851–0.90089–0.75545–0.82404–0.77952–0.48221–0.93489
Inoculated–0.70156–0.74993–0.57086–0.8677–0.75455–0.8497–0.86293–0.94174–0.89748–0.84046
90% humidity and 6 °CControl–0.70156–0.74993–0.87968–0.71258–0.66778–0.54233–0.79776–0.77902–0.65298–0.8679
Inoculated–0.70156–0.74993–0.72947–0.73028–0.445–0.90683–0.42131–0.78662–0.36581–0.73487
Forests 12 01786 i001 the significance level α = 0.05.
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Pędzik, M.; Przybylska-Balcerek, A.; Szwajkowska-Michałek, L.; Szablewski, T.; Rogoziński, T.; Buśko, M.; Stuper-Szablewska, K. The Dynamics of Mycobiota Development in Various Types of Wood Dust Depending on the Dust Storage Conditions. Forests 2021, 12, 1786. https://doi.org/10.3390/f12121786

AMA Style

Pędzik M, Przybylska-Balcerek A, Szwajkowska-Michałek L, Szablewski T, Rogoziński T, Buśko M, Stuper-Szablewska K. The Dynamics of Mycobiota Development in Various Types of Wood Dust Depending on the Dust Storage Conditions. Forests. 2021; 12(12):1786. https://doi.org/10.3390/f12121786

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Pędzik, Marta, Anna Przybylska-Balcerek, Lidia Szwajkowska-Michałek, Tomasz Szablewski, Tomasz Rogoziński, Maciej Buśko, and Kinga Stuper-Szablewska. 2021. "The Dynamics of Mycobiota Development in Various Types of Wood Dust Depending on the Dust Storage Conditions" Forests 12, no. 12: 1786. https://doi.org/10.3390/f12121786

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