Improving Fungal Decay Resistance of Less Durable Sapwood by Impregnation with Scots Pine Knotwood and Black Locust Heartwood Hydrophilic Extractives with Antifungal or Antioxidant Properties

: Research Highlights: The antifungal assay conﬁrmed that knotwood extractives of Scots pine inhibit the growth of wood decay fungi. Heartwood extracts of black locust were found to be much stronger free radical scavengers than the extracts of Scots pine. The extracts were deposited in the lumina and on the wall surface of cells in the impregnated sapwood. Impregnation of the sapwood blocks with Scots pine and black locust extracts reduced the fungal decay of wood. Objectives: Hydrophilic extracts of Scots pine knotwood and black locust heartwood were chemically analyzed, tested for antifungal and antioxidant properties and used for impregnation of beech and Scots pine sapwood. Materials and Methods: Scots pine knotwood and black locust heartwood were extracted, and obtained hydrophilic extractives were chemically analyzed. Extracts were analyzed for antifungal properties with the in vitro well-di ﬀ usion method. The free radical scavenging activity of wood extracts was measured colorimetrically. The retention of the extracts in the impregnated sapwood blocks was evaluated with microscopy and gravimetry. A decay test was performed with the mini block test. Results: Almost half of both Scots pine knotwood and black locust heartwood hydrophilic extracts obtained were described by phenolic compounds. The extracts were deposited in the lumina of cells and on the cell wall surface. Extractives of Scots pine knotwood had good inhibitory properties against white- and brown-rot fungi. On the other hand, extractives of black locust heartwood were found to be good radical scavengers, better than knotwood extractives of Scots pine. The extracts of Scots pine knotwood and black locust reduced the fungal decay of the tested sapwood blocks. Conclusions: The results of this research show that the less-valued knotwood of Scots pine and heartwood of black locust are a potential source of antifungal and antioxidant agents for bio-based wood preservatives. 400 nm. Peak assignments were achieved by comparing the retention times and UV spectra of the separated compounds to those of analytical standards Quantiﬁcation of identiﬁed compounds was done by comparing peak areas with calibrations made with standards and analyzed under the same conditions. Three chromatograms were recorded for each sample. The results were expressed as average values of all samples analyzed separately for Scots pine knotwood and black locust heartwood. Results are presented in milligrams of total hydrophilic


Introduction
Wood is a source of phytochemicals, also called extractives, which do not combine with structural components of the cell wall and can therefore be removed with polar and nonpolar solvents [1,2]. Wood is a renewable and sustainable polymer composite with several unique properties [3], among which, (bio)degradability is considered to be an advantage in biorefining [4,5], for instance, or a disadvantage in applications in which wood is exposed to unfavorable microenvironmental conditions [6]. The biodegradation of wood can be prevented with construction protection [7] and On the other hand, durable woods of less-utilized tree species could also be a source of extraction of natural bioactive agents. Black locust is an alien and invasive tree species that is well-distributed in certain parts of Europe [34,35]. The heartwood of black locust is characterized by its high natural durability, but it is still most frequently used as "low-value" wood in vineyards and orchards, although it is also used as material in external flooring applications [34,36]. Less literature data is available on black locust wood extractives and their anti-decay properties. Triterpenes and simple sugars (e.g., sucrose, glucose and fructose) and nonstructural carbohydrates (starch); soluble proteins and phenolic compounds such as simple phenols, phenolic acids, stilbenes, flavonoids and condensed tannins have been identified in the tissues of black locust [37][38][39][40][41][42]. Flavonoids dihydrorobinetin (flavanonol), robinetin (flavonol) and derivates of hydroxycinnamic acid have been reported to be the characteristic phenolics compounds present in the hydrophilic extracts of black locust heartwood [38,42,43]. The high natural durability of the heartwood of black locust is frequently explained by the presence of bioactive phenolic extractives [40,41,44]. It has been demonstrated that the decay resistance of normally nondurable wood can be improved after impregnation with extracts of black locust. Smith, Campbell, Walker and Hanover [44] impregnated aspen wafers by soaking them in a methanol solution containing the combined extracts of black locust heartwood (including hexane, ethyl acetate, methanol and aqueous acetone extracts). The authors found that the combined extracts increased the decay resistance of aspen wood against brown-rot fungus Gloeophyllum trabeum [44]. Sablik et al. [45] reported that the impregnation of sapwood of common beech with 50% methanol extract of black locust heartwood (aq, v/v) in a vacuum without an overpressure phase can increase the natural durability of beechwood samples against the white-rot fungus Trametes versicolor. Comprehensive work on the chemistry and possible applications of black locust extractives has been also done by Rademacher et al. [46]. Hosseinihashemi et al. [47] demonstrated that acetone extractives of black locust heartwood exhibited relatively low inhibition activity against white-rot Trametes versicolor; on the other hand, heartwood extractives have been shown to be good 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical scavengers. It has been reported that extractives may protect heartwood wood through fungicidal properties and possibly other nonbiocidal properties, such as free radical scavenging ability, i.e., antioxidants [48].
As already demonstrated by up-to-date findings, antifungal activity measured with antifungal tests on agar cannot fully represent the decay resistance capability [23,[49][50][51][52]. So, if the phytochemical of interest does not show antifungal activity on agar, that does not mean that it is not capable of inhibiting the fungal decay of wood. Schultz and Nicholas [48] reported that extractives in highly durable heartwood have very poor fungicidal activities compared to commercial biocides. It is therefore important that a bio-based preservative contains natural compounds with different bioactive properties to provide sufficient bioactive performances. The literature provides much interesting information on the antifungal efficiency of extractives of both Scots pine and black locust. The reports include either pure compounds [31,33], crude extracts or even fractions [28,45,47]. Testing on pines has also been done with extracts from wood materials of various pine species [28,31,32]. Different impregnation approaches have been reported. Less durable wood has been reported to have been impregnated with wood extractives of Scots pine and black locust in a vacuum [31,33,45], with two-phase impregnation using a vacuum and immersing [28] or soaking the wood in treating solutions [44]. A literature research revealed that information on the retention of extractives and their distribution in an impregnated wood matrix remains fragmentary. All the research reports mentioned indicate that the results on the antifungal efficiency of pine and black locust are actually ambiguous and do not give clear information due to differences in experimental approaches and tests employed.
The aims of the present investigation were therefore to provide a holistic study on antifungal, anti-decay and antioxidant activities of hydrophilic extractives of Scots pine and black locust. Only woody biomasses of forestry debris and less-utilized tree species usually having low market values were thus selected for extraction. The specific goals were (a) to use the knotwood of broken trees and/or heartwood of commercially less interesting tree species for the extraction and analysis of phytochemicals; (b) to use the obtained hydrophilic extractives for the preparation of aqueous treating Forests 2020, 11, 1024 4 of 23 solutions for wood preservation; (c) to impregnate the less durable sapwood of selected conifers and deciduous tree species and retain the extracts in the wood matrix with a two-phase impregnation process that consisted of a vacuum phase and a high-pressure phase; (d) to examine the retention and deposition of the extracts in impregnated wood using gravimetry and microscopy and (e) to perform a series of tests, including in vitro antifungal assay on agar, in vitro decay test on wood blocks and antioxidant test with measuring the radical scavenging activity. Wood-decaying fungi that frequently attack physiologically weakened standing and dead trees were selected, as well as wooden elements in outdoor use and as construction timber. Schizophyllum commune and Fibroporia vaillantii have also been reported to be resistant to several commercial biocides with semidurable wood [53][54][55][56].

Material
Wood of Scots pine (Pinus sylvestris L.) and black locust (Robinia pseudoacacia L.) were included in the present investigation. The materials used in this investigation have already been described in our recent research reports [57,58]. Briefly, six Scots pine trees were felled in a Rožnik urban forest (46 • 03 31.3" N 14 • 29 32.1" E) on 8 April 2014, and six black locust trees in a Panovec urban forest (45 • 56 46.8" N 13 • 40 05.1" E) on 26 January 2016. A number of stem discs were taken at different heights of the stems and transported to a woodworking workshop. Knotwood (or simply knots) of Scots pine and heartwood of black locust were selected as material for extraction for the purposes of this study. Selected tissues were then carefully isolated from the stem disc using a band saw and chisel. Discs taken from the lower part of Scots pine trees contained mostly dead knots, while upper parts contained living knots. Since we tried to simulate a larger-scale sampling for industrial purposes, knots were not separated into knotwood of living and dead branches. Twenty-four knots of the six Scots pine trees were prepared for extraction. Heartwood of black locust was sampled across the sample discs in a radial series. For this investigation, 48 heartwood samples of black locust were selected and prepared for extraction. Collected knotwood and heartwood samples were dried overnight at 50 • C and then ground with a Retsch SM 2000 cutting mill using a 1-mm-bottom sieve. The ground wood was placed in sealed bottles and stored at −25 • C until further analysis.

Extraction
Powders of Scots pine knotwood and black locust heartwood were freeze-dried in a Telstar LyoQuest lyophylizator at 0.040 mbar and −82 • C. The samples were extracted in a Soxhlet apparatus for 6 h at 110 • C. Prior to the extraction with acetone, Scots pine knotwood was extracted with cyclohexane in order to remove lipophilic and resinous matter from the knotwood samples. Acetone was used as a solvent for the extraction of hydrophilic extractives from the samples of both species. Scots pine knotwood was extracted with 95% acetone (aq, v/v) [59], while 90% acetone (aq, v/v) was used for the extraction of heartwood samples of black locust [60]. The acetone extractives of Scots pine and black locust were later used for the preparation of water-based preservative solutions. This meant that only hydrophilic extractives were used for antifungal, antioxidant and decay testing. For sufficient amounts of the hydrophilic extracts for the preparation of the treating solutions, each of the 72 samples was extracted two to three times. The obtained extracts were stored in the dark at −25 • C until further analysis with gravimetry, spectrophotometry and chromatography. After the chemical analysis, all the acetone extracts were combined and the mass aliquots were mixed separately for Scots pine knotwood and black locust heartwood. Two homogenized hydrophilic extracts were thus prepared, i.e., hydrophilic knotwood extract of Scots pine (KWE) and hydrophilic heartwood extract of black locust (HWE). KWE and HWE were freeze-dried in a lyophylizator as described above and stored in the dark at −24 • C.

Chemical Analysis of Extractives
The focus here was hydrophilic extractives. All the obtained acetone extracts were qualitatively and quantitatively evaluated for hydrophilic extractives by gravimetry, spectrophotometry and chromatography in order to get information on the amount of total hydrophilic extractives, total phenols and targeted stilbenes and flavonoids. As already mentioned, after the chemical analysis, the extracts were homogenized into KWE and HWE, as described above.
The protocol for the chemical analysis of wood extractives that was applied in this investigation was already described [61,62], and it is briefly summarized below. For assessment of the content of total hydrophilic extractives that were gained from knotwood and heartwood samples, 10 mL of each acetone extract was oven-dried at 105 • C to a constant mass.
For the determination of total phenols in extracts, a diluted 2N Folin-Ciocalteu's phenol reagent (aq) and an aqueous solution of sodium carbonate (75 g/L) were added to each of the wood extracts [63,64]. After two hours incubation of the reaction mixtures, the absorbance was measured at 765 nm. The content of total phenols was expressed in gallic acid mass equivalents (mg GAE).
For a quality check of extracts with HPLC (high-performance liquid chromatography), all individual knotwood and heartwood extracts, as well as homogenized KWE and HWE, were redissolved and diluted in methanol (HPLC grade) and filtered through a 0.22-µm polyamide syringe filter into 1.5-mL amber HPLC vials. The compounds were separated on a Thermo Scientific Accucore ODS column (4.6 mm internal diameter × 150 mm, 2.6 µm particle size). Sample trays and a column oven were thermostated at 5 • C and 30 • C, respectively. Water (A) and methanol (B), both containing 0.1% of formic acid (v/v), were used as the mobile phase. A gradient from 5% to 95% of solvent B in 20 min was applied for elution of the targeted molecules. The flow rate of the mobile phase was 1000 mL/min, and the total time per run was 30.2 min. The wavelength for monitoring the phenolic compounds was set at 280 nm, and UV spectra were recorded from 200 nm to 400 nm. Peak assignments were achieved by comparing the retention times and UV spectra of the separated compounds to those of analytical standards [21,62]. Quantification of identified compounds was done by comparing peak areas with calibrations made with standards and analyzed under the same conditions. Three chromatograms were recorded for each sample.
The results were expressed as average values of all samples analyzed separately for Scots pine knotwood and black locust heartwood. Results are presented in milligrams of total hydrophilic extractives, total phenols, pinosylvin, pinosylvin monomethyl ether robinetin and dihydrorobinetin that were extracted from one gram of dry material (mg g −1 , dw).
Before being tested on the wood-decaying fungi, KWE and HWE were again qualitatively checked for stilbenes and flavonoids by HPLC analysis.

Preparation of Treating Solutions for Antifungal and Decay Testing
Pure compounds, i.e., pinosylvin (PS), pinosylvin monomethyl ether (PSMME), dihydrorobinetin (DHR) and robinetin (Rob), and hydrophilic extracts of Scots pine knotwood (KWE) and black locust heartwood (HWE) were included in antifungal, decay and antioxidant testing. Pinosylvins were reported to be bioactive compounds [65] and were treated as reference compounds in the present study, in which their properties were compared with robinetins of black locust. The pure compounds (PS, PSMME, DHR and Rob) and the homogenized hydrophilic extracts (KWE and HWE) were freeze-dried in a lyophilizator, as described above. Extractives were then redissolved in dimethyl sulfoxide (DMSO) (for the in vitro antifungal assay) and in water (for the decay assay). KWE and HWE were prepared in two concentrations for the in vitro antifungal assay, as 1% (KWE1 and HWE1) and 5% (KWE5 and HWE5) dimethyl sulfoxide solutions (w/v). Since purified compounds are more difficult to purchase, pinosylvins and robinetins were only prepared as a 1% solution in DMSO. For the decay test, the aqueous treating solutions containing KWE and HWE were prepared in a concentration of 1% (w/v). All the prepared mixtures were then homogenized with overnight stirring and with 15-min sonication at room temperature in a Bandelin electronic RK 512 H ultrasonic bath. The treating solutions containing wood extractives were stored in amber glass bottles and placed in a refrigerator.

Fungal Cultures
The white-rot fungi Trametes versicolor and Schizophyllum commune (ZIM L039) and brown-rot fungi Gloeophyllum trabeum (ZIM L018) and Fibroporia vaillantii (ZIM L037) were used for the in vitro agar diffusion test. Trametes versicolor and Gloeophyllum trabeum were included in the wood block decay test (decay test). All the fungi used were available in the culture collection of industrial microorganisms of the Biotechnical Faculty, University of Ljubljana [66]. Each fungus was maintained on a previously prepared Petri dish containing potato dextrose agar (PDA, Difco™ Potato Dextrose Agar, Becton, Dickinson and Company (BD), Sparks, MD, USA). The white-and brown-rot fungi were incubated in a growth chamber at 25 • C and 85% relative humidity (RH) for one week [56].

Antifungal Assay
The inhibition effect of Scots pine and black locust extractives on the growth of selected white-rot (T. versicolor and S. commune) and brown-rot fungi (G. trabeum and F. vaillantii) was investigated with an in vitro agar well-diffusion method. Briefly, testing solutions of pinosylvin (PS), pinosylvin monomethyl ether (PSMME), dihydrorobinetin (DHR) and robinetin (Rob) and solutions of hydrophilic extracts of Scots pine (KWE1 and KWE5) and black locust (HWE1 and HWE5) were prepared with DMSO. The assay with each of the four fungi was performed on 6 replicates. After autoclaving (p = 220 kPa, T = 121 • C), three holes with a diameter of 8 mm were bored in potato dextrose agar in a Petri dish, and 1 milligram of PS, PSMME, DHR, Rob and hydrophilic KWE and HWE extracts was transferred into the wells. The center of each of the three wells was placed 10 mm from the edge of the Petri dish. Pure solvent was used in the same volume as for the control. White-and brown-rot fungal inoculums were placed in the center of the Petri dish and stored in a growth chamber, in which incubation followed at 25 • C and 75% relative humidity [67]. Growth of the mycelium toward the sites with pinosylvins, robinetins and hydrophilic extracts was measured every 2 to 3 days with a digital Vernier caliper (±0.01 mm). Fungal growth was determined by measuring the radius of the fungal colony in every direction after subtracting the radius of the inoculum plug. The radial growth of Forests 2020, 11, 1024 7 of 23 the mycelium was measured until the mycelium grew to the edge of the Petri dish in one direction. The results were expressed as the percentage of fungal growth inhibition in a radial direction (FI) and calculated using the following equation: where R m (mm) distance between the edge of the Petri dish and the mycelia, and R 0 (mm) is the distance between the edge of the Petri dish and the edge of the inoculum.

Impregnation of Wood Blocks for Decay Assay
A decay test was carried out on sapwood samples of European beech (Fagus sylvatica) and Scots pine (Pinus sylvestris). Beech and Scots pine sapwood blocks were prepared from commercially available sawn timber. Specimen dimensions were 15 mm (w) × 10 mm (h) × 40 mm (l), and 6 replicates per fungus were used in the decay test. Prior to impregnation, rough edges of the wood blocks were sanded, and samples were then oven-dried at 105 • C to constant mass. Six wood blocks were placed in a glass beaker in which a plastic mesh was used to prevent direct contact between the wood blocks during the impregnation process. The aqueous solution of Scots pine KWE and black locust HWE were injected into the beakers. Distilled water was used for the impregnation of wood blocks that served as a control. The impregnation of the wood blocks was done in a vacuum-pressure chamber (Kambič Laboratory & Process Equipment, Semič, Slovenia). The samples were first exposed to a vacuum at 0.9 kPa for 240 min, followed by the main impregnation phase at 900 kPa for 240 min. Impregnated wood blocks were then oven-dried at 105 • C to constant weight.

Decay Test
The decay test was done according to the modified EN 113 standard protocol (CEN, 2006). The mini block test [68,69] was performed for evaluating the decay-retaining properties of Scots pine KWE and black locust HWE on a wood substrate. A Petri dish (dimensions of Ø = 85 mm, h = 21 mm) containing 20-mL 3.9% (aq, w/v) Difco™ Potato Dextrose Agar (Becton, Dickinson and Company (BD), Sparks, MD, USA) was inoculated with wood-decaying fungi. All the impregnated wood blocks were autoclaved for 20 min at 220 kPa and 121 • C before being exposed to the wood-decaying fungi. Wood samples were then carefully placed in a Petri dish containing 0.8 g of PDA with a thin film of fungus mycelium. A plastic mesh was used to avoid direct contact between the impregnated wood blocks and the growth medium. The assembled test dishes were then incubated at 25 • C and 80% relative humidity (RH) for 12 weeks. After incubation, the fungal mycelium was removed from the surface of the wood blocks. Samples were then dried at 105 • C to constant weight. Mass loss (ML) was determined for control and impregnated wood blocks gravimetrically using the following equation: where m dw,1 (g) is the mass of the wood block before being exposed to wood decaying fungi, and m dw,2 (g) is the mass of the decayed wood block.

Sample Preparation
In order to assess the impregnation efficiency and occurrence of extractives in impregnated wood blocks, additional beech and Scots pine sapwood blocks, measuring 5 mm × 5 mm × 5 mm, were treated with KWE and HWE. Sapwood blocks were impregnated with a water solution of KWE and HWE in a vacuum-pressure chamber. Impregnated sapwood blocks were trimmed with a sliding microtome (Leica SM2010R) on the axial and tangential surfaces. Samples were then dried for 72 h in a vacuum chamber at 10 kPa and room temperature. Untreated/nonimpregnated beech and Scots pine sapwood served as controls. Confocal laser scanning microscope (CLSM) and scanning electron microscopy (SEM) were used for observation.

Confocal Laser Scanning Microscope (CLSM)
Dried samples were observed under a CLSM (LEXT OLS5000 3D, Olympus Corporation, Tokyo, 163-0914, Japan) with the following objectives: MPLFLN5x (numerical aperture 0.15, working distance 20), MPLFLN10xLEXT (numerical aperture 0.3, working distance 10.4), MPLAPON20xLEXT (numerical aperture 0.6, working distance 1) and MPLAPON50xLEXT (numerical aperture 0.95, working distance 0.35). Color digital images were acquired using wood autofluorescence and using polarized light. CLSM enabled color images to be obtained to observe the different appearance of wood with and without extracts.

Scanning Electron Microscopy (SEM)
Dried samples were mounted on stubs with a conductive carbon adhesive, Table 1. Samples were then coated with Au/Pd sputter-coater (Q150R ES Coating System; Quorum Technologies, Laughton, UK) for 30 s with 20-mA intensity, after which, SEM micrographs were taken at 5-kV voltage under both high and low vacuum conditions with an Everhart-Thornley (ETD) detector in a FEI Quanta 250 SEM microscope (FEI Company, Hillsboro, OR, USA) at a working distance between 9 and 11 mm. Results are expressed as the mean value of measurements (mean) with standard deviations (SD). * An asterisk indicates a statistically significant difference in the content of total phenols between knotwood samples of Scots pine and heartwood samples of black locust at a 95.0% confidence level (Fisher's least significant difference procedure).

Assessment of Impregnation Efficiency with Gravimetry
In the context of the above-described impregnation of beechwood and pinewood blocks for the decay test, the retention of the extracts in the wood blocks was also measured by gravimetric analysis. Wood blocks were oven-dried at 105 • C to constant weight before and after impregnation. The amount of retained extract in the wood was expressed by the percentage of gained weight (%), as presented by the equation below [69].
where m dw (g) is the mass of the dried wood block (g), and m dw,imp (g) is the mass of the impregnated and dried wood block (g).

Antioxidant Assay (a DPPH Radical Scavenging Activity)
The 2,2-diphenyl-1-picrylhydrazyl (DPPH) radical scavenging activity of Scots pine KWE and black locust HWE were measured according to the modified method as described [50,[70][71][72]. KWE and HWE were redissolved in water. Aqueous solutions of gallic acid (GA), ascorbic acid (AA) and butylhydroxyanisole (BHA) were used as reference. The solutions of KWE and HWE and reference antioxidants were tested for antioxidant activity in five testing concentrations, i.e., 1000 mg L −1 , 500 mg L −1 , 250 mg L −1 , 100 mg L −1 and 50 mg L −1 . Water alone was used as a control. A 2.25 mL of DPPH methanol solution (40 mg L −1 , MeOH) was mixed with 0.090 mL of the aqueous solutions of the hydrophilic wood extracts and the reference antioxidants. The reaction was performed in a 4.5-mL disposable macro cell closed with a 10 × 10-mm polyethylene lid. The reaction mixtures were then incubated in the dark at room temperature for 30 min. The macro cell was directly placed in a UV-Vis spectrophotometer Lambda (Perkin Elmer, Waltham, MA, USA) after incubation, and the reduction of DPPH radical was measured by taking absorbance at 517 nm. The measurements were taken in triplicate. The DPPH radical scavenging activity (RSA) was measured on the basis of the color change of the DPPH solution. Results were calculated using the equation: where A 517 nm,DPPH is the absorbance at 517 nm of the control DPPH solution, and A 517 nm,S is the absorbance at 517 nm of the wood extract and/or reference antioxidant.

Statistics
The results of the present investigation were analyzed for statistical significance by Statgraphics software. The data were first checked for normal distribution. ANOVA was used to test differences between the means of measurements, and Fisher's least significant difference (LSD) procedure was performed to indicate which means were significantly different from others at a 95.0% confidence level.

Extraction Yields and Chemical Composition of Extracts
The quantities of compounds extracted from knotwood samples of Scots pine and heartwood samples of black locust are presented in Table 1. One gram of the wood material gave comparable amounts of total hydrophilic extractives (THE), i.e., 72.78 mg THE for Scots pine knotwood and 61.83 mg THE for black locust heartwood (ANOVA, p > 0.050). In comparison to the black locust samples, extraction of Scots pine knotwood yielded significantly larger amounts of total phenols (Table 1) (ANOVA, p < 0.050). The characteristic and most abundant compound of knotwood hydrophilic extracts of Scots pine was pinosylvin monomethyl ether (PSMME) (Figures 1 and 2). DHR was the characteristic compound of the acetone extracts of black locust heartwood (Figures 1 and 3). Results are expressed as the mean value of measurements (mean) with standard deviations (SD). * An asterisk indicates a statistically significant difference in the content of total phenols between knotwood samples of Scots pine and heartwood samples of black locust at a 95.0% confidence level (Fisher's least significant difference procedure).   For fungal, antioxidant and decay testing, 13.09 g of KWE and 14.84 g of dried HWE were prepared. The chemical composition of the two homogenized extracts are presented in Figure 1. The homogenized hydrophilic extract of Scots pine knotwood (KWE) contained larger amounts of total phenols (46%) than the homogenized hydrophilic extract of black locust heartwood (HWE) (40% of HWE). KWE consisted of 15% PS and 24% PSMME, while HWE was characterized by 7% Rob and 29% DHR (Figure 1). Further investigation revealed that almost 72% of the total phenols (TP) in HWE are described by DHR. In terms of KWE of Scots pine, the share of PSMME in the TP of Scots pine  compounds were characterized by a weak detector response (Figure 2). A HPLC trace of HWE showed three unidentified compounds eluted between DHR and Rob, i.e., between tr = 7.5 min and tr = 10 min (Figure 3).

Occurrence of Extractives and Gained Weight after Impregnation of Wood Blocks
CLSM and SEM demonstrated that KWE and HWE were introduced and retained in the sapwood of beech and Scots pine (Figures 4-7). CLSM microscopy revealed HWE as yellowish deposits on the surface of the longitudinal sections of both beech ( Figure 4) and Scots pine sapwood ( Figure 5). The wood surface treated with KWE was slightly darker (Figures 4d and 5d) in comparison to the untreated wood (Figures 4c and 5c). For fungal, antioxidant and decay testing, 13.09 g of KWE and 14.84 g of dried HWE were prepared. The chemical composition of the two homogenized extracts are presented in Figure 1. The homogenized hydrophilic extract of Scots pine knotwood (KWE) contained larger amounts of total phenols (46%) than the homogenized hydrophilic extract of black locust heartwood (HWE) (40% of HWE). KWE consisted of 15% PS and 24% PSMME, while HWE was characterized by 7% Rob and 29% DHR (Figure 1). Further investigation revealed that almost 72% of the total phenols (TP) in HWE are described by DHR. In terms of KWE of Scots pine, the share of PSMME in the TP of Scots pine KWE was 53%, and the proportion of PS was 32% in the TP.
In addition to PS and PSMME, nortrachelogenin, pinostilbene, pinocembrin and pterostilbene were identified in KWE by HPLC analysis (Figure 2). HPLC peaks that were assigned to these compounds were characterized by a weak detector response (Figure 2). A HPLC trace of HWE showed three unidentified compounds eluted between DHR and Rob, i.e., between tr = 7.5 min and tr = 10 min (Figure 3).

Occurrence of Extractives and Gained Weight after Impregnation of Wood Blocks
CLSM and SEM demonstrated that KWE and HWE were introduced and retained in the sapwood of beech and Scots pine (Figures 4-7). CLSM microscopy revealed HWE as yellowish deposits on the surface of the longitudinal sections of both beech ( Figure 4) and Scots pine sapwood ( Figure 5). The wood surface treated with KWE was slightly darker (Figures 4d and 5d) in comparison to the untreated wood (Figures 4c and 5c).           More detailed information on the impregnation efficiency of pinewood and beechwood with the two extracts was obtained by SEM analysis. In wood blocks treated with HWE, crystal-like structures were observed in the lumina of cells (Figure 8). Due to albescence of these structures in the wood of the control samples, we assume that they represent dry HWE. Drying was a necessary step in the preparation of samples for SEM. HWE was deposited in the form of crystal-like structures in the lumina of vessels, fiber tracheids (Figures 6c and 8a) and ray parenchyma cells (Figure 6d), as well as on the surface of the transversely cut cell walls in beech (Figures 6c,d and 8a). In Scots pine sapwood, HWE occurred in the lumina of earlywood tracheids and in the lumina of ray parenchyma (Figures  7c,d and 8c,d). More detailed information on the impregnation efficiency of pinewood and beechwood with the two extracts was obtained by SEM analysis. In wood blocks treated with HWE, crystal-like structures were observed in the lumina of cells (Figure 8). Due to albescence of these structures in the wood of the control samples, we assume that they represent dry HWE. Drying was a necessary step in the preparation of samples for SEM. HWE was deposited in the form of crystal-like structures in the lumina of vessels, fiber tracheids (Figures 6c and 8a) and ray parenchyma cells (Figure 6d  In wood blocks treated with KWE, an opaque layer was observed, covering the cell walls of the vessels, fiber tracheids and parenchyma in beech (Figures 6e,f), as well as the walls of tracheids and parenchyma in Scots pine (Figure 7e,f). This layer was absent from the control wood samples (Figures  6a,b and 7a,b).
Data for the GW (Table 2) show that the uptakes of the two treating solutions were significantly different in beechwood and pinewood (ANOVA, p < 0.050). Uptakes of KWE and HWE in Scots pine sapwood were higher than those for beechwood (LSD test) ( Table 2) under the same impregnation conditions. These results could be ascribed to the higher porosity and longitudinal permeability of pine wood [73]. The highest GW of the wood samples was achieved by impregnation with HWE (LSD test) ( Table 2). We assume that this is explained by the higher polarity of HWE extractives (chemical structures of DHR and Rob on Figure 3) and, consequently, by the higher solubility and retention of DHR and Rob flavonoids on the hydrophilic cell wall substrate. The presence of partially nonpolar compounds (e.g., PSMME) in the Scots pine hydrophilic extracts can be explained by a lower uptake of the KWE-treating solution ( Table 2) [74][75][76]. Table 2. Gained weight (GW, %) for impregnated beech and Scots pine sapwood.

Sapwood Blocks GW (%) KWE GW (%) HWE
Fagus sylvatica 0.52 ± 0.07 a 0.84 ± 0.09 b Pinus sylvestris 0.61 ± 0.14 a 1.06 ± 0.14 c Results are expressed as the mean value of the measurements with standard deviations. ( a-c ) Different letters indicate statistically significant differences at a 95.0% confidence level (Fisher's least significant difference procedure). GW (%, w/w), gained weight representing the amount of retained extract in the wood blocks. In wood blocks treated with KWE, an opaque layer was observed, covering the cell walls of the vessels, fiber tracheids and parenchyma in beech (Figure 6e,f), as well as the walls of tracheids and parenchyma in Scots pine (Figure 7e,f). This layer was absent from the control wood samples (Figure 6a,b and Figure 7a,b).
Data for the GW (Table 2) show that the uptakes of the two treating solutions were significantly different in beechwood and pinewood (ANOVA, p < 0.050). Uptakes of KWE and HWE in Scots pine sapwood were higher than those for beechwood (LSD test) ( Table 2) under the same impregnation conditions. These results could be ascribed to the higher porosity and longitudinal permeability of pine wood [73]. The highest GW of the wood samples was achieved by impregnation with HWE (LSD test) ( Table 2). We assume that this is explained by the higher polarity of HWE extractives (chemical structures of DHR and Rob on Figure 3) and, consequently, by the higher solubility and retention of DHR and Rob flavonoids on the hydrophilic cell wall substrate. The presence of partially nonpolar compounds (e.g., PSMME) in the Scots pine hydrophilic extracts can be explained by a lower uptake of the KWE-treating solution ( Table 2) [74][75][76]. Table 2. Gained weight (GW, %) for impregnated beech and Scots pine sapwood.

Sapwood Blocks GW (%) KWE GW (%) HWE
Fagus sylvatica 0.52 ± 0.07 a 0.84 ± 0.09 b Pinus sylvestris 0.61 ± 0.14 a 1.06 ± 0.14 c Results are expressed as the mean value of the measurements with standard deviations. ( a-c ) Different letters indicate statistically significant differences at a 95.0% confidence level (Fisher's least significant difference procedure). GW (%, w/w), gained weight representing the amount of retained extract in the wood blocks.

Fungal Growth Inhibition of Scots Pine and Black Locust Extractives
The antifungal in vitro assay showed significant differences in fungal growth inhibition (FI) among the tested compounds and KWE and HWE (ANOVA, p < 0.001). The largest FI was shown by PS and PSMME (LSD test). The inhibition was especially conspicuous against the growth of G. trabeum ( Table 3). The FI of PS was weaker than that shown by PSMME (Table 3). Table 3. Fungal growth inhibition (FI, %) of white-rot and brown-rot-producing fungi by pure compounds (PS, PSMME, DHR and Rob) and HWE and KWE.
A 5% water solution of Scots pine knotwood extract (KWE5) had better FI than KWE1. The higher concentration of KWE used in plate tests played a significant role in the FI of S. commune and G. trabeum. The amount of KWE did not have a significant influence on the growth of T. versicolor and F. vaillantii. KWE5 had weaker FI than PSMME and comparable antifungal properties to pure PS (LSD test). KWE5 showed greater FI towards the G. trabeum than pure PS (LSD test). The growth of brown-rot fungi G. trabeum and F. vaillantii was affected to the same extent using either pure PS or KWE1 (LSD test). The results of the test on plates did not show any fungicidal properties of DHR, Rob and hydrophilic extracts of black locust heartwood (HWE1 and HWE5) ( Table 3). The black locust extractives did inhibit the growth of F. vaillantii; however, their FI were found to be irrelevant when compared with the knotwood extractives of Scots pine (Table 3).

Decay Resistance of Wood Impregnated with Scots Pine and Black Locust Extractives
The decay assay with the mini block test showed a significant influence of KWE and HWE on the mass loss (ML) of beech and pine sapwood exposed to the wood-decaying fungi ( Table 4). The ML of the impregnated beech and pine sapwood exposed to Trametes versicolor was not significantly different from that of the control samples (Table 4). T. versicolor is considered to be a nonselective type of fungus, which is capable of degrading all the structural components of a woody cell wall, viz., lignin and hemicelluloses, as well as cellulose [77]. On the other hand, T. versicolor is also known to be a better degrader of hardwoods and to have a limited effect on softwoods. This is in accordance with our results, in which the ML of nontreated beechwood blocks exposed to T. versicolor was significantly larger than the ML of pinewood control blocks ( Table 4). The exact opposite was found for the impregnated wood blocks exposed to Gloeophyllum trabeum. Here, a significantly smaller ML was found for KWE and HWE-impregnated beech and Scots pine wood than for the corresponding control samples (Table 4) (LSD test). The decay assay showed a small ML, especially in the case of Scots pine sapwood impregnated with HWE ( Table 4). The ML for KWE and HWE-impregnated Scots pine and beech sapwood samples exposed to G. trabeum were comparable.

Radical Scavenging Activity of Wood Extracts
HWE showed higher DPPH free radical scavenging activity (RSA) than KWE in the whole concentration range tested ( Figure 9). HWE exhibited higher RSA than ascorbic acid and comparable to butylhydroxyanisole even at lower concentrations, i.e., at 50 mg L −1 and 100 mg L −1 (Figure 9) (LSD test). The RSA of HWE was comparable to the RSA of gallic acid and ascorbic acid at concentrations of 250 mg L −1 , 500 mg L −1 and 1000 mg L −1 . Butylhydroxyanisole possessed comparable RSA only at 500 mg L −1 and at 1000 mg L −1 . The best RSA was shown by gallic acid (GA) (LSD test). KWE exhibited the lowest RSA among the tested compounds.

Radical Scavenging Activity of Wood Extracts
HWE showed higher DPPH free radical scavenging activity (RSA) than KWE in the whole concentration range tested ( Figure 9). HWE exhibited higher RSA than ascorbic acid and comparable to butylhydroxyanisole even at lower concentrations, i.e., at 50 mg L −1 and 100 mg L −1 (Figure 9) (LSD test). The RSA of HWE was comparable to the RSA of gallic acid and ascorbic acid at concentrations of 250 mg L −1 , 500 mg L −1 and 1000 mg L −1 . Butylhydroxyanisole possessed comparable RSA only at 500 mg L −1 and at 1000 mg L −1 . The best RSA was shown by gallic acid (GA) (LSD test). KWE exhibited the lowest RSA among the tested compounds. Knotwood hydrophilic extractives of Scots pine (KWE) and pure pinosylvins (PS and PSMME) showed significant fungal inhibitions that were demonstrated by both the test on plates and the decay assay (Table 3). On the other hand, they were not good DPPH radical scavengers (Figure 9). The Knotwood hydrophilic extractives of Scots pine (KWE) and pure pinosylvins (PS and PSMME) showed significant fungal inhibitions that were demonstrated by both the test on plates and the decay assay (Table 3). On the other hand, they were not good DPPH radical scavengers (Figure 9). The mechanisms by which stilbene-type molecules inhibit the growth of wood-decaying fungi may differ significantly with regard to their chemical structure and polarity. The protection role of phenolic extractives in wood could be explained by both fungicidal and nonbiocidal properties. The latter are radical scavenging (antioxidant) activity and the ability of a compound to form a complex with metals (metal chelators) [78]. A literature review showed that pinosylvins have already been reported to be phytoalexins or bioactive phytochemicals with antioxidant and antifungal properties [23,[26][27][28]65,79]. Knotwood extracts of Sots pine have also been reported to have an influence against Fenton-type degradation [23].
In contrast to pure pinosylvins (PS and PSMME) and KWE, the performed antifungal assay showed that black locust extractives did not inhibit the growth of fungi at all (Table 3). Phenolic extractives have been reported to have an important influence on the natural durability of black locust heartwood [41,42,45]. On the other hand, the HWE showed quite impressive antioxidant properties, even better than some commercial antioxidants (Figure 9). Not only antioxidant properties but good free radical scavenging has been demonstrated for a fraction isolated from the crude acetone extract of black locust heartwood containing alkanes, simple phenols, phthalates and fatty acids [47]. In addition to the described antifungal mechanisms, the ability of a molecule for radical scavenging has already been reported to be an important factor that restricts fungal decay [23,50]. Radical scavenging activity has been reported to be an important defense mechanism against both white-and brown-rot fungi. It has been suggested that wood-decaying fungi use nonenzymatic agents for the degradation of the wood cell wall, viz., free radicals produced by the Fenton reaction [23,26,80]. Particularly brown-rot decaying fungi are known to use free radicals in order initially to disrupt the cell walls to increase the pore size so that the relatively large extracellular fungal enzymes can penetrate the cell wall [20,48,54,81,82]. The results of our investigation suggest that the hydrophilic extractives of black locust heartwood have an important impact on the resistance of wood against wood-decaying fungi, primarily through their antioxidant activity rather than antifungal properties.
Wood degradation by fungi often also involves various metals, either in free form or as key components of enzymes [78]. The radical scavenging activity of pine extractives has been recognized to be more important than their interactions with iron [23]. The importance of the antioxidant activity was also demonstrated by the results of this investigation. In addition to having high antioxidant activity (RSA) potential, the sapwood blocks impregnated with HWE exhibited significantly lower ML than that of the nonimpregnated materials. The antioxidant properties of the extractives could therefore be understood as very important for the development of potential bio-based wood preservatives. Black locust extractives showed a completely opposite effect on the growth of fungi when they were tested on potato dextrose agar in Petri dishes or when they were tested as wood preservatives of sapwood blocks of beech and Scots pine. This could be explained by the fact that nonenzymatic agents that are produced by fungi are not needed for the degradation of the PDA growth media constituents, i.e., potato starch (4 g L −1 ), dextrose (20 g L −1 ) and agar (15 g L −1 ). Fungus hyphae can therefore absorb the substrate as it is, without mobilizing free radicals and extracellular enzymes. Extractives of black locust, with their antioxidant properties, thus had no important antifungal effect in the Petri dish test and were easily overgrown by the fungi. On the other hand, black locust extractives had a major influence on the decay resistance of impregnated sapwood blocks of beech and Scots pine. It can be assumed that heartwood extractives of black locust, with the high radical scavenging activity measured, make the extracellular enzymes of fungi inactive.

Conclusions
Our study demonstrated that forestry residues and woods of underutilized tree species should be considered to a greater extent as a potential source of natural bioactive compounds with applicable potentials. It can be speculated that wood extractives could also be combined for a synergistic effect, with the goal of developing a benign wood preservative made of "eco-friendly" antioxidants, fungicides and water repellents. The potential of combining commercial antioxidants and biocides has already been shown, with interesting results of synergism [14,48,51,52,78]. Phytochemicals from wood are foreseen in the formulations of preservatives as bioactive agents, although they are not at the moment able to compete with synthetic chemicals, characterized by low production costs and long-term efficiency. Some other drawbacks of using natural bioactive compounds for wood preservation are also reflected in the sufficient retention of bioactive compounds in the wood matrix, their susceptibility to degradation and potential cytotoxicological and ecotoxicological threats. The results of the investigation showed the impregnation of less durable sapwood with Scots pine and black locust extracts; these were deposited in the lumina and on the wall surface of cells of the impregnated wood and reduced the fungal decay of the wood. Furthermore, Scots pine extractives were demonstrated as good inhibitors of fungal growth, while black locust extractives were strong free radical scavengers. These findings represent an important step towards the development of bio-based wood preservatives that include extractives from Scots pine and black locust woody biomasses.